Generating device of high-temperature thermal radiator storage (versions)

FIELD: machine building.

SUBSTANCE: pipe (4) has lower section, in fact in the form of pyramid, and upper section forming cylindrical section (4a) which is extended upwards with the specified size and located in ceiling part of building (3) of temporary storage facility (1) for hot-rolled roll (2) which is a semi-finished product from iron and steel, which acts as high-temperature thermal radiator, which is made using the hot rolling equipment of steel mill. Electric generating turbine (5) is located in the specified position in cylindrical section. Plenum duct (7) is located on lower end section of side walls of the building. Hot-rolled rolls which are under high-temperature conditions after manufacture are supplied subsequently to the roll storage facility and stored there till they are moved to be used at the next processing stage. Ascending air flow is formed by subsequent heating of the air supplied to the building through plenum duct using the heat retained in hot-rolled rolls. Electric generating turbines are rotated by ascending air flow.

EFFECT: heat retained in thermal radiator can be used effectively, ie heat recovery is performed.

14 cl, 17 dwg

 

The technical field to which the invention relates.

The present invention relates to a generating device storage high temperature of the radiator, which is arranged to provide heat recovery held high temperature radiator that is cooled by natural heat radiation after fabrication in high temperature condition in the different types of equipment, thereby ensuring the efficient use of heat to generate electricity.

The level of technology

In General, at the metallurgical plant with a full cycle, working on their own raw materials, after fabrication steel molten steel is continuously poured so as to form a billet, such as a slab or the like, then the steel billet is subjected to hot rolling, and laminated sheet plate shaped in the form of hot-rolled coil, rolled. Then it is made of iron or steel product, such as steel, by exposure to hot-rolled coils predetermined processing such as cold rolling or the like

Thus, the temperature of the steel workpiece, such as a slab or the like, which continuously molded during manufacture of iron or steel products reaches more than 1000C directly the NGOs after fabrication. Therefore, steel billet, such as a slab or the like, is transferred to storage such as a warehouse slabs, for temporary storage prior to transfer to the next rolling process and the residual heat in the steel workpiece, such as a slab, caused by continuous casting, is radiated. Typically, the workpiece is transferred to the next process in the order in which they arrive in store.

Moreover, since the hot-rolled coils directly after production reaches a high temperature of 500-600C, they are transferred to the warehouse for rolls for radiation residual heat caused by hot rolling process, and temporarily stored prior to transfer to the next process. Usually hot-rolled coils are transferred to the next process in the order in which they arrive at the warehouse for the rolls.

Were the proposed building of a thermal power plant and generation system wind power, in which the means for generating wind power, which generates electricity using air currents created by the heat from the equipment to generate electricity, and the exhaust port, through which the produced air flow is provided in the building thermal power plants, which hold the equipment to generate electricity. Moreover, this system also offers the design of the building th the howl of a power plant with a boiler room or engine room. According to the building thermal power plants and systems for the generation of wind energy the heat produced by the equipment for power generation, located in the building of a thermal power plant, can be used to generate electricity by means of generation of wind energy, which uses air currents produced by the air heated by thermal radiation (for example, see Patent document 1).

Moreover, it was suggested that one of the power block, which makes efficient use of solar energy devices with the exhaust channel to generate electricity, which is formed by the solar collector, which uses solar radiation to heat the air exhaust channel (pipe), which introduces the air heated by the solar collector, to thereby produce an upward air flow, due to the lifting force of heated air, and electricity generating turbine, which is located in the exhaust duct and generates electricity using air currents generated in the exhaust duct (for example, see Patent document 2).

[Patent document 1] patent application Japan, first publication No. 2006-77676

[Patent document 2] the patent application of Japan, first publication No. 2007-77941.

Disclosure of invention

Task resh is by the invention of

However, at the metallurgical plant with a full cycle, working on their own raw materials, although a large amount of heat is introduced during the manufacture of semi-finished products of iron and steel, hot-rolled coils or the like, or steel workpieces, such as slabs, the residual heat in the semi-finished products of iron and steel, fabricated at high temperature, radiates only in the atmosphere and is not used in any effective way. However, due to the reduction of emissions of CO2that has become a problem in recent years, it is desirable that the heat radiated from the semi-finished products of iron and steel, fabricated at high temperature, the introduction of heat, as described above, recuperariamos and efficiently used as energy.

As a result, similar to building a thermal power plant and the system of generation of wind energy, as described in Patent document 1, it was suggested to install equipment to generate electricity at a metallurgical plant with a full cycle, working on their own raw materials, the building that houses the equipment for hot rolling, which produces hot rolled coils, or in the building that houses the equipment for continuous casting for the manufacture of steel billets, such as slabs or the like, However, even for hardware that produces polyfabric what you're made of iron and steel at high temperature, as described above, there is a limit to the amount of heat radiated by individual semi-finished products of iron and steel produced in succession on the same production line. Moreover, since the manufactured semi-finished products of iron and steel are unloaded sequentially, the amount of heat that is radiated semi-finished products of iron and steel in the building, which accommodates production equipment is limited. Moreover, the large size of the building, which accommodates production equipment for semi-finished products of iron and steel, causes low calorific in the building and, thus, it is difficult to perform efficient generation of electricity.

Device to the exhaust conduit for electricity generation, is described in Patent document 2 uses sunlight as a heat source and, therefore, there is no idea, whatever it was related to the recovery of heat radiated from the high-temperature heat-radiating body, such as semi-finished iron and steel, fabricated at high temperatures.

The authors of the present invention used the study and modification to ensure the effective use of heat radiated from the high-temperature heat-radiating body, such as semi-finished iron and steel, which is cooled natural clicks the zoom, as described above, after fabrication at high temperature, resulting from the introduction of heat in the different types of equipment. As a result, typically, the heat density is increased by the accumulation and storage of many high-temperature heat radiating bodies in storage, such as storage area for slabs, in which semi-finished steel products such as slabs or the like, temporarily stored, or storage for temporary storage of high-temperature emitter produced at high temperature in various types of equipment, such as the stock coil for temporary storage of hot-rolled coils. Moreover, when the steel workpiece, such as a slab or the like, or a hot roll, which is at high temperature directly after producing only what is put into storage such as a storage area for slabs or warehouse for the rolls, unloading warehouse is carried out consistently with regard to those objects which have significantly radiated heat in the earlier transportation to the warehouse and longer stays in it, and the total number of high-temperature heat radiating bodies that are placed in it, does not undergo a significant change. Therefore, emphasis was placed on the fact that the sum of the amount of heat held stored high-temperature radiator, exposed to znachitelnoe change, and the fact that the heat held a high-temperature heat radiating bodies, can be effectively recovered in stock, because nearly all the radiation of heat from these bodies is in stock. Based on the foregoing, the invention was based on the notion that the calorific can be obtained from the high-temperature heat radiating bodies, which accumulate and are stored in temporary storage for high-temperature heat radiating bodies, made under high temperature by the introduction of heat during manufacture, the total amount of heat in the storeroom high-temperature heat radiating bodies undergoes a slight change, and nearly all the radiation of heat takes place in the warehouse. Thus, the temperature of the air in the vault can be stably and effectively promoted. When air currents produced from the heated air, is used, the remaining energy in the high-temperature heat radiating bodies ensures stable electricity generation with small losses.

Therefore, the present invention is the creation of a generating device storage high temperature of the emitter, which generates electricity through efficient heat recovery, held high atemperature the emitter, which is produced at high temperature by introduction of heat. Moreover, another objective of the present invention is to provide a power generating device storage high temperature of the emitter, which can also be applied to the existing store of high-temperature emitter without interfering with the existing store operation high temperature emitter and which does not require large reconstruction works on the ceiling of the building. Moreover, another objective of the present invention is to provide a power generating device storage high temperature of the emitter, which increases the growth temperature of the air that is heated by thermal convection with high temperature emitter by increasing the time of heat exchange between the air entering the storage temperature of the emitter, and a high-temperature radiator stored in the storage temperature of the emitter, and thus a further reduction in the density of the rising air in the tower air release, increasing the work energy of the air flowing in the tower of venting, and an additional increase of energy recuperated electricity generating turbine. An additional object of the present invention is to provide a power generating device storage is ilima high temperature of the emitter, that compared with only natural convection heat increases the total amount of gas flow is heated in the storage high temperature thermoplates to produce a lifting force, and thus further increase the energy recuperated electricity generating turbine.

The solution to this problem

In order to solve the above problem, the present invention has a construction in which the tube having an upper section made in the form of a cylindrical section, continuing upwards, is located in the ceiling of the building storage high temperature of the emitter, which temporarily accumulates and stores the high-temperature radiator, and power-generating turbine, which generates electricity using upward air flow, is located in a predetermined position in the cylindrical section in the pipe, to thereby generate electricity using upward air flow.

In the above construction, the air supply conduit may be provided in the lower section of the side wall of the building, which accommodates the storage temperature of the emitter.

Moreover, in each of the above structures, radiant panel heat receiving separated a specified distance from the converted Bo the new walls, can be provided on the inner side of the side wall of the building, which accommodates the storage temperature of the emitter.

Moreover, in each of the above structures, emitting panel, receiving heat, can be arranged vertically in a predetermined position on the upper part of the building, which accommodates the storage temperature of the emitter, which does not interfere with stored high-temperature emitter.

Moreover, in each of the above structures, high-temperature heat radiating body can be a semi-finished iron and steel at the steel mill, and store high-temperature emitter may be a storage for temporary storage of semi-finished iron and steel.

In the above construction, the semi-finished iron and steel can be hot rolled coil manufactured equipment for hot rolling at a metallurgical plant, and storage for temporary storage of semi-finished iron and steel may be a warehouse for the rolls.

In the above construction, high temperature thermoinsulating may be hot rolled coil manufactured equipment for hot rolling at a metallurgical plant, and the tail section towards the discharge of hot-rolled coil from a building that accommodates the equipment for hot rolling, can communicate and be connected to a side section of the building, which accommodates the storage of high-temperature thermoplates, which accumulates and stores the hot-rolled coils to provide airflow.

Moreover, in the above-mentioned construction emitting panel, receiving the heat can be provided on the inner side of the side wall, except for the lateral area of the equipment for hot rolling, forming the connecting area with the building in the building that accommodates the storage of high-temperature thermoplates for temporary storage and accumulation of hot-rolled coils.

In each of the above structures, the lattice element can be provided on the floor of the building for storage high temperature thermoplates and high temperature thermoinsulating can be downloaded at him.

In each of the above structures, the insulating element having heat-resistant properties, can be located on the inner lower section of the building for storage high temperature thermoplates.

In another embodiment of the invention, the preset position of the building for storage high temperature thermoplates, which temporarily accumulates and stores high temperature thermoinsulating, communicates with and is connected through a connecting channel with the lower concave the plot tower air release, which continues in a vertical direction and provided on the outer area separately from the building. Moreover, electricity generating turbine is located in a predetermined position on the tower of air release or a connecting channel, and the air is passed to a lifting force by heating in the building, is introduced into the tower of air discharge through the connecting channel, to thereby generate electricity air flow through the tower air release.

Set the position of the building for storage high temperature thermoplates, which temporarily accumulates and stores high temperature thermoinsulating, communicates with and is connected through a connecting channel with the lower end section of the tower air release, which continues in a vertical direction and provided on the outer area separately from the building. Water spray nozzle for spraying water at high temperature thermoinsulating stored in the building, secured in a predetermined position on a ceiling part of the building, and electricity generating turbine is located in a predetermined position on the tower of air release or a connecting channel. In addition, pairs, which is derived by evaporation of water sprayed from the water spray nozzle, caused by the heat retained in the high-temperature thermoisloated, and air is passed themei force by heating in the building, entered in the tower of air discharge through the connecting channel, to thereby generate electricity air and steam passing through the tower air release.

In each of the above structures, tunnel equipment air release can be used as a tower air release, which is separated from the building.

Moreover, in each of the above structures, high-temperature thermoinsulating may be a semi-finished iron or steel at the steel mill, and the building that accommodates the storage of high-temperature thermoplates, which communicates with and is connected through a connecting channel with the lower end section of the tower air release may be a building that accommodates the storage that temporarily stores and accumulates the semi-finished iron and steel.

Moreover, in the above design, prefabricated, of iron or steel, forming a high-temperature thermoinsulating is hot rolled coil, which is made equipment for hot rolling at a metallurgical plant, and the building, which accommodates the store, acting as a building for the storage of high-temperature thermoplates that temporarily stores and accumulates the semi-finished iron and steel and communicates with and is connected through connecting the channel with the lower end section of the tower air release, may be the building that holds the stock to the rolls.

Moreover, in the above-mentioned construction, the tail section towards the discharge of hot-rolled coil in the building that houses the equipment for hot rolling, can be communicated and connected to provide air flow from the lateral area of the building that holds the stock to the rolls, which temporarily stores and accumulates the semi-finished iron and steel, and is connected through a connecting channel with the lower end section of the tower air release.

In addition, in yet another variant, separate from the above, the lower end section of the tower air release, which continues in a vertical direction and provided on the upper side of the building, communicates with and is connected to the Central section of the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high-temperature thermoinsulating. Moreover, a duct providing air flow in a horizontal direction along the inner surface of the peripheral wall of a building, can be provided in multiple preset positions on the peripheral wall of a building, so that the direction of airflow in the horizontal direction in the building through each duct corresponded to the direction of air circulation or clockwise p is the left main coronary artery, or counterclockwise, when viewed from above, and electricity generating turbine may be located in a predetermined position on the tower air release.

