CS208848B1 - Wiring for Electronic Program Switch - Google Patents

Abstract

Connection for an electronic program switch, designed to control the working cycle of machines or other devices without the use of mechanical components, e.g. cams. The function of the cam is replaced here by an electronic circuit, made up of circular shift registers and the appropriate electronic elements. The time diagram is set using switches. The accuracy of the setting of the individual functions of the working machine is easy to maintain. The connection allows remote setting of the program change. The set state is indicated by a light display. The connection is suitable for use in explosive environments. See connection diagram

Description

(54) Connection for electronic program switch

Wiring for electronic program switch, designed to control the duty cycle of machines or other equipment without the use of mechanical components such as cams. Here, the cam function is replaced by an electronic circuit made up of circular shift registers and associated electronic elements. The time diagram is set using the switches. The precision of the setting of the individual functions of the implement is easy to maintain. Wiring allows remote adjustment of program change. The set status is indicated by a light display. The wiring is suitable for use in explosive environments.

See wiring diagram

2Q8 848

The subject of the invention is a circuit for an electronic program switch intended to control the duty cycle of machines or other devices without the use of mechanical components, eg cams.

To programmatically control the operation of machines or other equipment, program switches are used. Such a program switch consists of a series of cams on a common shaft and a corresponding number of switches which are actuated by these cams. The duty cycle time diagram can only be changed within certain limits by adjusting the position or changing the cam shape. This determines the start and end of the program cycles. This program switch has a number of disadvantages.

Due to the use of the cam-switch system, the service life of these elements is limited. Switching speed It is considerably limited by the type of switch used. The shape of the control pulse is not precisely defined. The cam adjustment accuracy is limited by the sensitivity of the switches. The sensitivity of the switch, whether contact or non-contact, is low. This implies that the number of switching positions is considerably limited. It is very difficult to achieve accurate setting of the follow-up functions within a narrow time frame. Checking and adjusting the time-cam-to-cam-time schedule is very tedious. Remote control is very difficult to implement, since changes to the program can only be made by adjusting the cams.

Said drawbacks are overcome or at least significantly reduced by wiring for an electronic program switch for controlling the duty cycle of machines or other devices, formed by a set of program stages comprising at least one group, for example two members, in which at least one program stage is control, circular shift register, whose common setting inputs are connected to logic level L, switch and flip-flop, connected by its outputs to power circuits, whose essence is that flip-flop is by its first input connected to the trigger button, its second input with With the stop button and its only one output it is connected via clock pulse generator to clock pulse inputs of all circular shift registers and simultaneously to their reset inputs and also to reset inputs of flip-flops of each program the control program stage flip-flop output is connected to the serial input of the circular shift register in its control stage, while the serial inputs of the circular shift registers of the other program stages are connected to the negated outputs of their flip-flops that part of the parallel outputs from the circular shift register the program stage is connected via the other switches and pulse formers to the first flip-flop input of the other program stages, and at the same time, the terminal parallel outputs of the circular shift registers of these other program stages are connected through these switches and pulse formers to the second inputs of its flip-flop stages, the terminal parallel outputs, up to the last ones, are connected via their switch, through the pulse former to the first input of the flip-flop Its second input is connected exclusively outside the switch but via the pulse former with the last parallel output of the circular shift register of the control stage.

The electronic program switch according to the invention offers a number of advantages. One advantage is that it is easy to execute a program with guaranteed precision in the setting of individual controlled functions. The size of the program switch is still high even when a large number of controlled functions are used. The wiring enables remote control of program change and its indication. Having no moving parts subject to wear will increase its reliability as well as its service life. Maintenance requirements are negligible. Power consumption is very low due to semiconductors. When using the electronic program switch according to the invention in a harsh environment, eg explosive, humid or aggressive, the prescribed enclosure can be achieved much more easily than mechanical switches, eg by impregnation.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is illustrated in greater detail in the accompanying drawing which illustrates an exemplary circuit of a three-stage electronic program switch with a selected logic level (h) of the flip-flop of a control program stage.

