Numbering process and numerator to execute process

FIELD: printing industry.

SUBSTANCE: invention relates to the field of securities numbering. The method of treatment of a substrate in the form of sheets or periodically repeating sections of a roll consists in the fact that stacks from sheets or periodically repeating roll sections turned into separate sheets are formed and processed into packs of separate objects by cutting of the specified stacks along the specified rows and columns. At the same time the packs produced by means of serial cutting of the stacks that follow each form a continuous flow of serially numbered objects. A numerator for typographic numbering on sheet or roll printing machines, at the same time the specified numerator includes numbering wheels to form serial numbers. The numbering wheels are actuated by a fully sequential driving facility and a fully individually adjusted driving facility.

EFFECT: group of inventions makes it possible to form stacks in the form of a continuous flow of serially numbered objects.

11 cl, 27 dwg

 

The present invention relates to the process of numbering the numbering of objects such as banknotes, securities, passports, identification (ID) cards, and other similar objects arranged in rows and columns on the sheet substrate, and the method of processing the substrate using the above-mentioned process.

The present invention relates also to a serial device or a numerator for numbering objects, such as banknotes, securities, passports, ID cards, and other similar objects arranged in rows and columns on the sheet substrate.

In the technique of printing machines for securities having the form of a credit tickets such as banknotes, checks and other similar objects, an important feature, which is printed on the above-mentioned objects is the serial number. For example, each banknote is printed on a substrate, for example, a sheet of paper, gets a unique combination of numbers and letters that make up the serial number mentioned credit card.

In the technique known many processes numbering. For example, in U.S. patent 4,677,910, the content of which is incorporated into the present application by reference, a process and a device for processing sheets of securities, arranged in rows and columns on the base material in the form of paper rolls or sheets. Printed materials-the media after avatele pass through the read-out device, which determines the position of the defective credit tickets, indicated by, and transmits the position to the computer for storage in the memory, a computer-controlled cancelling a printer that applies on the defective banknotes stamp cancellation, and numbering machine. Numerovannie mechanisms of this numbering machines are nominated by the computer so that should be numbered serially always suitable paper prints consistently placed in any longitudinal row, and damaged credit cards are not taken into account. Then printed materials-carriers after passing through another reading device is cut into individual securities or credit cards, defective credit cards separated in the separation device, and the other, serially numbered individual securities picked up in bundles with the full sequence number in each. Thus ensure proper and continuous order of securities in packs regardless of the branch of the defective banknotes.

In the case of securities, usually printed in the form of a matrix on a substrate, there are several problems when you want to reach the foot of the individual securities, which are numbered with consecutive numbers. The first problem arises from the fact that each sheet of the substrate should be cut into individual banknotes. the button to ensure proper performance, it is impossible, in principle, to cut off each bill separately from each made of a sheet of substrate, and preferably put in a foot party of the sheets together and cut the corresponding known cutting device.

It was also established that a satisfactory compromise is reached when working with the soles of 100 sheets of the substrate, since this size is optimal for accurate cutting when assembled in the foot leaves should be cut into individual banknotes.

Another emerging problem is the individual numbering of each manufactured object, such as securities. Of course, it is impossible to count every single credit card if he already cut, serial numbers before the end of the so-called solid set of rooms, usually containing a million credit numbered tickets in a separate series. In fact, credit cards are numbered before cutting, i.e. when the backing sheet is still intact, and the numbering is part of the printing process credit notes, and not after the cutting operation. In accordance with this method is another option that should be considered is the presence of defective prints or defective credit tickets on the substrate. Since all credit cards stop numbered sequentially, foot credit tickets naselenia asno be put together with the bad credit tickets want to replace later than perfect credit tickets with the same serial numbers. U.S. patent 4,677,910 offers a solution to this problem in the above manner. However, in this patent, the sheet substrate is cut individually on separate credit cards: due to the presence of defective prints cannot be cut foot sheets at the foot of individual credit tickets, and separate credit cards to be sorted before folding in the foot for making credit packs of tickets with consecutive orders of rooms.

According to another process, the sheets containing defective prints are removed before the operation, numbering, and numbered only leaves without defective credit tickets.

Another process numbering described in the application for the European patent EP 0598679, the contents of which are incorporated into the present application by reference. In this process, for each sheet containing N prints credit tickets located transverse and longitudinal rows, which passes through the numbering machine with N numerovannie sections, the numbering of containing a solid set of numbers with W securities, and the number of sheets constituting a multiple of 100, the number N of prints credit tickets divided by 10, and on each page every 10 adjacent sheets of credit tickets form the group of des is ti, which receives the number to one and the same series of thousands. Additionally, in each sequence of 100 consecutive sheets of prints credit tickets, respectively located in the same position credit ticket, i.e. in the same transverse row and the same longitudinal row, numbered 100 consecutive numbers of the sequence of one hundred and ten prints credit tickets for groups of ten each sheet numbered numbers consecutive series of hundreds with the same units and tens. In addition, reprints of credit tickets for all subsequent sequences of 100 sheets each numbered numbers of consecutive series of thousands, in each case, with the same units, tens and hundreds of prints credit tickets, located in the same position credit tickets, so prints credit notes in a sequence of 100 sheets belonging to the same group of ten, getting a continuous sequence of non-specific sequence of the thousands, and prints the credit of rooms following sequence of 100 sheets belonging to the same group of ten, getting a continuous sequence rooms the following order of thousands, and prints credit tickets, DVD, the containing different groups of ten, numbers so that the numbers in one group of ten differ from the numbers in the other group of ten by an amount which is at least equal, W/Z, where Z is the number of groups of ten on a single sheet.

Another area of technology, which deals with the process of numbering prints or objects arranged in rows and columns on a substrate, is of course the region number of devices used to print the appropriate number on each individual imprint of the credit card. There are two main categories of such devices, which typically contain multiple digital wheels or discs that bear sequential numbers or letters, engraved in relief form their circle. Or digital wheels are driven sequentially, which means that this numbering device capable of printing only a sequential number, and the wheels are shifted by one step in a fixed sequence, or digital wheel operate freely and because of this we can take any position independently and is able to print any desired sequence number.

In numbering the devices of the first category applies a simple mechanism, which is able to change rooms only in sequential order. Digital wheel units are mechanically connected to the digital wheel of the tens, so the tens wheel is fed forward by one step only when the wheel units goes from 9 to 0. Similarly, the wheel hundred moves forward one step only when the tens wheel and wheel units moving from number 99 to the number 00 and so on. Therefore, this numerical device cannot skip a number or print the following any given room, and with this device you can only perform strictly sequential numbering process. These devices are known in the art and described, for example, in U.S. patent 4,677,910.

