KR19990039638U - Suspension of washing machine - Google Patents

Abstract

The present invention improves the suspension structure of the washing machine so that the sliding frictional force acts in the transient state before the resonance point, while the sliding frictional force does not act in the normal state after the resonance point so that the suspension damping action is different depending on the vibration characteristics. It is to maximize the vibration damping performance.

To this end, according to the present invention, as the suspension cap 9 supported on the outer tub 3 is elevated together with the outer tub, the snubber base 11 located inside the suspension cap slides frictionally with the inner circumferential surface of the suspension cap while the suspension cap 9 is in the suspension cap. In the suspension device of the washing machine to prevent the phenomenon that the vibration of the outer tank is transmitted to the outer case (1) of the outer side by the buffering action of the installed compression spring (10); An expansion tube 900 having a diameter larger than the diameter of the snubber base 11 is formed in the lower portion of the suspension cap 9 so that the suspension cap (in the transient state before the amplitude of the system at the time of dehydration maintains a constant size) As a result of the lifting and lowering of 9), the snubber base 11 is subjected to the sliding friction against the inner circumferential surface of the suspension cap so that the vibration attenuation effect on the system is achieved, and in the steady state in which the amplitude of the system maintains a constant magnitude, When the snubber base 11 is positioned in the expansion pipe 900 and is spaced apart from the inner circumferential surface of the suspension cap 9, the vibration damping action of the system is achieved only by the buffering action of the compression spring 10 without sliding friction. It is a suspension device.

Description

Suspension of washing machine

The present invention relates to a suspension device of a fully automatic washing machine, and more particularly, to improve the structure of the suspension device to suppress the vibration generated in the washing machine during washing and dehydration, the damping action of the suspension device is different depending on the vibration characteristics This is to achieve a significant improvement in dustproof performance.

In general, a washing machine is a device that removes various contaminants attached to clothes and bedding by using the action of emulsifying the detergent and the friction action of the water flow due to the rotation of the washing blade, and the impact action of the washing wing on the laundry. As the amount and type of the laundry is sensed by the sensor, the washing method is automatically set, while the washing water is supplied to an appropriate level according to the amount and type of the laundry, and the washing is performed under the control of the microcomputer.

1A and 1B, the conventional washing machine includes an outer tub 3 supported by a suspension device inside the outer case 1, and a washing tank for a dehydration tank is also used in the outer tub 3. 4) is rotatably installed.

In addition, a lower portion of the outer tub 3 is equipped with a motor 5 for generating a driving force, and in the center receives the driving force of the motor 5 through the V-belt and the inside of the outer tub 3 and the washing tub 4. The clutch 7 which selectively rotates the pulsator 6 installed in the bottom center is attached.

In the conventional washing machine configured as described above, when laundry and detergent are put into the washing tank 4 and the washing start button is selected, washing and rinsing are performed over a predetermined time according to a control signal of a controller (not shown). Dehydration is performed automatically.

On the other hand, the vibration is generated in the washing tank 4 due to the impact action of the water flow due to the inversion of the pulsator 6 and the washing of the laundry during the washing process, and the vibration is transmitted to the outer tank 3 to the outer tank ( 3) to flow in the vertical and horizontal directions.

In particular, when the dehydration tank (4), which is a combined use of the washing tank, rotates at a high speed during dehydration, the vibration force transmitted to the outer tub (3) and the out case (1) when washing due to bias of laundry is acted upon. It becomes larger than that.

In addition, the vibration and noise generated in the drive unit such as the motor (5) is transmitted to the outer tub (3) through the tub base for fixing the drive unit, and again to the dehydration tank and suspension assembly (2a).

At this time, the vibration transmitted to the dehydration tank (4) is transmitted to the auto balancer (8), the vibration and noise transmitted to the suspension assembly (2a) by the snubber bar 12 in the suspension cap (9a) as a medium Delivered to the outer tub (3).

When vibration occurs in the washing machine as described above, the vibration of the washing system is attenuated by the suspension device as follows.

The conventional suspension assembly 2a constituting the suspension provided in the washing machine is, as shown in Figures 2a and 2b, a suspension cap 9a (suspension) inserted and supported at the lower edge of the outer tub 3 cap, a snubber base 11 fitted under the suspension cap 9a and hermetically connected to the inner circumferential surface of the suspension cap 9a by the compression spring 10, and the suspension cap 9a. The snubber bar 12 (snubber bar) which is connected to the snubber base 11 through the lower end and the upper end is supported by the outer case 1 to support the outer tub 3 from the outer case 1, Compression spring that is provided in the suspension cap (9a) to give elasticity to the snubber base (11) when the suspension cap (9a) is lowered along the snubber bar (12) by a load acting on the outer tub (3) 10).

In addition, the suspension assembly 2a of the above-described configuration is fixed to the outer circumferential surface of the outer tub 3 at an angle of 90 ° along the circumferential direction, respectively.