The lower end section of the tower air release, which continues in a vertical direction and provided on the upper side of the building, communicates with and is connected to the Central section of the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high temperature teploizolyatsii body. Water spray nozzle for spraying water at high temperature thermoinsulating stored in the building, secured in a predetermined position on a ceiling part of the building. Moreover, a duct providing air flow in a horizontal direction along the inner surface of the peripheral wall of a building, can be provided in multiple preset positions on the peripheral wall of a building, so that the direction of airflow in the horizontal direction in the building through each duct corresponded to the direction of air circulation either clockwise or counterclockwise, when viewed from above, and electricity generating turbine is located in a predetermined position on the tower exhaust. Steam, which is produced by evaporation of water sprayed from the water spray nozzle, caused by heat is, held in high thermoisloated, and the air is subjected to a rotating flow in the building due to the inflow of air from the duct into the building, entered the tower of air discharge to thereby generate electricity by actuation of the turbine upward flow of air and steam, which rises in the tower air release.

Moreover, in each of the above structures, high-temperature thermoinsulating may be a semi-finished iron or steel at the steel plant and the storage building high temperature thermoplates with the duct in the set of specified locations on the peripheral wall may be a storage building, which temporarily stores and accumulates the semi-finished iron and steel.

Moreover, in the above design, prefabricated, of iron or steel, acting as high-temperature thermoplates may be hot rolled coil manufactured equipment for hot rolling at the metallurgical plant and storage building, acting as storage high temperature thermoplates, temporarily storing semi-finished iron and steel and provided with a duct in the set of specified locations on the peripheral wall may be a warehouse building for the rolls.

Even the bottom additional variant, the lower end section of the tower air release, which continues in a vertical direction and provided on the upper side of the building, communicates with and is connected to a specified position on the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high-temperature thermoinsulating. Moreover, the water spray nozzle is provided in a predetermined position on a ceiling portion of the inner area of the building and is connected through a water supply line to water pump. Electricity generating turbine may be located in a predetermined position on the tower air release.

Moreover, the lower end section of the tower air release, continuing vertically and provided on the upper side of the building, communicates with and is connected to a specified position on the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high-temperature thermoinsulating. Moreover, the water spray nozzle is provided in a predetermined position on a ceiling portion of the inner area of the building and is connected through a water supply line to the tank for rain water, provided in a higher position than the position where the water spray nozzle. Electricity generating turbine may be located in a predetermined position on the tower vypuskavshem.

Moreover, in each of the above structures, a lot of water spray nozzles can be provided in a predetermined position on a ceiling portion of the inner area of the building, and a valve in the water supply can be provided in accordance with each water spray nozzle.

Moreover, in each of the above structures, high-temperature thermoinsulating may be a semi-finished iron and steel at the steel plant and the storage building high temperature thermoplates, in which the water spray nozzle is provided in a predetermined position on a ceiling portion may be a storage building for temporary storage of semi-finished iron and steel.

In addition, in the above design, prefabricated, of iron or steel, acting as high-temperature thermoplates may be hot rolled coil manufactured equipment for hot rolling at the metallurgical plant and storage building, acting as a building that accommodates the storage of high-temperature thermoplates, for temporary storage of high-temperature thermoplates and in which the water spray nozzle is provided in a predetermined position on a ceiling portion may be a warehouse building for the rolls.

The effects of the invention

Generate is its storage high temperature thermoplates according to the present invention has the following advantages.

(1) Pipe with the upper section made in the form of a cylindrical section, continuing upwards, is located in the ceiling of the building storage high temperature thermoplates, which temporarily accumulates and stores high temperature thermoinsulating, and electricity generating turbine, which generates electricity using upward air flow in a predetermined position in the cylindrical section. Thus, the air in the storage high temperature thermoplates is heated mainly by convection heating from the heat retained in the high-temperature thermoisloated, which was obtained by the introduction of heat. Upward airflow created by the lifting force due to the decrease in density of the heated air is concentrated in and flows through a cylindrical pipe section. Because electricity generation is provided by rotation of the electricity-generating turbines with upward air flow in a cylindrical pipe heat held in high thermoisloated, can be effectively used.

(2) Since the air supply conduit is provided at the lower section of the side wall of the building storage high temperature thermoplates, low-temperature outside air can be drawn into the lower portion of the building subordinatestes. The air that is drawn into the lower portion of the building is heated with heat held high-temperature heat radiating body building in order to create upward air flow. As a result, the upward air flow to the pipe in the building can be effectively created, and it is possible to perform efficient generation of electricity using electricity generating turbine.

(3) Ensured by design, in which the radiant panel heat receiving separated a specified distance from the facing side walls, may be provided on the inner side of the side wall of the building storage high temperature thermoplates, or provided a construction in which the radiating panel, receiving the heat is vertically positioned on top of the building storage high temperature thermoplates, which does not interfere with the stored high-temperature thermoinsulating. Thus, in addition to increasing the temperature of the air in the building due to the convection of heat from high-temperature thermoplates, because you can also heat the air in the building of the convective heat from the radiating panel, receiving heat, which is heated by absorption of heat radiated from the high-temperature thermoisloated, the number of generated power electrogenesis is the fact that the turbine can be increased by strengthening the upward air flow, created in the building. Moreover, the construction in which radiant panel heat receiving, separated a specified distance from the side wall, can limit position, in which air currents may be generated in the building near the side wall.

(4) When high temperature thermoinsulating is a semi-finished iron and steel at the steel plant, and storage high temperature thermoplates is the repository for temporary storage of semi-finished iron and steel, the heat held in the material of iron and steel produced in the high temperature metallurgical plant, can be effectively used to generate electricity.

(5) When the semi-finished iron and steel is hot rolled coil manufactured equipment for hot rolling at a metallurgical plant, and storage for temporary storage of semi-finished iron and steel is a warehouse for the rolls, the heat retained in the hot-rolled coil produced at high temperature metallurgical plant, can be effectively used to generate electricity.

(6) In the structure described in (1), since high-temperature thermoinsulating is hot rolled coil manufactured equipment for hot rolling on metallurgicheskom plant, and the tail section towards the discharge of hot-rolled coils in building equipment for hot rolling, communicates with and is connected to provide air flow, with a side plot of building storage high temperature thermoplates, which temporarily accumulates and stores the hot-rolled coils, heat retained in the hot-rolled coils produced at high temperature equipment for hot rolling at a metallurgical plant, can be effectively used to generate electricity. Moreover, the air which has a higher temperature than outside air due to the heat emitted during hot rolling process in the building for the equipment for hot rolling, can be sucked into the building, which accommodates the storage of high-temperature thermoplates, which stores the hot-rolled coils. As a result, the temperature of the air heated due to heat held hot-rolled coils in the building, can be further enhanced, thereby increasing the final temperature at the upper end of the outlet openings of the cylindrical pipe section. Thus, the force of the air stream passing through the cylindrical portion of the tube can be increased to thereby increase the amount of generated electricity power generation, turbine is.

(7) In the construction in (6), the provision of the radiating panel, receiving the heat on the inside of the side walls, except for the lateral area of the equipment for hot rolling, forming the connecting area with storage building high temperature thermoplates that temporarily stores and accumulates the hot-rolled coils, provides an additional increase in the heating efficiency of the air in the building. As a result, the ascending air stream created in the building, can be further strengthened and, thus, provided an additional increase in the number of generated power.

(8) Design, in which the grating element is provided on a floor of a building for the storage of high-temperature thermoplates and high temperature thermoinsulating can be downloaded at him, provides air to pass through the lower side of the lattice element on the lower side of the high-temperature thermoplates, and semi-finished iron and steel acts as a high-temperature thermoplates, or hot rolled coil acts as a semi-product of iron and steel in building storage high temperature thermoplates. Thus, the convection heat transfer can be supported in the air in the building due to heat held in viscotester is to become thermoisloated, and semi-finished iron and steel acts as a high-temperature thermoplates, or hot rolled coil acts as a semi-product of iron and steel. Thus, the air in the building can be heated more efficiently. As a result, the ascending air stream created in the building, can be further strengthened and, thus, provided an additional increase in the number of generated power.

(9) Since the heat-insulating element having heat-resistant properties, is located on the inner lower section of the building for storage high temperature thermoplates, you can reduce the heat dissipation from the bottom of the building in the earth's surface. Therefore, the amount of heat used for heating the air in the building can be increased and the efficiency of heating the air in the building can be increased. Therefore, an additional increase in the number of generated power is provided through the strengthening of the upward air flow that is created in the building.

(10) Specified provisions of the building for storage high temperature thermoplates, which temporarily accumulates and stores the high-temperature heat-radiating body, communicates with and is connected through a connecting channel with the lower end section of the tower exhaust to the I continues in a vertical direction and provided on the outer area separately from the building. Moreover, electricity generating turbine is provided in a predetermined position on the tower of air release or a connecting channel, and the air is passed to a lifting force by heating in the building, is introduced into the tower of air discharge through the connecting channel, to thereby generate electricity air flow through the tower exhaust. Thus, the heat retained in the high-temperature thermoisloated, which is produced by the introduction of heat can be used for air heating, mainly by convection heating in the building storage high temperature thermoplates. Air is passed lifting force by heating, is introduced into the lower end section of the tower release of air through the connecting channel to thereby create upward air flow and generate electricity by turning the electricity generating turbines ascending air flow.

(11) Since the tower of air discharge is provided separately from the building storage high temperature thermoplates, construction work for tower air release, requiring several days to realize the electricity generating device for storage high temperature thermoplates according to the present invention, can be performed without any effect on the stores the high-temperature thermoplates. Thus, even when the generating device storage high temperature thermoplates according to the present invention is carried out in existing storage high temperature thermoplates, the risk of obstacles to the work of the existing storage high temperature thermoplates may be expelled and his work can be continued.

(12) Set the position of the building storage high temperature thermoplates, which temporarily accumulates and stores high temperature thermoinsulating, communicates with and is connected through a connecting channel with the lower end section of the tower air release, which continues in a vertical direction and provided on the outer area separately from the building. Water spray nozzle for spraying water at high temperature thermoinsulating stored in the building, secured in a predetermined position on a ceiling part of the building. Moreover, electricity generating turbine is provided in a predetermined position on the tower of air release or a connecting channel. Steam, which is produced by evaporation of water sprayed from the water spray nozzles, the heat retained in the high-temperature thermoisloated, together with air, lifting force transmitted by heating in the building, entered the tower air release through connect the positive channel, in order to generate electricity, the passage of air and steam through the tower exhaust. Thus, in addition to the same effect as in (11) and (12), as the water sprayed from the water spray nozzle evaporates the heat retained in the high-temperature thermoisloated to produce large quantities of hot steam, and the resulting vapor is mixed with the air stream entered the building through the connecting channel into the tower air release, you can increase the amount of heated gases rising in the tower exhaust. Thus, the speed of the air flow upward inside the tower air release, radically increases, thereby increasing the energy that is recovered electricity generating turbine, and, thus, providing a noticeable increase in power electricity-generating turbines.

(13) Since the existing tunnel for equipment exhaust is used as tower air release, which is separated from the building, the construction work for tower air release can be reduced, thereby facilitating the implementation of the cash-generating device storage high temperature thermoplates according to the present invention.

(14) high-Temperature thermoinsulating is a semi-product of iron or steel metal the technological plant, and building storage high temperature thermoplates, which communicates with and is connected through a connecting channel with the lower end section of the tower air release, is a storage building that temporarily stores and accumulates the semi-finished iron and steel. Thus, the heat held in the semi-finished iron and steel, fabricated at high temperature metallurgical plant, can be recovered as energy for effective use in power generation.

(15) Semi-finished iron or steel, forming a high-temperature thermoinsulating is hot rolled coil, which manufactured equipment for hot rolling at the metallurgical plant and storage building, acting as a building for the storage of high-temperature thermoplates that temporarily stores and accumulates the semi-finished iron and steel and communicates with and is connected through a connecting channel with the lower end section of the tower air release, is building a warehouse for the rolls. Therefore, the heat retained in the hot-rolled coil manufactured at high temperatures, can be recovered as energy for effective use in power generation.

(16) the Tail section towards the discharge of hot-rolled rul is on in the building equipment for hot rolling may be provided and be connected, to provide airflow, with a side plot of the building stock for the rolls, which temporarily stores and accumulates the semi-finished iron and steel, and is connected through a connecting channel with the lower end section of the tower exhaust. As a result, the air which has a higher temperature than outside air due to the heat emitted during hot rolling process in building equipment for hot rolling, can be sucked into the storage building high temperature thermoplates, which stores the hot-rolled coils. As a result, the temperature of the air heated due to heat held hot-rolled coils in the building, can be further enhanced. Moreover, since the temperature of air introduced into the tower release of air from the building stock for the rolls through the connecting channel can be additionally increased, the speed of the upward air flow in the tower of air discharge can be increased and thus the amount of generated electricity power generation turbine may be increased.

