JP2565965B2 - Open / closed state detection method for non-voltage contacts - Google Patents

Description

DETAILED DESCRIPTION [Table of Contents] Outline Industrial field of application Conventional technology (Figs. 5 to 7) Problem to be solved by the invention Means for solving the problem (Fig. 1) Operation (Fig. 1) ) Example (Figs. 2 to 4) Effect of the invention [Overview] For example, a method for detecting the open / closed state of a non-voltage contact such as an external push button switch in an LP gas automatic meter reading system, which detects the open / closed state of the non-voltage contact, has low power consumption. Connection between the non-voltage contact and the resistor by supplying the current from the limited battery to the external no-voltage contact through the resistor for the purpose of detecting the open / closed state of the no-voltage contact by the consumption amount. In the open / closed state detection method of the non-voltage contact for detecting the open / closed state of the non-voltage contact by detecting the state of the part, first, the state in which the voltage from the finite battery is supplied to the non-voltage contact via the resistor is set. Every time By inorganic voltage contacts close, when the state of the connection between the wireless-voltage contact and said resistance changes, stops the supply of voltage from the finite cell, then,
The supply / stop of the voltage from the limited battery is intermittently repeated until the open state of the non-voltage contact is detected.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an open / closed state detection method for a non-voltage contact for detecting the open / closed state of a non-voltage contact such as an external push button switch in an automatic LP gas meter reading system.

[Prior Art] FIG. 5 is an overall configuration diagram showing an LP gas automatic meter reading system. In FIG. 5, 1 is an LP gas consumer and 2 is an information processing center.

First, the LP gas consumer 1 is provided with an automatic meter-reading terminal device 3. The automatic meter-reading terminal device 3 includes a centralized monitoring type microcomputer meter 4, a gas leak alarm 5, a seismic detector 6, and a reset. The switch 7, the automatic switching regulator 8 and the telephone 9 are connected. In addition, the automatic alarm terminal device 3 includes a preliminary alarm device 10
Can also be connected.

In addition, the LP gas consumer 1 and the information processing center 2
It is connected via a subscriber telephone line 12, a communication control adapter 13 is provided in the information processing center 2, and a processing device 14 such as a personal computer is connected to the communication control adapter 13. . A printer 15 is connected to the processing device 14, but a larger host computer 16 is also connected.

 In addition, in FIG. 5, 17 is an LP gas cylinder.

By the way, the automatic meter reading terminal device 3 and the reset switch 7
The relationship between and is shown in FIG. That is, the automatic meter-reading terminal device 3 has a power source 18 composed of a limited battery (primary battery) in terms of the relationship with the reset switch, and the reset switch 7 is connected from this power source 18 via the current limiting resistor 19. Voltage can be supplied to the non-voltage contact 7A.

Further, an inverting circuit (inverter) 20 as a digital interface is connected to the connection between the non-voltage contact 7A and the current limiting resistor 19, and the output side of this inverter 20 is the output logic (output of the inverter 20). (Level) is connected to the detection circuit 21.

With such a configuration, the voltage from the power supply 18 is constantly supplied to the non-voltage contact 7A via the current limiting resistor 19, so that when the non-voltage contact 7A is open, the inverter
The output logic of 20 is 0. After that, for example, when a person pushes the reset switch 7 to close the non-voltage contact 7A, the input level of the inverter 20 lowers and the output logic of the inverter 20 changes to 1. Therefore, this change is detected by the detection circuit 21. Then, it is detected that the non-voltage contact 7A is closed.

[Problems to be Solved by the Invention] However, in such a conventional open / closed state detection method of a no-voltage contact, the no-voltage contact 7A changes from open to closed,
Even after the detection circuit 21 detects that the output logic of the inverter 20 has changed from 0 to 1, as shown in FIGS. 7 (a) and 7 (b), the current limiting resistance is maintained while the non-voltage contact 7A is closed. 19
However, there is a problem that the current limited by is kept flowing and the current consumption increases. Such a problem is particularly serious considering that a limited battery is used as a power source.

Therefore, a large battery may be used in consideration of the above current consumption, but this cannot reduce the size and cost of the device.

Therefore, an object of the present invention is to provide a method for detecting the open / closed state of a non-voltage contact, which is capable of detecting the open / closed state of the non-voltage contact with a small amount of power consumption.

[Means for Solving the Problems] FIG. 1 shows a block diagram of the principle of the present invention.

In FIG. 1, D is a no-voltage contact open / close state detection device,
S is an external sensor unit, and this sensor unit S is a non-voltage contact.
Has SW.

Further, the no-voltage contact open / closed state detection device D includes the control circuit 10
0, inverting circuits (inverters) 101 and 102 as digital interfaces, a current limiting resistor 103, and a power source 104 composed of a finite battery.