Numbering devices of the second category with movable digital wheels described in U.S. patent 5,660,106, the content of which is incorporated into the present application by reference. In this patent offers a numbering device that uses an electromagnetic system to block digital wheel in a predetermined position for each stage numbering of printed material. Therefore, described fully automatically installed numbering section gives the advantage of the ability to set at any time by choosing an arbitrary, even inconsistent rooms, allowing you to skip numbers in the sequence. A detailed explanation of the actions the number of sections contained in the description of U.S. patent 5,660,106 in General.

Dunn is e numbering devices, particularly useful for processes in which the missing numbers between credit tickets, numbers one and the same numbering device, or when the same number you want to print on two or more successive credit tickets. However, the numerical data sections there are such disadvantages that they are usually harder sequential numbering devices, which are usually entirely mechanical, and that they become very hot due to its design, according to which much of the energy expended in friction.

Another category of hybrid number of devices presented, for example, in U.S. patent 4,677,910 mainly on figures 6 and 6A, and the corresponding description data number of devices included in the present application by reference. This numbering device copes with the lack of fully sequential numbering devices and allows changes in the number sequence. Numerical device described in this patent contains six digital wheel (see, for example, figure 6A), i.e. from right to left, the wheel 21 for discharge units, the wheel 22 for the tens digit, the wheel 23 for the discharge of hundreds, wheel 24 for discharge of thousands, etc. All wheel mechanically linked to the implementation of a simple posledovatel the Noah numbering in addition to the wheel, the printing discharge units, which is kinematically independent from the others and moved by an electric motor. Due process of numbering used in this patent, according to which credit cards that are printed on the substrate and are arranged in a matrix, constructed from the rows and columns are numbered with consecutive numbers on the same sheet. Therefore, if the sheet is defective imprint, two adjacent credit ticket, namely the credit ticket, printed correctly, and the following credit ticket, receive the same serial number without changing the discharge units. Therefore, it is necessary to miss a single unit in the process of numbering, that is, to prevent movement of the wheel corresponding to the discharge units. For this reason, this wheel is driven independently by an electric motor and does not move when found defective prints if transaction numbering sheet.

There is therefore a need for simplified processes and devices numbering, which effectively solve various problems encountered in the field numbering of objects in rows and columns on the substrate, i.e. the substrate size or folded at the foot of a substrate, the process of numbering used to optimize the operation of the numbering and numbering at the of troist, able to complete the process of numbering.

The purpose of the present invention is to provide a method of numbering and improvements numbering devices.

In particular, the purpose of the present invention is to create a process of numbering, which allows for easier selection of numbered objects for making the stop of these sequentially numbered objects.

Another objective of the present invention is to create a numbering device that is both simple to manufacture, but is also able to print serial numbers in sequence.

The process of numbering and numbering devices according to the present invention is determined by the characteristics of the claims.

Other characteristic features and advantages of the present invention are evident from the following detailed description, given for non-limiting examples for the case of such securities, as the banknotes placed on the sheet substrate, for example paper in columns and rows, with the illustration of the above-mentioned examples of the attached drawings, in which

Figure 1 shows the first and last sheet of a batch of 100 sheets, numbered in ascending using numerical process according to the present invention.

Figures 2a-2h pok is given a sequential number, printed on each credit ticket for successive batches of leaves.

Figures 3A-3E show the serial numbers printed on each credit ticket for successive batches of sheets, while credit cards are located in five columns and nine rows.

Figures 4A-4C show the serial numbers printed numbered in descending order.

Figure 5 represents a schematic illustration of the numbering devices.

Figures 6-8 present the numbering device according to the present invention in the form in the future.

Description of the process according to the present invention begins with reference to figure 1, where as a non-limiting example illustrates the sheet securities on which the bills of credit, for example banknotes, printed in rows and columns in matrix form. Each credit ticket shall be seven-bit serial number (starting from the right) digit units digit tens digit hundreds digit thousands, etc. of Course, you can use more digits, as well as in combination with letters and other alphanumeric characters. Banknotes are usually printed in a continuous series of 1 million sequentially numbered credit tickets, why and shows an example with seven-digit serial numbers. In addition, the line is perpendicular the direction of movement of the sheet, and columns parallel to the aforementioned direction. In the example in figure 1 sheet contains 4*8 credit cards (four columns and eight rows).

The formula used in the process according to the invention allows to determine the initial number in the discharge of hundreds and thousands, to be printing on the first sheet of each batch of 100 consecutive sheets for each printed credit ticket sheet, numbering in ascending order.

The formula has the following form: Z=(j-1)+(i-1)*n+(m-1)*(k*n), where

Z is the initial number of digits in the hundreds and thousands for this position credit tickets in batches of 100 credit tickets

j is the position of this line of credit ticket

i is the column position of this credit ticket

n is the total number of rows on the sheet,

m is the number of a batch of 100 sheets (the first batch, the second batch and so on) and

k is the number of columns in the sheet.

Then the sequence of assignments end of the machine is i/j, i=1...k, j=1...n, starting from 1/1, 1/2, ... 1/n 2/1 2 ... /n ... k/n.

Accordingly, in this example, the number of digits R=7, k=4, n=8 and q=100 (lot of 100 sheets), so s=2.

In the example in figure 1, each printed credit ticket includes, without limitation this example, a seven-digit serial number, and credit tickets in batches of 100 sheets, which are in the same paragraph shall stand, that is, in the same row and the same column are numbered sequentially, and after 100 sheets numbered and stacked in the foot, in the row and column of the foot contains 100 sequentially numbered credit tickets. In addition, in the next line in the sequence assignments end of the machine in the same column contained 100 sequentially numbered credit card numbers, directly following the numbering of the preceding line, so that when a batch of 100 sheets cut on foot from 100 individual credit tickets, successive bundles are numbered sequentially.

This becomes clearer when referring to figure 1, which, by default, the successive sheets are moved in the downward direction, as shown by the arrow. First credit ticket the first sheet is at the bottom on the left hand side of the above-mentioned sheet and has a row position j=1 and the position of the column i=1, as shown in figure 1. As the first credit ticket, he gets the number 000 00 00. As described above, since a separate credit tickets in the same row position and column are numbered sequentially in order to fold the foot of 100 consecutively numbered credit tickets, when the foot is composed of 100 sheets, the credit ticket, receiving room 000 00 01 is credit the ticket at position j=1 and i=1 on the second sheet batch of 100 sheets, and similarly, credit ticket in the same position on the third sheet is 000 00 02 etc. For clarity, in the figure 1 presents not all 100 sheets of the party, and only the first sheet and the last sheet. Therefore, in accordance with the foregoing principle credit ticket at position j=1 and i=1 the last sheet in a batch of 100 sheets is 000 00 99. After 100 sheets of the party assembled in the stop position j=1 and i=1 actually contains 100 sequentially numbered credit card numbers 000 00 00 (first sheet), 000 00 01 (second sheet), 000 00 02 (third sheet) ... 000 00 99 (100-th sheet).