(17) the Lower end section of the tower air release, continuing in the vertical direction and provided on the upper side of the building, communicates with and is connected to the Central section of the ceiling of the building storage high temperature thermoplus the body, which temporarily stores and accumulates the high-temperature thermoinsulating. Moreover, a duct providing air flow in a horizontal direction along the inner surface of the peripheral wall of a building, provided many preset positions on the peripheral wall of a building, so that the direction of airflow in the horizontal direction in the building through each duct corresponded to the direction of air circulation either clockwise or counterclockwise, when viewed from above, and electricity generating turbine is provided in a predetermined position on the tower exhaust. Thus, the air in the storage building high temperature thermoplates is heated mainly by convection heating in the heat retained in the high-temperature thermoisloated, which was made by the introduction of heat. Upward airflow created by the lifting force of the heated air, is concentrated in and flows through a cylindrical pipe section, which is connected with the Central section of the ceiling of the building in order to generate the electric power by the rotation of the electricity-generating turbine. Moreover, when the air in the outer area of the building enter the building through each duct is provided in the peripheral wall of a building, due to the movement of ozdoba, heated in the building, to the tower of air discharge, air flow direction, flowing from each duct is horizontal along the inner surface of the peripheral wall of a building and corresponds to the direction of air circulation either clockwise or counterclockwise, when viewed from above. Therefore, the rotating air stream, which has a low level of vertical components may be provided in the building. Thus, the time of heat exchange between the air in the building and high temperature thermoisloated can be increased, the air in the building can be effectively heated, to thereby enable the introduction of more lifting of heated air into the tower exhaust. Thus, the amount of air upward through the inner area of the tower of air discharge can be increased and the energy recuperated electricity generating turbine can be increased. Therefore, the electricity generating capacity of the turbine may be increased.

(18) Thus, it is possible to reduce the time required to return the capital costs associated with installation of the generating device storage high temperature thermoplates according to the present invention in the storage building high temperature thermoplates.

(19) the Lower end section of the tower you USCA air, continuing vertically and provided on the upper side of the building, communicates with and is connected to the Central section of the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high-temperature thermoinsulating. Water spray nozzle for spraying water at high temperature thermoinsulating stored in the building, secured in a predetermined position on a ceiling part of the building. Moreover, a duct providing air flow in a horizontal direction along the inner surface of the peripheral wall of a building, provided many preset positions on the peripheral wall of a building, so that the direction of airflow in the horizontal direction in the building through each duct corresponded to the direction of air circulation either clockwise or counterclockwise, when viewed from above. Moreover, electricity generating turbine is provided in a predetermined position on the tower exhaust. Steam, which is produced by evaporation of water sprayed from the water spray nozzle, caused by the heat retained in the high-temperature thermoisloated, together with the rotating air flow in the building due to the inflow of air from the duct into the building, entered the tower of air discharge to thereby generate the electric power is s by actuation of power-generating turbines upward flow of air and steam, which rises in the tower exhaust. Thus, in addition to the same effect obtained in (17) and (18) above, as the water sprayed from the water spray nozzle, steam heat, held in high thermoisloated to produce large quantities of hot steam, and the resulting vapor is mixed with the air flow rotating in the building, you can increase the amount of heated gases rising from the building to the tower exhaust. Thus, the speed of the air flow upward inside the tower air release, radically increases, thereby increasing the energy that is recovered electricity generating turbine and, thus, providing a noticeable increase in power electricity-generating turbines.

(20) high-Temperature thermoinsulating is a semi-finished iron or steel at the steel plant, and the storage building high temperature thermoplates, provided with a duct in the set of specified locations on the peripheral wall, is a storage building that temporarily stores and accumulates the semi-finished iron and steel. Thus, the heat held in the material of iron or steel, made in the condition of high temperature, can be recovered as energy for effective use is in the production of electricity.

(21) Semi-finished iron or steel, acting as high-temperature heat-radiating body is hot-rolled coil manufactured equipment for hot rolling at the metallurgical plant and storage building, acting as storage high temperature thermoplates, temporarily storing semi-finished iron and steel and provided with a duct in the set of specified locations on the peripheral wall may be a warehouse building for the rolls. Thus, the heat held in the material of iron or steel, made at high temperature, can be recovered as energy for effective use in power generation.

(22) the Lower end section of the tower air release, continuing vertically and provided on the upper side of the building, communicates with and is connected to a specified position of the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high-temperature thermoinsulating. Water spray nozzle is provided in a predetermined position on a ceiling portion of the inner area of the building and is connected through a water supply line to water pump. Moreover, electricity generating turbine is provided in a predetermined position of the tower exhaust and produces the electric power is s by actuation of power-generating turbines upward flow of air. Thus, the air in the storage high temperature thermoplates is heated mainly by convection heating from the heat retained in the high-temperature thermoisloated, which was obtained by the introduction of heat. In addition, the water sprayed from the water spray nozzle, steam heat, held in high thermoisloated to produce large quantities of hot steam. Upward airflow created by the lifting force of the heated air and steam are concentrated in and pass through the tower of air discharge to thereby generate electric power by the rotation of the electricity-generating turbine. Thus, compared with the heated air in the storage high temperature thermoplates using only convection heating, the speed of the air flow upward inside the tower air release, radically increases, thereby increasing the energy recuperated electricity generating turbine, and, thus, providing a noticeable increase in power electricity-generating turbines.

(23) Thus, it is possible to reduce the time required to return the capital costs associated with installation of the generating device storage high temperature thermoplates according to the present invention in the storage building viscotemp Turnovo thermoplates.

(24) the Lower end section of the tower air release, continuing vertically and provided on the upper side of the building, communicates with and is connected to a specified position on the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high-temperature thermoinsulating. Moreover, the water spray nozzle is provided in a predetermined position on a ceiling portion of the inner area of the building and is connected through a water supply line to the tank for rain water, provided in a higher position than the position where the water spray nozzle. Moreover, electricity generating turbine may be located in a predetermined position of the tower exhaust and produces electricity, powering electricity generating turbine ascending air flow. Consequently, it is possible to obtain the same effect as in (22) and (23). Moreover, the rainwater in the tank for rain water can be fed by gravity as the water spray from each water spray nozzle provided on a ceiling of the building. Thus, the energy used to supply water required for each water spray nozzles can be reduced and it is possible to reduce the energy consumed in order to recover the heat held in Vysokoe the temperature of thermoisloated, stored on storage high temperature thermoplates.

(25) Many water spray nozzles are provided in a predetermined position on a ceiling portion of the inner area of the building, and a water supply valve provided in accordance with each water spray nozzle. Thus, water can be selectively sprayed from the water spray nozzle on a group of high-temperature thermoplates, which has a relatively high temperature in the storage high temperature thermoplates. Thus, steam can be effectively produced by the evaporation of the sprayed water, and can prevent the risk of accumulation of water not evaporated in the storage high temperature thermoplates.

(26) high-Temperature heat-radiating body is a semi-finished iron or steel at the steel mill, and the building that accommodates the storage of high-temperature thermoplates where water spray nozzle is provided in a predetermined position on a ceiling part is a storage building for temporary storage of semi-finished iron and steel. Thus, the heat held in the material of iron or steel, made in high temperature metallurgical plant, can be recovered as energy for use in the efficient production of electricity./p>

(27) Semi-finished iron or steel, acting as high-temperature thermoplates is hot rolled coil manufactured equipment for hot rolling at the metallurgical plant and storage building, acting as building storage high temperature thermoplates for temporary storage high temperature thermoplates, in which the water spray nozzle is provided in a predetermined position on a ceiling part, is building a warehouse for the rolls. Thus, the heat retained in the hot-rolled coil manufactured at high temperatures, can be recovered as energy for use in the efficient production of electricity.

Brief description of drawings

Figure 1 is a schematic side view in cross section showing a first variant implementation of the cash-generating device storage high temperature thermoplates according to the present invention, with reference to the warehouse for the rolls.

Figure 2 is a schematic side view in cross section showing a modified example of the device shown in figure 1, as an alternative implementation of the present invention.

Figure 3 is a schematic side view in cross section showing another modified example of the device, showing the tion in figure 1, as another variant implementation of the present invention.

Figure 4 is a schematic side view in cross section showing another modified example of the device shown in figure 1, as another additional option of implementing the present invention.

Figure 5 is a schematic side view in cross section showing another modified example of the device shown in figure 1, as another additional option of implementing the present invention.

6 is a schematic side view in cross section showing a practical example of the device shown in figure 1, as another additional option of implementing the present invention.

7 is a schematic side view in cross section showing a modified example of the device shown in Fig.6, as another additional option of implementing the present invention.

Fig is a detail view along the arrow direction X-X 7.

Fig.9 is a schematic view in perspective showing the use of a warehouse for the rolls, as another additional option of implementing the present invention.

Figure 10 is a schematic side view showing a modified example of the device is VA, shown in Fig.9, as another additional option of implementing the present invention.

11 is a schematic side view showing a modified example of the device shown in Fig.9, as another additional option of implementing the present invention.

Figa is a schematic view in side view, showing the application to the warehouse for the rolls, as another additional option of implementing the present invention.

FIGU is a schematic top view showing the air flow in the building, in relation to the warehouse for the rolls, as another additional option of implementing the present invention.

Figa is a schematic perspective view from the outside of the building, showing the example of the duct for the device shown in Fig.

FIGU is a schematic view in perspective from the inside of the building, showing the example of the duct for the device shown in Fig.

Figa is a schematic perspective view from the outside of the building, showing another example of the duct for the device shown in Fig.

FIGU is a schematic view in perspective from the inside of the building, showing another p the emer duct for the device, shown in Fig.

Figa is a schematic side view in cross section showing another variant implementation of the present invention.

FIGU is a schematic top view showing the air flow in the building shown in yet another additional embodiment of the present invention.

Fig is a schematic view in side view in cross section showing the application to the warehouse for the rolls, as another additional option of implementing the present invention.

Fig is a schematic side view showing an example of the device shown in Fig, as an additional option, the implementation of the present invention.

Preferred embodiments of the invention

Preferred embodiments of the invention will be described below with reference to the drawings.

Figure 1 shows a variant implementation of the cash-generating device storage high temperature thermoplates according to the present invention, which is applied to warehouse 1 coil, which acts as a repository for high-temperature thermoplates for temporary storage of hot-rolled coil 2, which is a semi-finished iron and steel, acting as the dust is REGO thermoplates, which is manufactured using the equipment for hot rolling steel plant with a full cycle, working on their own raw materials, or the like, and its construction will be described below.

More specifically, the pipe 4, which has a lower section essentially in the shape of a pyramid and the upper portion forming the cylindrical section 4a, which continues with the specified size up and secured in the roof of the building 3 of the stock coil, which is used for temporary storage of hot-rolled coil 2, which is produced by the introduction of heat through the equipment for hot rolling, to transfer to the next process. Electricity generating turbine 5 is provided in a predetermined position on the cylindrical section 4a.

Moreover, the air supply conduit 7 is provided in the lower end area of the four side walls 6 of the building 3.

Although not shown, an opening for loading and opening for discharge for hot-rolled coils 2 building 3 warehouse for the rolls can be provided in a given side wall 6 of the building 3 of the stock coil and can be equipped with opening and closing the door. Moreover, the inlet duct, similar to the intake duct 7 may be provided in the lower end area of the door openings for loading and holes to upload.

Means of transportation (not on Asano) for hot-rolled coils 2 may be provided in the building 3.

Hot rolled coil 2, which is manufactured by hot rolling process, causing the introduction of heat from the equipment for hot rolling (not shown)is loaded through the opening to load (not shown) in building 3 warehouse 1 for rolls, provided with a power generating device storage high temperature thermoplates, as described above, and is stored temporarily before being transferred to the next processing stage. Thus, the heat held in each hot-rolled coil 2 in the building 3 of the stock coil is heat transfer to the air in the building 3, mainly due to convection heating, and thereby the air in the building 3 is heated. The density of the heated air is reduced, and it is shifted to the pipe 4 in the ceiling part by ascent in building 3 because the total lifting force. After passing through the cylindrical section 4a of the pipe 4, the air is released into the outer area of the upper end of the discharge holes (not shown) in the cylindrical section 4a. At this stage, low-temperature outside air introduced into the building 3 through the inlet duct 7, which is provided in the lower end area facing four walls in building 3, in the ascent of air in the building 3 to the pipe 4. Then the air that is introduced into the building 3 through the inlet duct 7, sequentially naked is eveda convection heat from the hot-rolled coils 2 and as mentioned above rises inside the building 3 to the pipe 4. Thus, as shown by the arrow a in figure 1, the upward air flow is provided so that after climbing to the pipe 4 through the interior of the building 3 of the inlet channel 7, secured to the four side walls 6, passes from the lower position upward in the cylindrical section 4a. This upward air flow drives the power-generating turbine 5, which is provided in the cylindrical section 4a of the pipe 4, to thereby carry out the generation of wind energy.

Thus, according to the generating device storage high temperature thermoplates according to the present invention, the accumulation and storage of high-temperature hot-rolled coils 2 directly after manufacturing ensures efficient air heating using heat retained in the hot-rolled coils 2 building 3 warehouse 1 for rolls, which has increased the calorific. Consequently, the upward air flow can be effectively provided in the building 3 warehouse 1 for rolls of air, which effectively heats the heat retained in the hot-rolled coil 2. Thus, the power-generating turbine 5, which is provided in the cylindrical section 4a of the pipe 4, can effectively operate to perform a more efficient generation of electricity.