Therefore, in the related art, when vibration occurs in the washing machine during dehydration, as the suspension cap 9a fixed to the outer tub 3 moves up and down against the snubber bar 12, the snubber base 11 and the suspension cap ( The sliding friction force acting between 9a) acts as a damping force against vibration, and the compression spring 10 installed inside the suspension cap 9a is combined with the compressed air existing inside the suspension cap 9a. The buffer function to maintain the balance of the outer tank (3).

That is, the vibration is reduced by the compression of the air present in the suspension cap 9a constituting the suspension device, the sliding friction force, and the buffering action of the compression spring 10, so that the washing machine is in a stable state and the dehydration can proceed smoothly. .

Then, when dehydration is completed, as shown in FIG. 2B, the load applied to the compression spring 10 constituting the suspension assembly 2a is almost released.

As described above, vibration of the outer tub 3 of the washing machine generated during dehydration may generally increase damping force by increasing sliding friction or increasing air damping force.

On the other hand, when damping the vibration generated when the dehydration of the laundry system by using friction damping, the vibration of the system is not attenuated depending on the state of the system, but rather a problem that increases.

That is, when friction damping is performed, the relationship between the magnitude of the frictional force during the suspension action and the excitation force transmitted to the system, that is, the relationship between the magnitude of the frictional force and the excitation force transmitted to the outer case 1 is shown in FIG. 5. Depending on the state of transition and the state of steady state, there are different aspects.

In other words, when the system is in a transient state, there is an effect of suppressing the vibration of the system. However, after the transient state, the transmission force hardly decreases, so that the frictional force rather increases the vibration of the system.

Here, the transient state refers to a system vibration state in the primary resonance region and the secondary resonance region, and is a state before the amplitude has a constant value.

4 and 5 are graphs showing the vibration characteristics in a no-load state of a washing machine having a capacity of 10 kg, wherein the primary resonance region under the above conditions is a region in which the rotation speed of the washing tub 4 is about 60 rpm or less as shown in FIG. 4. The secondary resonance region refers to a region in which the rotation speed of the washing tank 4 is 60 to 240 rpm, and the system vibration patterns in the primary resonance region and the secondary resonance region are different from each other as shown in FIGS. 3A and 3B.

That is, in the primary resonance region, the system vibrates up and down as shown in FIG. 3A, and in the secondary resonance region, the system vibrates in a conical shape as shown in FIG. 3B.

In addition, in the transient state including both the primary resonance region and the secondary resonance region, the magnitude of the transmission force transmitted to the out case 1 is increased.

On the other hand, the system state after the transient state is called a steady state, and the steady state is a state in which the amplitude of the system is constant and after the threshold point (secondary resonance point) at which the magnitude of the transmission force transmitted to the out case 1 begins to decrease. Say the status.

In other words, in the transient state, the greater the frictional force, the greater the effect of reducing the vibration of the system. However, in the normal state, the smaller the frictional force, the smaller the transmission force transmitted to the system, the less effective the vibration of the system. Can be.

That is, Fig. 5 is a graph showing the relationship between the vibration ratio and the transmission force, and the transmission force in the transient state according to the friction force magnitude (F _I > F _II > F _III = 0) by comparing the I, II and III lines. The magnitude of is inversely proportional to the frictional force, whereas the magnitude of the transmission force at steady state is proportional to the frictional force.

Accordingly, there is a need for a suspension device having characteristics in which a large frictional force acts in the transient state and a frictional force does not act when the transient state is exceeded.

However, as can be seen from FIG. 2A and FIG. 2B, the conventional suspension device can damp the vibration using the sliding friction force in the transient state due to its structural characteristics, while the steady state is advantageous in damping the vibration when the sliding friction force is not applied. In addition, the sliding frictional force acts at, which had the disadvantage of adversely affecting vibration damping.

That is, since the transmission force transmitted to the outer case 1 by the sliding frictional force becomes large, the vibration of the system rather increases in the steady state.

In other words, even if the conventional suspension system effectively attenuates the system vibration in the transient state, the vibration of the system in the steady state is rather increased, and in the transient state in the case of damping the vibration of the system in the steady state. There are structural limitations such as the inability to dampen system vibrations.

The present invention is to solve the above-mentioned problems, while the sliding frictional force acts in the transient state, while the sliding frictional force does not act in the steady state to reduce the vibration of the system irrespective of the vibration characteristics of the transient state and the steady state. It is an object of the present invention to provide a suspension device for a washing machine to maximize vibration damping performance.