Here, the control signal * SEN, SW from the control circuit 100 is adapted to be supplied to the current limiting resistor 103 via the inverter 101, and the current limiting resistor 103 is connected to the non-voltage contact SW. . Also, the current limiting resistor 103 and the non-voltage contact S
An inverter 102 is connected to a connection portion with W, and an output signal SEN of this inverter 102 is input to the control circuit 100.

The power source 104 is connected to the control circuit 100, and power can be supplied to the current limiting resistor 103 side via the control circuit 100.

By the way, the control circuit 100 initially includes the current limiting resistor 103.
The state in which the voltage from the power source 104 is supplied to the non-voltage contact SW through the non-voltage contact SW, and then the non-voltage contact SW is closed, the state of the connection portion between the non-voltage contact SW and the current limiting resistor 103, that is, When the output logic of the inverter 102 changes,
The inverter stops the supply of voltage from the power supply 104 and then intermittently supplies and stops the voltage from the power supply 104 until the open state of the non-voltage contact SW is detected.
The control signal * SEN, SW can be output to 101.

[Operation] With such a configuration, the non-voltage contact open / closed state detection device D initially supplies the voltage from the power source 104 to the non-voltage contact SW via the current limiting resistor 103, and thereafter, When the state of the connection portion between the non-voltage contact SW and the current limiting resistor 103 changes due to the operation of closing the non-voltage contact SW, the no-voltage contact open / close state detection device D
Stops the supply of the voltage from the power supply 104, and thereafter intermittently repeats the supply / stop of the voltage from the power supply 104 until the open state of the non-voltage contact SW is detected.

In this way, the outflow current flows from the open state to the closed state of the non-voltage contact SW until the open state is further opened only intermittently, so that the power source 104 is less consumed.

Embodiments Embodiments of the present invention will be described below with reference to the drawings.

This embodiment relates to the LP gas automatic meter reading system shown in FIG. 5, but in the following examples, in this system, the relationship between the automatic meter terminal device and the reset switch related to the present invention will be described. explain in detail.

Now, FIG. 2 is a block diagram showing an embodiment of the present invention. In FIG. 2, 3 is an automatic meter reading terminal device as a voltageless contact open / closed state detecting device in the LP gas automatic meter reading system, 7 Is also a reset switch as an external sensor unit in the LP gas automatic meter reading system,
The reset switch 7 has a non-voltage contact 7A which is opened and closed by a person.

Further, the automatic meter-reading terminal device 3 includes a control circuit 100, an inverting circuit (inverter) 101 as a digital interface,
102, current limiting resistor 103 and power source 104 consisting of limited battery
have.

Here, the control signal * SEN, SW from the control circuit 100 is adapted to be supplied to the current limiting resistor 103 via the inverter 101, and the current limiting resistor 103 is connected to the non-voltage contact SW. . Also, the current limiting resistor 103 and the non-voltage contact S
An inverter 102 is connected to a connection portion with W, and an output signal SEN of this inverter 102 is input to the control circuit 100.

The power source 104 is connected to the control circuit 100, and power can be supplied to the current limiting resistor 103 side via the control circuit 100.

By the way, the control circuit 100 includes the level detection unit 100a and the determination unit 10
It has 0b, a timer 100c, and a control signal output unit 100d, and the determination unit 100b, the timer 100c, and the control signal output unit 100d are functionally provided in the CPU.

Here, the level detection unit 100a receives the signal SEN from the inverter 102 and detects this signal level, and the determination unit 100b determines the signal level from the detection signal from the level detection unit 100a.

Also, the timer 100c is triggered when the determination unit 100b determines that the signal SEN level has changed from 0 (low level; L) to 1 (high level; H), and intermittently sets the control signal * SEN, SW level. When the determination unit 100b determines that the level of the signal SEN has changed from H to L, the signal is reset and is a signal for setting the control signal * SEN, SW level to L. Is output to the control signal output unit 100d.

Further, the control signal output unit 100d receives each signal from the determination unit 100b and the timer 100c, and first leaves the voltage-less contact 7A supplied with the voltage from the power supply 104 via the current limiting resistor 103, After that, when the non-voltage contact 7A is closed, the state of the connection between the non-voltage contact 7A and the current limiting resistor 103 changes, and the output logic of the inverter 102 becomes 0.
When it changes from 1 to 1, the supply of voltage from the power supply 104 to the detection 7A is stopped, and thereafter, the supply of voltage from the power supply 104 to the non-voltage contact 7A is detected until the open state of the non-voltage contact 7A is detected.
The control signal * SEN, SW is output to the inverter 101 so that the stop is repeated intermittently.

That is, the operation flow of the CPU including the control signal output unit 100d is shown in FIG. In this flow,
First, in step a1, it is determined whether the signal SEN is 1 (H level). If YES, in step a2, the control signal * S
Set EN and SW to 1 (H level) and set control signal * SEN and SW to 0 (L level) after the required time determined by timer 100c.
(Steps a3 and 4). After that, in step a5, it is determined whether the output logic of the inverter 102 is 0 (L level). If NO, the process returns to step a2, and after the processes of steps a3 and 4, the process goes to step a5. And in this step a5,
If the output logic of the inverter 102 has changed to 1 (H level), the YES route is taken and the process is terminated.