In accordance with the foregoing condition credit tickets located at the position j=2 and i=1 (second row, first column) get the serial number following the serial numbers of the credit tickets located at the position j=1 and i=1, therefore, as the credit ticket in this position of the last sheet in a batch of 100 is number 000 00 99, the credit ticket at position j=2 and i=1 for the first sheet in a batch of 100 retrieves the serial number 0000100, as shown in figure 1. Accordingly, the credit ticket in this position on the last sheet in a batch of 100 sheets, thus, receives the number 000 99 01 and so on for the following rows of the same column. Following this condition, credit tickets at position j=8 and i=1 obtain the serial number from 000 07 00 (first sheet) to 000 07 99 (the last leaf), and credit the ticket with the following serial number 000 08 00 is at position j=1 and i=2, i.e. in the first row, second column of the first sheet. The same principle is applied to each column, namely the credit ticket following the credit ticket at position j=8 i=2 the last sheet of the party of 10 sheets is at position j=1 i=3 of the first sheet in a batch of 100, etc. It allows you to pick up stacks of individual banknotes, which are numbered consecutively simple method for making the stop of banknotes, for example from 1000 banknotes, which are also numbered sequentially.

On the first sheet in a batch of 100 sheets seed in the discharge of the hundreds digit thousands and higher digits are determined by the formula above.

For example, at position j=1 and i=1 for the first batch of 100 sheets (m=1), the calculation gives:

Z=(j-1)+(i-1)*n+(m-1)*(k*n)=(1-1)+(1-1)*8+(1-1)*(4*8)=0+0*8+0*32=0, and, therefore, the number 000 00 00.

For example, in the position of j=5 and i=1 in the first game (m=1), the calculation gives:

Z=(5-1)+(1-1)*8+(1-1)*(4*8)=4+0*8+0*32=4, and, therefore, the number 000 04 00.

In another example, for position j=4 and i=3 in the first game (m=1), the calculation gives:

Z=(4-1)+(3-1)*8+(1-1)*(4*8)=3+16+0*32=19, and, therefore, the number 19 00 000. Accordingly, all the initial values of the digits in the hundreds and thousands for each credit ticket on the first worksheet in the party out of 100 are determined by this formula. After last numbered credit ticket to the party of 100 sheets, the first credit ticket to the next party must in order to get the next sequential serial number. In the example in figure 1 the last serial number assigned to a credit card, credit issued ticket at position j=8 and i=4, which receives the number 000 31 99. So the first number you want to use on the first sheet in position j=1 and i=1 the next batch of 100 sheets must be 32 000 00.

As in the example in figure 1, this serial number must be issued by a credit ticket at position j=1 and i=1 in the second batch of 100 sheets, as figure 1 represents the first batch of 100 sheets.

The calculation formula gives the following result, where m=2 (the second batch of 100 sheets):

Z=(j-1)+(i-1)*n+(m-1)*(k*n)=(1-1)+(1-1)*8+(2-1)*(4*8)=0+0*8+1*32=32, and, therefore, the number 32 00 000.

Accordingly, the calculated number exactly corresponds to the above number for discharges of hundreds and thousands, ie 32.

Detailed examples of sequence numbering is shown in figures 2a-2h for consecutive batches of 100 sheets containing 4*8 credit tickets, arranged in four columns and eight rows.

Figure 2A is similar to the figure 1 in that the numbering sequence in batches of 100 sheets is given in each position of the credit ticket, i.e. at position j=1 and i=1 000 00 00-000 00 99 (shown as 000 00 00..99), respectively, the rooms on the first sheet and the last sheet in a batch of 100 sheets in the figure 1. The first batch of 100 sheets gives thus credit tickets, Ponomareva the data from 000 00 00 (credit ticket at position j=1 and i=1 for the first sheet) to 000 31 99 (credit ticket at position j=8 and i=4 for the last sheet in the party).

The second batch are presented in figure 2b and gives credit tickets, numbered from 32 000 00 000 63 99.

The third party represented on figure 2C, gives credit tickets, numbered from 000 64 00 000 95 99.

The same applies to successive batches of 100 sheets, which are shown in figures 2d (fourth party), 2E (the fifth party), 2f (sixth party), 2g (seventh party) and 2h (eighth party), and the above explanation for the first batch of similarly applicable to the above-mentioned serial parties together with the above formula, can be used to identify discharges of hundreds and thousands on the first page of each party.

The formula is illustrated by other examples of calculations. For example, in part 4, column 1, non slip from 99 000 99 (line 4) to 001 00 00 (line 5).

Use formulas to calculate the number that should be printed at the position j=5 i=1 of the fourth party, gives the result:

Z=(5-1)+(1-1)*8+(4-1)(8*4)=4+0*8+3*32=100, and, therefore, room 001 00 00 for this position on the first page of the party 4.

Similarly, for a party of 7, in position j=1 and i=2, the formula results in a 200, and therefore, room 002 00 00 credit for the ticket at the given position on the first page of this party.

In figures 3A-3E shows the numbering sequence for parties of 100 sheets with the location is about 5 columns and 9 rows. Figure 3A shows numbers from 000 00 00 000 44 99 on figure 3b - from 45 000 00 000 89 99 on figure 3C - from 90 000 00 001 34 99, figure 3d - 001 35 00 001 79 99 and figure 3E - 001 80 00 002 24 99.

Again, as in figures 1 and 2a-2h, the numbers used in the discharge corresponding to the digits in the hundreds and higher discharges for each credit ticket on the first worksheet in each batch of 100, calculated by the above formula.

For example, the position j=1 and i=5 in the first game (m=1) gives the following value for Z:

Z=(1-1)+(5-1)*9+(1-1)*(5*9)=4*9=36, and, therefore, the serial number 36 000 00.

In another example, for j=2 i=2 batch 3 (m=3) Z is: Z=(2-1)+(2-1)*9+(3-1)*5*9=1+9+2*45=100, and, therefore, the serial number 001 00 00.

All initial values for the numbering of the first sheet in each batch of 100 sheets, respectively, are easily calculated using a simple algorithm, and it can be programmed before each party, for example, on a computer, if you know the number of credit tickets on a single sheet.

Due to the use of a special algorithm for numbering credit tickets on the sheet substrate standard numbering devices to apply it is impossible. Indeed, the bills of credit in a specific position of the credit ticket on the worksheet are numbered sequentially only in batches of 100 sheets. For example, at position j=1 and i=1, the serial numbers that mark is no printing on each sheet in the first batch of 100 sheets, in accordance with the foregoing, a change from 0000000 to 0000099 (see, for example, figures 1 or 2A). The natural sequence numbering series is only for discharge units and discharge hundreds.

