PL141622B1 - Counter-memory unit,especially for flat waving knitting machine - Google Patents

Description

The subject of the invention is a memory-counter unit, especially for a flat undulating knitting machine, for counting the spools made and for activating the program shifter after making the number of spars based on a given program segment, with the weaving technique and the number of knitting stitches also according to a given program segment, where from one The program reader transmits data to the memory-counter unit, concerning the programmed number of rarities, and on the other hand, the sparse pulse transmitter - data concerning the number of rarities made. As it is known, in flat knitting machines waving a knitting weave is performed according to a given program, usually fixed on the programming cards. The program shows, in order, how many spans and with which knitting technique, and also the number of knitting stitches to be made. For this reason, to control knitting machines, the so-called a memory-counter unit, adapted to count the spools already made and to start the program shifter when the knitting working units have already made the number of spars according to a given program segment with the knitting technique provided therein and the number of knitting stitches. In known solutions, various electromechanical methods are used for this purpose: for example, in a flat undulating knitting machine for heavy knitting of the Textima type (manufactured in East Germany), on one side, signals read from the programming card lead to the correct position of the marking machines of the binary numbering system, respectively to the created group of these machines, on the other hand, the marking machines also receive, by means of a spine pulse transmitter, information about the number of spars made by the knitting machine, therefore the marking machines are triggered by sparse pulses, ensuring that the knitting spars are performed according to a given segment of the program as long as until it is returned to its home position. The program shifting then takes place and the next sparse is performed by the individual workgroups on the basis of the new program segment. To one control unit belongs simultaneously a number of, for example twelve, working units. These electromechanical solutions are characterized by the following disadvantages. Their reliability and durability is relatively short, as is the case with most electromechanical components, since they are subject to wear.2 141622 Another disadvantage is that the operation of the respective units is noisy. In addition to the mechanical noise, they can also cause radio-electric interference, which can cause faults in other current circuits. Another disadvantage is the relatively high consumption of electricity. Reliable operation of the memory / meter unit results in a product defect (e.g. a dimensional error) that cannot be eliminated, and in this case all the working units produce a fault due to the parallel operation of several such units. The aim of the invention is to develop a solution by which the above-mentioned defects are eliminated, and thus the flat undulating knitting machine is able to work reliably. According to the invention, this aim was achieved thanks to the fact that the memory-counter unit was equipped with a memory with the possibility of writing and reading , comparator, sparse counter, forbid and allow counting stage, I element and program end stage, so that on the one hand the program reader is connected to the inputs for writing and the memory outputs for reading are connected with comparator inputs, with on the other hand, the sparse pulse transmitter is it is connected to the input of the stage that prohibits or allows counting, the output of which is connected to the input of the rarer counter, and the outputs of the rarer counter are connected to the inputs of the comparator, and the comparator outputs are connected to the inputs of the element I, while the output of the element I is connected to the input of the end of the program which is instructed with a program reader or with a write-capable memory input, followed by a number of spars, and also directly or via a power amplifier with a program shifter. In the event of an abnormal start-up voltage level, it is necessary to use a matching step between a program reader and a memory preferably formed by optical coupling. It may also be necessary to use a matching stage between the forbidding and counting stage and the rarer counter. It may also be necessary to provide for decoupling of the signal from the rarer pulse emitter; then regular signals, for example quadrilateral, already reach the input of the decoupling stage from the output of the decoupling stage. If necessary, it is advisable to provide the memory with a manually activated programming stage. It becomes necessary, for example, in the case of a prolonged lack of voltage, so that the operator can, after restoring the voltage and deleting any false information, enter the information corresponding to the actual condition (based on the program on the card and the part made by knitting). supply voltage, supplying the components