Usually, when the and just made the hot-rolled coils 2, having a large number of retained heat, sequentially loaded into the warehouse 1 for rolls, the earliest loaded a roll of hot-rolled coils 2, which are already stored in the warehouse 1 for rolls, in other words, a hot roll 2 with the lowest temperature due to heat dissipation for the longest period of time, is discharged in the same sequence through the opening for unloading (not shown). Hence, the total amount of heat held hot-rolled coils 2 that are stored in the building 3 warehouse 1 for rolls, changes little. As a result, the building has 3 warehouse 1 for the rolls, because the amount of heat used for heating the air from all the hot-rolled coils 2, there is little change in the long term, provided a stable heating of the air, and a stable upward air flow passes through the cylindrical section 4a of the pipe 4. This ensures stable electricity generation electricity generating turbine 5.

Next, figure 2 shows a modified example of the device shown in figure 1, as an alternative implementation of the present invention. This example has a construction similar to figure 1, in which the radiant panel 8, receiving heat, which are designed to ensure effective absorption of the radiation is the volumetric heat located on the inner side of each side wall 6 of the building 3 warehouse 1 coil at a given distance from the surface of each side wall 6, for example a distance of from a few centimeters to tens of centimeters, and is arranged to close the distance from the position which closes the inner side of the inlet channel 7 provided on the lower end section of each side wall 6, to the upper end portion of each side wall 6. Panel 8 mounted on the corresponding side walls 6 by using a fixing element (not shown).

Each radiant panel 8, receiving the heat can be supplied, for example, the surface layer having a high absorption intensity ultraviolet wavelength range, on the porous aluminum plate.

Although not shown, the radiating panel 8, receiving the heat can also be set with predetermined intervals on the inside of the door openings for loading and openings for discharging buildings 3 warehouse 1 for rolls.

Other aspects of construction are the same as shown in figure 1, and the same reference items refer to the same elements.

According to this variant implementation, when a hot roll 2 is made by hot rolling process, causing the introduction of heat from equipment dragrace rolling (not shown), and loaded through holes for download (not shown) in building 3 warehouse 1 to rolls to temporarily accumulate and be stored before transfer to the next processing stage, the air in the building 3 is heated convective heat from each hot-rolled coil 2. Moreover, radiant heat (shown by a dotted line in the drawing and subsequent drawings hereinafter)emitted from each hot-rolled coil 2 in the building 3 of the stock coil, effectively absorbed by each of the radiating panel 8, the receiving warmth provided on the inner side of each side wall 6, and thereby heats each radiant panel 8, the receiving warm. Therefore, the air trapped near the surface, heated by convective heat from radiating panels 8, receiving heat. At this stage, the lower end section of each of the radiating panel 8, receiving heat, is located on the inner side of the inlet channel 7, secured on the lower end section of each side wall 6 of the building 3 of the stock coil. Thus, low-temperature outside air introduced into the building 3 through each inlet channel 7, is effectively heated by convective heat from each of the radiating panel 8, receiving heat, and the total upward air flow to the ceiling of the space with the side wall 6, correspond to the her each of the radiating panel 8, receiving the heat generated lifting force.

Thus, this variant implementation provides create upward air stream rising in building 3 to the pipe 4 ceiling part and passing through the cylindrical section 4a due to air heated by the heat source held in the hot-rolled coils 2 building 3 warehouse 1 for rolls. Thus, the generation of electricity is performed by actuation of power-generating turbine 5. This provides the same effect as in the embodiment shown in figure 1.

Moreover, each radiant panel 8, the receiving warmth, located on the inner side of each side wall 6, is heated by the absorption of radiant heat from hot-rolled coils 2, to thereby create a convection heating in air from each of the radiating panel 8, receiving heat, which primarily heats the air in the building 3. Thus, the area in which the air currents created in the building 3 can be limited to the region near each of the side wall 6. Consequently, it is possible to reduce the risk of contact of the upward flow of heated air with devices (not shown), which are located near the Central section of the building 3.

Next, figure 3 shows a modified example of the device, pokazanno the figure 1, as another variant implementation of the present invention. This example has a construction similar to figure 1, in that the radiating panel 8, receiving heat, which is the same as radiant panel 8, the host warmly, shown in figure 2, is located in a position that does not interfere with stored hot-rolled coils 2, or when the hot-rolled coils 2 are transferred to the upper portion of the building 3 warehouse 1 for rolls in a direction that does not interfere with the upward flow of air created inside the building 3, for example in the vertical direction, and is installed in a predetermined position on the pipe 4 and a predetermined position in building 3, using the mounting element (not shown).

Other aspects of construction are the same as shown in figure 1, and the same reference items refer to the same elements.

According to this variant implementation, when hot rolled coil 2, which is manufactured by hot rolling process, causing the introduction of heat from the equipment for hot rolling (not shown)is loaded through holes for download (not shown) in building 3 warehouse 1 for rolls, and temporarily accumulates and is stored prior to transfer to the next processing stage, the air in the building 3 is heated convective heat from each hot-rolled coil 2. Moreover, the radiant heat radiated about what each hot-rolled coil 2 building 3 warehouse for the rolls, effectively absorbed by each of the radiating panel 8, receiving heat, and thereby heats each radiant panel 8, the receiving warm. Therefore, the air trapped near the surface, heated by convective heat from radiating panels 8, receiving warm.

Thus, this version of the implementation also ensures the creation of an ascending air stream, rising in the building 3 to the pipe 4 ceiling part and passing through the cylindrical section 4a due to air heated using a heat source held in the hot-rolled coils 2 building 3 warehouse 1 to rolls, to thereby carry out a generation operation of electricity generating turbine 5. This provides the same effect as in the embodiment shown in figure 1. Moreover, the presence of the radiating panel 8, the receiving warmth and provides more efficient heating of air than an implementation option, shown in figure 1, and increases the strength of the total upward air flow to thereby increase the amount of generated electricity.

Figure 4 shows a modified example of the device shown in figure 1, as another additional option of implementing the present invention. This example has a construction equivalent which figure 1 is that grating element 9 is provided on part of the floor area of the building 3 warehouse 1 for rolls, and hot-rolled coils 2, which are loaded into the warehouse 1 for the rolls are placed on the upper side of the lattice element 9, to thereby provide a flow of air from the bottom of each hot-rolled coil 2 through the lower side of the lattice element 9.

Lattice element 9 may be made of any material provided that it can withstand the weight of the hot-rolled coils 2 and the temperature of the hot-rolled coils 2 directly after loading at the warehouse 1 for rolls.

Other aspects of construction are the same as shown in figure 1, and the same reference items refer to the same elements.

According to this variant implementation, when hot rolled coil 2, which is manufactured by hot rolling process by introducing heat from the equipment for hot rolling (not shown)is loaded through holes for download (not shown) in building 3 warehouse 1 for rolls and temporarily accumulates and is stored prior to transfer to the next processing stage, the air in the building 3 is heated convective heat from each hot-rolled coil 2. Then, because the air can pass under each hot-rolled coil 2, passing through the lower side of the lattice element 9, which is provided on the floor of the warehouse 1 for loop is s, low-temperature outside air, which is drawn from the outdoor area through the air supply conduit 7 provided in the lower end area of the three side walls of building 3, is introduced from the bottom of each hot-rolled coil 2 through the lower side of the lattice element 9. Thus, since the air flow is also provided between the hot-rolled coils 2 or on the lower section of each hot-rolled coil 2, the convective transfer of heat into the air from the heat held in each hot-rolled coil 2 is supported, and thus provides an efficient heating of the air in the building 3 of the stock coil. Thus, it is possible to increase the strength of the upward air flow created in the building 3.

Thus, this version of the implementation also ensures the creation of an ascending air stream, rising in building 3 as a result of air heated using a heat source held in the hot-rolled coils 2 building 3 warehouse 1 to rolls, to thereby carry out a generation operation of electricity generating turbine 5, provided in the cylindrical section 4a of the pipe 4 in the ceiling part. This provides the same effect as in the embodiment shown in figure 1. Moreover, since the total power of the rising air stream, with the given building 3, increased, the amount of generated electric power can be increased in comparison with a variant of execution, shown in figure 1.

Figure 5 shows a modified example of the device shown in figure 1, as another additional option of implementing the present invention. This example has a construction similar to figure 1 in that the insulating element 10 having heat-resistant properties for high temperature applications, such as insulating element 10, such as refractory brick, is located on the inner lower section of the building 3 warehouse 1 for the rolls and with the inner bottom portion of the building 3 forms a heat insulating structure so as to ensure reduction of heat dissipation from the bottom of the building in the earth's surface.

Other aspects of construction are the same as shown in figure 1, and the same reference items refer to the same elements.

According to this variant implementation, when hot rolled coil 2, which is manufactured by hot rolling process by introducing heat from the equipment for hot rolling (not shown)is loaded through holes for download (not shown) in building 3 warehouse 1 for rolls and temporarily accumulates and is stored prior to transfer to the next processing stage, the air in the building 3 is heated convective heat from every sorrow is catalogo roll 2. Then, since the insulating element 10 is located in the inner lower section of the warehouse 1 for rolls, even when the inner lower portion of the building 3 is heated convective heat or radiant heat hot-rolled coils 2, this heat can be prevented from scattering in the earth's surface under the building 3. Thus, the dissipation in the earth's surface from the building 3 can be reduced, and the amount of heat available for heating the air inside a building can be increased. Thus, it is possible to increase the efficiency of heating the air in the building 3 and to increase the strength of the upward air flow generated in the building 3.

Thus, this version of the implementation also provides create upward air stream rises in building 3, the air is heated using a heat source held in the hot-rolled coils 2 building 3 warehouse 1 to rolls, to thereby carry out a generation operation of electricity generating turbine 5, provided in the cylindrical section 4a of the pipe 4 in the ceiling part. This provides the same effect as in the embodiment shown in figure 1. Moreover, since the total power of the rising air stream generated in building 3, is increased, the number of generated e is extraenergy can be increased in comparison with the embodiment, shown in figure 1.

Figure 6 shows a practical example of the device shown in figure 1, as another additional option of implementing the present invention. This example has a construction similar to figure 1 that the pipe 4 is provided in a ceiling portion of the building 3 warehouse 1 for rolls, and electricity generating turbine 5 is provided in the cylindrical section 4a of the pipe 4. One side portion which forms the side holes for download in building 3 warehouse 1 for rolls, communicates with and is connected with an end section on a side of the discharging hot-rolled coils 2 in the building for 12 equipment 11 for hot rolling, in which the hot-rolled coils 2 are made using the processes of hot rolling, in which heat is introduced. Building 3 warehouse 1 to rolls made in one piece with the building 12 equipment for hot rolling.

Because there is a design in which the air drawn from the building 12 equipment 11 for hot rolling in the building 3 warehouse 1 for rolls, a supply channel 7 of the side walls 6 may be omitted. Other aspects of construction are the same as shown in figure 1, and the same reference items refer to the same elements.

According to this variant implementation, when a hot roll 2, which manufactured equipment 11 for hot rolling, loaded is carried out in the building 3 warehouse 1 for rolls and temporarily accumulates and is stored prior to transfer to the next processing stage, similar to the device shown in figure 1, the air in the building 3 is heated mainly, and decreases its density due to the convection of heat from the heat held in each hot-rolled coil 2, building 3 warehouse for the rolls, and the total lifting force creates an upward air stream, which rises in the building 3 to the pipe 4 in the ceiling part and passes through the inner area of the cylindrical section 4a.

As a result, when the air in the building 3 warehouse 1 coil rises to the pipe 4, the air in the building 12 is drawn into the building 3 warehouse 1 for rolls through a connection point in building 3 building 12 equipment 11 for hot rolling. This air is successively heated by convective heat from the hot-rolled coils 2 in building 3. Then, in building 12 equipment 11 for hot rolling, the air in the building 12 is heated above ambient temperature due to the heat emitted during the processes of hot rolling. Therefore, the introduction of the atmospheric air in the building 3 warehouse 1 for rolls additionally increases the temperature of the air heated convective heat from the hot-rolled coils 2, building 3 warehouse 1 for rolls and increases the final temperature of the air in the upper end of the outlet openings of the cylindrical part 4a of the pipe 4, is provided to the ceiling portion. Therefore, the thrust force of the air passing through the cylindrical section 4a, may be increased.

As a result, this version of the implementation also ensures the creation of an ascending air stream, rising in the building 3 to the pipe 4 in the ceiling portion and passing through the cylindrical section 4a in the air, is heated using a heat source held in the hot-rolled coils 2, building 3 warehouse 1 to rolls, to thereby carry out a generation operation of electricity generating turbine 5, provided in the cylindrical section 4a of the pipe 4 in the ceiling part. This provides the same effect as in the embodiment shown in figure 1. Moreover, since the thrust force of the rising air stream, which drives the power-generating turbine 5 can be increased, the amount of generated electric power may be increased.

7 and Fig shows a modified example of the device shown in Fig.6, as another additional option of implementing the present invention. This example has a construction similar to Fig.6 that the radiant panel 8, receiving heat, which is the same as radiant panel 8, the host warmly, shown in figure 2, is provided on the inner side of the said side walls 6, excluding the connection to the building 12 equipment 11 for hot rolling and building 3 warehouse 1 for rolls.

Other aspects of construction are the same as shown in Fig.6, and the same reference items refer to the same elements.

As a result, this version of the implementation obtains the same effect as an implementation option, shown in Fig.6. Moreover, in building 3 warehouse 1 for rolls emitting panel 8, receiving heat, which are located on the inner side of the three side walls 6 are heated by absorption of the radiant heat hot-rolled coils 2, to thereby provide an introduction convective heat into the air from each of the radiating panel 8, the receiving warm. Thus, since the heating of the air in the building 3 can be performed more efficiently and the force of the rising air stream created in the building 3 warehouse 1 coil can be increased, the amount of generated electric power can be further increased.

