KR19990081174A - Multifunctional detection device of automatic washing machine - Google Patents

Abstract

The present invention relates to a fully automatic washing machine. In particular, the magnetic bobbin is coupled to the upper pivot of the upper corner formed on the outer part of the washing machine, and at the same time, the movable cap is coupled to the end of the snubber bar, and an elastic member is provided between the movable cap and the upper pivot. By combining the load applied to the snubber bar with the detection coil built into the moving cap, it is possible to detect the amount of washing before washing, the outflow during feeding and draining, the amount of washing water entering, and the occurrence of excessive vibration due to unbalance during dehydration. Was created so that

It is coupled to the snubber bar to detect the load applied to the snubber bar of the automatic washing machine and to detect the amount of washing water before washing, drainage during feeding and draining, the amount of washing water entering, and the occurrence of excessive vibration due to unbalance during dehydration. A moving cap with a built-in detection coil,

Magnetic bobbin coupled to the upper pivot of the upper corner to change the resistance value of the sensing coil embedded in the moving cap when the moving cap moves with the snubber bar,

Multifunctional sensing device of the automatic washing machine, characterized in that the movable cap is provided with an elastic member coupled to the upper cap and the upper pivot so as to generate a displacement proportional to the displacement of the movable cap generated while moving up and down with the snubber bar. To provide.

Description

Multifunctional detection device of the fully automatic washing machine

The present invention relates to a fully automatic washing machine. In particular, the magnetic bobbin is coupled to the upper pivot of the upper corner formed on the outer part of the washing machine, and at the same time, the movable cap is coupled to the end of the snubber bar, and an elastic member is provided between the movable cap and the upper pivot. By combining the load applied to the snubber bar with the detection coil built into the moving cap, it is possible to detect the amount of washing before washing, the outflow during feeding and draining, the amount of washing water entering, and the occurrence of excessive vibration due to unbalance during dehydration. It relates to a multifunctional detection device of a fully automatic washing machine.

The water level detecting device of the conventional washing machine 1 is shown in FIG.

That is, the configuration of the drive shaft 5 is rotated by receiving the rotational force of the motor (7) to the pulley (6),

A washing wing (4) coupled to the drive shaft (5) to stir laundry and wash water of the washing tub (3);

A guide hole 9 formed in the support plate 8 coupled to the bottom surface of the washing tub 3 in order to sense the level of the washing tub 3;

A chamber 11 formed on the bottom surface of the laundry outer tub 2 to collect the washing water flowing into the guide hole 9 and detect the water pressure;

A cover 14 coupled to the upper side of the chamber 11 to prevent the wash water guided to the chamber 11 from leaking to the bottom surface of the laundry outer tub 2;

A water level sensor 17 connected to the chamber 11 and the connection hose 16 to detect the water pressure generated in the chamber 11;

A first sealing ring 10 coupled to the coupling portion of the support plate 8 and the washing tub 3 to seal the coupling portion of the support plate 8 and the washing tub 3;

A second sealing ring 12 coupled to the coupling portion of the support plate 8 and the cover 14 to seal the coupling portion of the support plate 8 and the cover 14,

A third sealing ring 13 coupled between the washing tub 2 and the drive shaft 5 to seal the coupling portion of the washing tub 2 and the drive shaft 5;

In order to seal the engagement portion of the laundry outer tub 2 and the cover 14, the fourth seal ring 15 is coupled to the engagement portion of the laundry outer tub 2 and the cover 14.

Referring to the effects of the conventional configuration as described above are as follows.

First, when the laundry is put into the washing tub 3, water is supplied, and when the water is completed, the motor 7 is rotated.

Then, as the drive shaft 5 is rotated by receiving the rotational force of the motor 7 by the belt, the washing blade 4 is rotated.

In addition, the washing blade (4) is to perform the washing by stirring the laundry and the wash water of the washing tank (3) while the reverse movement.

On the other hand, in the conventional washing machine 1, since the washing inner tank 3 is formed as a non-porous wall, the washing water is not supplied to the washing outer tank 2 and only the washing water is supplied to the washing inner tank 3 to wash.