of the memory-counter unit with the supply voltage, with time-set data protection and an alternate power source, e.g. a battery. In the absence of such equipment, the stored data is deleted in the event of a power failure, so that not only is the operation interrupted, but also deficiencies occur. The subject of the invention is illustrated in the example of the embodiment in the drawing which shows a block diagram. In the block diagram shown in the figure, the program reader 7 enters the program stored on the program card, via an optically-coupled matching stage 9 into a memory 1 having also a manually actuated program stage 11. On the other hand, a pulse transmitter Rare 8, located at the main shaft, responds to sparse made on a flat waving knitting machine and transmits information about them to the binary counter 3 via the 4 degree, prohibiting and allowing counting, and the matching stage 10, and also via the decoupling stage 15. Comparatorbinary 2 compares the memory signals 1 and li of the sparse switch 3, and the output of the comparator 2 reaches the end of the program 6 via a five-input element 15, which stage is connected to the memory 1, the program reader 7, the sparse counter 3 and via a power amplifier 14 with a program shifter. All components are supplied with electrical voltage from a stabilized power supply unit 12, which is provided with a step 13 in the event of a mains failure, including a time-set data backup and a backup power source. The point is that, during operation, semiconductor memories lose their information content in the event of a temporary power failure. The difficulties caused by such short interruptions in the supply of electrical voltage are eliminated by stage 13, which includes a time-set data protection and a backup power source; with this stage 13, the memories retain their information content for a few minutes after the mains voltage interruption, and this is enough for the operator to be able to read the temporary information content from the indicating devices connected with the memory 1 and the sparse counter 3 , then subtract the reading results from each other, note and when re-energizing the mains voltage, store the subtraction result 1 with the manually operated program step 11. This means that the program does not run incorrectly in the event of a power failure. In the solution according to the example given, in the event of a power failure lasting more than four minutes, the stage containing the time-set data backup and the backup power source will turn off automatically. Stage 13, which includes time-controlled data protection and a backup power source, has a battery 14, charged from the mains during unit operation via a charge circuit 21, a sensing unit 17, responding to a mains failure, lasting more than four minutes, a quick switch 18 having the form of a Schmitt trigger, a switch 19, a directional valve 2i comprised of diodes and contributing to the fact that the battery 16 only supplies the components of the memory / counter in the absence of a mains voltage. In the absence of mains voltage within four minutes, the battery 16 takes over the power to the components without special switching, thus ensuring that the stored data is not erased. In the absence of voltage for more than four minutes, the sensor unit 17 transmits a signal to the quick switch 18 which actuates the switch 19 which disconnects the battery 16 from the mains supplying the components. A four-minute period of time is sufficient for the operator to be able to read the indications from the individual components regarding the necessary data, and to activate the program stage 11, intended for manual start-up after the mains voltage recovers. Memory task 1 is to collect until the end of the counting of information, registered from the program card. In this case, it is necessary to accumulate at most five bits. The task of the comparator 2 is to compare the binary number entered in the memory 1 with the content of the sparse counter 3. The task of the sparse counter 3, in turn, consists in counting the pulses that come from the sparse pulse emitter 8, located at the main shaft of the undulating flat knitting machine. In the described example, a binary asynchronous preliminary counter was used as a rarer counter. The task of the step 4, which prohibits and allows counting, is to block, if necessary, the pulses coming from the rotating main shaft of the heaving flat knitting machine, and then to allow these pulses again. . This is necessary when a flat undulating knitting machine is set up after a new program segment, e.g. when adjusting to quantitative increase. Such a setting requires some time and then there is a pause in knitting, but the main shaft of the knitting machine continues to rotate, as a result of which, at the input of stage 4, prohibiting and allowing counting, sparse pulses appear. If these pulses also reached the rare counter, then the knitting machine would not run according to the program. For this reason, it is necessary that during the so-called These pulses were blocked (e.g., to increase or decrease the knitting parameters). The output signal appears at the output of the I 5 element when the signal is present at all five inputs, i.e. when the knitting machine has performed the number of knitting threads according to the program segment. 