HU188440B - Data-storage and counting unit, preferably for straight-bar machine - Google Patents

Abstract

The invention relates to a data storage and counting unit, in particular for Flachkulierwirkmaschinen, where it is used for counting the knitted rows and for actuation of the program shifter. Main parts of the data storage and counting unit according to the invention are a memory with write-in and read-out capability, a comparator, a row counter, a count-prohibiting and permitting stage, an AND gate and a program termination stage. The program reader is located on the inputs of the memory, the outputs of which are connected to the comparator input. The series pulse generator is located at the input of the counting and prohibiting counter whose output is connected to the row counter input. The Reihenzaehlerausgaenge are connected to the comparator inputs, further the comparator outputs are connected to the inputs of the AND gate, while the output of the AND gate at the input of the program termination stage, with the program reader, the write permitting input of the memory, the Reihenzaehler and directly or via a power amplifier is connected to the program shifter. The unit is characterized by a high level of operational safety, low energy consumption and a simple structure. figure

Description

BACKGROUND OF THE INVENTION The present invention relates to a data storage and counting unit, in particular for a flat knitting machine, for counting the bound rows and operating a program stepper after binding a given program row with a binding mode and tool according to a given program row. -counting unit.

As is known, in the case of flat crochet machines, the bonding is carried out according to the program prescribed by the machines, usually on a program card. The program contains, in sequence, the number of rows to bind with which knitting method and tool. The control of the machines therefore requires a so-called. a data storage and counting unit suitable for counting the rows that have already been tied and for forwarding the program stepper, when the rows quantity in the given program line has already been committed by the machine work units with the binding mode and tool in the given program row. Various electromechanical methods are used for this purpose in the prior art.

For example, in the NDK Textima type roughing machine, the readings from the program card place the markers of the marker line constructed in accordance with the binary number system in the right position. until a reset. They then move on to the next line and draw the next line based on the newer line. There is usually more to one control unit, e.g. 12 work units belong simultaneously.

These electromechanical solutions have the following disadvantages. As with most electromechanical devices, their reliability and life span are relatively low because the components wear out and wear out. Another disadvantage is that their operation is noisy. In addition to mechanical noise, they can also cause radio frequency interference, which can cause other circuits to malfunction. Another disadvantage is the relatively high electricity consumption.

In the event of unreliable operation of the data storage and counting unit, the resulting debris (eg due to a size error) cannot be repaired and, in addition, due to the number of parallel working units, each working unit produces waste.

It is an object of the present invention to provide a solution that eliminates the above drawbacks and thus enables the flat knitting machine to be operated reliably.

The main components of the data storage and counting unit according to the present invention consist of read-write-read memory, comparator, sequence counter, counting-blocking and enabling stage, AND-gate and program end stage, the program reader on the one hand, the memory reader input, on the other hand, the line pulse transmitter to the counting and disabling stage input, its output to the row counter input, the row counter outputs to the comparator input, and the comparator outputs to the AND gate input, and the AND gate output to the program end is connected, and the program end stage is connected to the program reader, the memory write enable input, the sequence counter, and directly or via a power amplifier to the program stepper.

Different operating voltage levels require the use of an interface between the program reader and the memory, preferably an optocoupler.

Similarly, an adapter step may be required between the counting and disabling counters and the queue counter. It may also be necessary to provide a de-burst signal for the pulse transmitter signal, in which case the output of the de-burst stage is already regular, for example rectangular signals are applied to the serial counter input.

If necessary, the memory should also be manually programmed. This is required, for example, in the event of a prolonged power outage, so that the operator can write to the memory after the power outage, after erasing any incorrect information, the information corresponding to the actual state (based on the card program and the committed portion).

In the event of a power outage, it is advantageous to provide the power supply to the power supply units of the data storage and counting unit with a timed data protector having an alternating current source such as a battery. Failure to do so will result in the loss of stored data in the event of a power failure, resulting in power failure as well as loss of working time.

The data storage and counting unit according to the invention will be described in more detail with reference to the following examples.

Figure 1 is a block diagram of an embodiment of a data storage and counting unit according to the invention. According to the block diagram of Fig. 1, the program card recorded on the program card is transmitted by the program reader 7 to the memory 1 via the optocoupler interface 9, which is also provided with the manual program stage 11. On the other hand, the rows tied on the flat crochet machine are detected and signaled by the pulse transmitter 8 at the crankshaft, via the blocking and enabling counting 4, the alignment stage 10 and the anti-skid stage 15 to the binary row counter 3. The binary comparator 2 compares the signals of memory 1 and the sequence counter 3, and through the five-input AND gate 5, the output signal of the comparator 2 is output to the end of program 6, which is connected to memory 1, program reader 7, 14 power amplifiers with program step 22. Each component is supplied by a stabilized power supply 12, which is supplemented by a timed data protection unit 13 in the event of a power failure. Namely, in the event of a temporary outage of the mains voltage, the semiconductor storage loses its information content. To solve these problems caused by short - term mains power outages

188,440 timed data protection units that allow storage to retain information for several minutes after a power outage. This time is sufficient for the server to read the current information content from the displays on the memory 1 and the queue counter 3, subtract and record them from each other, and enter the difference data into memory 1 using the manual program stage 11.

Thus, no program errors occur even in the event of a power failure. In the embodiment of the present invention, the power-down unit 13 switches itself off in the event of a power failure for more than four minutes. The timed data protection unit 13 includes a battery 16, which is powered from the mains via the charging circuit 21, a sensor unit 17 that detects a power failure for more than four minutes, a quick switch 18 formed by a Schmitt trigger, a power switch 19, a directional test 20, which is constructed of diodes and ensures that the battery 16 only supplies power to the components in the event of a power failure. Thus, in the event of a power failure within four minutes, the battery 16 will automatically power the components without any switching, thus ensuring that stored data is not erased. In the event of a power failure for more than four minutes, the detector unit 17 provides a signal to the quick switch 18, which actuates the power switch 19, which disconnects the battery 16 from the power supply to the components. The four minutes are sufficient for the operator to read the necessary data from the displays of each component and to operate manual program stage 11 when the mains voltage returns.

