KR100190315B1 - Flowing speed switch quality testing system - Google Patents

Abstract

The present invention relates to a performance test system of a flow rate switch (SWITCH) that enables the precise inspection of the performance of the flow rate switch using a flow rate sensor that detects the speed of the fluid applied to the flow rate switch. In the flow rate switch 10 of the flow rate resistor 10-1 and the Hall element 10-2 for detecting the variable fluid resistor 10-1, the position of the flow rate switch 10 The outlet part is connected to the water tank 90 for storing the fluid through the conduit 100, and the inlet of the flow rate switch 10 is one side of the flow rate sensor 20 for detecting the velocity of the fluid through the conduit 100-3. Is connected to, the tile side of the flow rate sensor 20 is connected to one side of the pump (PA) 30 through the conduit (100-2), the tile side of the pump 30 through the conduit (100-1) Connected to the water tank 90, the computer 70 through the pump drive unit 40 for driving the pump 30 A frequency voltage connected to the pump 30 and converting the frequency signal output from the flow rate sensor 20 for sensing the speed of the fluid flowing through the conduit 100-2 by the driven pump 30 to a voltage The conversion unit 50 is connected to the computer 70 through an analog digital conversion unit 60 for converting an analog signal into a digital signal, and has a predetermined speed through the flow rate sensor 20 and the conduit 100-3. The digital input unit 80 converts the analog signal output from the Hall element 10-2 detecting the flow rate resistor 10-1 whose position is changed by the fluid flowing into the digital signal and inputs the digital signal to the computer 70. In the present invention, by using a flow rate sensor that detects the speed of the fluid applied to the flow rate switch automatically and precisely inspects the performance of the flow rate switch, the quality of the flow rate switch can be uniform, so that the flow rate switchCan improve the quality of the Hydraulic device or hydraulic device prepared for, and it can improve the accuracy of the inspection of the flow rate switch.

Description

Performance test system of SWITCH

1 is an exploded perspective view of a typical flow rate switch.

2 is a configuration block diagram of a performance test system of a flow rate switch according to the present invention.

* Explanation of symbols for main parts of the drawings

10: flow rate switch 10-1: flow resistance resistor

10-2: Hall element 20: Flow sensor

30: pump (PUMP: RA) 40: pump (PUMP) drive unit

50: Frequency Voltage Change Part (FREQUENCY VOLTAGE CONVERTER: FVC)

60: analog digital converter (ADC)

70: computer 80: digital input

90: water tank 100, 100-1, 100-2: pipeline

The present invention relates to a system for inspecting the performance of the flow rate switch, and in particular, using a flow rate sensor (SENSOR) to detect the speed of the fluid applied to the flow rate switch (SENSOR) flow rate that can be precisely inspected the performance of the flow rate switch A performance test system of a switch (SWITCH).

In the related art, a device for inspecting the performance of the flow rate switch has not been developed, and thus the quality of the pneumatic or hydraulic device manufactured by applying the flow rate switch was not uniform.

In addition, since the performance of the flow rate switch itself can not be accurately examined, there was also a decrease in the reliability of the product for the flow rate switch.

Therefore, the present invention provides a flow rate switch according to the velocity of the fluid detected using the flow rate sensor for detecting the velocity of the fluid applied to the flow rate switch in order to solve the problems caused by the conventional flow rate switch as described above The purpose of the present invention is to provide a performance test system of the flow rate switch, which enables precise inspection of the performance of the flow rate switch.

In addition, the present invention by using a flow rate sensor for detecting the speed of the fluid by processing the state of the flow rate switch operating in accordance with the speed of the fluid applied to the flow rate switch, it is possible to automatically perform the performance test of the flow rate switch It is another object of the present invention to provide a performance test system for a flow rate switch, and another object of the present invention is to apply the flow rate switch by precisely inspecting the state of the flow rate switch operating according to the speed of the fluid applied to the flow rate switch. It is to provide a performance test system of the flow rate switch to improve the quality of the pneumatic or hydraulic equipment.