6 fulfills a number of functions in the described example, namely: "deleting" (with delay), "prohibiting" ("enabling"), starting the power amplifier 14. The "deleting" function becomes necessary after reading all program segments, because only when memory 1 and an empty sparse counter 3, it is possible to save and read the next program segment or information and run on rare occasions. The program end stage 4 141 622 6 thus clears the contents of both memory 1 and sparse counter 3 after the execution of the program segment concerned - understandably with a certain delay, since the mechanical parts are only able to follow the electronic parts with a certain time drift. It is also advantageous to allow manual deletion at the end of the program. In order to avoid writing possible false information later, it is necessary to "prohibit". Program end stage 6 prohibits further input into memory 1 after information has been entered, so that the reader is programmed to be blocked. It could also be used. direct disabling in case of memory 1. Program end stage 6 transmits a signal via the power amplifier 14 to the program shifter for further movement of the program card. Information stored on the program card about the number of spars to be made with a given knitting pattern and the same number of knitting stitches , takes place via the matching step 9 by means of the program reader 7 to the memory 1 which is in the erase state. The idle state of the element 15 with five inputs is interrupted and the end stage of the program 6 is started if the input of information occurs. and to memory 1. As long as no writing takes place, element 15 transfers to memory 1 via program end stage 6 a permanent command to erase information. After entering the information into the memory, the 1st stage of the program end 6 blocks the program reader 7 with a delay of a few microseconds using the signal coming from the I 5 element, thanks to which any false information cannot reach the memory 1. On the other hand, the sparse pulse transmitter 8 at the main flat shaft The undulating knitting machine transmits, however, one pulse when knitting, each rare to the degree 4, forbidding or allowing counting, as well as to the binary sparse counter 3 via the matching stage 16 and the decoupling stage 15. At the comparator input 2, the signals, read from binary numbers, arrive on one side from memory 1, on the other side from the sparse counter 3. The signal starting the program end stage 6 appears at the output of comparator 2 via element 15 when all bits at the comparator 2 input are equal according to the positional values, and thus when actually done li the number of spars corresponds to the programmed number. The program end stage 6 is then operational, which deletes the information in memory 1 and in the sparse counter 3 so that the process can restart from zero with the next program on the cards. The program shift necessary for the next implementation stage is also carried out by the program end stage 6 after the power amplifier 14 has been started. As advantages of the memory / counter unit according to the invention are: very reliable starting, long life, noiseless operation, relatively low energy consumption and simple structures. Patent claims rzez1. A memory-counter unit, especially for a flat undulating knitting machine, for counting the knitting spars made and for activating the program shifter after performing the number of spars on the basis of a given program segment, with the weaving technique and the number of knitting stitches also according to the given program segment , whereby the information about the number of rarities according to the program is transmitted to the memory-counter unit on the one hand by the program reader, and on the other hand, the information on the number of rarities actually made - by the sparse pulse transmitter, identified by the fact that its basic components are: memory ( 1) with the possibility of working writing and reading, comparator (2), sparse counter (3), stage (4) forbidding and allowing counting, element I (5) and program end stage (6), with a program reader ( 7) is linked to the memory inputs (1), and the memory outputs (1 ) for reading, are connected to the inputs of the comparator (2), on the other hand, the sparse pulse transmitter (8) is connected to the input of the forbidding and counting stage (4), the output of which is connected to the rarefaction counter input (3), and the outputs of the sparse counter (3) are connected to the inputs of the comparator (2), moreover the outputs of the comparator (2) are connected to the inputs of the element I (5), 141622 5 while the output of the element I (5) is connected to the input of the program end stage (6) which is connected to the program reader (7) or to the write-capable memory input (1), further to the sparse counter (3), and also directly or via a power amplifier (14) to the program shifter. 