Therefore, the amount of wash water supplied to the washing tub 3 or the amount of wash water drained to the outside should be accurately sensed.

That is, the washing water in the washing inner tank 3 is supplied to the chamber 11 formed in the washing outer tank 2 through the guide hole 9 formed in the support plate 8.

In addition, since the cover 14 is coupled to the upper portion of the chamber 11, the washing water of the chamber 11 is not leaked by the washing outer tub 2.

In addition, water pressure is generated in the chamber 11 by washing water.

Then, the water pressure is transmitted to the water level sensor 17 through the connection hose 16 to detect the water level.

However, the above-mentioned prior art makes the chamber 11 to detect the minute pressure in the chamber 11 as the level rises, so that the level of water level detection is reduced.

And, in order to detect the water level in the washing machine 1, a large amount of washing water is used.

That is, since the wash water of the washing inner tub 3 is diverted to the chamber 11 through the guide hole 9 formed in the support plate 8, it takes up a large area.

Therefore, the washing water for detecting the water level and the washing water for washing are required, so that washing is supplied by supplying a large amount of washing water.

Therefore, the waste of water is severely used by using the wash water more than the said need.

In addition, the first sealing ring 10, the support plate 8, and the cover coupled to the coupling portion of the support plate 8 and the washing inner tub 3 to prevent leakage of the wash water supplied to the air chamber 11. Combination of the second sealing ring (12) and the washing seal (2) and the washing outer tub (2) and the cover (14) coupled between the washing outer tub (2) and the drive shaft (5) coupled to the coupling portion of 14) Since many cyrings, such as the fourth seal ring 15 coupled to the part, are required, it is difficult to provide a perfect seal and may also increase the material cost.

On the other hand, prior to washing the washing capacity detection of the washing machine uses an indirect method of detecting the amount of rotation of the rotation of the motor (7) after stopping the rotation.

However, the above-described amount of capacity detection requires a separate device for detecting the amount of capacity, the detection device may vary the amount of detection depending on the type of laundry or the location of the laundry, and the washing blade (4) in the motor (7) It is difficult to accurately detect because the difference is displayed according to the power transmission state up to), that is, the tension of the belt or the like.

In addition, in the state in which the laundry is eccentric, unbalance occurs when dehydration. In the related art, there was a separate detection sensor to detect the unbalance.

The purpose of the present invention for solving and complementing such a conventional problem,

It is possible to increase the level of water level detection at the same time to make accurate quantity detection of the automatic washing machine, and with simpler configuration, it detects the level of water and the amount of wash water flowing in and out of water supply and drainage and the detection of excessive vibration caused by unbalance during dehydration. It provides a purpose to improve the washing performance and to reduce the productivity and production cost by enabling.

In order to achieve the above object, the present invention,

The magnetic bobbin is coupled to the upper pivot of the upper corner to which the snubber bar of the washing machine is coupled, and the moving cap and the upper are displaced so that the moving cap is displaced in the same manner as the displacement of the snubber bar after combining the moving cap having a sensing coil built into the snubber bar. By coupling the elastic member between the pivots, the sensing coil of the moving cap, which is displaced in the same way as the snubber bar, changes the resistance value by the amount of overlap with the magnetic body bobbin. When the three functions of can be performed by one device, it is possible to achieve the object of the present invention.

1 is a cross-sectional view showing a detection device of a conventional washing machine

Figure 2 is a perspective view showing a multifunctional sensing device of the present invention washing machine

Figure 3 is an enlarged cross-sectional view showing a multifunctional sensing device of the present invention washing machine

Figure 4 is an enlarged cross-sectional view showing a coupling state of the snubber bar of the present invention washing machine

Figure 5 is a cross-sectional view of the elastic member showing an embodiment of the present invention

Figure 6 is a cross-sectional view of the elastic member showing another embodiment of the present invention

Figure 7 is a diagram showing the characteristics of the elastic member according to the present invention

<Code Description of Main Parts of Drawing>

101-Washing Machine 102-Upper Corner

103-Up Pivot 104-Guide

105-magnetic bobbin 106-insert

107-Snubbar 111-Moving Cap

112-elevation hole 113-engagement hole

114-Flange 115-Detection Coil

121-elastic member 122,123-first, second buffer part

The configuration of the present invention will be described in detail with reference to Figs.