At the end of the numbering of the first batch of 100 sheets of the next number, which must be printed on the first sheet, the second batch of 100 sheets in position j=1 and 1=1, not equal 000 01 00 (the next consecutive number after 000 00 99), and 32 00 000 (see figure 2b). Therefore, you must have the ability to transition from 000 99 00 000 32 to 00. For discharges of units and tens transition, actually, no, because 00 immediately follows 99, but the discharge and the hundreds digit thousands must make the transition from 00 to 32 in this position of the sheet. A similar problem applies to all credit positions tickets, in which, as shown in figures 2a-2h, the transition takes place, at least in the discharge of hundreds and thousands after each batch of 100 sheets, and the specified transition occurs for each new batch of 100 sheets.

When numbering down you can use a similar formula, and apply the above explanation for the numbering on the ascendant, but with appropriate modifications. The formula is: Z=D/10s-((0-1)+(i-1)*(i-1)*n+(m-1)*k*n), where D means the serial number from which to start numbering on down the line. This formula allows you established what your starting number, want to print on the first subject numbering substrate.

In figures 4A-4C shows an example of the numbering down to successive layers using the above formula to determine the initial numbers in batches of 100 sheets (S=2) with numbers containing 8 digits (P=8). In this example, the numbering starts descending with non 200000 (D=200000). In figure 4A the numbering sequence for parties from m=1 to m=3 are shown with numbers from 00200000 (m=1, j=1, i=1) to 00190401 (m=3, j=8, i=4); figure 4b the numbering sequence for parties from m=4 to m=6 is shown with numbers from 00190400 (m=4, j=1, i=1) to 00180801 (m=6, j=8, i=4); and figure 4C sequence numbering for parties from m=7, m=8 and m=63 shown with numbers from 00180800 (m=1, j=1, i=1) to 00174401 (m=8, j=8, i=4) and the layer 63 from 00001600 (j=1, i=1) to 00000001 (j=8, i=2). As you can see, the sequence ends in lot 63, column 2, line 8. This is logical, since in the described configuration with 32 objects on a substrate, each batch of 100 substrates gives 3200 numbered objects. 62 party give 198400 numbered objects (62*3200) and to get 200000 numbered objects should be numbered 200000-198400=1600 objects in the 63rd party. As the party gives 3200 objects, half of the party is sufficient to obtain other objects.

As shown above, you must use the enumerators that can allow numbers, Thu is to carry out the selected process numbering. In U.S. patent 5,660,106, for example, which is mentioned in this application, there are so freely programmable serial device that is able to print any given room, and even inconsistent numbers.

However, this numbering device is difficult to manufacture and therefore expensive, tend to generate heat and slowly change rooms due to the complexity of its mechanism. Consequently, there is a need to develop simpler numerator, which can carry out the numbering process of the present invention, and is fast, accurate and reliable.

Device numbering according to the invention contains a hybrid design that combines at least two different technologies, in which wheels are used for discharge of ones and tens digit, are connected and operate as sequential numbering device, i.e. entirely mechanical numerical section, and at least the wheels to discharge hundreds and discharge thousands are driven completely independently, for example, special motors, to ensure the transmission of rooms.

Further higher-order bits, numbers of wheels 5, 6, 7 and 8 (tens of thousands, hundreds of thousands, millions, ...), can be shifted sequentially mechanical system to which I will operate similarly to the system for discharges of units and tens.

Indeed, as shown for the above examples, it is enough that only the wheel for discharges of units and tens were operated entirely sequentially, because these bits are always the natural sequence (00-99) for serial numbers of sheets. This gives a special advantage, since these two digits are changed for each sheet, and the mechanical actuating mechanism is more reliable and fast than the mechanism used in programmable numerical device proposed in U.S. patent 5,660,106. Discharges of hundreds, thousands, or more high-order bits do not change numbers for each sheet and ignore the rooms, as mentioned above and described with reference to the examples shown in figures 1, 2a-2h and 3A-3E, therefore, freely programmable mechanisms necessary to move the corresponding digital wheels and actuators will operate only when changing bits 4 and 5 that occurs every 100 sheets.

Description options the implementation of the numbering device according to the invention is given with reference to figures 5-8.

With reference to figure 5 the principle of numbering devices is illustrated first for mechanical sequential numbering, i.e. for discharge units and discharge desad the century Numerical device contains seven digital wheels 1-7, namely the wheel 1 for units, wheel 2 to the tens wheel 3 for hundreds, etc. Preferably all-wheel mounted on the frame 8 to be rotated around a common axis 9. Wheels 1 and 2 are kinematically interconnected known in the art method, for example, described in U.S. patent 4,677,910. In fact, the well-known lever 10 of the front feeder is used for the front feeder digital wheels 1, 2. The lever 10 is installed with the possibility of rotation around the axis 9 and contains on one side of the drive roller 11 and on the other side of the holder 12 tabs work tabs 13, the so-called stoppers forward course. The holder 12 tabs work tabs 13 is installed to rotate around the axis 9 on the respective console arm 10 of the front feeder. The tabs 13 are tightened by a spring 50 so that they push in the direction of the grooves recorded on the digital side of the wheels 1, 2. The depth of the gaps between teeth of different digital grooves of the wheels 1, 2 and the length of the corresponding working retainers 13 are designed and calculated the size of the known methods so that the work clamp 13 relating to digital wheel 1 units, were always within the grooves of this digital wheel 1, but that the work clamp 13 relating to digital wheel 2 dozen, could be linked with hollows is the Olsen 2 only, if the digital wheel units is set to 0 in the process of numbering in descending order.

Further explanations concerning the functioning of the mechanical numbering devices described in U.S. patent 4,677,910, in particular, excerpts from column 4, line 54, to column 5, line 65, column 11, line 16 to column 12, line 31, which is incorporated into the present application by reference.

Then, as schematically shown in figure 5, the wheel 3 to discharge hundreds and wheel 4 for discharge of thousands are driven independently, for example, electric motors 15 and 16, through the gears 17, 18 (see figure 7). This allows you to quickly move both wheels 3 and 4 by any given number, and, consequently, it is possible to program a skip in the sequence numbering, printed label device. The principle independent of the Executive motor for digital wheel is proposed in U.S. patent 4,677,910 where you can find a detailed explanation of the functioning. Preferably the motors are automatically controlled from a computer device (not shown), in which the numbering sequence programmed/calculated for batch data sheets. Thus, gaps in the sequence numbering are known and can be included in the numbering unit numbering machine in% the SSE numbering.

The Executive mechanism of the digital wheels 6-8, etc. corresponding to the tens of thousands, hundreds of thousands and higher discharges (if available), made also preferably mechanically in series. However, it is included only when the algorithm requires increments of tens of thousands and later hundreds of thousands and higher digits.