With the above configuration, for example, at a certain time t ₀ , the fourth
As shown in the figure (a), when the non-voltage contact 7A is in the open state, the control signal * S from the control circuit 100 at this time
EN and SW are L level (0) as shown in Fig. 4 (c).
Has become. As a result, the voltage from the power supply 104 is supplied to the non-voltage contact 7A via the current limiting resistor 103.

After that, at time t ₁ , the non-voltage contact 7A is closed, so that the state of the connection between the non-voltage contact 7A and the current limiting resistor 103, that is, the output signal SEN of the inverter 102 is 0 to 1 (from L level to H Level) [Fig. 4 (b)]
After the required time delay (at time t ₂ ), the control circuit 100 causes the control signal * SEN, S as shown in FIG. 4 (c).
Set W to H level (1). As a result, the output level of the inverter 101 drops to L level (0), and the supply of voltage from the power source 104 to the non-voltage contact 7A is stopped. Therefore, the outflow current flowing out through the current limiting resistor 103 flows only from time t ₁ to time t ₂ as shown in FIG. 4 (d).

After that, until the open state of the non-voltage contact 7A is detected,
The control circuit 100 sets the output level of the control signal * SEN, SW to H
It is repeatedly changed from (1) to L (0) or vice versa. That is, the control signal * SEN at time t _3, the SW falls to L (0), raised again H (1) in the subsequent time t _4, also at time t ₅ falls to L (0), Further time t ₆
Then, it rises to H (1) again, and falls to L (0) at time t ₈ . As a result, the supply / stop of the voltage from the power source 104 to the non-voltage contact 7A is repeated intermittently.

And, in this example, at time t ₇ before time t _8, since dry contact 7A is made open, the control signal * SEN, the fall at time t ₈ when the SW, the output of inverter 102 At the same time, since it becomes L level (0), the control circuit 100 detects from this state that the non-voltage contact 7A is opened, and thereafter, the control signal * SEN, SW is fixed to L level (0). .
As a result, the initial state in which the voltage from the power source 104 is supplied to the non-voltage contact 7A via the current limiting resistor 103 again is restored.

In this way, the outflow current from the open state of the non-voltage contact 7A to the closed state, and further until the open state, is as shown in FIG. 4 (d), between the times t ₃ and t ₄ and the time t ₅ , since during t ₆ only, consumption of power supply 104 is small. As a result, it is possible to detect the open / closed state of the non-voltage contact with a small amount of power consumption, and it is possible to sufficiently reduce the size and cost of the device.

[Effects of the Invention] As described in detail above, according to the open / closed state detection method of the non-voltage contact of the present invention, the outflow current from the open state to the closed state of the non-voltage contact is further intermittent. Since the current flows only for the purpose, it is possible to detect the open / closed state of the non-voltage contact with a small amount of power consumption, which has the advantage that the size and cost of the device can be sufficiently reduced.

[Brief description of drawings]

FIG. 1 is a block diagram showing the principle of the present invention, FIG. 2 is a block diagram showing an embodiment of the present invention, FIG. 3 is a flowchart explaining the operation of the embodiment of the present invention, and FIG. 5 is a time chart explaining the operation of one embodiment, FIG. 5 is an overall configuration diagram of the LP gas automatic meter reading system, FIG. 6 is a block diagram showing a conventional example, and FIG. 7 is a time chart explaining the operation of the conventional example. is there. In the figure, 3 is an automatic detection terminal device as a non-voltage contact open / closed state detection device, 7 is a reset switch as a sensor unit, 7A is a non-voltage contact, 100 is a control circuit, 100a is a level detection unit, 100b.
Is a determination unit, 100c is a timer, 100d is a control signal output unit, 10
1, 102 is an inverter, 103 is a current limiting resistor, 104 is a power source (finite battery), D is a no-voltage contact open / close state detection device, S is a sensor unit, and SW is a no-voltage contact.

Claims (1)

(57) [Claims] 1. A resistance (103) to an external non-voltage contact (SW, 7A).
By supplying the current from the limited battery (104) via the, the state of the connection between the non-voltage contact (SW, 7A) and the resistor (103) is detected to detect the non-voltage contact (SW, 7A). In the open / closed state detection method of the non-voltage contact for detecting the open / closed state, first, the voltage from the limited battery (104) is supplied to the non-voltage contact (SW, 7A) through the resistor (103). , Then, by closing the non-voltage contact (SW, 7A),
When the state of the connection between the non-voltage contact (SW, 7A) and the resistor (103) changes, supply of voltage from the limited battery (104) is stopped, and thereafter the non-voltage contact (SW, 7A) A method for detecting the open / closed state of a non-voltage contact, characterized in that the supply / stop of the voltage from the limited battery (104) is repeated intermittently until the open state of 7A) is detected.