2. Memory-counter unit according to claim The method of claim 1, characterized in that between the program reader (7) and the memory (1) there is also a matching stage (9) preferably with optical coupling. 3. Memory-counter unit according to claim The method of claim 1, characterized in that there is also a matching step (10) between the prohibition and counting step (4) and the rarer counter (3). 4. Memory-counter unit according to claim A method as claimed in claim 3, characterized in that there is also a decoupling stage (15) between the prohibiting and allowing stage (4) and the rarer counter (3). 5. Memory-counter unit according to claims A method as claimed in claim 1, characterized in that the memory (1) is also provided with a manually operated program stage (11). 6. Memory-counter unit according to claim A method as claimed in claim 1 or 5, characterized in that the power supply unit (12), which supplies its components with a supply voltage, is provided with a stage (13) containing a time-adjustable data protection circuit and a backup power source. 7. Memory-counter unit according to claim 6. A method according to claim 6, characterized in that the stage data protection circuit (13) consists of a sensor unit (17), which responds to the duration of the mains voltage failure, a quick switch (18), a switch (19) and a directional valve (20). the alternate source of current is connected via the switch (19) and the downstream directional valve (20) to the component supply network, and the control input of the switch (19) is connected to the output of the quick switch (18) on the behind the team (17), responding to the duration of the power failure 141622 1) Lt — i "i 1 - 1 * 1 M CD XT cn Printing Workshop of the UP PRL. Circulation 100 copies Price PLN 130 PL

Claims (7)

Patent claims 1. ¦1. A memory-counter unit, especially for a flat undulating knitting machine, for counting the knitting spars made and for activating the program shifter after performing the number of spars on the basis of a given program segment, with the weaving technique and the number of knitting stitches also according to the given program segment , whereby the information about the number of rarities according to the program is transmitted to the memory-counter unit on the one hand by the program reader, and on the other hand, the information on the number of rarities actually made - by the sparse pulse transmitter, identified by the fact that its basic components are: memory ( 1) with the possibility of working writing and reading, comparator (2), sparse counter (3), stage (4) forbidding and allowing counting, element I (5) and program end stage (6), with a program reader ( 7) is linked to the memory inputs (1), and the memory outputs (1 ) for reading, are connected to the inputs of the comparator (2), on the other hand, the sparse pulse transmitter (8) is connected to the input of the forbidding and counting stage (4), the output of which is connected to the rarefaction counter input (3), and the outputs of the sparse counter (3) are connected to the inputs of the comparator (2), moreover the outputs of the comparator (2) are connected to the inputs of the element I (5), 141622 5 while the output of the element I (5) is connected to the input of the program end stage (6) which is connected to the program reader (7) or to the write-capable memory input (1), further to the sparse counter (3), and also directly or via a power amplifier (14) to the program shifter. 2. Memory-counter unit according to claim The method of claim 1, characterized in that between the program reader (7) and the memory (1) there is also a matching stage (9) preferably with optical coupling. 3. Memory-counter unit according to claim The method of claim 1, characterized in that there is also a matching step (10) between the prohibition and counting step (4) and the rarer counter (3). 4. Memory-counter unit according to claim A method as claimed in claim 3, characterized in that there is also a decoupling stage (15) between the prohibiting and allowing stage (4) and the rarer counter (3). 5. Memory-counter unit according to claim A method as claimed in claim 1, characterized in that the memory (1) is also provided with a manually operated program stage (11). 6. Memory-counter unit according to claim A method as claimed in claim 1 or 5, characterized in that the power supply unit (12), which supplies its components with a supply voltage, is provided with a stage (13) containing a time-adjustable data protection circuit and a backup power source. 7. Memory-counter unit according to claims 6. A method according to claim 6, characterized in that the stage data protection circuit (13) consists of a sensor unit (17), which responds to the duration of the mains voltage failure, a quick switch (18), a switch (19) and a directional valve (20). the alternate source of current is connected via the switch (19) and the downstream directional valve (20) to the component supply network, and the control input of the switch (19) is connected to the output of the quick switch (18) on the behind the team (17), which responds to the duration of the power failure 141622 1) Lt — i "i 1 - 1 * 1 M CD XT cn Printing Workshop of the UP PRL. Circulation 100 copies Price PLN 130 PL