KR20080013597A - Electronic valve control circuit which uses a feedback resistance - Google Patents

Abstract

A circuit for driving an electronic proportional valve using a feedback resistor is provided to drive the valve by comparing a control signal with an actual current value measured at the feedback resistor and then turning a switching element on or off. A sensing unit(5) is connected to a front end of an electronic proportional valve(4) to measure an actual current value using a feedback resistance. A controller(2) compares the measured current value with a control signal to output a control command to a driving unit(3). The driving unit is connected to the electronic proportional valve, and turns a switching element(31) on or off to output an electric current to the electronic proportional valve. A feedback resistor(51) receives the electric current from the driving unit to vary a flow rate to be discharged.

Description

Electronic valve control circuit which uses a feedback resistance

1 is a view showing a conventional electromagnetic proportional valve driving circuit.

2 is a diagram illustrating an electromagnetic proportional valve driving circuit using a feedback resistor according to an exemplary embodiment of the present invention.

*** Explanation of symbols for main parts of drawing ***

1 ECU 2 Control part

3: driving part 4: electromagnetic proportional valve

5 sensing unit 31 switching element

51: feedback resistance

The present invention relates to an electromagnetic proportional valve driving circuit using a feedback resistor.

More specifically, the electromagnetic proportional valve driving circuit using the feedback resistor which compares the control signal (command value) and the actual current value measured at the feedback resistance installed at the front end of the electromagnetic proportional valve to turn on / off the switching element to drive the electromagnetic proportional valve. It's about the furnace.

In general, heavy equipment using hydraulic pressure and gas-related equipment using gas pressure are equipped with an electromagnetic proportional valve which is driven by electric force to control discharge flow rate and gas amount. In addition, a drive control circuit is essentially required to control the driving state of the electromagnetic proportional valve.

1 is a view showing a conventional electromagnetic proportional valve driving circuit. Referring to Figure 1 describes a conventional electromagnetic proportional valve driving circuit,

The control signal input from the outside is applied to the non-inverting terminal (+) of the first input terminal and the current value sensed from the feedback resistor 51 of the sensing unit 5 is applied to the inverting terminal (-) of the second input terminal. The control unit 2 which compares the two signals and outputs the control signal to the driving unit 3 is connected to the front end of the electromagnetic proportional valve 4 to turn on / off the switching element 31 according to the output signal of the control unit. A driving unit 3 for outputting a predetermined current to the electromagnetic proportional valve 4, an electromagnetic proportional valve 4 for controlling a discharge flow rate and a gas amount by receiving a predetermined current according to on / off of the switching element of the driving unit; The sensing unit 5 is connected to a rear end of the electromagnetic proportional valve and senses a current value flowing through the electromagnetic proportional valve 4 and outputs it to the second input terminal of the controller.

Looking at the operation of the drive circuit of the conventional electromagnetic proportional valve having the configuration as described above, when the user operates a predetermined switch to adjust the discharge flow rate and the gas amount from the outside, this switch operation signal is shown in FIG. As described above, the control signal is converted into a control signal having a current value of a predetermined level and is input to the first input terminal of the controller as a non-inverting terminal (+). At this time, since the electronic proportional valve 4 is not driven initially, the current value measured by the sensing unit 5 has a ground level and is applied to the second input terminal of the controller as an inverting terminal (−). The control unit 2 compares two input signals and outputs a control signal to the driving unit 3, and the driving unit 3 turns on a switching element to supply a predetermined current corresponding to the control signal to the electromagnetic proportional valve. (4), the position of the electromagnetic proportional valve (4) is moved corresponding to the predetermined current applied, and the flow rate and the amount of gas discharged are varied accordingly.

On the other hand, the current flowing through the electromagnetic proportional valve 4 is measured by the feedback resistor 51 of the sensing unit 5 to detect a current value of a predetermined level, and this current value is supplied to the second input terminal of the controller again. . Accordingly, the driving state of the electromagnetic proportional valve is controlled by comparing two input signals inputted by the controller.

However, in the conventional electromagnetic proportional valve driving circuit, since the feedback resistor 51 is placed behind the electromagnetic proportional valve 4, two (A, B) lines are required in the ECU (Electronic Contronic Unit, 1). A and B) is long, and two connectors are required on the ECU 1 side, so that the overall amount of wiring increases and the number of ECU 1 connectors also increases.

In addition, as shown in FIG. 1, when a high voltage enters the B line, a separate protection circuit has to be added to prevent breakage of the feedback resistor 51.

The present invention has been made to solve the problems described above, by comparing the control signal (command value) and the actual current value measured in the feedback resistance installed in the front of the electromagnetic proportional valve by switching the switching element on / off electron proportional An object of the present invention is to provide an electromagnetic proportional valve driving circuit using a feedback resistor for driving a valve.

SUMMARY OF THE INVENTION An object of the present invention is to provide an electromagnetic proportional valve driving circuit including an electromagnetic proportional valve for controlling a discharge flow rate and a gas volume, wherein an actual current value connected to a front end of an electromagnetic proportional valve and flowing through an electromagnetic proportional valve is measured using a feedback resistor. And a sensing unit for outputting the measured current value to the control unit, a control unit for comparing the measured current value of the sensing unit with a control signal and outputting a control command to the driving unit, and a control command directly connected to the electronic proportional valve. Electromagnetic proportionality using a feedback resistor comprising a driving unit for turning on / off the switching element and outputting a predetermined current to the electromagnetic proportional valve and an electromagnetic proportional valve for varying the discharge flow rate and gas amount by receiving a predetermined current from the driving unit. By providing a valve drive circuit.