Detecting the load acting on the snubber bar 107 of the fully automatic washing machine 101 to detect the amount of washing before washing, the outflow during feeding and draining, the amount of washing water entering, and the occurrence of excessive vibration due to unbalance during dewatering Moving cap 111 with a detection coil 115 is coupled to the snubber bar 107,

The moving cap 111 is coupled to the upper pivot 103 of the upper corner 102 to change the resistance value of the sensing coil 115 embedded in the moving cap 111 when moving with the snubber bar 107. Magnetic bobbin 105,

The moving cap 111 is coupled to the moving cap 111 and the upper pivot 103 so that a displacement proportional to the displacement of the moving cap 111 generated while moving up and down with the snubber bar 107. It is a structure provided with the elastic member 121.

In addition, the movable cap 111 is a lifting hole 112 formed in the movable cap 111 so that the magnetic bobbin 105 can rise and fall smoothly,

A coupling hole 113 formed in the moving cap 111 so that a snubber bar 107 may be coupled to the moving cap 111,

The movable cap 111 was provided with a flange 114 formed on the movable cap 111 so that the movable cap 111 can be supported by the elastic member 121.

In addition, the guide tube 104 formed on the upper pivot 103 to firmly couple the magnetic bobbin 105 to the upper pivot 103,

The guide tube 104 was provided as an insertion hole 106 formed in the magnetic bobbin 105 to be pressed out to the outside.

In addition, the elastic member 121 is a first shock absorbing portion 122 formed on the elastic member 121 so as to be sensitively displaced when the weak load is applied to the moving cap 111 to detect the amount of the main body,

When a strong load is applied to the movable cap 111, it exhibits strong elasticity so that an elastic member may be mainly used to detect the amount of wash water that flows in and out of the water supply and drainage, and the occurrence of excessive vibration due to unbalance during dehydration. It was provided as a second buffer 123 formed in 121).

In addition, the pitch P2 of the second shock absorbing portion 123 is wider than the pitch P1 of the first shock absorbing portion 122.

Then, the spring constant of the second buffer 123 is higher than the spring constant of the first buffer 122.

In addition, the coil diameter d2 of the second buffer part 123 is larger than the coil diameter d1 of the first buffer part 122.

In addition, the average diameter D2 of the second shock absorber 123 is larger than the average diameter D1 of the first shock absorber 122.

Referring to the operation of the present invention as described above is as follows.

First, when the laundry is put into the washing tank 110 of the washing machine 101, the quantity detection is made.

That is, the laundry outer tub 109 is lowered by the weight of the laundry put into the washing tub 110, and the laundry outer tub 109 and the upper corner 102 of the outer tub 108 are connected to each other. The snubber bar 107 also moves to the lower side.

In addition, the movement of the snubber bar 107 causes a result of moving the moving cap 111 coupled to the upper snubber bar 107, so that the moving cap 111 compresses the elastic member 121 to the lower side. Will move.

When the moving cap 111 is moved downward, the lifting hole 112 is also moved downward to be coupled to the outer side of the magnetic bobbin 105 coupled to the upper pivot 103.

At this time, the magnetic force generated in the magnetic bobbin 105 changes the resistance value of the sensing coil 115 embedded in the moving cap 111.

Therefore, since the resistance value of the sensing coil 115 changed by the magnetic bobbin 105 is connected to an external resistance, inductance and capacitance R L C resonant circuit, it is represented by a change in resonance frequency.

In addition, since the load calculation is performed in the microcomputer using the resonance frequency value, it is possible to detect the correct amount of the dose.

In addition, the above-described amount of capacity detection because the relatively small load is applied to the moving cap 111 should be moved sensitively.

That is, the elastic member 121 according to the present invention was formed by dividing the first shock absorber 122 and the second shock absorber 123 in order to allow the sensitive movement of the movable cap 111.

In other words, since the first buffer part 122 of the elastic member 121 is formed to have a pitch P1 at a narrow interval as shown in FIG. 3, the snubber bar 107 and the moving cap 111 are sensitively compressed. And relaxation.

