KR20120139039A - Sensor assembly for washing machine - Google Patents

Abstract

PURPOSE: A sensor assembly for a washing machine is provided to measure a minute water level in a water container of the washing machine by using a piezoelectric sensor. CONSTITUTION: A piezoelectric sensor(300) outputs variation rates of power according to pressure variation by using a piezoelectric effect. A space(400) supports the piezoelectric sensor. An inlet guides air in order to draw the air into the inside of a cover(200). An O-ring(410) shields a gap between the cover and the piezoelectric sensor. A sealing member(420) blocks the inflow of a foreign substance through a gap between a case(100) and the cover.

Description

Sensor assembly for washing machine

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sensor assembly for a washing machine, and more particularly, to a sensor assembly for a washing machine configured to measure a water level inside a washing machine tank by a piezoelectric sensor using a piezoelectric effect or a resistance effect (Piezo method).

In general, a washing machine is a device that washes laundry through a process of washing, rinsing, or dehydrating water by using water and a detergent supplied into a washing tank.

The main control unit of the washing machine is provided with a pressure sensor for appropriately adjusting the water supply amount according to a predetermined level or a level directly set by the user.

As such, the pressure sensor provided in the washing machine adjusts the level of the washing water according to the oscillation frequency of the LC oscillation circuit. That is, as disclosed in Korean Patent Laid-Open Publication No. 10-2011-0023939, the pressure sensor for a washing machine includes a diaphragm inside the water level sensor due to a change in air pressure that changes as the water height inside the washing tank (water tank) of the washing machine changes. DIAPHRAGM) and FERRITE are raised to detect the height of water by changing the frequency due to the change of magnetic flux of the coil.

However, in such a conventional pressure sensor, since a diaphragm, a coil spring, or the like, which provides a compressive force to the ferrite core, is used, there is a problem in that the measurement accuracy is lowered during repeated use for a long time. In addition, in such a conventional structure, there is a problem that it is difficult to manage the water level over the entire range (low water level to high water level).

In addition, the conventional pressure sensor is mainly installed integrally with the main board (Main PCB) for controlling the overall operation of the washing machine. Therefore, when replacement and after-sales service is required due to defects in the pressure sensor or foreign matter penetration, there is a problem in that the main board (Main PCB) is opened and repaired or replaced.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, is provided with a piezoelectric sensor using a piezoelectric effect, to provide a sensor assembly for a washing machine that can accurately detect the water level inside the washing machine tank as a whole. .

Another object of the present invention, the sensor assembly for a washing machine equipped with a piezoelectric sensor is spaced apart from the main board (Main PCB) of the washing machine, so that the inspection and replacement of the main board (Main PCB) is not accompanied by the problem of the sensor assembly. It is.

According to a feature of the present invention for achieving the object as described above, the sensor assembly for a washing machine according to the present invention, the main board (Main PCB) of the washing machine is installed and spaced apart from the case; A cover that is tightly fixed to one side of the case and shields one open side of the case; A piezoelectric sensor provided inside the case and outputting an amount of change in voltage according to a pressure change using a piezoelectric effect; A space provided inside the cover to support the piezoelectric sensor; An inlet formed at one end of the cover to guide air to the inside of the cover from the outside; An O-ring provided at one side of the space and shielding a gap between the cover and the piezoelectric sensor; And a sealing member provided between the case and the cover to block the inflow of external foreign matter through the gap between the case and the cover.

Inside the case, a PCB substrate is connected to one end of the piezoelectric sensor; The PCB substrate is characterized in that the connection terminal is connected to one end is exposed to the outside.

The piezoelectric sensor may include a head unit having a piezoelectric element therein; It is formed integrally on one side of the head portion, it characterized in that it has a configuration including a port portion for guiding the air introduced through the inlet to the head portion.

At the center of the cover, the receiving end for supporting the head of the piezoelectric sensor is formed; Inside the receiving end, the space surrounding the port portion of the piezoelectric sensor and the O-ring is installed up and down.

The O-ring and the sealing member, characterized in that made of an elastic material.

The sensor assembly for a washing machine according to the present invention is provided with a piezoelectric sensor using a piezoelectric effect. Therefore, such a piezoelectric sensor has the advantage that both fine water level measurement can be carried out over the whole section of the washing machine tank. That is, there is an advantage in that the change in water level is linearly measured precisely between all the regions instead of a specific point.

In addition, in the present invention, an O-ring having an airtight function is provided between the piezoelectric sensor and the cover, and the O-ring is pressed by a space. Therefore, when the assembly is completed, the O-ring is pressed by the space and expands to the outside, so that the gap leakage of air introduced through the inlet is completely prevented.

In addition, the sensor assembly for a washing machine according to the present invention is installed separately from the main board (Main PCB) that controls the operation of the washing machine as a whole. Therefore, even when repair is required due to a malfunction of the sensor, there is no need to disassemble or replace the main board (Main PCB) as in the prior art, thereby improving work efficiency and reducing material costs.