With reference to figures 6-8 shows an example of the actuator for a wheel 5-7 in numerical device according to the invention. Numerical device contains nine wheels (wheels 1-8 and the wheel 8'), where the wheel 8' suitable for printing prefix printable wheels 1-8. The actuator includes a holder 12 retainers, which contains additional independent latches 25, these holder 12 is installed with the possibility of rotation around the axis 9. The latches 25 are installed on the holder 12 of the clamps can be rotated around the axis 14 and preloaded by a spring 26 so that they push in the direction of the grooves recorded on the digital side of the wheels 5, 6, 7. These tabs 25 will be activated only when the control latch 27 is released by the Cam 28 of the control. The Cam 28 of the control is rotated by the electromagnetic actuator 29, which its operation increases the digits 5, 6, 7 according to the algo is ITMU for the initial non-layer. This system is in principle similar to mechanical systems for wheels 1 and 2. The difference lies in its actuation of the latches 25 only when the mechanical release.

Numbering device according to the invention contains three steps: entirely mechanical stage, which is the most reliable mechanism for discharges of units and tens, changing all the time, stage driven by a motor for hundreds and thousands, which quickly works with digits, not changing all the time, but which ignores rooms, and electromagnetic stage for higher bits that are changed sequentially in numerical sequence with less frequency.

Numbering device according to the present invention gives the optimal solution value of the complexity and reliability of the principle of the systems used to drive the digital wheels, and also allows you to effectively implement specific numbering method.

On the basis of the proposed processes numbering it is possible to implement a method for processing a substrate in the form of sheets or rolls. According to this processing method, each sheet or each recurring period of roll contains objects that are located in k columns and n rows, and these objects are numbered by the number with p digits, linking the digits from 1 to s, from s+1 to r and from r+1 to R. the Foot of q sheets or q repetitive segments of the roll into individual sheets and molded and processed in packs of individual objects by cutting on these rows and columns, and thus q is divided to obtain a result on the 10swhen this bundle obtained by sequential cutting of successive stop, form a continuous stream of objects, sequentially numbers according to the formula proposed for numbering, either ascending or descending. As described above, in the target machine after party lists or stop roll, cut into sheets, cut into sequential foot, the sequence of assignments preferably has the form i/j, i=1...k, j=1...n, starting from 1/1, 1/2, ... 1/n 2/1 2 ... /n ... k/n. Going to the foot of the successive rows of the first column, then row of the second column and so on

Embodiments of the present invention is shown for example only and should not be considered as limiting the scope of the claims.

In addition, the examples provided in the present application is generally related securities, which are located on the sheet substrate, for example paper. However, it should be understood that the invention is not limited to securities, but is applicable to any objects that receive the serial number, which are arranged in rows and columns on the trail who were each other substrates, included in the numbering machine.

1. A method of processing a substrate in the form of sheets or recurring segments of the roll, in which each sheet or each recurring period of roll contains objects that are located in k columns and n rows, and these objects are numbered in such a way that each object provide the serial number that contains p bits, which includes the digits from 1 to s, from s+1 to r and from r+1 to p, with the initial value bits from s+1 to r serial number of each object is calculated for each of the first substrate party of 10ssuccessive substrates according to the formula Z=(j-1)+(i-1)*n+(m-1)*(k*n),
where j represents a string object, i denotes the column of the object and m is the batch of 10ssuccessive substrates, k*n less than 10sthat's less than p,
when this foot of q sheets or q recurring segments of the roll into individual sheets, molded and processed into bundles of individual objects by cutting above the stop on the said rows and columns, and thus q is divided to obtain a result on the 10swhen this bundle obtained by sequential cutting of successive stop, form a continuous stream sequentially numbered objects.

2. The method according to claim 1, in which said objects are securities, anketam, cheques, cards or numbers of objects that are arranged in rows and columns on a substrate.

3. The numerator for the implementation of typographic numbering sheet or roll-fed printing presses in accordance with the method according to claim 1, with the specified numerator differs completely consistent driving means (10, 11, 12, 13) for discharges from 1 to s, where 10sless than or equal to q, fully customizable driving means (15, 16, 17, 18) for discharges from s+1 to r, where the maximum number of printed digits from 1 to s and from s+1 to r, is less than or equal to k*n*q, and consistent driving tool(25, 26, 27, 28, 29) for discharges from r+1 to p.

4. The numerator according to claim 3, characterized in that it contains p numbering wheels (1-8) to print referred to p digits.

5. The numerator according to claim 3 or 4, characterized in that the fully sequential driving means (10, 11, 12, 13) for discharges from 1 to s contains a mechanical drive means.

6. The numerator according to claim 3 or 4, characterized in that the said fully customizable driving means (15, 16, 17, 18) for discharges from s+1 to r contains independent actuators (15, 16).

7. The numerator according to claim 3 or 4, characterized in that the said successive drive means(25, 26, 27, 28, 29) for discharges from r+1 to p contains an electromagnetic drive means (29).

8. The numerator for the sushestvennee typographic numbering sheet or roll printing machines, when the specified numerator contains p numbering wheels (1-8) to generate serial number with p digits, which includes the digits from 1 to s, from s+1 to r and from r+1 to p, while the above numerator differs in that the numbering wheels to the digits from 1 to s are fully consistent driving means (10, 11, 12, 13) and the fact that the numbering wheels for discharges from s+1 to r are fully customizable driving tool(15, 16, 17, 18).

9. The numerator of claim 8, wherein the fully sequential driving means (10, 11, 12, 13) for discharges from 1 to s contains a mechanical drive means.

10. The numerator of claim 8 or 9, characterized in that the said fully customizable driving means (15, 16, 17, 18) for discharges from s+1 to r contains independent actuators (15, 16).

11. Numbering machine for numbering objects located on the substrate, these machine differs in that it contains at least one enumerator according to claim 3 or 8.



 

Same patents:

FIELD: technological processes; printing industry.

SUBSTANCE: device represents numerator that comprises at least six numbering wheels, namely wheel of units digit, wheel of hundred's unit, wheel of thousand's unit, wheel of thousand tens unit and wheel of thousand hundred's unit. Wheels comprise combinations of ratchet profiles and cuts on their side surfaces. Mentioned numbering wheels are actuated by drive lever that interacts with above mentioned combinations of ratchet profiles and cuts on numbering wheels via the first and second drive pawls. The first drive pawl is a two-pronged drive pawl that interacts with ratchet profiles and cuts on the right side of units digit wheel and tens' unit wheel. The second drive pawl is a five-pronged drive pawl that interacts with ratchet profiles and cuts on front side of ten's unit wheel, hundred's unit wheel, thousand's unit wheel, thousand ten's unit wheel and thousand hundred's unit wheel.