Accordingly, the quantity detection is mainly performed by the first buffer part 122 of the elastic member 121.

In addition, the coil diameter d1 constituting the first shock absorbing portion 122 of the elastic member 121 is smaller than the coil diameter d2 of the second shock absorbing portion 123 as shown in FIG. 5 or the first shock absorbing portion ( Even if the spring constant of 122) is smaller than the spring constant of the second shock absorbing part 123, the spring constant of the second shock absorber 123 is satisfied.

In addition, even if the average diameter (D1) of the first buffer portion 122 is smaller than the average diameter (D2) of the second buffer portion 123 as shown in Figure 6 it can achieve the object of the present invention.

Therefore, it is possible to detect a high amount of dose due to the sensitive displacement of the first shock absorbing portion 122 formed on the elastic member 121 as described above, and obtain a diagram as shown in FIG. 7.

On the other hand, when the laundry is added to the washing tub 110 of the washing machine 101, the water supply is made, and when the washing is completed, the wash water of the washing tub 110 must be drained.

As described above, when the water supply and drainage, a substantial load acts on the washing inner tub 110, the outer tub 109 and the snubber bar 107.

That is, the laundry outer tub 109 is lowered by the weight of the laundry put into the washing tub 110, and the laundry outer tub 109 and the upper corner 102 of the outer tub 108 are connected to each other. The snubber bar 107 is also in a state of moving much downward.

In addition, the movement of the snubber bar 107 causes a result of moving the moving cap 111 coupled to the upper snubber bar 107, so that the moving cap 111 compresses the elastic member 121 a lot and is lower. Will be moved to.

When the moving cap 111 is moved downward, the lifting hole 112 is also moved to the lower side and is coupled to the outer side of the magnetic bobbin 105 coupled to the upper pivot 103.

At this time, the magnetic force generated in the magnetic bobbin 105 will greatly change the resistance value of the sensing coil 115 embedded in the moving cap 111.

Therefore, since the resistance value of the sensing coil 115 changed by the magnetic bobbin 105 is connected to an external resistance, inductance and capacitance R L C resonant circuit, it is represented by a change in resonance frequency.

In addition, since the load calculation is performed in the microcomputer using the resonance frequency value, the amount of washing water supplied and drained can be detected.

In addition, since the relatively large load is applied during the supply and drainage, the moving cap 111 should be supported by a strong elasticity.

That is, the elastic member 121 in the present invention was formed by dividing the first shock absorbing portion 122 and the second shock absorbing portion 123 in order to exert a strong elasticity of the movable cap 111.

In other words, since the second cushioning portion 123 of the elastic member 121 has a pitch P2 formed at a wide interval as shown in FIG. 3, it is strong to cope with the movement of the snubber bar 107 and the moving cap 111. It is possible to exert elasticity.

Therefore, the amount of wash water that is mainly supplied and drained by the second buffer unit 123 of the elastic member 121 is sensed.

In addition, the coil diameter d2 constituting the second shock absorbing portion 123 of the elastic member 121 is larger than the coil diameter d1 of the first shock absorbing portion 122 as shown in FIG. 5 or the second shock absorbing portion ( Even if the spring constant of 123 is greater than the spring constant of the first buffer part 122, it is suitable for the purpose of the present invention.

In addition, even if the average diameter (D2) of the second buffer portion 123 is smaller than the average diameter (D1) of the first buffer portion 122 as shown in Figure 6 it can achieve the object of the present invention.

Therefore, the strong level of the second shock absorbing portion 123 formed in the elastic member 121 as described above can accurately detect the water level and obtain a diagram as shown in FIG. 7.

In addition, by the lifting hole 112 formed in the movable cap 111, the movable body 111 can be easily lifted to the outside of the magnetic body bobbin 105.

In addition, when excessive vibration occurs when the washing machine 101 is dewatered, vibration is generated by the interaction between the elastic member 121 and the sensing coil 115 and the magnetic bobbin 105 of the moving cap 111 as described above. When the amount of vibration detected is greater than or equal to the allowable value, the washing machine 101 is charged.

