KR910000360Y1 - Solenoids opening and closing detecting apparatus - Google Patents

Abstract

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Description

Solenoid open / close detection device

1 is an external perspective view of the present invention solenoid.

2 is a side view showing a button installation state of the solenoid of the present invention.

3 is a plan view showing a switch contact state of the present invention solenoid.

4 is a cross-sectional view taken along the line A-A shown in FIG.

5 is a conventional solenoid drive circuit diagram.

6 is a solenoid drive circuit diagram of the present invention.

7 is a drive flow chart of the present invention.

* Explanation of symbols for main parts of the drawings

1: planar 3: adsorption plate

4,14 button 5,15 fixing piece

9.19: long 6,16: switch

10: body 11: stopper

MIC: Micom I ₁ : Inverter

TR: Triac R ₁ -R ₃ : Resistance

C ₁ , C ₂ : condenser

The present invention relates to a solenoid open and close detection device that can detect the opening and closing of the solenoid used in the drain valve, such as a washing machine to prevent damage and overheating of the solenoid.

The solenoid of the washing machine currently on the market is constrained and is not equipped with a device that can prevent the occurrence of problems caused by excessive heat ignition.

In other words, if the valve is not operated smoothly due to foreign matter stuck to the drain valve, or the water remaining in the drain hose freezes around the drain valve in winter, the cover drain valve is constrained than the pulling force of the solenoid that operates the drain valve. The short circuit caused by the overcurrent flow occurred between the internal coils of the wires, causing a fire.

The purpose of the present invention is to configure a contact switch for detecting the drain valve opening and closing inside the solenoid and then detect whether or not the solenoid is driven in accordance with the contact state of the contact switch in case of a problem (drain valve drainage, drain valve freezing, etc.). The solenoid opening and closing detection device for removing the cause of damage and overheating of the solenoid by cutting off the power applied to the solenoid to be described in detail by the accompanying drawings as follows.

1 is an external perspective view of the solenoid of the present invention, in which a button 4 is pushed by a push of the suction plate 3 to a solenoid body 10 that sucks the planar 1 to which the suction plate 3 is attached. This is the same as the general configuration of the solenoid, but in the present invention is to configure another button 14 in a position opposite to the button (4).

Therefore, when the solenoid is normally driven, the flanza 1 is pulled toward the body 10, and thus the buttons 4 and 14 are pressed by the suction plate 3.

2 and 3 show the button installation state and the switch contact state of the solenoid of the present invention. When the buttons 4 and 14 are pushed onto the suction plate 3, the buttons 4 and 14 are moved to the switch 6 ( 16 is pressed down and the contact (a) (b) installed on the fixing piece (5) (15) and the contact (b) (d) installed on the switch (6) (16) is configured to fall.

At this time, the installation of two contacts (a) (b) is to maintain a more secure connection state and the contact (c) (d) is the same as above.

4 is a cross-sectional view taken along line AA of FIG. 2 and includes a switch (b) (d) formed at a solenoid body (10) having a stopper (11) and a flanza (1) embedded therein and a coil (2) installed outside thereof. 6) 16 are provided and the buttons 4 and 14 pushed by the adsorption plate 3 of the flanza 1 are configured to push the switches 6 and 16.

In addition, the fixing piece (5) (15) is provided to be connected to the contact point (b) (c), and the buttons (4) and (14) are pressed by the pressing force of the suction plate (3). If it is pushed and the pressing force is lost, it is configured to return to its original position by the elasticity of the switches 6 and 16.

In the drawings, reference numerals 9 and 19 denote holes for protruding and installing the buttons 4 and 14 to the body 10 as long holes. FIG. 5 is a diagram showing a conventional solenoid driving circuit. The diode D ₅ penetrates and is connected to the coil diode 2 through the bridge diodes D ₁ -D _{4 to} which an AC power source AC is applied.

Then, the resistor R ₁ and the capacitor C ₁ are configured to be connected between the coils LA and LB, and the switches 6 are connected in parallel. Is the same as FIG. 1 to FIG.

The sixth turning power supply (Vcc) side of the input port (P ₂₎ of the via the switch 16, the resistance (R ₃₎ (R ₄₎ and a microcomputer (MIC) and then connected to the capacitor (C _3), a solenoid driving circuit subject innovation The output port P ₁ of the MIC is connected to the gate side of the triac TR through an inverter I ₁ and a resistor R ₁ , and a coil to which a power source AC is supplied. (2) is connected in series with the triac TR, but the triac TR is configured to be connected in parallel with a resistor R ₂ and a capacitor C ₂ .

Where B represents a rectified DC power supply.

In this way, the present invention is configured so that one button 4 is provided with the same button 14 as the button 4 to the solenoid having one button 4 to detect whether the solenoid is opened or closed, and the first button 4 is installed. The solenoid drive of will be described in detail with reference to FIG.

Since the switch 6 is pushed by the button 4 before the power is turned on, the contact point a is maintained.