1 is a perspective view showing the configuration of a preferred embodiment of a sensor assembly for a washing machine according to the present invention.
Figure 2 is a cross-sectional view showing the internal configuration of a preferred embodiment of a sensor assembly for a washing machine according to the present invention.

Hereinafter, a preferred embodiment of a sensor assembly for a washing machine according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 illustrate an embodiment of a sensor assembly for a washing machine according to the present invention, respectively, in a perspective view and a cross-sectional view.

As shown in these figures, the sensor assembly for a washing machine according to the present invention,

A case 100 forming an appearance, a cover 200 shielding an opened one (down) of the case 100, and a piezoelectric sensor 300 outputting an amount of change in voltage according to a pressure change using a piezoelectric effect. ), A space 400 for supporting the piezoelectric sensor 300, an inlet 250 for guiding air into the cover 200 from the outside, and the cover 200 and the piezoelectric sensor 300. O-ring 410 for shielding the gap between, and the sealing member 420, etc. to block the inflow of foreign matter through the gap between the case 100 and the cover 200.

As shown in the case 100, the lower side is opened, and a predetermined space in which a plurality of components are installed is formed therein.

In addition, the case 100 is installed as a separate component at a position spaced apart from the main board (Main PCB) of the washing machine. That is, the sensor assembly for a washing machine according to the present invention is installed at the upper end of the washing machine, but is separately installed as a separate component from the main board (Main PCB) for controlling the overall operation of the washing machine.

The cover 200 is tightly fixed to the lower side of the case 100. Therefore, the lower part of the case 100 in which the lower part is opened is shielded.

In addition, the sealing member 420 is fitted between the case 100 and the cover 200.

The sealing member 420 is made of a flexible elastic material such as rubber. Therefore, not only the rotation of the cover 200 is prevented by the sealing member 420, but also moisture or external foreign matter is prevented from flowing into the inside through the gap between the case 100 and the cover 200.

The piezoelectric sensor 300, as shown, is installed upright inside the case 100.

The piezoelectric sensor 300 is a piezoelectric sensor, and is a device for measuring a pressure acceleration strain using a piezoelectric effect and converting it into an electrical signal.

The piezoelectric effect is a phenomenon in which electrical polarization occurs on the surface of a crystal when a force is applied to a solid.

The piezoelectric sensor 300 includes a head portion 310 having a piezoelectric element therein, and a port portion 320 for guiding air introduced through the inlet 250 to the head portion 310. .

The head portion 310, as shown, is made of a circular shape, and has a thickness of a predetermined size. The lower end of the head 310 is further protruded outward to form the head jaw 312.

The port portion 320 is integrally formed under the head portion 310. That is, the port part 320 has a cylindrical shape having an outer diameter smaller than that of the head part 310, and is integrally formed under the head part 310.

Accordingly, the pressure of the air flowing through the inlet 250 is transmitted to the piezoelectric element (not shown) inside the head 310 through the port 320.

The port part 320 is formed stepped. That is, as shown, the step portion 322 is formed in the central portion of the port portion 320, the outer diameter of the lower port portion 320 is formed to have a smaller size than the upper side.

On the other hand, in the central portion of the cover 200, the receiving end 210 for supporting the head portion 310 of the piezoelectric sensor 300 is formed. In addition, the space 400 and the O-ring 410 surrounding the outside of the port part 320 of the piezoelectric sensor 300 are installed in the accommodation end 210.

Specifically, the center portion of the cover 200 is formed with a cylindrical receiving end 210 protruding upwards, and the head portion 310 of the piezoelectric sensor 300 is formed on the upper end of the receiving end 210. Placed and supported. That is, the head jaw 312 of the head 310 is hanged on the upper end of the receiving end (210).

In addition, a plurality of coupling hooks 220 are formed at the inner side of the upper end of the cover 200 to protrude inward. The coupling hook 220 serves to support the lower end of the case 100 so as not to be detached from the cover 200.

The interior of the receiving end 210 is formed stepped. That is, as shown, the receiving end 210 is formed in the receiving space of a predetermined size, the inner diameter of the upper side is larger than the outer diameter of the lower side. Accordingly, the support end 212 is formed near the center of the receiving end 210 to support the space 400 and the O-ring 410.

The space 400 is installed to surround the port portion 320 of the piezoelectric sensor 300 and is located inside the receiving end 210. That is, the space 400 is formed in a ring shape having a predetermined height, and surrounds the outside of the upper portion of the step portion 322 of the port 320.

The O-ring 410 is made of a flexible elastic material such as rubber, and is located below the space 400. That is, the O-ring 410 is placed above the support end 212 in the receiving end 210, and surrounds the outer side of the lower portion of the step part 322 of the port part 320.