The present invention is not limited to the structure in each of the above embodiments, and provided that the electricity generating turbine 5 may operate an ascending air stream passing through the cylindrical section 4a of the pipe 4, the height of which is electricity generating turbine 5 in the cylindrical the section 4a of the pipe 4, may vary accordingly.

In the embodiment shown in Fig.6, or the embodiment shown in Fig.7 and Fig, radiant panel 8, receiving the heat may be located in the same way as shown in figure 3 in the position which does not interfere with stored hot-rolled coils 2 or when the hot-rolled coils 2 are transferred to the upper portion of the building 3 warehouse 1 for rolls. Thus, because the air in the building 3 is heated more efficiently and the power of the upward air flow in the building 3 warehouse 1 for rolls additionally increased, the amount of generated electric power can be further increased.

In the embodiment shown in figure 2, the embodiment shown in figure 3, the embodiment shown in Fig.6, and the embodiment shown in Fig.7 and Fig, lattice element 9, which is the same as shown in figure 4, may be provided on part of the floor area of the building 3 warehouse 1 for rolls. Thus, it is possible to pass air through the bottom side of each hot-rolled coil 2 and to support the convective transfer of heat into the air in the building 3 in the heat held in each hot-rolled coil 2. Thus, the air in the building 3 is heated more efficiently, the force of the rising air stream created in the building 3 of the IC is hell 1 for rolls, can be further increased, thereby further increasing the number of generated power.

In the embodiment shown in figure 2, the embodiment shown in figure 3, the embodiment shown in figure 4, and the embodiment shown in Fig.7 and Fig, the insulating element 10 having heat resistant properties similar to that shown in figure 5, may be located on the inner lower section of the building 3 warehouse 1 for rolls. Thus, since one can reduce the heat dissipation from the lower section 3 warehouse 1 for rolls in the earth's surface, the amount of heat available to heat the air inside the building 3 can be increased and the efficiency of heating the air in the building 3 can be increased. This provides an additional increase in the number of generated power by increasing the force of the rising air stream, which is created in the building 3.

Figure 9 shows another variant implementation of the electricity generating device storage high-temperature heat radiating body according to the present invention, which is applied to warehouse 1 coil, which acts as a repository for high-temperature thermoplates for temporary storage of hot-rolled coil 102, the which is a semi-finished iron and steel, acting as a high-temperature thermoplates, which is manufactured using the equipment for hot rolling steel plant with a full cycle, working on their own raw materials, or the like, and its construction will be described below.

Tower 104 air vent which is provided with a tunnel-shaped air channel 104a, continuing vertically to the specified value inside the tower in a given part, separated by a specified distance from the building 103 of the stock coil on the outer side of the building 103 of the stock coil, designed for temporary storage of hot-rolled coils 102, manufactured by introduction of heat equipment for hot rolling to transfer to the next processing stage, erected separately from the building 103.

Moreover, the discharge opening 105 is provided near the upper section of the side wall of the building 103 and the connecting channel 106 connects the lower position of the tunnel-shaped air channel 104a tower 104 release air from the outlet 105. Moreover, electricity generating turbine 107 is located in a predetermined position in the vertical direction of the tower 104 air release.

From the sides of the building 103 of the supply channel 108 is provided in a predetermined position on each side wall with the exception of one side wall in which the outlet channel 105 provides soedinenie connecting channel 106.

Alternatively, the hole for downloading and opening for discharge for hot-rolled coils 102 in the building 103 of the stock coil provided in a given side wall 103 of the stock coil and opening and closing doors can be provided. Alternatively, the air supply conduit, similar to the inlet channel 108 can also be provided in the lower section of the door openings for loading and holes to upload.

Moreover, the means of transport (not shown) for hot-rolled coils 102 may be provided in the building 103.

All peripheral surface of the connecting channel 106 provided with a heat-insulating element (not shown) and the air 109, issued from the outlet 105 of the building 103, is introduced into the tower 104 air release at the same time, preventing the decrease in temperature and thereby maintaining the temperature 109 passing through the inner area of the tower 104 air release as possible. Reference position 104b marked the supporting structure of the tower 104 air release.

Hot rolled coil 2, which is manufactured by hot rolling process by introducing heat equipment for hot rolling (not shown)is loaded through holes for download (not shown) in the building 103 warehouse 101 coil supplied with the electricity generating device x is anilide high-temperature heat-radiating body, as described above, and is stored temporarily before being transferred to the next processing stage. Thus, the heat held in each hot-rolled coil 102 in the building 103 of the stock coil is heat transfer into the air 109 in the building 103, mainly due to convection heating, and thereby the air 109 in the building 103 is heated. The heated air 109 becomes easier due to the reduced density rises in the building 103 to the outlet 105 provided on the upper section near one side wall of the building 103, is fed from the outlet 105 through the communication channel 106 in the lower portion tunnel-shaped air channel 104a tower 104 of the vent and climbs through a tunnel-shaped air channel 104a tower 104 air release for release in the outer area of the exhaust hole of the upper section of the tower 104 air release.

As described above, low-temperature outside air introduced into the building 103 through each inlet channel 108, which is provided in the side walls of the building 103, due to the introduction of the 109 air, heated in the building 103, from the exhaust hole 105 through the communication channel 106 to the tower 104 air vent. Thus, the air flow 109 is created in the building 103, which passes through the building 103 of each inlet channel 108 connected in series to the outlet 05 and air 109 is sequentially heated by convection heating by heat, held in the hot-rolled coils 102, during which the air 109 passes through the building 103.

Thus, because the air 109, which is heated to become easier, passes from the outlet 105 of the building 103 through the communication channel 106 sequentially to the tower 104 air release, creates an upward air flow air 109, which runs from the bottom of the plot up in a tunnel-shaped air channel 104a tower 104 air vent. Thus, the power-generating turbine 107 provided in the tower 104 of the discharge of the air is driven upward by the air stream to effect the generation of wind energy.

Thus, in generating the storage device of high temperature thermoplates according to the present invention, the air 109 can be effectively heated with heat retained in the hot-rolled coils 102, building 103 warehouse 101 for the rolls, which has a high calorific, since high-temperature hot-rolled coils 102 directly after processing are accumulated and stored. Moreover, the air 109, which effectively heats up to create a lifting force, the heat retained in the hot-rolled coils 102, passes from the outlet 105 of the building 103 through the communication channel 106 and is introduced into the outer tower 104 venting to the eat effectively to create upward air flow in the tower 104 air vent. Thus, the efficient generation of electricity can be effective in triggering a power-generating turbine 107 provided in the tower 104 air release.

Because the tower 104 air vent provided in a separate part of the building 103 warehouse 101 for the rolls, the construction work for tower 104 air release, requiring several days to build an electricity generating device for storage high temperature thermoplates according to the present invention, can be performed without any impact on the warehouse 101 for the rolls. Moreover, the work associated with securing the outlet 105 or inlet channel 108 in the side wall 103 a warehouse for the rolls, can be performed without problems. Thus, even when the generating device storage high temperature thermoplates according to the present invention is provided in the warehouse 101 for the rolls on the existing storage high temperature thermoplates, the risk of obstacles to the work of the existing storage high temperature thermoplates may be expelled and his work can be continued.

Figure 10 shows a modified example of the device shown in Fig.9, as another additional option of implementing the present invention. This example has the design is the Ktsia, similar Fig.9 that the other side of the area facing the one side wall, on which is provided the outlet 105, building 103 warehouse 101 for rolls, communicates with and is connected with an end section on a side of the discharging hot-rolled coils 102 in building 111 for equipment 110 for hot rolling, which manufactures hot-rolled coils 102, using the processes of hot rolling, by introducing heat. Building 111 equipment 110 for hot rolling and building 103 warehouse 101 for rolls made in one piece.

In the building 103 warehouse 101 coil inlet channel 108 on the side walls are omitted, to thereby provide a pulling air out of the building 111 equipment 110 for hot rolling. Other aspects of construction are the same as shown in Fig.9, and the same reference items refer to the same elements.

According to this variant implementation, when the hot-rolled coils 102, manufactured equipment 110 for hot rolling, are loaded in the building 103 warehouse 101 for rolls and temporarily stored prior to transfer to the next processing stage, similarly to variant implementation, shown in Fig.9, the air in the building 103 is heated mainly by convection heating through heat held in each hot-rolled coil 102 in the building 103 of the stock coil. Thus the m the 109 air, which is heated to its lower density and lighter is introduced from the outlet 105 of the building 103 through the communication channel 106 to the tower 104 is released, to thereby create upward air flow in the tower 104 release.

When the air in the building 103 warehouse 101 coil is introduced similarly to the above from the exhaust hole 105 through the communication channel 106 to the tower 104 is released, the air that has been heated in comparison to the outside air heat emitted during the processing steps of hot rolling in the building 111 equipment 110 for hot rolling, is fed from the connection points in the building 103 building 111 for equipment 110 for hot rolling in the building 103 warehouse 101 for the rolls. Thus, the temperature is 109, which is heated convective heat from the hot-rolled coils 102 in the building 103 warehouse 101 for rolls, additionally increases. Thus, as the temperature is 109, which is introduced from the outlet 105 of the building 103 warehouse 101 for rolls through the communication channel 106 to the tower 104 is released, can be additionally increased, the speed of the rising air stream created by the lifting force of the heated air in the tower 104 is released, can be increased, and the amount of generated electricity power generation turbine 107 may be led is expected.

Figure 11 shows a modified example of the device shown in Fig.9, as another additional option of implementing the present invention. This example has a construction similar to figure 9 in that a lot of water spray nozzles 112 are provided at a ceiling part of the building 103 warehouse 101 for the rolls, respectively, the location of the hot-rolled coils 102, located in building 103. Moreover, line 114 water supply, introducing water 115 of the water pump 113 on the outer area of the building, connected to each water spray nozzle 112, and water 115 supplied from the water pump 113 through line 114 water may be sprayed in the form of a spray or in the form of the soul of each water spray nozzles 112 for hot-rolled coils 102, stored in the building 103.

Moreover, the valve 116 water supply corresponding to each of the individual water spray nozzle 112, is provided in the line 114 water supply, attached to each water spray nozzle 112, to thereby provide a separate switching between spray water 115 of each water spray nozzles 112 and stop spraying. Thus, selective spraying water 115 to the group of hot-rolled coils 102 of the respective hot-rolled coils 102, stored in the building 103, which have a relatively high temperature, ensures the fast opening only valve 116 water supply, the respective water spray nozzles 112 located above the group of relatively high-temperature hot-rolled coils 102 that have not spent a lot of time in the warehouse after loading in building 103.

Water 115, which is supplied to each water spray nozzle 112 water pump 113 may be, for example, cold water that is heated (warmed up) after filing for use in the process of cooling during hot rolling mill equipment, hot rolling mill, which manufactures hot-rolled coils 102. Thus, because the energy corresponding to the dry heat required to heat the water 115 to the evaporation temperature can be reduced when water is 115, which is sprayed from the water spray nozzles 112, evaporates the heat retained in the hot-rolled coils 102, provides a useful structure in which the efficiency of steam production 117 heat retained in the hot-rolled coils 102 increases.

Other aspects of construction are the same as shown in Fig.9, and the same reference items refer to the same elements.

According to this variant implementation, similar to the device shown in Fig.9, the air heated in the building 103 warehouse 101 for the rolls, which stores the hot-rolled coils 102, convection heating through heat, keep aemula in each hot-rolled coil 102, is fed from the outlet 105 of the building 103 through the communication channel 106 to the tower 104 release.

Regarding hot-rolled coils 102, stored in the building 103, when the valve 116 water supply corresponding to each of the individual water spray nozzle 112 located above the group of relatively high-temperature hot-rolled coils 102, open, water 115, which is supplied from the water pump 113 through the channel 114 of the feed water is sprayed in the form of a spray or shower on a group of relatively high-temperature hot-rolled coils 102. Thus, some water droplets 115, which is sprayed on a group of high-temperature hot-rolled coils 102 are heated and evaporated by mid-fall through contact with air 109, which is heated convective heat retained in the hot-rolled coils 102. Moreover, the remaining portion of water droplets that are sprayed, falls to the group of relatively high-temperature hot-rolled coils 102, and drops of water that come into contact with each hot-rolled coil 102, directly heated and vaporized due to the heat held in each hot-rolled coil 102.

When the water is 115, which is sprayed on a group of relatively high-temperature hot-rolled coils 102 each water spray nozzle 112, heat is moved directly heat held in the group of hot-rolled coils 102, or indirectly heated air 109, and evaporates to form steam 117, the volume increased to one thousand and several hundred times. Thus, the amount of heated gas is significantly increased by the addition of large quantities of steam 117 created by the evaporation of water 115, sprayed from each water spray nozzle 112 in the 109 air, which is heated by convection heating, hot-rolled coils 102 of the building 103.

Thus, when the steam 117, mixed with the heated air 109 is offset from the outlet 105 of the building 103 through the communication channel 106 to the tower 104 is released, the air flow rate, rising in a tunnel-shaped air channel 104a in the tower 104 is released, can be increased and, thus, electricity generating turbine 107 provided in the tower 104 issue, driven by the accelerated air stream to effect the generation of wind energy.