EFFECT: provision of serial printing and therefore complete automation of carriers processing.

12 cl, 16 dwg, 28 tbl, 3 ex

FIELD: process engineering.

SUBSTANCE: numbering system is designed to be incorporated with printing machine and consists of numbering cylinder, rotary shaft, at least, one supporting disk fitted in said shaft to revolve therewith. Support disk comprises peripheral set ring to mount at least one numbering device 2.06 on support disk periphery. Said device 2.06 is secured to peripheral et ring by means of locking mechanism. Peripheral set ring features T-cross section that defines two annular mounting grooves on each side of the ring. Numbering device 2.06 has its each side supporting locking elements 2.50 to interact with annular mounting grooves for attachment of numbering device to peripheral set ring. Locking elements 2.50 represent, preferably, spring-loaded locking elements.

EFFECT: higher reliability, simplified design.

21 cl, 12 dwg

FIELD: printing industry.

SUBSTANCE: invention relates to the field of printing. Described system of sheets control intended for sheet printing machine for double-sided printing of such type comprises two printing cylinders intended to do simultaneous double-sided printing of sheets. At the same time specified system comprises at least one control device to produce images of one side of printed sheets. System of sheets control comprises the first and second transmission cylinders arranged between the first of specified two printing cylinders and chain system with grips provided in printing machine. At the same time printed sheets are moved serially from the first printing cylinder to the first transmission cylinder, to the second transmission cylinder and chain system with grips. Control device comprises linear shaper of image signals intended to produce image of one side of printed sheets by means of linear scanning, at the same time this linear shaper of image signals visually produces image of printed sheet, while printed sheet moves on the first or second transmission cylinder.

EFFECT: invention makes it possible to provide for efficient prevention of sheets smudging in process of control.

6 cl, 3 dwg

FIELD: printing industry.

SUBSTANCE: invention relates to the field of printing. Described system of sheets control, intended for sheet machine for double-sided printing of such type, comprises two printing cylinders, intended to do simultaneous double-sided printing of sheets, at the same time specified system of sheets control comprises at least the first control device to produce image of the first side of printed sheets. The first control device comprises the first linear shaper of image signals, intended to produce image of the first side of printed sheets by means of linear scanning. At the same time the first control device is arranged so that the first linear shaper of image signal visually produces image of printed sheet, while specified printed sheet still sticks to surface of the first of two printing cylinders of printing machine, and directly prior to displacement of specified printed sheet into chain system with grips provided in printing machine. Also printing machine equipped with control system is described.

EFFECT: invention makes it possible to provide for efficient prevention of sheets smudging in process of control.

12 cl, 3 dwg

FIELD: printing industry.

SUBSTANCE: method for adjustment of inking apparatus (16) of printing machine consists in the fact that in phase of preparation of printing machine for printing the first measuring accessory (22) is used to identify at least one first measuring value versus the one adjusted on inking apparatus (16) of printing machine, applied at least on one material for printing (21) of ink application, besides based on this first actual value inking apparatus applying ink onto material is adjusted for printing (21). In phase of printing machine run printing the second measuring accessory (23), which varies from the first measuring accessory (22) is used to identify several second actual values related to imprint applied onto material for printing (21) and to deliver to the adjustment device (26) that adjusts inking apparatus (16). One of second actual values detected by the second measuring accessory (23) is used in adjustment device (26) as a specified value, at the same time adjustment device (26) detects deviation of other second actual values identified in phase of printing machine run printing from applied specified value, and this deviation is minimised by new adjustment of inking apparatus that applies ink onto material for printing (21).

EFFECT: invention makes it possible to improve quality of printing.

16 cl, 2 dwg

Sensor device // 2335403

FIELD: physics.

SUBSTANCE: invention refers to fluorescing or phosphorescing print check and detection on sheets fed to printing press for securities printing. Luminescent sensor device contains set of subunits, optical sensitive elements, at that each subunit contains ultra-violet lighters for sample illumination, digital camera system containing front element, mirror assembly tracking light radiated from the specified sample to front element of digital camera system; and digital signal processor providing processing of signals, generated by the specified front element of digital camera system. Thus fluorescing or phosphorescing print check and detection system on security sheets contains luminescent sensor device.

EFFECT: improved control quality.

10 cl, 6 dwg

FIELD: polygraphic industry, possible use for controlling technological parameters of paper flat of input roll on printing factories, which is formed in advance at paper factory.

SUBSTANCE: in the method, length of flat part of input roll, which includes control marks, is selected as controlled parameter. Marks are positioned with constant value step, which is selected depending on technologically acceptable error relatively to length of roll flat, regulated by its tensioning during technological cycle of creation of this roll at paper factory. Detection, recognition and registration of informative signs of controlled parameter is performed twice. Namely: during insertion of a roll into technological zone of roll printing machine and during removal from it. Recording of read and transformed information in memory block of electronic computing device is performed with ensured storage of that information and its possible output to information carriers, which are functionally a "roll report" with given database, based on "roll passport" information. Particularities of the system are as follows. It is provided with second block of optic-electronic devices, functionally and structurally identical to first block. One block is mounted at the point of insertion of a flat into technological zone of roll printing machine, second one - at exit point of same. Each block has commutated connection to its own electronic computing device. In front of each block, flat speed sensor is mounted, in commutated connection with corresponding electronic computing device. Software of one of the blocks is created with possible creation of database of input roll flat, and of another block - of output roll flat, and with possible storage of that information in memory blocks and its output to information carriers, which functionally act as "roll reports".

EFFECT: possible control of technological parameters of flat at input and output of roll printing machine, resulting in increased precision of control.

2 cl, 5 dwg

FIELD: method and device for colored flexography.

