SU1587544A1 - Pneumatic device for memorizing maximum signal - Google Patents

Abstract

This invention relates to pneumatic computing tools. The purpose of the invention is to simplify the design and improve accuracy. The device contains a three-membrane relay 1, the element of comparison 3, the minus chamber 7 of which is connected to the input channel 8 of the device, and the flow chamber 22 - with the normally closed nozzle 21 of the three-membrane relay 1, a single-membrane repeater 4, the nozzle 12 of which is connected to the atmosphere, the input chamber 11 - with a normally open nozzle 9 of a three-membrane relay 1, and a flow chamber 13 is connected to the device output channel 14 and through a choke 5 - to the power channel 15. A three-membrane relay 1 contains a back-up spring 2. The flow chamber 19 with a normally closed nozzle 2 1 is connected to the input chamber 18 of the relay 1 and to the flow chamber 20 of the comparison element 3, the nozzle 23 of which is connected to the supply channel 15. The first input chamber 16 of the three-membrane relay 1 is connected to the control channel 17. The nozzle 9 of the three-membrane relay 1 is connected to the positive blank camera 10 comparison element 3, and the nozzle 21 - with the flow chamber 22 of the comparison element 3. 1 sludge.

Description

The invention relates to pneumatic means of computing, in particular to pneumatic devices for storing a maximum. 5

The purpose of the invention is to increase accuracy and simplify the design.

The drawing shows a diagram of the device.

The device contains a three-membrane JQ relay 1 with a backup spring 2, a comparison element 3, a single-membrane repeater 4 and a choke 5. The flow chamber 6 of the relay 1 and the negative chamber 7 of element 3 are connected to the input channel 8. Normally open nozzle 9

G relay 1 is connected with the positive chamber of element 3 and with the input chamber of the repeater 4. The nozzle 12 of the repeater 4 is connected to the atmosphere, and 20 the flow chamber 13 is connected to the output channel 14 and through the inductor 5 with the supply channel 15.

'The first input chamber 16 of the relay 1 is connected to the control channel 17, and 25 the second input chamber 18. And the flow chamber 19 are in communication with the flow chamber 20 of the element 3. The normally closed nozzle 21 of the relay 1 is connected to the flow chamber 22 of the element 3, the nozzle 30 23, and 24 which are connected respectively to the power supply channel 15 and to the atmosphere.

The comparison element 3 is configured so that, with equal signals in the chambers 7 and 10, the nozzle 23 is open.

The device operates as follows.

In the absence of a command signal RK in channel 17 and an input signal Ρ _βχ dd in channel 8, after supplying power to channel 15 at the output of repeater 4 and in output channel 14, a signal P _Bb is generated _(X = P _8x . In the flow chamber 20, a signal P = 1, the relay 45 1 switches, its nozzle 9 closes and the pressure Rec.

When the pressure Ρ _β * begins to increase and reaches a value exceeding 59 the previous value by the value of the response zone of the comparison element 3, the latter is triggered and the pressure P is released into the atmosphere through the currently open nozzles 21 pressure $ 1 and 24 of the element 3. When relay 1 activates this, through its normally open nozzle 9, the input channel 8 communicates with the camera 11 of the repeater 4 and the camera 10 of the comparison element 3, then again a signal ”1 is generated in the camera 20. Under the action of this signal, relay 1 again trips and in the output channel 14 the new value of the signal Ρ _{βχ is repeated} . With a further increase in pressure at the inlet of the device, its operation is carried out in the described sequence. When the pressure starts to fall at the inlet, the stored maximum pressure value P _gJe remains in channel 14.

When a command signal P _{k is} supplied to the device, relay 1 is activated, the input chamber 11 of the repeater 4 through the open nozzle 9 of the relay 1 is connected to the input channel 8 and the pressure P _int ~ Ρθ _χ appears at the output of the device. In this mode, the device repeats the input signal Ρβχ · (without storing the maximum value),

Claims (1)

Claim A pneumatic device for storing the maximum signal containing a reference element, the negative chamber of which is connected to the input channel, a one-membrane repeater, the nozzle of which is connected to the atmosphere, and the flow chamber communicates with the output channel through the choke with the power channel and a three-membrane relay whose first input chamber associated with the control channel, characterized in that, in order to simplify the design and increase accuracy, the input chamber of the single-membrane repeater and the positive camera of the comparison element with communicated with a normally open nozzle of a three-membrane relay made with a backpressure spring, and the flow chamber of this nozzle is connected to the input channel, the flow chamber connected to the power channel of the nozzle of the reference element is connected to the second input chamber and the flow chamber of a normally closed nozzle of the three-membrane relay The nozzle of the comparison element connected to the atmosphere is in communication with the normally closed nozzle of a three-membrane relay.