Therefore, according to this variant implementation, in addition to obtaining the same effect as the device of figure 9, a large number of pair 117 is produced by the evaporation of water 115, sprayed from the water spray nozzles 112, using the heat retained in the hot-rolled coils 102. A large number of pair 117 is also entered in the tower 104 is released, to thereby provide a radical increase the s velocity of air flow, rising through the tower 104 release. Thus, the energy is recovered as electricity generating turbine 107 can be increased and the capacity of electricity generating turbine 107 can be considerably increased.

When newly produced hot-rolled coils 102, having a large number of retained heat, sequentially loaded into the warehouse 101 for the rolls, the earliest loaded a roll of hot-rolled coils 102, which is already stored in the warehouse 101 for the rolls, in other words, a hot roll 102 with the lowest temperature due to heat dissipation for the longest period of time, is discharged in the same sequence through the opening for unloading (not shown). Therefore, when the hot rolled coil 102 having a large number of retained heat, only loaded in the building 103 warehouse 101 coil, the valve 116 feed those valves 116 water supply provided for each of the water spray nozzles 112, which corresponds to a water spray nozzle 112 located above the newly downloaded hot rolled coil 102 is opened and a jet of water can be released on hot rolled coils 102, having a large number of retained heat, which was just downloaded in building 103.

On the other hand, stops the valve 116 water supply, which is relevant to the duty to regulate water spray nozzle 112, located above hot rolled coil 102, those hot-rolled coils 102, which is already stored in the warehouse 101 for the rolls, with temperatures that dropped to the level at which sprayed water 115 cannot effectively evaporate.

When the staff enters the building 103 warehouse 101 for the rolls to move the hot-rolled coils 102 or the like, the water spray 115 of the water spray nozzles 112 may be stopped.

Moreover, the present invention is not limited to the above-mentioned variants of implementation, and the outlet 105 of the building 103 warehouse 101 for the rolls can be provided in a predetermined position on a ceiling of the building 103, and not in a position near the upper section of the side wall, and the exhaust port 105 provided on the ceiling of the building 103 may be connected through the communication channel 106 with the lower section of the tower 104 release.

Provided that the electricity generating turbine 107 is driven upward air flow through the tower 104 release height, which is a power-generating turbine 107 in the tower 104 release, may vary accordingly. Moreover, instead of a tower 104 release electricity generating turbine 107 may be provided in the connecting channel 106. In this case, a cylindrical channel that corresponds to the diameter electrogenerated the second turbine 107, can be formed in the connecting channel 106, and power turbine 107 may be installed on the section of the cylindrical channel.

Since the existing tunnel for equipment exhaust is used as a tower 104 air release, construction work for tower 104 air release can be omitted, thereby facilitating the creation of cash-generating device storage high temperature thermoplates according to the present invention. Moreover, in this case, when the value stream, flow rate, pressure, etc. of release of air released through the tunnel through the existing equipment issue taken into account, the position of the joint, corresponding to the tunnel at the end towards the lower flow in the connecting channel provided in the outlet 105 of the building, which accommodates warehouse 101 for coils may be respectively provided so as to produce the air flowing through the tunnel is not changed over to the reverse, relative to the building 103 warehouse 101 for the rolls.

In the embodiment shown figure 11, although the valves 116 water supply that can be switched independently between the spray of water from each water spray nozzle 112 and the termination of spraying, respectively provided for each water spray nozzles 112, ensure uchenogo in the roof of the building 103 warehouse 101 for the rolls, one-way valve 116 water supply can be provided for each of the many water spray nozzles 112, secured inside a certain space in the building 103. Moreover, when the position to which newly produced hot rolled coil 102 with a large amount of heat loads in the building 103 warehouse 101 for rolls, water spray nozzle 112 may be provided only above the point at which newly produced hot rolled coil 102 with a large amount of heat is loaded.

The design of the above options may not be changed on the design, which provided the element to increase the efficiency of heating the air in the building 103, using the heat retained in the hot-rolled coil 102, stored in the building 103. For example, the lattice element (not shown)to allow passage of air to the lower side of each hot-rolled coil 102, is provided on part of the floor area of the building 103 warehouse 101 for the rolls, and hot-rolled coils 102, loaded to the warehouse 101 for the rolls are placed on the upper side of the grid element. In addition, the design can be changed to a construction in which the insulating element having heat-resistant properties, are designed to reduce heat dissipation in the earth's surface from the bottom portion of the building 103 warehouse 101 for rulona is.

On figa and 12B - figa and 14B shows another optional implementation of the present invention, applied to the warehouse 201 for the rolls, which is an example of storage high temperature thermoplates for temporary storage of hot-rolled coil 202, which is a semi-finished iron and steel, acting as a high-temperature thermoplates, which is manufactured using the equipment for hot rolling steel plant with a full cycle, working on their own raw materials, or the like, and its construction will be described below.

The lower end section of the cylindrical tower 204 air release, continuing in the vertical direction and provided on the upper side of the building 203 communicates with and is connected near the Central section of the ceiling of the building 203 warehouse for the rolls, which temporarily stores and accumulates the hot-rolled coils 202, manufactured by introduction of heat equipment for hot rolling to transfer to the next processing stage. Electricity generating turbine 205 is provided in a predetermined position in the vertical direction in the tower 204 air vent so that the surface of the ceiling of the building 203 warehouse for rolls smoothly connected with the inner side of the tower 204 air release through the formation of the lower end portion 204a of the tower 204 release air in f is RMI socket.

Moreover, ducts, providing a constant flow of air (outdoor air) 208 in a horizontal direction along the inner surface of each side wall 206 are provided in the set of specified locations on the lower section with four side walls 206, forming a peripheral wall of a building 203, so that the direction of air flow 208, sucked in a horizontal direction in the building 203 through each duct 207, consistent with the direction of air circulation either clockwise or counterclockwise, when viewed from above, for example, as shown in figv, all directions of air flow 208 passing through each duct 207 correspond the clockwise direction, when viewed from above.

More specifically, for example, as shown in figa and FIGU, duct 207 is formed as a channel NACA type, in which the hole 207a, attached to the building 203 and continuing with the specified size in the horizontal direction is made in the form of rectangular holes 207a, continuing vertically along the inner surface of the side wall 206 of the building. As shown in figa and 14B, the duct 207 may be made in the form of a flat channel tube type, in which the hole 207a, attached to the building 203 and continuing with the specified size in the horizontal direction is made in the form of direct the coal hole 207a, continuing vertically along the inner surface of the side wall 206 of the building. Thus, the air flow 208 in the horizontal direction along the inner wall 206a of the side wall 206 can be effectively created inside the building 203 by introducing air 208 in the building 203 of the outer section of the building through the duct 207. Moreover, the reference position 206b shown in figa and FIGU, and figa and figv marked the outer surface of the side wall 206.

The size of the duct 207 may respectively be set, given the size of the building 203 warehouse for the rolls, the height of the tower 204 of issue and the number of hot-rolled coils 202, typically stored in the building 203, so that the intake air mass was balanced by the quantity of air from the building 203 in the outer section when the air in the building 203 is heated by convective heat heat retained in the hot-rolled coils 202 stored in the building 203, rises in the tower 204 air release and is packaged in an outer area of the upper end openings of the tower 204 release. Moreover, the number of ducts 207 may also respectively be changed, so that the intake air mass was balanced by the quantity of air inside the building 203 in the outer area.

Opening for loading and opening for discharge to goryachkina what's coils 202 in the building 203 warehouse for rolls (not shown) may be provided in a given side wall 206 of the building 203 warehouse for rolls and can be equipped with opening and closing the door. Moreover, the duct, similar to the duct 207 may also be provided in the lower section of the door openings for loading and holes to upload.

Moreover, the means of transport (not shown) for hot-rolled coils 202 may be provided in the building 203.

Hot rolled coils 202, which is manufactured by hot rolling process, causing the introduction of heat from the equipment for hot rolling (not shown)is loaded opening for a load (not shown) in the building 203 warehouse 201 for the rolls, provided with a power generating device storage high temperature thermoplates, as described above, and is stored temporarily before being transferred to the next processing stage. Thus, the heat held in each hot-rolled coil 202 in the building 203 warehouse for the rolls is subjected to heat transfer in the air 208 in building 203, mainly due to convection heating, and thereby the air 208 in the building 203 is heated. The density of the heated air 208 is reduced, and it shifts to the tower 204 air vent in the ceiling part by ascent in the building 203 due to the total lifting force. After passing through the tower 204 exhaust the heated air is produced in the outer portion of the upper end of the outlet.

Therefore, low-temperature outside air introduced into the building the e 203 through the duct 207, which is provided in the lower area of the four walls 206 in the building 203 due to the ascent of the air 208 in the building 203 to the tower 204 air vent. Then, the air flow 208, introduced into the internal area of the building 203 through each duct 207 from the outdoor area of the building 203, passes along the inner surface 206a of the side wall 206 of the building 203. Moreover, all the currents of air 208 correspond to the clockwise direction, when viewed from above, and thus the air flow 208 that is absorbed into the internal area of the building 203 through each duct 207, formed mainly of the horizontal component that facilitates the passage along the outer periphery of the building 203. Therefore, the rotating air flow 208, which has a low level of vertical components can be created in the entire building 203, as shown in figv, the inertia of the air flow 208, sucked through each duct 207.

Because the air flow 208, forming a rotating flow in the building 203, has a low level of vertical components, the time required to reach the tower 204 air outlet provided near the center of the ceiling of the building 203 increases. Thus, the time of heat transfer for convection heating of each hot-rolled coil 202, distributed on a large surface area in the building 203 warehouse for p is lonow, increases, the temperature increase of the air 208, which is heated by convection heat from each hot-rolled coil 202, additionally increases.

Thus, since the density of air 208 in the building 203 can be reduced to thereby increase the lifting force, the magnitude of the air flow 208 can be increased with a slight air 208 in building 203, introduced into the tower 204 deflation and rising in him. Consequently, actuation of power-generating turbine 205 provided in the tower 204 air release may be executed by the rising air flow 208, which has increased the value stream in order to perform the generation of electricity.

Thus, according to the generating device storage high temperature thermoplates according to the present invention, the rotating air flow 208, which has a small vertical components can be created in the building 203 warehouse 201 for the rolls, which has increased the calorific through the accumulation and storage of hot-rolled coils 202, which have high temperature immediately after production. Moreover, the time of heat transfer of each hot-rolled coil 202 to 208 air in the building 203 can be increased. Thus, compared with a construction in which a hole is provided in the side wall 06 building 203 warehouse for the rolls, just to introduce outside air, the air 208 in the building 203 is heated more efficiently and the air heated in order to provide a greater lifting force can be introduced into the tower 204 air vent. Therefore, the value of the air flow upward in the inner area of the tower 204 release of air can be increased, the energy is recovered as electricity generating turbine 205 can be increased, and thus, the capacity of electricity generating turbine 205 may be increased.

Thus, it is possible to reduce the time required to return the capital costs associated with installation of the generating device storage high temperature thermoplates according to the present invention in the building 203 for warehouse 201 for the rolls.

On figa and figv shows a modified example of the device shown in figa and FIGU - figa and figv as another variant implementation of the present invention. In this example, similar to the design shown in figa and FIGU - figa and FIGU, lots of water spray nozzles 209 corresponding to the location of the hot-rolled coils 202, located in the building 203, is provided in the ceiling of the building 203. Moreover, line 211 water supply, introducing water 212 of the water pump 210 in the outer part of the building, respectively, are connected with each voorspel the tion nozzle 209, and water 212, supplied through line 211 water flow from the water pump 210, is sprayed in the form of a spray or shower on hot-rolled coils 202 stored in the building 203, each water spray nozzle 209.

Moreover, the valve 213 water supply corresponding to each of the individual water spray nozzle 209, is provided in line 211 water supply, attached to each water spray nozzle 209, so as to provide a separate switching between spray of water and 212 of each water spray nozzle 209, and stop spraying. Thus, selective spraying of water 212 to the group of hot-rolled coils 202 of the respective hot-rolled coils 202 stored in the building 203, which have a relatively high temperature, is provided by opening only valve 213 water, appropriate water spray nozzles 209, which are located above the group of relatively high-temperature hot-rolled coils 202, which are not spent much time in the warehouse after loading in the building 203.

Water is 212, which is supplied to each water spray nozzle 209 water pump 210 may be, for example, cold water that is heated (warmed up) after filing for use in the process of cooling during hot rolling mill equipment, hot rolling mill (not shown), which izgotovlen is no hot-rolled coils 202. Thus, because the energy corresponding to the dry heat required to heat the water 212 to the evaporation temperature can be reduced when water is 212, which is sprayed from the water spray nozzles 209, evaporates the heat retained in the hot-rolled coils 202, provides a useful structure in which the efficiency of steam production 214 heat retained in the hot-rolled coils 202 increases.

Other aspects of construction are the same as shown in figa and FIGU - figa and FIGU, and the same reference items refer to the same elements.

According to this variant implementation, similarly to the above-mentioned variants of the implementation of the 208 air enters the building 203 through each duct 207 provided in the four side walls 106 of the building 203 warehouse 201 for the rolls, which stores the hot-rolled coils 202, to thereby create an air flow 208 which rotates in building 203, at the same time, with low levels of vertical components.