The present invention, in order to achieve the above object, the flow rate resistor 10-1 and the Hall element (10-2) for detecting the variable flow rate resistor (10-1) whose position is changed in accordance with the speed of the incoming fluid In the flow rate switch 10, the outlet portion of the flow rate switch 10 is connected to the water tank 90 for storing the fluid through the conduit 100, the inlet portion of the flow rate switch 10 is a conduit (199-) 3) is connected to one side of the flow rate sensor 20 for sensing the speed of the fluid, the tile side of the flow rate sensor 20 is connected to one side of the pump (PA) 30 through the conduit (100-2) The tile side of the pump 30 is connected to the water tank 90 through a conduit 100-1, and the computer 70 is connected to the water tank 90 through the pump driver 40 driving the pump 30. Is connected to, and the frequency output from the flow rate sensor 20 for sensing the speed of the fluid flowing through the pipeline 100-2 by the driven pump 30 The frequency voltage converter 50 for converting a signal into a voltage is connected to the computer 70 through an analog digital converter 60 for converting an analog signal into a digital signal, and the flow rate sensor 20 and the pipe 100 The computer 70 converts the analog signal output from the Hall element 10-2 which detects the flow rate resistor 10-1 whose position is changed by the fluid flowing at a predetermined speed through -3) into a digital signal. It is achieved by the performance test system of the flow rate switch, characterized in that consisting of a digital input unit 80 to input.

The above and other objects, features, and effects of the present invention will be more clearly understood by the embodiments described in detail with reference to the accompanying drawings.

1 is an exploded perspective view of a conventional flow rate switch, and FIG. 2 is a block diagram of a performance test system of the flow rate switch according to the present invention.

As shown in FIG. 1, the flow rate switch 10 has a flow rate resistor 10-1 installed to change its position by the speed of the fluid flowing into the inlet, and a flow rate resistor whose position is changed by the inflowing fluid. As a conventional flow rate switch of the Hall element (10-2) for detecting the (10-1), the outlet of the flow rate switch 10 is connected to the water tank (90) for storing the fluid through the conduit 100 In addition, the inflow portion of the flow rate switch 10 is connected to one side of the flow rate sensor 20 that detects the velocity of the fluid through the conduit 100-3.

The flow rate resistor 10-1 of the flow rate switch 10 is installed at one side of the flow rate switch 10 so that its position is changed by the speed of the fluid flowing into the inflow portion. A small permanent magnet is built in the inside of 1).

The Hall element 10-2 of the flow rate switch 10 is a Hall element that senses a magnetic field formed in a permanent magnet or an electromagnet, and is formed by the velocity of the fluid flowing into the inlet of the flow rate switch 10. Hall element for detecting the magnetic field formed in the small permanent magnet embedded in the flow-rate resistor (10-1) that changes the position, and the magnetic element formed in the small permanent magnet embedded in the flow-resistant resistor (10) Numeral 10-2 is connected to a digital input unit 80 that converts an analog signal into a digital signal and inputs it to a computer 70.

Flow sensor (SENSOR) 20 is to detect the speed of the fluid to output the detected signal as a frequency, the pipe line (100-3) and the pump connected to the inlet of the flow rate switch (10) 30 is connected between the pipe lines 100-2 connected to one side, and the output terminal of the flow rate sensor 20 is connected by a frequency voltage converter 50 for converting a frequency into a voltage. .

The pump driving unit 40 is configured to control the driving and speed of the pump PA 30 by a control signal output from the computer 70.

The frequency voltage converter (FREQUENCY VOLTAGE CONVERTER: FVC) 50 is capable of converting the magnitude of the frequency signal output from the flow rate sensor 20 into a voltage, and converts an analog (ANALOG) signal into a digital ( It is connected to the analog digital conversion unit 60 for converting into a digital signal.

The analog digital converter (ADC) 60 is a conventional A / D converter, which converts an analog signal voltage output from the frequency voltage converter 50 into a digital signal to convert the internal signal into a computer 70. It is connected to the computer 70 to store in the memory (MEMORY).

The computer 70 is a computer in which a general microprocessor, a memory, and the like are embedded to control the entire system. The computer 70 controls the driving and speed of the pump PA 30. In order to be connected to the pump drive unit 40, and to store the digital signal output from the analog digital conversion unit 60 in the memory (MEMORY), the Hall element 10- of the flow rate switch 10 It is connected to the digital input unit 80 to digitalize the analog signal sensed and output by 2).

Hereinafter, the operational relationship and the effect of the performance test system of the flow switch (SWITCH) according to the present invention.

Assuming that the magnitude of the flow rate at which the flow rate switch 10 can operate is '5' (M / S), for example, a control signal output from the computer 70 to drive the pump PA 30 at a low speed. Is transmitted to the pump driver 40, the signal from the pump driver 40 to drive the pump (PA) 30 at a low speed by a control signal transmitted from the computer 70, the pump (PA) (30) The pump PA is driven at a low speed by the signal transmitted from the pump driver 40.