SUBSTANCE: method for applying multiple paint layers onto a substrate includes following stages: application onto a substrate of at least one painting layer of energy-hardened liquid paint with viscosity less than approximately 4000 centipoises, and including reaction-incapable paint thinner, where applied layer of energy-hardened paint has first viscosity; evaporation of at least a part of reaction-incapable paint thinner from applied paint layer for increasing viscosity of applied layer of energy-hardened paint; application onto substrate and applied layer of energy-hardened paint with increased viscosity of at least one layer of non energy-hardened liquid paint, viscosity of which is less than increased viscosity of previously applied layer of energy-hardened paint; and drying of both paint layers on the substrate. Another variant of method for applying multiple paint layers onto a substrate is differentiated by applied layer of energy-hardened paint having to be of increased viscosity compared to following layer of energy-hardened liquid paint with viscosity less than approximately 4000 centipoises, and containing reaction-incapable paint thinner, where viscosity of following layer is less than increased viscosity of energy-hardened paint layer applied beforehand. Also a method is suggested for printing multiple paint layers on a substrate, which includes stage of selection of first and second energy-hardened liquid flexography paint, where each paint contains viscosity controlling reaction-incapable paint thinner, consisting of water in amount of from 5% to 50% of thinner weight, where each paint has viscosity approximately ranging from 30 to 70 centipoises, and stage of serial application of first and second energy-hardened liquid flexography paint onto a substrate to create first and second paint layers, having overlapping parts, where second paint is applied only after at least a part of paint thinner is evaporated in first paint layer. Device for serial application of multiple overlapping paint layers onto a substrate contains substrate route and substrate drive for moving the substrate along a route, where paint application sections are adapted for applying paint onto substrate, which paint includes reaction-incapable paint thinner and has viscosity less than 4000 centipoises, and also management system, which manages transportation of substrate along a route. Viscosity of first layer of liquid paint, applied onto a substrate in one of paint sections, is increased due to evaporation of at least a part of paint thinner from first paint layer to higher viscosity compared to viscosity of second paint, applied on top of first paint layer in next paint section, located at a certain distance from first paint section, up to viscosity, sufficient for "crude" application of second liquid paint layer during transportation of substrate between paint sections.

EFFECT: in suggested methods, relief printing is achieved without insignificant modifications of printing equipment.

4 cl, 2 dwg

FIELD: polygraphic industry, in particular, technique for processing of perfected paper sheets, in particular, bonds.

SUBSTANCE: apparatus has device for sequential feeding of sheets, transportation means, means for processing of said sheets, and means for sorting out of sheets into at least two paper sheet stacks. Indicated parts of apparatus are sequentially arranged in direction of advancement of said paper sheets. Means for processing of sheets has first print quality controlling device, device for applying series numbers and/or additional members onto sheets, second print quality controlling device adapted for controlling of applied numbers and/or images of additional members, and sheet marking device actuated in response to data generated by first and second print quality controlling devices for marking of sheets rejected by said first and second print quality controlling devices.

EFFECT: increased efficiency in carrying out of complex or part of said operations and provision for high-degree controlling of print quality.

12 cl, 5 dwg

FIELD: operative color control in printing presses for used primary and auxiliary colors by continuous conducting of spectral measurements in conjunction with linear equations for determining the required correction of printing ink feed for conservation of color precision in printing.

SUBSTANCE: when the color anomaly is exceeded, the measured values of the spectral reflectivity of the tested area are compared with the respective preset values, and the anomaly of the reflection spectrum is determined. The linear equations are used for correlation of the reflection spectrum anomalies with varieties of the solid ink density or thickness of the ink layer for ink feed control with the use of an operatively empitically produced corrective matrix, such that the reflection spectrum is minimized.

EFFECT: provided color control during printing with the use of spectral measurements.

65 cl, 4 dwg

FIELD: polygraphic engineering.

SUBSTANCE: method for printing of protected documents, in which the latters are printed on sheets, each containing a great number of protected documents. Each sheet has a unique type-readable identifier. In the process of production the lots are processed with the aid of several printing presses. On each printing press the identifiers are read off with the aid of a local computer separated for the given printing press. The results are transmitted by inquiry in the form of poles of data to the central data base. Each pile contains information on several sheets, which eliminates the necessity of transmission of the respective data in the conditions of real time through the network. To enhance the safety of reduction of dependence from operation, each local computer has a means of automatic checkup of the state of the lot processing.

EFFECT: checkout of printing production at a large enterprise at low requirements to hardware, software and computer circuit.

10 cl, 3 dwg

FIELD: polygraphic engineering.

SUBSTANCE: method for printing of protected documents, in which the latters are printed on sheets, each containing a great number of protected documents. Each sheet has a unique type-readable identifier. In the process of production the lots are processed with the aid of several printing presses. On each printing press the identifiers are read off with the aid of a local computer separated for the given printing press. The results are transmitted by inquiry in the form of poles of data to the central data base. Each pile contains information on several sheets, which eliminates the necessity of transmission of the respective data in the conditions of real time through the network. To enhance the safety of reduction of dependence from operation, each local computer has a means of automatic checkup of the state of the lot processing.

EFFECT: checkout of printing production at a large enterprise at low requirements to hardware, software and computer circuit.

10 cl, 3 dwg

FIELD: operative color control in printing presses for used primary and auxiliary colors by continuous conducting of spectral measurements in conjunction with linear equations for determining the required correction of printing ink feed for conservation of color precision in printing.

SUBSTANCE: when the color anomaly is exceeded, the measured values of the spectral reflectivity of the tested area are compared with the respective preset values, and the anomaly of the reflection spectrum is determined. The linear equations are used for correlation of the reflection spectrum anomalies with varieties of the solid ink density or thickness of the ink layer for ink feed control with the use of an operatively empitically produced corrective matrix, such that the reflection spectrum is minimized.

EFFECT: provided color control during printing with the use of spectral measurements.

65 cl, 4 dwg

FIELD: polygraphic industry, in particular, technique for processing of perfected paper sheets, in particular, bonds.

SUBSTANCE: apparatus has device for sequential feeding of sheets, transportation means, means for processing of said sheets, and means for sorting out of sheets into at least two paper sheet stacks. Indicated parts of apparatus are sequentially arranged in direction of advancement of said paper sheets. Means for processing of sheets has first print quality controlling device, device for applying series numbers and/or additional members onto sheets, second print quality controlling device adapted for controlling of applied numbers and/or images of additional members, and sheet marking device actuated in response to data generated by first and second print quality controlling devices for marking of sheets rejected by said first and second print quality controlling devices.

EFFECT: increased efficiency in carrying out of complex or part of said operations and provision for high-degree controlling of print quality.

12 cl, 5 dwg

FIELD: method and device for colored flexography.