The function of memory 1 is to store information from the smart card until the countdown is complete. In this case, you need to store up to 5 bits. The function of the comparator 2 is to compare the binary number entered in the memory 1 with the contents of the row counter 3.

The function of the row counter 3 is to count the pulses from the row pulse transmitter located at the crankshaft crankshaft. In our example, a binary, prime counter, asynchronous counter was used for the 3 row counter.

The function of the 4 counting and disabling levels is to disable and re-enable pulses from the rotary crankshaft of the flatbed machine if necessary. This is needed when setting up a flat crochet according to a new program line, such as when setting up for propagation. This adjustment takes some time and no bonding occurs, but the crankshaft crankshaft rotates, resulting in a series of pulses at the input of the counting disable and enable levels. If these pulses were to be placed on the row counter 3, the planar knife would not be connected according to the program. It is therefore necessary that these pulses are denied during decking (eg, consumption, reproduction).

The output of the AND gate 5 is output when all five inputs have signal levels, that is, the number of lines in the given program line is occupied by the machine.

The end-of-program step 6 in our example has a number of tasks, such as "clear" (with delay), "disable" ("enable"), and operate the power amplifier 14. The "clear" function is needed after every program line is read out, since only with empty memory 1 and line counter 3 it is possible to enter and read the next program line or bound line data. Thus, the program end stage 6 deletes the contents of both the memory 1 and the sequence counter 3 after the program sequence runs, of course with some delay, since the mechanical parts can only follow the electronics with a certain time delay. It is also advantageous to allow manual deletion at the end of the 6 programs.

A "ban" is required to prevent any possible inaccurate input of subsequent information. Thus, after writing to memory 1, the program end stage 6 disables further writing to memory 1 by disabling program reader 7. Of course, this prohibition could also be implemented directly in memory 1. The program end stage 6, via the power amplifier 14, signals to the program stepper 22 to advance the program card.

The serial number data on the program card, to be bound with a particular binding mode and the same tool, is transferred to the erased memory 1 via the interface 9 via the program reader 9. The 5-gate AND gate 5 is dormant and actuates program end level 6 when writing to memory 1. As long as no entry is made, the AND gate 5 sends a permanent erase command to the memory 1 via program end 6. After entering into memory 1, with a delay of a few microseconds, the program end stage 6 disables program reader 7 based on the signal from AND gate 5, so that no further, possibly erroneous, information is stored in memory 1.

On the other hand, the row pulse transmitter 8 on the crankshaft crankshaft provides each pulse with a pulse to the binary row counter 3 through the blocking and enabling stages 4, the alignment stage 10 and the anti-slip stage 15.

The input of the comparator 2 is provided with binary numbers read from memory 1 and read from the row counter 3. The output of program end stage 6 is displayed at the output of comparator 2 when all bits at the local value of comparator 2 are equal to each other, i.e. when the assigned sequential number is the same as programmed. Then the program end stage 6 is activated, which clears the memory 1 and the sequence counter 3 so that the next card program can start again from the beginning. The program step for the next card program is also performed by the program end stage 6 by actuating the power amplifier 14.

Advantages of the data storage and counting unit according to the invention are that it is very reliable, has a long life, is noise-free, has a relatively low power consumption and is relatively simple in construction.

Claims (7)

Patent claims 1. A data storage and counting unit, particularly for a flat crochet machine, for operating a program stepper for counting the number of bound rows and for sequencing a given row of program with a binding mode and tool according to that program, having a program reader is characterized in that its main components consist of read-write-read memory (1), comparator (2), sequence counter (3), counting and disabling stage (4), AND gate (5) and program end stage (6) such that, on the one hand, the input inputs of the program reader (7) to the memory (1), the outputs of the memory (1) to the input of the comparator (2), and on the other the serial pulse transmitter (8) to the input of the sequence counter (3), the sequence counter (3) is off its threads are connected to the comparator (2) input, the outputs of the comparator (2) are connected to the AND gate (5) input, while the output of the AND gate (5) is connected to the program end stage (6) and the program end stage (6). 6) communicating with a program reader (7), an input enabling memory (1), a sequence counter (3), and directly or via a power amplifier (14) with a program stepper (22). Data storage and counting unit according to Claim 1, characterized in that an optocoupler adapter stage (9) is preferably provided between the program reader (7) and the memory (1). The data storage and _5- counting unit according to claim 1 or 2, characterized in that there is an interface (10) between the counting and blocking stage (4) and the row counter (3). 4. A data storage and counting unit according to any one of claims 1 to 5, characterized in that there is also a de-icing stage (15) between the counting and blocking stage (4) and the sequence counter (3). 5. storing data of any preceding claim and counters unit, characterized in that the _{1 (-} is provided with a memory (1) manual program setting (11). 6. A data storage and counting unit according to any one of claims 1 to 3, characterized in that the power supply unit (12) is provided with a timed data protection unit (13) ₂₀ . The data storage and counting unit according to claim 6, characterized in that its timed data protection unit (13 / a) comprises a mains voltage outage detection unit (17), a quick switch ₂₅ (18), a power switch (19), an auxiliary power supply (16). comprising a directional latch (20) such that the auxiliary power supply (16) is connected to the power supply (19) via the power switch (19) and subsequent directional latch (20), the control input of the power3Q switch (19) connected to the output of the next quick switch (18).