When the valve 213 water supply corresponding to each water spray nozzle 209, located above the group of relatively high-temperature hot-rolled coils hot-rolled coils 202 202 stored in the building 203, opens, water is 212, which is supplied from the water pump 210 via line 211 of the feed water is sprayed in the form in which Danai dust or shower on a group of relatively high-temperature hot-rolled coils 202. Thus, some drops of water 212 sputtered to a group of high-temperature hot-rolled coils 202, is heated and vaporized in the middle during the fall through contact with air 208, which is heated convective heat retained in the hot-rolled coils 202. Moreover, the remaining portion of water droplets that are sprayed, falls to the group of relatively high-temperature hot-rolled coils 202, and drops of water that come into contact with each hot-rolled coil 202, directly heated and vaporized due to the heat held in each hot-rolled coil 202.

When the water is 212, sprayed on a group of relatively high-temperature hot-rolled coils 202 each water spray nozzle 209 is heated directly by the heat held in the group of hot-rolled coils 202, or indirectly heated air 208, and evaporates to form pairs 214, the volume increased to one thousand and several hundred times. Thus, the amount of heated gases in the building 203 can be increased significantly by the addition of large quantities of steam 214, created by the evaporation of water 212, sprayed from each water spray nozzle 209 in the air 208, which is heated by convection heating, hot-rolled coils 202.

Thus, since the pairs 214, mixed with rotating on the eye of heated air 208, shifted to the tower 204 air outlet provided near the center of the ceiling of the building 203, and passes through the inner section of the tower 204 air release, and then is released into the outer section through the upper end outlet, the air flow rate, rising in the tower 204 release of air can be increased. Thus, the power-generating turbine 205 provided in the tower 204 release is actuated accelerated upward air flow to carry out the generation of wind energy.

Therefore, according to this variant implementation, in addition to obtaining the same effect as the above embodiments of, a large number of pair 214 is created by evaporation of water 212, sprayed from the water spray nozzles 209, using the heat retained in the hot-rolled coils 202. A large number of pair 214 is introduced into the tower 204 is released, to thereby provide a radical increase in the rate of flow of air upward through the tower 204 release. Thus, the energy is recovered as electricity generating turbine 205 can be increased and the capacity of electricity generating turbine 205 can be considerably increased.

Thus, it is possible to reduce the time required to return the capital costs associated with installation of the generating device storage you atemperature thermoplates according to the present invention in the building 203 for warehouse 201 for the rolls.

Moreover, when the newly produced hot-rolled coils 202, which have a large number of retained heat, sequentially loaded into the warehouse 201 for the rolls, the earliest loaded a roll of hot-rolled coils 202, which is already stored in the warehouse 201 for the rolls, in other words, hot rolled coils 202 with the lowest temperature due to heat dissipation for the longest period of time, is discharged in the same sequence through the opening for unloading (not shown). Therefore, when hot rolled coils 202, which has a large number of retained heat, only what is loaded in the building 203 warehouse 201 coil, the valve 213 water supply of those valves 213 water supply provided for each water spray nozzle 209, which corresponds to a water spray nozzle 209 located above just entered hot rolled coil 202, opened, and the water jet can be used for hot rolled coils 202, which has a large number of retained heat and was just uploaded in the building 203.

On the other hand, the valve 213 water supply, which corresponds to a water spray nozzle 209 located above hot rolled coil 202 of those hot-rolled coils 202, which is already stored in the warehouse 201 for the rolls, which has a temperature, which fell to the Ural branch of the nya, when sprayed water 212 is unable to effectively evaporate, is closed.

When the staff enters the building 203 warehouse 201 for the rolls to move the hot-rolled coils 202 or the like, the water spray 212 of the water spray nozzles 209 can be stopped.

Moreover, the present invention is not limited to the above-mentioned variants of implementation, provided that the electricity generating turbine 205 is driven upward by the air flow passing through the inner area of the tower 204 is released, the height and position of power-generating turbine 205 in the tower 204 release may vary accordingly.

Although the duct 207 provided in the side wall 206 of the building 203 warehouse 201 for the rolls, was introduced by the channel NACA type figa and figv and flat channel tube type figa and FIGU, the design of the duct 207, different from the construction shown in the drawings may be used provided that the air flow 208 from the outdoor area of the building 203 passes through the duct 207 and passes into the internal area of the building 203, to thereby create an air flow 208 in the horizontal direction along the inner surface 206a of the side wall 206 of the building 203.

Vertical and horizontal location of each duct 207 provided in the side wall 206 of the building 203 may correspond the public to change in accordance with the shape, etc. of the building 203.

In the embodiment shown in figa and FIGU, the valve 213 water supply, which is separate switches between spray and stop spray of water and 212 of each water spray nozzle 209, respectively located in each water spray nozzle 209 provided in the ceiling of the building 203 warehouse 201 for the rolls. However, one-way valve 213 water supply can be provided for a variety of water spray nozzles 209 secured inside a certain space in the building 203. Moreover, in building 203 warehouse 201 for the rolls, when the position to which newly produced hot rolled coils 202, having a large number of retained heat loads, water spray nozzle 209 may be provided only above the point at which newly produced hot rolled coils 202, having a large number of retained heat load.

Moreover, the design can be amended to increase the heating efficiency of the air 208 in building 203, using the heat retained in the hot-rolled coil 202 stored in the building 203. For example, the lattice element (not shown)to provide air 208 to pass through to the bottom side of each hot-rolled coil 202, is provided on part of the floor area of the building 203 warehouse 201 for the rolls, and g is racemachine rolls 202, loaded to the warehouse 201 for the rolls are placed on the upper side of the grid element. Furthermore, the design can be supplemented insulating element having heat-resistant properties and located on the inner lower section of the building 203 warehouse 201 for the rolls to reduce the dissipation in the earth's surface from the bottom portion of the building 203 warehouse 201 for the rolls.

On Fig shows a further variant of implementation of the present invention, applied to the warehouse 301 coil, which acts as a repository for high-temperature thermoplates for temporary storage of hot-rolled coil 302, which is a semi-finished iron and steel, acting as a high-temperature thermoplates, which is manufactured using the equipment for hot rolling steel plant with a full cycle, working on their own raw materials, or the like, and its construction will be described below.

The lower end section of the cylindrical tower 304 exhaust, continuing vertically and provided on the upper side of a building 303 communicates with and is connected near the Central section of the ceiling of the building 303 of the warehouse for the rolls, which temporarily stores and accumulates the hot-rolled coils 302, manufactured by introduction of heat equipment for hot rolling to transfer to the next stage of processing. In addition, electricity generating turbine 305 is provided in a predetermined position in the vertical direction in the tower 304 exhaust so that the surface of the ceiling of the building 303 of the stock coil was smoothly connected with the inner side of the tower 304 exhaust through the formation of the lower end portion 304a of the tower 304 exhaust in the form of a socket.

Inlet channel 307 is provided on the lower end of the plot in the four side walls 306 building 303.

Moreover, many water spray nozzles 308 corresponding to the storage location of hot-rolled coils 302 located in the building 303, is provided in the ceiling of the building 303. Moreover, line 310 water supply, introducing 311 water from the water pump 309 to the outer area of the building, respectively connected to each of water spray nozzles 308, and 311 water supplied through line 310 water supply from the water pump 309, sprayed from each water spray nozzle 308 in the form of a spray or shower on hot-rolled coils 302 stored in the building 303.

Moreover, the valve 312 water supply corresponding to each of the individual water spray nozzle 308, is provided in line 310 water supply, attached to each of the water spray nozzles 308, so as to provide a separate switching between water spray 311 of each water spray nozzles shall 308, and stop spraying. Thus, selective spraying water 311 on those groups of hot-rolled coils 302 corresponding to a relatively high-temperature hot-rolled coils 302 stored in the building 303, is provided by opening only valve 312 water supply, the respective water spray nozzles 308, located above the group of relatively high-temperature hot-rolled coils 302, which are not spent much time in the warehouse after loading in the building 303.

Water 311, which is supplied to each water spray nozzle 308 water pump 309 may be, for example, cold water that is heated (warmed up) after filing for use in the process of cooling during hot rolling mill equipment, hot rolling mill (not shown). Thus, because the energy corresponding to the dry heat required to heat the water 311 to the evaporation temperature can be reduced when water is 311, which is sprayed from the water spray nozzles 308, evaporates the heat retained in the hot-rolled coils 302, provides a useful structure in which the efficiency of steam production heat retained in the hot-rolled coils 302, increased.

Although not shown, an opening for loading and opening for discharging hot-rolled coils 302 in the building 303 of the warehouse for the rolls can be is provided in a given side wall 306 of the building 303 of the stock coil and can be equipped with opening and closing the door. Moreover, the duct similar to the above-mentioned duct 307 may be provided in the lower section of the door openings for loading and holes to upload.

Means of transportation (not shown) for hot-rolled coils 302 may be provided in the building 303. In this case, the location of a vehicle (not shown) and each water spray nozzle 308 and line 310 water supply can be determined to avoid a collision.

Hot rolled coils 302, which is manufactured by hot rolling process, by introducing heat from the equipment for hot rolling (not shown) is loaded through holes for download (not shown) in the building 303 warehouse 301 for the rolls, provided with a power generating device storage high temperature thermoplates, as described above, and is stored temporarily before being transferred to the next processing stage. Thus, the heat held in each hot-rolled coil 302 in the building 303 of the stock coil is heat transfer to the air in the building 303, mainly due to convection heating, and thereby the air in the building 303 is heated. The density of the heated air is reduced, and it shifts to the tower 304 release in the ceiling part by ascent in the building 303 due to the total lifting force. After passing through the tower 304 you USCA air is produced in the outer section through the upper end of the discharge hole.

Low-temperature outside air introduced into the building 303 through the inlet duct 307, which is provided in the lower end area of the four outer surfaces of the walls in the building 303 due to the ascent of air in the building 303 to the tower 304 release. Then the air that is introduced into the building 303 of the inlet duct 307 sequentially heated by convection heat from the hot-rolled coils 302, and the air rises inside the building 303 to the tower 304 release. Thus, in building 303 warehouse 301 for the rolls, as shown by the arrow A in Fig, after climbing to the tower 304 release through the inner area of the building 303 of the inlet duct 307 secured to the four side walls 306, creates an upward air flow, which passes from the lower position up in the tower 304 release.

Regarding hot-rolled coils 302 stored in the building 303, when the valve 312 water supply corresponding to each water spray nozzle 308 located above the group of relatively high-temperature hot-rolled coils 302, opens, 311 water supplied from the water pump 309 via line 310 water, is sprayed in the form of a spray or shower on a group of relatively high-temperature hot-rolled coils 302. Thus, some drops of water 311 sputtered to a group of high-temperature hot-rolled Rusanov, heated and vaporized in the middle during the fall through contact with air, which is heated convective heat retained in the hot-rolled coils 302. The remaining part of water droplets that are sprayed, falls to the group of relatively high-temperature hot-rolled coils 302, and drops of water that come into contact with each hot-rolled coil 302, directly heated and vaporized due to the heat held in each hot-rolled coil 302.

Thus, building 303, when the water is 311, which is sprayed on a group of relatively high-temperature hot-rolled coils 302 each water spray nozzle 308 is heated directly by the heat held in the group of hot-rolled coils 302, or indirectly heated by the heated air and vaporized to form steam, the volume increased to one thousand and several hundred times and forms a large number of heated gases. Thus, the density of the vapor formed from the large quantities of hot gases generated thereby is reduced and it is shifted to the tower 304 release in the ceiling part by ascent in the building 303 due to the total lifting force, as shown by the arrow B in dotted lines in Fig, and mixed with the stream of heated air in the building 303. After passing through the tower 304 l is and the air is released into the outer section through the upper end of the discharge hole.

Thus, in the inner area of the tower 304 release in addition to the upward flow (arrow A) heated air is created upward steam flow (arrow B) in building 303, to thereby increase the speed of the air stream, which rises in the tower 304 exhaust, and be powered electricity generating turbine provided in the tower 304 edition using accelerated upward air flow in order to carry out the generation of wind energy.

Thus, according to the generating device storage high temperature thermoplates of the present invention, air can be heated more efficiently using the heat retained in the hot-rolled coils 302 in the building 303 warehouse 301 for the rolls, which are subject to high heat density by accumulating and storing high-temperature hot-rolled coils 302 directly after manufacturing. Moreover, since a large amount of steam can be created using heat retained in the hot-rolled coils 302, to evaporate the water 311, sprayed from the water spray nozzles 308, you can enter the upward flow of large quantities of steam generated in the building 303, tower 304 release. Thus, the flow rate of air rising inside the tower 304 exhaust drastically increased compared to the introduction of the descending air flow, which is heated only by convection heating of hot-rolled coils 302 in the building 303 of the tower 304 release. Thus, an increase in the speed of the upward air flow in the tower 304 release increases energy, which is recovered as electricity generating turbine 305, and thus provides a significant increase in power electricity generating turbine 305.

Thus, it is possible to reduce the time required to return the capital costs associated with installation of the generating device storage high temperature thermoplates according to the present invention in the building 303 warehouse 301 for the rolls.

Moreover, when the newly produced hot-rolled coils 302 that have a large number of retained heat, sequentially loaded into the warehouse 301 for the rolls, the earliest loaded a roll of hot-rolled coils 302 are already stored in the warehouse 301 for the rolls, in other words, hot rolled coils 302 with the lowest temperature due to heat dissipation for the longest period of time, sequentially discharged through the opening for unloading (not shown). Therefore, when hot rolled coils 302, having a large number of retained heat, only loaded in the building 303 warehouse 301 coil, the valve 312 water supply of those valves 312 water supply, secured decadeago of water spray nozzles 308, which corresponds to the water spray nozzle 308 located above just entered hot rolled coil 302 is opened and a jet of water can be released on hot rolled coils 302, having a large number of retained heat, which was just downloaded in the building 303.