The present invention has the same components as the conventional electromagnetic proportional valve driving circuit, but the conventional sensing unit (5 in FIG. 1) is connected to the rear end of the electromagnetic proportional valve to measure the current flowing in the electromagnetic proportional valve, but the sensing unit (FIG. 2, 5) is characterized in that the front end of the electromagnetic proportional valve, that is, connected between the main power source B + and the switching element 31 of the driving unit, measures the actual current value flowing through the electromagnetic proportional valve 4.

Hereinafter, an electromagnetic proportional valve driving circuit using a feedback resistor according to an exemplary embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

2 is a diagram illustrating an electromagnetic proportional valve driving circuit using a feedback resistor according to an exemplary embodiment of the present invention. Referring to Figure 2 specifically describe the electromagnetic proportional valve driving circuit using a feedback resistor, an embodiment of the present invention,

The electromagnetic proportional valve driving circuit using the feedback includes a sensing unit 5 including a feedback resistor 51, a control unit 2, a driving unit 3 including a switching element 31, and an electromagnetic proportional valve 4. It is composed.

The sensing unit 5 is connected to the front end of the electron proportional valley, and in particular, is connected between the main power source B + and the switching element 310 of the driving unit to supply an actual current value flowing through the electromagnetic proportional valve 4 to the feedback resistor 51. ) Is measured and the measured current value is output to the controller 2.

The control unit 2 compares the measured current value of the sensing unit with a control signal (command value) input from the outside and outputs a control command to the driving unit 3, for example, the feedback resistor 51. If the measured current value is greater than the control signal (command value) input from the outside is to give a control command to turn off the switching element 31.

The driving unit 3 is directly connected at the front end of the electromagnetic proportional valve 4 to turn on / off the switching element 31 according to the control command of the controller to output a predetermined current to the electromagnetic proportional valve 4, The electromagnetic proportional valve 4 receives a predetermined current from the driver 4 to vary the discharge flow rate and the gas amount.

Hereinafter, the operation principle of the electromagnetic proportional valve driving circuit using the feedback resistor according to an exemplary embodiment of the present invention will be described in more detail with reference to FIG. 2.

When the user operates a predetermined switch to adjust the discharge flow rate and the gas amount from the outside, the switch operation signal is converted into a control signal (command value) having a current value of a predetermined level as shown in FIG. The non-inverting terminal (+) is input to the first input terminal of the.

At this time, since the electromagnetic proportional valve 4 is not driven initially, the actual current value measured by the sensing unit 5 has a ground level and is applied to the second input terminal of the controller as an inverting terminal (−). .

The controller 2 compares two input signals and outputs a control command to the driver 3 to turn on the switching element because the control signal (command value) is larger than the measured actual current value. The driving unit 3 turns on the switching element 31 to output a predetermined current corresponding to the control command to the electromagnetic proportional valve 4, and the electromagnetic proportional valve 4 responds to the applied predetermined current. The position is moved, and thus the flow rate and the gas amount discharged are varied.

On the other hand, the actual current value flowing through the electromagnetic proportional valve 4 is measured by the feedback resistor 51 of the sensing unit 5 and detected as a current value of a predetermined level, and this current value is returned to the second input terminal of the controller. Supplied. Therefore, the driving state of the electromagnetic proportional valve is controlled by comparing two input signals inputted by the controller.

Although one preferred embodiment of the present invention has been described above, it is clear that the present invention may use various changes, modifications, and equivalents, and may be applied in the same manner by appropriately modifying the embodiment. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

As described above, the present invention, the electromagnetic proportional valve driving circuit using a feedback resistor, by placing a feedback resistor for measuring the actual current value of the electromagnetic proportional valve in front of the electromagnetic proportional valve can reduce the number of connectors and wirings connected to the ECU. It works,

Another effect is that the component circuit is simplified and the volume is reduced by eliminating the need for a protection circuit that was needed when a high voltage was applied.

Claims (2)

An electromagnetic proportional valve driving circuit comprising an electromagnetic proportional valve for controlling a discharge flow rate and a gas amount, A sensing unit connected to a front end of the electromagnetic proportional valve and measuring an actual current value flowing through the electromagnetic proportional valve using a feedback resistor and outputting the measured current value to the controller; A controller which compares the measured current value of the sensing unit with a control signal and outputs a control command to a driver; A driving unit connected directly to the electromagnetic proportional valve and outputting a predetermined current to the electromagnetic proportional valve by turning on / off a switching element according to a control command of the controller; And An electromagnetic proportional valve configured to vary a discharge flow rate and a gas amount by receiving a predetermined current from the driving unit; Electronic proportional valve drive circuit using a feedback resistor comprising a. The method of claim 1, wherein the position of the feedback resistor is Electronic proportional valve drive circuit using a feedback resistor, characterized in that configured between the main power supply and the switching element.

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