JPH068764B2 - Pneumatic reference signal generator - Google Patents

Description

TECHNICAL FIELD The present invention relates to an air pressure reference signal generator used when performing an input / output test of various industrial instruments that receive an air pressure signal as an input.

(B) Conventional technology In general, the input range of industrial instruments has a wide range, for example, about 20 to 20,000 mmH ₂ O in a differential pressure transmitter. When conducting an input / output test over such a wide input range, the air pressure reference signal generator is usually for 2,000 mmH ₂ O, for example.
Separate pieces are made for 20,000 mm H ₂ O. The supply air pressure is also different from 0.5 kgf / cm ² and 2.6 kgf / cm ² . Therefore, when the air pressure reference signal generator is replaced and used, it is inconvenient that the supply pressure must be reset each time.

(C) Purpose The object of the present invention is to eliminate the drawbacks of the above-described conventional air pressure reference signal generator, eliminate the inconvenience of manually converting the air supply pressure depending on the magnitude of the air pressure reference signal, and provide an optimum air supply corresponding to the air pressure reference signal. To provide a pneumatic reference signal generator which is supplied with pressure.

(D) Structure In order to achieve the above object, the pneumatic reference signal generator of the present invention includes a setting unit for setting the pneumatic reference signal and a D / A for converting the setting signal from the setting unit into an analog value.
A converter, an electro-pneumatic converter that converts an analog electric signal from the D / A converter into a pneumatic signal, and a memory that stores an optimum supply pressure signal corresponding to the generated pneumatic pressure output of the electro-pneumatic converter in advance. Means for reading the corresponding optimum supply pressure signal from the storage means in accordance with the reference air pressure setting signal, and the supply air pressure corresponding to the optimum supply pressure signal to the electro-pneumatic converter. It is composed of an air pressure supply means.

In this air pressure reference signal generator, when the air pressure reference signal is set by the setting unit, this setting signal is applied to the electro-pneumatic converter via the D / A converter, and the electro-pneumatic converter outputs the setting signal. An air pressure signal corresponding to is output. The optimum supply pressure signal is read from the storage means by the setting signal, and the supply air pressure corresponding to the optimum supply pressure signal is
It is automatically input to the electro-pneumatic converter.

(E) Examples Hereinafter, the present invention will be described in more detail with reference to Examples.

FIG. 1 is a block diagram of a pneumatic reference signal generator showing an embodiment of the present invention.

In the figure, the setting unit 1 includes a numeric keypad, function keys, and the like, and can set an air pressure reference signal. The setting signal input by the setting unit 1 is taken into the CPU (microprocessor) 3 via the bus 2 and stored in the memory (storage means) 4. Further, the memory 4 stores in advance an optimum air pressure signal corresponding to the output air pressure. When the air pressure reference signal is output according to the instruction from the UPU 3, the setting signal is read from the memory 4, the digital setting signal is input to the D / A converter 5, converted into an analog signal, and then the analog signal. The signal is input to the electro-pneumatic converter 6, converted into an air pressure signal and output.

The optimum air pressure signal corresponding to the setting signal is read out from the memory 4 and input to the D / A converter 7 to be converted into an analog signal. Then, the analog signal is input to the supply pressure converter 8, and the supply pressure converter 8 inputs the supply pressure corresponding to the optimum supply pressure signal to the electro-pneumatic converter 6.

Next, the outline of the entire operation executed by the control of the CPU 3 will be described with reference to the flowchart shown in FIG.

When the operation starts, first, the setting signal at that time is read from the setting unit 1 (step ST1). With this setting signal, the optimum supply pressure signal corresponding to the setting is read from the memory 4 (step ST2). This optimum supply pressure signal is input to the D / A converter 7 and an analog signal is output (step ST3). Further, the set signal is also input to the D / A converter 5 to output an analog signal corresponding to the set value (step ST4).

The analog signal of the D / A converter 7 is the supply pressure converter 8,
It is converted to the optimum supply pressure and input to the electro-pneumatic converter 6.
On the other hand, the analog signal of the D / A converter 5 is the electro-pneumatic converter 6
Is input, converted into a reference air pressure, and output. If the set value is not changed, the determination in step ST5 is NO.
Then, the processing ends, and the state as it is is maintained.

If the set value is changed, the changed data is input from the setting unit 1. If there is a change, step ST5
Is YES, the process returns to step ST1,
The processing of steps ST1 to ST5 is repeated again. Even if the set value is changed, the corresponding optimum supply pressure signal is read from the memory 4, and the supply pressure corresponding to this optimum supply pressure signal is automatically input to the electro-pneumatic converter 6.

In the pneumatic reference signal generator of this embodiment, even if the supply pressure fluctuates, a predetermined optimum supply pressure is input to the electro-pneumatic converter 6 by the supply pressure converter 8. The decrease can be prevented.

In the above embodiment, assuming that the memory 4 stores the optimum supply pressure that continuously changes with respect to the change of the set value, the optimum supply pressure corresponding to the output air pressure is set to the electro-pneumatic converter 6. D / A converter 7, supply pressure converter 8
However, if it is sufficient to switch the optimum supply pressure in several steps with respect to the change in the set value, instead of these, as shown in FIG. 3, the decoder 17 and the supply pressure switch 18 are used. The output of the decoder 17 controls the supply pressure to A,
It is also possible to switch between B and C (A>B> C).

(F) Effect According to the present invention, the optimum supply pressure corresponding to the output air pressure is stored in advance, and the supply pressure corresponding to the set voltage is automatically input to the electro-pneumatic converter. When changing, it is not necessary to change the supply pressure manually,
The test means can be simplified.

[Brief description of drawings]

FIG. 1 is a block diagram of an air pressure reference signal generator showing an embodiment of the present invention, FIG. 2 is a flow chart for explaining the operation of the air pressure reference signal generator, and FIG. FIG. 3 is a block diagram showing a part of a main part of the pneumatic reference signal generator of the embodiment of FIG. 1: Setting unit, 3: CPU, 4: Memory, 5/7: D / A converter, 6: Electro-pneumatic converter, 8: Supply pressure converter,

Claims (1)

[Claims] 1. A setting unit for setting an air pressure reference signal, a D / A converter for converting the setting signal from this setting unit into an analog value, and an analog electric signal from this D / A converter for pneumatic pressure. The electro-pneumatic converter for converting into a signal, the storage means for storing the optimum supply pressure signal corresponding to the generated air pressure output of the electro-pneumatic converter in advance, and the corresponding optimum supply pressure signal by the air pressure reference setting signal An air pressure reference signal generator comprising an optimum supply pressure signal reading means for reading from the storage means and an air pressure supply means for inputting a supply air pressure corresponding to the optimum supply signal to the electro-pneumatic converter.