In addition, since the flange 114 receives elasticity of the elastic member 121 while the coupling hole 113 of the movable cap 111 is coupled to the snubber bar 107, the movable cap 111 is a snubber bar. Close to the 107 can be moved with the snubber bar 107, so that accurate displacement measurement is possible.

In addition, since the insertion hole 106 formed in the magnetic bobbin 105 is pressed into the outer side of the guide tube 104 formed in the upper pivot 103, the magnetic bobbin 105 is formed by the upper pivot 103 by a rigid coupling structure. It will not be removed from.

Meanwhile, the sensing device of the present invention is formed in one snubber bar 107 as shown in FIG. 2, and the upper pivot 103 is coupled to the upper corner 102 as shown in FIG. 4 in the three snubber bars 107. Since the conventional configuration is adopted, more accurate detection can be achieved.

Thus, the present invention, a magnetic bobbin is coupled to the upper pivot of the upper corner to which the snubber bar of the washing machine is coupled, and the movable cap is coupled with the displacement of the snubber bar after the snubber bar is coupled to a moving cap having a sensing coil. By coupling the elastic member between the moving cap and the upper pivot so that the displacement of the detection cap of the moving cap, which is displaced in the same way as the snubber bar, the resistance value varies depending on the amount of overlapping with the magnetic body bobbin. Three functions such as detection and vibration detection can be performed by one device, enabling accurate quantity detection and increasing the level of water level detection. To detect the amount of water and to detect excessive vibration caused by unbalance during dehydration Have a beneficial effect in sikilsu down to improve the performance and uninterrupted productivity and production costs, etc.

Claims (8)

It is coupled to the snubber bar to detect the load applied to the snubber bar of the automatic washing machine and to detect the amount of washing water before washing, drainage during feeding and draining, the amount of washing water entering, and the occurrence of excessive vibration due to unbalance during dehydration. A moving cap with a built-in detection coil, Magnetic bobbin coupled to the upper pivot of the upper corner to change the resistance value of the sensing coil embedded in the moving cap when the moving cap moves with the snubber bar, Multifunctional sensing device of the automatic washing machine, characterized in that the movable cap is provided with an elastic member coupled to the upper cap and the upper pivot so as to generate a displacement proportional to the displacement of the movable cap generated while moving up and down with the snubber bar. . The method of claim 1, The moving cap is a lifting hole formed in the moving cap to be able to easily lift and move to the outside of the magnetic bobbin, A coupling hole formed in the moving cap to allow a snubber bar to be coupled to the moving cap; Multifunctional sensing device of a fully automatic washing machine, characterized in that the movable cap is provided with a flange formed on the movable cap so as to be carried by the elastic member. The method of claim 1, A guide tube formed on the upper pivot so as to firmly couple the magnetic bobbin to the upper pivot; Multifunctional sensing device of a full-automatic washing machine, characterized in that provided with an insertion hole formed in the magnetic body bobbin to be press-fitted to the outside of the guide tube. The method of claim 1, The elastic member is a first shock absorbing portion formed in the elastic member so as to be sensitively displaced when the weak load is applied to the moving cap to mainly detect the amount of capacity; When a strong load is applied to the movable cap, the elastic member is formed on the elastic member so as to detect the occurrence of excessive vibration due to the outflow and drainage during the supply and drainage, and the amount of wash water entering and the unbalance during dehydration. Multifunctional sensing device of a fully automatic washing machine, characterized in that provided with two buffers. The method of claim 4, wherein Multifunction sensing device of a full-automatic washing machine, characterized in that the pitch (P2) of the second buffer unit is wider than the pitch (P1) of the first buffer unit. The method of claim 4, wherein Multifunctional sensing device of a fully automatic washing machine, characterized in that the spring constant of the second buffer portion higher than the spring constant of the first buffer portion. The method of claim 4, wherein Multifunction sensing device of the fully automatic washing machine, characterized in that the larger than the coil diameter (d1) of the first buffer portion of the second buffer portion (d2). The method of claim 4, wherein Multifunctional sensing device of a full-automatic washing machine, characterized in that the average diameter (D2) of the second buffer unit is larger than the average diameter (D1) of the first buffer unit.