In the configuration as described above, when the piezoelectric sensor 300 is applied to the lower side while assembling, the space 400 is to press the O-ring 410, the O-ring 410 made of an elastic material is expanded to the side . Therefore, since the O-ring 410 is in close contact with the outer surface of the piezoelectric sensor 300 and the inner surface of the receiving end 210, the gap between the piezoelectric sensor 300 and the cover 200 is further sealed.

The inlet 250 is formed at the lower end of the cover 200. That is, as shown, the lower end of the cover 200 is formed to protrude inclined to the lower right (in Figure 2). In addition, an inflow passage 252 having a predetermined size is formed through the inlet 250.

The inlet 250 is connected to a washing tank (bath) in the washing machine by a hose or the like. Therefore, the air pressure inside the washing tank is transmitted to the piezoelectric sensor 300 through the inlet 250.

Inside the case 100, a PCB substrate 500 connected to one end of the piezoelectric sensor 300 is provided. That is, as shown, the upper side of the piezoelectric sensor 300 is provided with a PCB substrate 500, the PCB substrate 500 is connected to the upper end of the piezoelectric sensor 300 by soldering.

The PCB 500 is connected to a connection terminal 510 having one end exposed to the outside of the case 100. That is, as shown in FIG. 1, three connection terminals 510 are formed at the upper end of the case 100 so as to protrude outward, and the lower end of the connection terminal 510 is soldered with the PCB substrate 500. Is connected by.

Hereinafter will be described the operation of the sensor assembly for a washing machine of the present invention having the configuration as described above.

First, the sensor assembly for a washing machine according to the present invention is installed inside the upper end of the washing machine, and the main board (Main PCB) mainly installed at the upper end of the washing machine is not formed integrally, and is formed of separate parts.

In addition, a hose is connected to the inlet 250, and the air pressure of the water tank inside the washing machine is transferred to the inside of the cover 200 as it is.

Therefore, when water is supplied into the washing machine to increase the water level, air pressure inside the washing machine is transmitted to the piezoelectric sensor 300 through the inflow passage 252.

In this case, pressure is applied to the piezoelectric element (piezoelectric material) inside the piezoelectric sensor 300, and such a change in pressure causes a change in resistance to change the output voltage. Therefore, the water level inside the washing machine is measured by the output voltage provided to the outside through the connection terminal 510, and the water in and out of the washing machine is controlled by the main board (Main PCB).

For example, when the input voltage is DC 5V and the input voltage is zero, the output voltage of the output connection terminal 510 is 0, and when the input pressure is 100 mmH ₂ O, the output connection terminal 510 is disconnected. The output voltage is about 1.05V, and when the input voltage is changed to 0 to 500mmH ₂ O, the output voltage of the output connection terminal 510 is changed to about 1.4 to 4.8V. Thus, since the change in the washing machine water level varies linearly across the whole, the water level is accurately measured across the whole.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention.

100. Case 200. Cover
210. Receiving stage 250. Inlet
300. Piezoelectric Sensor 310. Head
320. Port 400. Space
410. O-ring 420. Seals
500. PCB board

Claims (5)

A case 100 installed spaced apart from the main board of the washing machine and forming an appearance;
A cover 200 fixed to one side of the case 100 to shield an opened one of the case 100;
A piezoelectric sensor 300 provided inside the case 100 and outputting an amount of change in voltage according to a pressure change using a piezoelectric effect;
A space 400 provided inside the cover 200 to support the piezoelectric sensor 300;
An inlet port 250 formed at one end of the cover 200 to guide air into the cover 200 from the outside;
An o-ring (410) provided at one side of the space (400) and shielding a gap between the cover (200) and the piezoelectric sensor (300);
And a sealing member (420) provided between the case (100) and the cover (200) to block inflow of foreign matter through a gap between the case (100) and the cover (200). Sensor assembly. The method of claim 1, wherein the inside of the case 100,
A PCB substrate 500 connected to one end of the piezoelectric sensor 300 is provided;
The PCB substrate 500,
Sensor assembly for a washing machine, characterized in that the connection terminal 510 is exposed to the outside. According to claim 1 or 2, The piezoelectric sensor 300,
A head portion 310 provided with a piezoelectric element therein;
The washing machine, which is integrally formed at one side of the head portion 310 and has a configuration including a port portion 320 for guiding air introduced through the inlet 250 to the head portion 310. Sensor assembly. The method of claim 3, wherein the central portion of the cover 200,
An accommodation end 210 for supporting the head portion 310 of the piezoelectric sensor 300 is formed;
Inside the receiving end 210,
Sensor assembly for a washing machine, characterized in that the space surrounding the port portion 320 of the piezoelectric sensor 300 and the O-ring 410 is installed up and down. The method of claim 4, wherein the O-ring 410 and the sealing member 420,
Sensor assembly for a washing machine, characterized in that made of an elastic material.

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