The terminals 25 and 26, which are connected together to the logical L level of the signal, are connected to the flip-flop 13, so that terminal 36 is connected via the start button 14 with the first input and terminal 35 through the stop button 15 with the second input flip-flop. The terminal 35 is connected to the common setting inputs of the individual circular shift registers 8, 2 >. The output of the flip-flop 13 is connected to the clock pulse generator 16 and to the reset inputs 20, 21, 22 of the respective circular shift registers h, j, 6. and at the same time to reset the inputs of the respective flip-flops 10, 11, 12, which together with said circular shift registers 4, 6, 6 are part of the program stages 1, 2, 2 " £ 8, 19 circular shift registers 4, 5, 6,

The output of the flip-flop 10 in the programming stage 11 is connected both to the serial input 23 of the circular shift register 6 and to the machine control element (not shown), eg a solenoid coil of the switchgear or the like, requiring program switching.

The other program steps £ 2 j ^sou serial inputs 24, 25 of circular shift registers £, _6 connected to the negated output of its flip-flops 11, 12, according to need it is possible to engage to not shown control elements use both outputs of flip-flops 10, 11, 12.

Terminal parallel outputs 29, 22 '3 ¹ of circular shift registers 4, 5, 6 are formed with engagement across suitably set the position of switches £, 8, 9 and over the respective mold pulse 32 »22' 2j formed e.g. gate and capacitor inputs respective flip- 10, li, 12 circuits 1, 2, 2 *

Initial parallel outputs 26 are connected via switch positions 27 2728 and through pulse formers 13, oo formed, for example, by a gate and a capacitor with the first input of flip-flops 11, 12 in slave program stages 2., 2, · Other remaining initial parallel outputs can be used when driving with multiple slave stages.

The last parallel output 31 of the circular shift register k has a wiring only through the pulse former 37 ^{3 through the} second input of the flip-flop 10 of the control program stage 11.

The function of the device is as follows!

The electronic program switch according to the invention consists of individual program stages, the number of which is determined by the number of functions to be controlled by this switch. Program stages can be divided into groups in which one program stage is always the control stage and ensures the activity of subordinate program stages within the cycle. The slave program stages take cycle pulses from the control stage during the cycle, which create the origin of the control signals, which are offset in time relative to each other at the beginning of the cycle and 1. The selection of these subordinate program stage origins is determined by selecting the position of the initial parallel output from the position of the serial input on the circular shift register of the control program stage by setting the respective switch positions connected to these initial parallel outputs. By selecting the end parallel output, i.e. its position relative to the start of the control signal shift on each book shift register, the duration of the control signal action can be determined. Other switches with an appropriately set position are used. Each triggering of the control signal shift in each of the circular shift registers represents the start of the control signal's effect in the electrical systems of the machine or plant control elements that takes place from the control ring shift register within a given cycle. this cycle. The start of the new cycle is ensured by starting the flip-flop of the control program stage with the signal from the last parallel output of the control ring shift register.

In the following, the function of the exemplary embodiment of an electronic program switch with three program steps will be described. The circuit shown in FIG. 1 results from the selection of the logic level H of the flip-flop state to the control program stage in the control signal funcI.

In the idle state, the illustrated electronic switch is blocked by a signal at the output of the flip-flop 8 which is applied to the input of the clock pulse generator 16, to the reset inputs of the flip-flops 10, 11, 12 and simultaneously to the reset inputs 20, 21, 22 Thus, a state whose level is represented by a control signal is applied to the serial input 23 of the control shift register 4.

In the other program stages 2, g, the serial inputs 24, 25 of the circular shift registers 6 are connected to the negated outputs of the flip-flops 11, 12 of these program stages. Press button 14 to start the electronic program switch. The trigger signal activates the clock pulse generator 16 and thus begins to shift in the circular shift registers a signal whose status level was on its serial inputs 23, 24, 25 before it was triggered. With logic level H of the flip-flop 10 in the control program stage 1, the logic level H of the signal, i.e. the control signal, begins to shift at the moment of the clock pulse generator operation, while in the circular shift registers,, í of the subordinate program stages,, např, for example, the L signal level, not the control signal.

In the circular shift register 4, the control signal shifts and fills the register as long as the control signal is at the output of the flip-flop 10 which is connected to the serial input 23; in circular shift registers J5> the signal with logical level L is shifted as long as this logical level is at the output of flip-flops

11, i £ *

As soon as the control signal, proceeding! in the circular shift register 4 reaches the first parallel initial output 26, this driver is applied via the selected position of the switch 27, 28, the pulseformer 38, 40, to the first input of the flip-flop 11, 12 in program stage 6, thereby changing its state from the original logical level L to the logical level H, that is, to the state level of the control signal. At this point, this driver signal will begin to shift in the circular shift register 6 and will fill this register. Accordingly, the start of the control signal shift in the circular shift register 2 is delayed against the start of the control signal shift in the first control program stage 6 and hence from the start of the cycle. The value of this delay is precisely determined by the distance of the parallel output 26 from the position of the serial input 23 in the circular shift register 4 and the clock frequency used.