On the other hand, the valve 312 water supply, which corresponds to a water spray nozzle 308 located above hot rolled coil 302 of those hot-rolled coils 302 are already stored in the warehouse 301 for the rolls, with temperatures that dropped to the level at which sprayed water 311 cannot effectively evaporate, is closed.

When the staff enters the building 303 warehouse 301 for the rolls to move the hot-rolled coils 302 or the like, the water spray 302 of water spray nozzles 308 can be stopped.

On Fig shows an example of the device shown in Fig, as another additional option of implementing the present invention. In this example, similar to the design shown in Fig, instead of attaching the pump 309 water supply to the line 310 water supply, which is connected with the respective water spray nozzles 308 located on the ceiling of the building 303 warehouse 301 coil, provided the tank 313 for rainwater, which is higher Polo is the situation, than the position where the corresponding water spray nozzle 308 on the ceiling part in the building 303, for example on the upper side of the roof of the building 303, connected to line 310 water supply. Moreover, the mechanism 314 extraction of rain water to extract the water falling on the building 303, installed in the tank 313 for rainwater.

Assuming that the reservoir 313 for rainwater is located in a higher position than the corresponding water spray nozzle 308 provided on the ceiling of the building 303 warehouse 301 coil, the tank may be secured in any position other than the roof of the building 303 warehouse 301 for the rolls. Moreover, the rainwater from the retrieval mechanism rainwater secured to the structural member above the building 303 warehouse 301 coil (not shown)may be collected in the reservoir 313 for rain water by gravity. Even in the absence of rainwater in the tank 313 for rainwater due to lack of rainfall, means for supplying water, such as water or the like, may be provided for the tank 313 for rainwater to continue the water supply 311 to the respective water spray nozzles 308.

Other aspects of construction are the same as shown in Fig, and the same reference items refer to the same elements.

Under this variant the NTU implementation apart from the fact that the same effect is obtained as in the embodiment shown in Fig, rainwater tank 313 for rain water can be fed under the action of gravity as the water 311 for spraying to each water spray nozzle 308 provided on the ceiling of the building 303. Thus, the energy required to supply water to each water spray nozzle 308 can be reduced and, thus, reduces the energy consumed during recovery as heat retained in the hot-rolled coils 302 stored in the warehouse 301 for the rolls.

Moreover, the present invention is not limited to the above-mentioned variants of implementation, and provided that the electricity generating turbine 305 is driven upward by the air flow passing through the inner area of the tower 304 release position and the height of the electricity generating turbine 305 in the tower 304 release may change accordingly.

In each of the above embodiments shows an example in which a water spray nozzle 308 is provided on the entire surface of the ceiling of the building 303 warehouse 301 coil and switching between spray and stop spray water 311 of each water spray nozzle 308 is provided with valve 312 water supply, provided the output in each water spray nozzle 308. However, one-way valve 312 water supply can be provided for each of the many water spray nozzles 308 secured inside a certain space in the building 303, and switching between spray and stop spray water 311 from a variety of water spray nozzles 308 secured inside a certain space in the building 303 may be provided with a control valve 312 water supply. Moreover, when the position to which newly produced hot rolled coils 302 with a large amount of heat loads in the building 303 warehouse 301 coil, water spray nozzle 308 may be provided only above the point at which newly produced hot rolled coils 302 with a large amount of heat loads in the building 303.

The flow of outside air into the building 303 of the outer area of the building 303 can be provided only through each inlet channel 307 provided in the side walls 306 building 303 warehouse 301 coil, and a valve (not shown) backflow prevention may be provided to prevent the release of gas into the outer section from the inner section of the building 303. Thus, when the steam is created by spraying water 311 of the water spray nozzles 308 a group of relatively high-temperature hot-rolled coils 302, which were introduced in the building 303, it is possible to prevent the risk of the issue is the ka of steam out through each inlet channel 307, provided in the side walls 306 building 303, even if produced an excess of steam, and thus, you can enter all the steam produced in the building 303, tower 304 release.

The design of the above options may not be changed on the design, which provided the element to increase the efficiency of heating the air in the building 303, using the heat retained in the hot-rolled coil 302 stored in the building 303. For example, there may be provided a construction in which the radiating panel (not shown)receiving the heat provided at the position which does not obstruct the water sprayed from the water spray nozzles 308 in the upper section of the building 303 warehouse 301 coil, or a transportable hot-rolled coils 302 or stored hot-rolled coils 302 or the inside of the side wall 306 of the building 303 of the stock coil. Can be provided with a design in which the grating element (not shown) to allow passage of air to the lower side of each hot-rolled coil 302 is provided on part of the floor area of the building 303 warehouse 301 for the rolls, and hot-rolled coils 302, loaded to the warehouse 301 for the rolls are placed on the upper side of the grid element. Can be provided with the construction in which the insulating element having heat-resistant properties, is made with the possibility of the reduction of heat dissipation in the earth's surface from the bottom portion of the building 303 warehouse 301 for the rolls.

All of the above describe embodiments of the application example storage area for rolls for temporary storage of hot-rolled coil 2, which is a semi-finished iron and steel, which are made at the metallurgical plant with a full cycle, working on their own raw materials, or the like, acting as high-temperature thermoplates, manufactured by introducing heat. However, you can also use to store semi-finished products of iron and steel, for example warehouse slabs, which temporarily stores the steel workpiece, such as a slab or the like, manufactured by continuous casting by introducing heat in steel plant with a full cycle. Moreover, provided that the storage temperature of thermoplates is intended for temporary accumulation and storage before transfer to the next processing stage, while keeping the heat dissipation in high temperature thermoisloated, manufactured by introducing heat various types of equipment that can be applied to any type of storage high temperature heat-radiating body.

It should be understood that various other modifications in the volume, which is not beyond the scope of the invention.

1. Generating device storage high temperature thermoplates containing:
Proc. of the BU, with the upper section made in the form of a cylindrical section, continuing up button located in the ceiling of the building storage high temperature thermoplates, which temporarily accumulates and stores high temperature thermoinsulating; and power generation turbine, which is located in a predetermined position in the cylindrical section in the pipe, to thereby generate electricity using upward air flow,
when this radiant panel heat receiving separated a specified distance from the facing side walls, is located on the inner side of the side wall of the building storage high temperature thermoplates.

2. The device according to claim 1, in which the supply channel is located in the lower section of the side wall of the building storage high temperature thermoplates.

3. The device according to claim 1, in which the radiating panel, receiving the heat is held vertically in a predetermined position in the upper part of the building storage high temperature thermoplates, which does not interfere with stored high-temperature thermoinsulating.

4. The device according to claim 1, in which the high-temperature thermoinsulating is a semi-finished iron and steel at the steel plant, and storage high temperature thermoplates is abouhalima for temporary storage of semi-finished iron and steel.

5. The device according to claim 4, in which the semi-finished iron and steel is a hot rolled coil manufactured equipment for hot rolling at a metallurgical plant, and storage for temporary storage of semi-finished iron and steel is a warehouse for the rolls.

6. The device according to claim 1, in which the high-temperature thermoinsulating is a hot rolled coil manufactured equipment for hot rolling at a metallurgical plant, and the tail section towards the discharge of hot-rolled coil in building equipment for hot rolling communicates with and is connected to a side section of the building storage high temperature thermoplates, which accumulates and stores hot rolled coil, to thereby enable the air to flow.

7. The device according to claim 1, wherein the grating element is located on the floor of the building storage high temperature thermoplates, to thereby provide a load on it high-temperature thermoplates.

8. The device according to claim 1, in which the insulating element having heat-resistant properties, is located on the inner lower section of the building storage high temperature thermoplates.

9. Generating device storage high temperature thermoplates in which the place is ublis the upper section of the side wall of the building storage high temperature thermoplates, which temporarily accumulates and stores high temperature thermoinsulating, communicates with and is connected through a connecting channel with the lower end section of the tower air release, which continues in a vertical direction and provided on the outer area separately from the building, with electricity generating turbine is located in a predetermined position on the tower of air release or a connecting channel, and the air is passed to a lifting force by heating in the building, is introduced into the tower of air discharge through the connecting channel, to thereby generate electricity air flow through the tower air release,
at this high temperature thermoinsulating is a hot rolled coil, which manufactured equipment for hot rolling at a metallurgical plant, and the roll is a semi-finished iron or steel at the steel plant and the storage building high temperature thermoplates, which communicates with and is connected through a connecting channel with the lower end section of the tower air release, is a warehouse for the rolls, with the stock coil is a storage building that temporarily stores and accumulates the semi-finished iron and steel, and the tail section towards the discharge Horacek anago roll in building the equipment for hot rolling and communicates with connected to a side section of the building stock for the rolls, in order to provide airflow.

10. The device according to claim 9, in which the existing tunnel for equipment exhaust is used as tower air release, which is separated from the building.

11. Generating device storage high temperature thermoplates, in which the lower end section of the tower air release, continuing in the vertical direction and located on the top side of the building, communicates with and is connected to the Central section of the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high-temperature thermoinsulating, and a duct providing air flow in a horizontal direction along the inner surface of the peripheral wall of a building, there are many preset positions on the peripheral wall of a building so that the direction of airflow in the horizontal direction in the building through each duct corresponded to the direction of air circulation either clockwise or counterclockwise, when viewed from above, while the power-generating turbine is located in a predetermined position on the tower of air discharge to thereby generate electricity using upward air flow.

12. Generating a storage device vysokotemperaturnogo, in which the lower end section of the tower air release, continuing in the vertical direction and located on the top side of the building, communicates with and is connected to the Central section of the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high-temperature thermoinsulating and water spray nozzle for spraying water at high temperature thermoinsulating stored in a building located in a predetermined position on a ceiling part of the building and is connected through a water supply line to water pump, while electricity generating turbine is located in a predetermined position on the tower of air discharge to thereby generate electricity using upward air flow.

13. Generating device storage high temperature thermoplates, in which the lower end section of the tower air release, continuing vertically and located on the top side of the building, communicates with and is connected to a specified position on the ceiling of the building storage high temperature thermoplates that temporarily stores and accumulates the high-temperature thermoinsulating and water spray nozzle is located in a predetermined position on a ceiling portion of the inner area of the building and is connected through a water supply line from the tank is La rainwater, located at a higher position than the position where the water spray nozzle, while electricity generating turbine is located in a predetermined position on the tower of air discharge to thereby generate electricity using upward air flow.

14. The device according to item 12 or 13, in which many water spray nozzles are located in a predetermined position on a ceiling portion of the inner area of the building, and a valve in the water supply is in compliance with each of the water spray nozzles.



 

Same patents:

FIELD: power industry.

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FIELD: power industry.

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FIELD: power industry.

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2 cl, 3 dwg

FIELD: power industry.

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3 cl, 1 dwg

FIELD: engines and pumps.

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2 dwg

FIELD: electricity.

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2 dwg

Windmill // 2382234

FIELD: engines and pumps.

SUBSTANCE: invention relates to wind power engineering. Proposed windmill comprises air wing, generator, coupling, brake, reduction gear, pulley block, coils and auxiliary weights. Pulley block weight approaching top position, first coil is de-energised and first auxiliary weight, moving down, unlocks coupling and brakes the drum. Pulley block weight approaching bottom position, second contact closed first contact for first coil to pull core in and throw in the coupling that couples reduction gear, drum and pulley block with generator shaft so that pulley block lefts the weight. In no-wind condition, second coil is de-energized for second auxiliary weight to lift first auxiliary weight so that drum brake is released and coupling is engaged to generate electric current due to pulley block weight gravity travel.

EFFECT: continuous operation irrespective of wind availability.

1 dwg

FIELD: power engineering.

SUBSTANCE: wind heat electric generator comprises cylindrical body with cover and bottom, driving vertical shaft, tube coil, electric generator and swirling device in the form of blades. Driving vertical shaft is connected via coupler with power shaft of wind-driven engine. Tube coil is connected to heating system or hot water supply system via nozzles of cold water inlet and hot water outlet. Driving shaft at the bottom is rigidly connected to disk installed freely in annular groove at cylinder bottom. Shaft is fixed to cylinder in centre via sealing devices, being mechanical connected via coupler to rotor of electric generator. On top of body bottom there is fixed disk, which contacts to cylinder bottom from external side. Blades that alternate with each other are horizontally fixed to driving shaft and internal wall of cylinder. Tube coil is installed outside body and is closed with jacket. At bottom inside body and cylinder bottom there cells arranged along the whole circumference, which are filled with heat accumulating substance of phase transition.

EFFECT: improved efficiency of mechanical energy transformation into heat energy with simultaneous production of electric energy.

2 cl, 1 dwg

FIELD: power engineering.

SUBSTANCE: geopower plant comprises a thermal chamber located at the depth of more than 1000 m from the Earth surface, a channel of air supply from atmosphere into the heat chamber, a channel of air drainage from the heat chamber into atmosphere, a power generator, a turbine of power generator drive installed at the outlet from the heat chamber. The method to increase capacity of the geopower plant consists in the fact that water is supplied via the air supply channel, for instance, water is supplied as sprayed via nozzles installed at the inlet to the channel of air supply. The geopower plant converts inner energy of Earth into power.

EFFECT: geopower plant makes it possible to reduce prime cost of 1 kWhr of power.

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