SUBSTANCE: method for applying multiple paint layers onto a substrate includes following stages: application onto a substrate of at least one painting layer of energy-hardened liquid paint with viscosity less than approximately 4000 centipoises, and including reaction-incapable paint thinner, where applied layer of energy-hardened paint has first viscosity; evaporation of at least a part of reaction-incapable paint thinner from applied paint layer for increasing viscosity of applied layer of energy-hardened paint; application onto substrate and applied layer of energy-hardened paint with increased viscosity of at least one layer of non energy-hardened liquid paint, viscosity of which is less than increased viscosity of previously applied layer of energy-hardened paint; and drying of both paint layers on the substrate. Another variant of method for applying multiple paint layers onto a substrate is differentiated by applied layer of energy-hardened paint having to be of increased viscosity compared to following layer of energy-hardened liquid paint with viscosity less than approximately 4000 centipoises, and containing reaction-incapable paint thinner, where viscosity of following layer is less than increased viscosity of energy-hardened paint layer applied beforehand. Also a method is suggested for printing multiple paint layers on a substrate, which includes stage of selection of first and second energy-hardened liquid flexography paint, where each paint contains viscosity controlling reaction-incapable paint thinner, consisting of water in amount of from 5% to 50% of thinner weight, where each paint has viscosity approximately ranging from 30 to 70 centipoises, and stage of serial application of first and second energy-hardened liquid flexography paint onto a substrate to create first and second paint layers, having overlapping parts, where second paint is applied only after at least a part of paint thinner is evaporated in first paint layer. Device for serial application of multiple overlapping paint layers onto a substrate contains substrate route and substrate drive for moving the substrate along a route, where paint application sections are adapted for applying paint onto substrate, which paint includes reaction-incapable paint thinner and has viscosity less than 4000 centipoises, and also management system, which manages transportation of substrate along a route. Viscosity of first layer of liquid paint, applied onto a substrate in one of paint sections, is increased due to evaporation of at least a part of paint thinner from first paint layer to higher viscosity compared to viscosity of second paint, applied on top of first paint layer in next paint section, located at a certain distance from first paint section, up to viscosity, sufficient for "crude" application of second liquid paint layer during transportation of substrate between paint sections.

EFFECT: in suggested methods, relief printing is achieved without insignificant modifications of printing equipment.

4 cl, 2 dwg

FIELD: polygraphic industry, possible use for controlling technological parameters of paper flat of input roll on printing factories, which is formed in advance at paper factory.

SUBSTANCE: in the method, length of flat part of input roll, which includes control marks, is selected as controlled parameter. Marks are positioned with constant value step, which is selected depending on technologically acceptable error relatively to length of roll flat, regulated by its tensioning during technological cycle of creation of this roll at paper factory. Detection, recognition and registration of informative signs of controlled parameter is performed twice. Namely: during insertion of a roll into technological zone of roll printing machine and during removal from it. Recording of read and transformed information in memory block of electronic computing device is performed with ensured storage of that information and its possible output to information carriers, which are functionally a "roll report" with given database, based on "roll passport" information. Particularities of the system are as follows. It is provided with second block of optic-electronic devices, functionally and structurally identical to first block. One block is mounted at the point of insertion of a flat into technological zone of roll printing machine, second one - at exit point of same. Each block has commutated connection to its own electronic computing device. In front of each block, flat speed sensor is mounted, in commutated connection with corresponding electronic computing device. Software of one of the blocks is created with possible creation of database of input roll flat, and of another block - of output roll flat, and with possible storage of that information in memory blocks and its output to information carriers, which functionally act as "roll reports".

EFFECT: possible control of technological parameters of flat at input and output of roll printing machine, resulting in increased precision of control.

2 cl, 5 dwg

Sensor device // 2335403

FIELD: physics.

SUBSTANCE: invention refers to fluorescing or phosphorescing print check and detection on sheets fed to printing press for securities printing. Luminescent sensor device contains set of subunits, optical sensitive elements, at that each subunit contains ultra-violet lighters for sample illumination, digital camera system containing front element, mirror assembly tracking light radiated from the specified sample to front element of digital camera system; and digital signal processor providing processing of signals, generated by the specified front element of digital camera system. Thus fluorescing or phosphorescing print check and detection system on security sheets contains luminescent sensor device.

EFFECT: improved control quality.

10 cl, 6 dwg

FIELD: printing industry.

SUBSTANCE: method for adjustment of inking apparatus (16) of printing machine consists in the fact that in phase of preparation of printing machine for printing the first measuring accessory (22) is used to identify at least one first measuring value versus the one adjusted on inking apparatus (16) of printing machine, applied at least on one material for printing (21) of ink application, besides based on this first actual value inking apparatus applying ink onto material is adjusted for printing (21). In phase of printing machine run printing the second measuring accessory (23), which varies from the first measuring accessory (22) is used to identify several second actual values related to imprint applied onto material for printing (21) and to deliver to the adjustment device (26) that adjusts inking apparatus (16). One of second actual values detected by the second measuring accessory (23) is used in adjustment device (26) as a specified value, at the same time adjustment device (26) detects deviation of other second actual values identified in phase of printing machine run printing from applied specified value, and this deviation is minimised by new adjustment of inking apparatus that applies ink onto material for printing (21).

EFFECT: invention makes it possible to improve quality of printing.

16 cl, 2 dwg

FIELD: printing industry.

SUBSTANCE: invention relates to the field of printing. Described system of sheets control, intended for sheet machine for double-sided printing of such type, comprises two printing cylinders, intended to do simultaneous double-sided printing of sheets, at the same time specified system of sheets control comprises at least the first control device to produce image of the first side of printed sheets. The first control device comprises the first linear shaper of image signals, intended to produce image of the first side of printed sheets by means of linear scanning. At the same time the first control device is arranged so that the first linear shaper of image signal visually produces image of printed sheet, while specified printed sheet still sticks to surface of the first of two printing cylinders of printing machine, and directly prior to displacement of specified printed sheet into chain system with grips provided in printing machine. Also printing machine equipped with control system is described.

EFFECT: invention makes it possible to provide for efficient prevention of sheets smudging in process of control.

12 cl, 3 dwg

FIELD: printing industry.

SUBSTANCE: invention relates to the field of printing. Described system of sheets control intended for sheet printing machine for double-sided printing of such type comprises two printing cylinders intended to do simultaneous double-sided printing of sheets. At the same time specified system comprises at least one control device to produce images of one side of printed sheets. System of sheets control comprises the first and second transmission cylinders arranged between the first of specified two printing cylinders and chain system with grips provided in printing machine. At the same time printed sheets are moved serially from the first printing cylinder to the first transmission cylinder, to the second transmission cylinder and chain system with grips. Control device comprises linear shaper of image signals intended to produce image of one side of printed sheets by means of linear scanning, at the same time this linear shaper of image signals visually produces image of printed sheet, while printed sheet moves on the first or second transmission cylinder.

EFFECT: invention makes it possible to provide for efficient prevention of sheets smudging in process of control.

6 cl, 3 dwg

FIELD: process engineering.

SUBSTANCE: numbering system is designed to be incorporated with printing machine and consists of numbering cylinder, rotary shaft, at least, one supporting disk fitted in said shaft to revolve therewith. Support disk comprises peripheral set ring to mount at least one numbering device 2.06 on support disk periphery. Said device 2.06 is secured to peripheral et ring by means of locking mechanism. Peripheral set ring features T-cross section that defines two annular mounting grooves on each side of the ring. Numbering device 2.06 has its each side supporting locking elements 2.50 to interact with annular mounting grooves for attachment of numbering device to peripheral set ring. Locking elements 2.50 represent, preferably, spring-loaded locking elements.

EFFECT: higher reliability, simplified design.

21 cl, 12 dwg

Up!