The fluid stored in the water tank 90 flows into the pipe line 100-1 connected to one side of the pump PA 30 by the driven pump PA 30. The fluid flowing in the fluid flows to the flow rate sensor 20 at a predetermined speed through a conduit 100-2 connected to the other side of the pump 30 by a predetermined pressure of the driven pump 30. The fluid flowing into the flow rate sensor 20 flows into the inlet of the flow rate switch 10 through the conduit 100-3 at a predetermined speed.

At this time, the speed of the fluid through the flow rate sensor 20 is detected by the flow rate sensor 20, the frequency signal corresponding to the detected speed of the fluid through the output terminal of the flow rate sensor 20 frequency voltage converter ( 50, and the frequency signal transmitted to the frequency voltage converter 50 is converted into a voltage VOLTAGE by the frequency voltage converter 50.

The signal converted into a voltage through the frequency voltage converter 50 is converted into a digital through an analog digital converter 60, and the digitalized signal is stored in a memory built into the main body of the computer 70. do.

On the other hand, the flow rate of the fluid flowing into the inlet of the flow rate switch 10 (for example, '3'M / S) is lower than the flow rate (' 5'M / S) that can operate the flow rate switch 10 The position of the flow rate resistor 10-1 installed inside the flow rate switch 10 does not reach a position detectable by the hall element 10-2, and the hall element 10-2. The magnetic field formed by the permanent magnet embedded in the flow resistor 10-1 cannot be detected, thereby transmitting a signal in a low state to the digital input unit 80, and the hole of the flow switch 10. The analog signal in the low state transmitted from the element 10-2 is converted into a digital signal by the digital input unit 80 and transmitted to the computer 70.

The computer 70 may store data corresponding to the rapid movement of the fluid detected from the flow rate sensor 20 stored in the memory and data of the low level digital signal transmitted from the digital input unit 80. The speed of the fluid applied to the flow rate switch 10 by the data processed by the microprocessor (CPU) of the computer 70 is mutually computed by the microprocessor (CPU). The computer 70 recognizes that the flow rate set at the time is smaller than '5' M / S) and increases the speed of the pump PA 30 which is driven at a low speed. The control signal from the 70 is output to the pump driver 40.

The pump driver 40 receiving the control signal from the computer 70 transmits the control signal to the pump PA so as to increase the driving speed of the pump PA 30 which is driven at a low speed. To 30.

Therefore, the pump PA 30 is driven at a higher speed by the signal transmitted to the pump PA 30 which is driven by the transmission.

The pressure of the driven pump (PA) 30 is stronger than the initial pressure so that the fluid stored in the water tank (90) flows into the pipeline (100-1) connected to one side of the pump (PA) 30, The speed (for example, '5' M / S) that is faster than the speed of the flow rate flowing through the pipe (100-1) is detected by the flow rate sensor 20, the frequency signal corresponding to the detected speed of the fluid flow rate It is transmitted to the frequency voltage converter 50 through the output terminal of the sensor 20, the frequency signal transmitted to the frequency voltage converter 50 is converted into a signal of the voltage by the voltage converter 50.

The signal of the analog voltage converted into the signal of the voltage through the frequency voltage converter 50 is transmitted to the analog digital converter 60, the signal of the analog voltage transmitted to the analog digital converter 60 is analog digital The conversion unit 60 converts the signal into a digital voltage, and the signal of the voltage digitalized through the analog digital conversion unit 60 is transmitted to and stored in an internal memory of the main body of the computer 70.

Claims (1)

In the flow rate switch 10 of the flow rate resistor (10-1) and the Hall element (10-2) for detecting the variable fluid resistor (10-1) is variable in position according to the speed of the fluid flow, the The outlet of the flow rate switch 10 is connected to the water tank 90 for storing the fluid through the conduit 100, and the inlet of the flow rate switch 10 detects the velocity of the fluid through the conduit 100-3. It is connected to one side of the sensor 20, the tile side of the flow rate sensor 20 is connected to one side of the pump (PA) 30 through a conduit (100-2), the tile side of the pump 30 is a pipeline ( 100-1) is connected to the water tank 90, the computer 70 is connected to the pump 30 through the pump drive unit 40 for driving the pump 30, the driven pump 30 Frequency voltage conversion for converting the frequency signal output from the flow rate sensor 20 for detecting the speed of the fluid flowing through the pipe (100-2) by a voltage to a voltage by 50 is connected to the computer 70 through an analog digital conversion unit 60 for converting an analog signal into a digital signal, and flows in at a predetermined speed through the flow rate sensor 20 and a conduit 100-3. The analog signal output from the Hall element 10-2 sensing the flow rate resistor 10-1 whose position is changed by the fluid to be converted into a digital signal to the digital input unit 80 to input to the computer 70 Performance test system of the flow rate switch (SWITCH), characterized in that configured.