In the above, when the power is turned on, current flows in the coil 2, but at this time, the current is transmitted through the coil LA and the contact (a) because the contact (a) (b) of the switch 6 is connected. Will flow. When the current flows through the coil LA, the solenoid suction force is ignited to suck the flanza 1, and when the flanza 1 is sucked, the suction plate 3 moves accordingly to press the button 4 so that the switch 6 Pushed out, the contact point a is opened.

When the contact (a) (b) is open, the current flows through the coil (LA) (LB) so that the solenoid flows only a holding current for maintaining the flanza (1) in a suctioned state.

That is, the conventional solenoid is connected to the contact (a) (b) before the power is turned on to flow a lot of current to the coil (LA) to suck the flanza (1) and when the flanza (1) is sucked in the button ( 4) to open the contact (a) (b) to flow only the current for maintaining the suction state of the planar (1) through the coil (LA) (LB).

Therefore, a large amount of starting current flows only during inhalation of the flanza 1, and only a small amount of holding current flows after inhalation of the flanza 1.

The solenoid operated as described above had a problem such as damage to the solenoid and overheating of the solenoid because the solenoid was continuously supplied with current even if foreign matter was caught in the drain valve or the freezing around the drain valve caused the solenoid to restrain.

In view of the above, the present invention provides a button 14 having the same structure as the button 4 in the solenoid to block the current applied to the solenoid when the solenoid is constrained.

That is, when the adsorption plate 3 fixed to the planar 1 pushes the button 14, the switch 16 is pushed by the button 14 so that the contact point (c) (d) is opened and such a contact ( C) The open state of (d) was recognized by MIC. First, in FIG. 6, when the solenoid driving signal “L level” is output to the output port P ₁ of the MIC, the inverter I ₁ is inverted to turn on the triac TR. Therefore, a current flows in the coil 2 so that the flanza 1 of the solenoid is sucked.

When the status signal of "H level" is output to the output port P ₁ of the MIC again, the triac TR is "turned off" so that the solenoid flanza 1 is released from the suction.

This is a general solenoid driving circuit, and in the present invention, when the planar 1 is sucked as described above, the contact 14 of the switch 16 is pushed by pushing the button 14 to the suction plate 3.

At this time, the contact point (c) (d) is maintained in the connected state before the planar (1) is sucked.

Therefore, before the solenoid operates, the contact point (c) (d) of the switch 16 is in a connected state, and a status signal of "H level" is applied to the input port P ₂ of the microcomputer MIC, and the solenoid operates. When the suction plate 3 pushes the button 14, the contact point c is opened so that a state signal of "L level" is applied to the input port P ₂ .

Therefore, when the microcomputer (MIC) outputs the "H level" status signal for driving the solenoid to the output port P ₁ , if the "H level" status signal is not input to the input port P ₂ , the drain valve is restricted. By considering the solenoid abnormality and converting the output port P ₁ into the "H level" status signal, the current supply to the solenoid can be cut off further to prevent problems such as damage to the solenoid or overheating fire.

In other words, when the solenoid is driven by outputting the "L level" status signal to the output port (P ₁ ) of the microphone (MIC), but the solenoid is damaged and the drain valve is constrained, the planar (1) is not sucked. If the supply is not blocked, the solenoid may be damaged. In this design, if the flanza (1) is inhaled normally, the contact (c) (ㄹ) is opened to inform the microcomputer (MIC) that the solenoid is in normal operation. If the lanza (1) is not inhaled, the contact (c) (d) is maintained in a connected state, so at this time, the solenoid driving is stopped to eliminate problems such as damage and overheating of the solenoid.

The operation of the microcomputer (MIC) is shown in the flowchart of FIG.

That is, when the "L level" status signal for driving the solenoid is output to the output port P ₁ and the "L level" status signal is applied to the input port P ₂ , it is determined that the drain solenoid operation is good and continues. Proceed with the operation.

However, if the "L level" status signal is not applied to the input port P ₂ for a certain period of time, the operation of the drain solenoid is stopped, and the chattering occurs when the solenoid is chattered due to insufficient holding force of the solenoid coil. If more than three occurrences occur by checking the occurrence frequency of the phenomenon, it is regarded that the suction power of the drainage solenoid is not enough, and the operation of the drainage solenoid is stopped.

As described above, the present invention adds another solenoid driving state detecting switch to the inside of the solenoid so that the microcomputer senses that the switch is connected and opened so that the operation state of the solenoid can be recognized. When the icing, the solenoid itself suction power and the holding power is insufficient, the power supply to the solenoid is cut off to prevent accidents caused by overheating of the solenoid.

Claims (1)

A suction plate 3 fixed to the flanza 1, a coil 2 for sucking the flanza 1, a button 4 pushed by the suction plate 3 when the flanza 1 is sucked; In the solenoid composed of a switch (6) having a contact point (a) (b) open by the push of the button (4), which has an elasticity, it is installed in a position opposite to the button (4) and attached to the suction plate (3) And a button 14 pushed by the button and a switch 16 having elasticity by opening the contact point (c) by pressing the button 4 and recognizing a connection state of the contact point (c). And a microcomputer (MIC) for controlling solenoid driving.