At the moment of the start of the shifts of the control signals in the individual circular shift registers 4, 6, the start of the control signals is created in the circuits (not shown) of the controlled elements, eg electric motors, etc., which are brought there. The switch is provided by, for example, not deploying the trigger button 14 with a limiter, which at the moment of switching brings the already set control signal from the outputs of the flip-flops 10, 11, 12 to the controlled elements.

As soon as the control signal in the circular shift register 4 is shifted to the parallel terminal outputs 29, this signal is applied via the selected switch position to the first input of the flip-flop 10. Tim so changes its level from the original logical level to the logical level ^M L and of course this change will appear on its outputs. This change is applied simultaneously to the serial output 23 of the circular shift register and in this register, the signal with the logical level L begins to shift, and the register begins to fill. This connection achieves the selected duration of the control signal. Similarly, by connecting the selected parallel end outputs 31 ^{and the} respective switches 8, 6 through the pulse formers 29, 41, with the second inputs of the flip-flops 11, 12, they change their state and thereby end the duration of the control signals in these circular shift registers 6, 6.

The progressive logical level L of the signal in the circular shift register 4 of the control program 1, which does not represent the control signal, reaches a certain number of times in a certain period of time, the parallel output output j4. This L-level signal is then applied via pulse former 17 to the second input of the flip-flop circuit PO. With this pulse the output of the flip-flop will regain the logic level Η, that is, the state of the control signal.

When the electronic program switch is stopped by the button lg, a change in the signal state level occurs at the output of the flip-flop 13, which stops the clock pulse generator l1 and connects this output to the reset inputs 20, 2.1, 22 of the circular shift register 1 *, 5, 6. of stages JL, £, £ flushes these registers and brings them to the initial state, and by simultaneously applying this reset signal to the reset inputs of the flip-flops 10, 11, 12, these flip-flops 10, 11, 12 are brought into the selected initial state.

Claims (3)

P ft B D M S T LOW, BZU Wiring for an electronic program switch for controlling the duty cycle of machines of nobo other devices, formed by a set of program stages comprising at least one group, for example a two-member, in which at least one program stage Jo controls, setting inputs are connected to logic level L, switch and other flip-flop, connected by its outputs to power circuits, characterized by the flip-flop (13) by its first input connected to the start button (14), by its second input with the stop button ( 15) and with its only one output it is connected via clock pulse generator (16) to clock pulse inputs (17, 18, 19) of all circular shift registers (4, 5, 6) and simultaneously to their reset inputs (20, 21) , 22) and at the same time to the reset inputs of the flip-flops (10, 11, 12) of each program st clamps (1, 2, 3) wherein the output of the flip-flop (10) of the control program stage (1) is connected to the serial input of the circular shift register (1 ») in its control stage (1), while the serial inputs (24, 2j) the shift register (5, 6) of the other program stages (2, 3) is connected to the negated outputs of their flip-flops (11, 12), while a portion of the parallel outputs (26) from the circular shift register (4) of the control program stage (1) pife and other switches (27, 28) and pulse formers (38, 40) are connected to the first input of the flip-flops (11, 12) of the program stages (2, 3) and simultaneously the parallel outputs (30, 31) of the circular shift registers 5, 6) of the program stages (2, 3) are connected via the switches (8, 9) of these program stages (2, 3) and the pulse former (39, 41) to the second inputs of their flip-flops (11, 12), of the control program stage (l) are the end pa the parallel outputs (29) i to the last are connected via the switch (7) and the pulse former (32) to the first input of the flip-flop (lo) of the control program stage (1), its second input being connected via the pulse former (37) the last parallel output (34) of the circular shift register (4) of the control program stage (1). Connection according to claim 1, characterized in that the pulse formers (32, 38, 39, 40, 41) are a series combination of a gate and a capacitor, Connection according to Claims 1 and 2, characterized in that the pulse former (37) is formed by a capacitor.