Figure 1a is a front sectional view showing the main part of the conventional washing machine

FIG. 1B is a top view of FIG. 1A

2A and 2B are enlarged longitudinal sectional views of portion A of FIG. 1A;

Figure 2a is a state diagram when the suspension cap is lowered by the load applied to the suspension cap and the compression spring is applied to the compression spring

Figure 2b is a state diagram when the load applied to the suspension cap is removed to release the compression force applied to the compression spring

Figure 3a and Figure 3b is a schematic diagram showing the vibration form in the transient state caused by the unloading of the laundry during dehydration in the conventional washing machine,

3A is a state diagram in the primary resonance region

3B is a state diagram in the secondary resonance region

4 is a graph showing a frequency change with respect to a time change in friction damping during dehydration

Figure 5 is a graph showing the change in the transmission force to the ratio of the frequency according to the amount of friction in friction damping during dehydration

Figure 6 is a longitudinal cross-sectional view showing a suspension assembly according to the present invention

7 is a front view illustrating a process of assembling the suspension assembly of FIG. 6.

8 is a perspective view showing the suspension cap of FIG.

9 is a perspective view illustrating the snubber base of FIG. 7;

10a and 10b is a longitudinal cross-sectional view for explaining the operation of the suspension assembly according to the present invention,

10A is a suspension state diagram in a transient state

10b is a suspension state diagram in a steady state

Explanation of symbols for main parts of the drawings

1: Out case 2: Suspension assembly

3: outer tank 9: suspension cap

10: Compression spring 11: Snubber base

110: slit groove 12: snubber bar

900: expansion unit

In order to achieve the above object, the present invention is a compression cap installed in the suspension cap while the snubber base located inside the suspension cap is sliding friction with the inner circumferential surface of the suspension cap as the suspension cap supported on the outer tank is elevated together with the outer tank In the suspension device of the washing machine to prevent the phenomenon that the vibration of the outer tank is transmitted to the outer case of the outside by the buffering action of the spring; The expansion part having a diameter larger than the diameter of the snubber base is formed in the lower part of the suspension cap, so that the snubber base is suspended according to the lifting and lowering of the suspension cap in a transient state before the amplitude of the system during dehydration maintains a constant size. The vibration attenuation of the system is achieved by sliding friction against the inner circumferential surface, and in the steady state in which the amplitude of the system is kept constant, the sliding friction is caused by the snubber base being positioned in the expansion part and spaced apart from the inner circumferential surface of the suspension cap when the suspension cap is elevated. It is a suspension device of a washing machine in which the vibration damping of the system is achieved only by the buffering action of the compression spring.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

6 is a longitudinal sectional view showing a suspension according to the present invention, Figure 7 is a front view showing the assembly process of FIG.

8 is a perspective view illustrating the suspension cap of FIG. 7, FIG. 9 is a perspective view illustrating the snubber base of FIG. 7, and FIGS. 10A and 10B are longitudinal cross-sectional views for explaining the operation of the suspension according to the present invention.

The suspension assembly 2 of the present invention includes a vertical suspension cap 9 and a suspension cap 9 which are inserted into and fixed to the lower edge of the outer tub 3 installed inside the washing machine out case 1. And a lower end connected to the snubber base 11 through the suspension base 9 and a snubber base 11 which is fitted in the airtight connection with the inner circumferential surface of the suspension cap 9. 1) a snubber bar 12 for fixing the upper end 3 to support the outer tub 3 from the outer case 1, and a cap installed by the load on the suspension cap 9 and acting on the cap. Compression spring 10 for imparting elasticity to the suspension cap 9 when descending along the snubber bar 12.

At this time, the expansion portion 900 having a diameter larger than the diameter of the snubber base 11 is formed in the lower portion of the suspension cap 9, the transient state before the amplitude of the system to maintain a constant size when dewatering In the steady state in which the snubber base 11 slides against the inner circumferential surface of the suspension cap 9 by the lifting and lowering of the suspension cap 9, the vibration attenuation effect on the system is achieved and the amplitude of the system maintains a constant magnitude. When the suspension cap 9 is raised and lowered, the snubber base 11 is located in the expansion part 900 and is spaced apart from the inner circumferential surface of the suspension cap 9 so that the vibration damping of the system is caused only by the buffering action of the compression spring 10 without sliding friction. Action is achieved.

At this time, a plurality of slit grooves 110 are formed on the outer circumferential surface of the snubber base 11 at equal intervals along the circumferential direction, so that the system vibrates during washing and the system vibrates in a transient state during dehydration. When the snubber base 11 slides and slides along the inner circumferential surface of the suspension cap 9, the compressed air inside the suspension cap 9 escapes through the slit groove 110, and the snubber base 11 is When sliding and sliding down, the air outside the suspension cap 9 is configured to flow through the slit groove 110.

In addition, the suspension assembly 2 of the above-mentioned structure is provided in the outer peripheral surface of the outer tub 3, respectively, making an angle of 90 degrees along the circumferential direction.

The action of the suspension of the present invention configured as described above is as follows.

First, when the outer tub 3 vibrates during washing, the vibration is transmitted to the suspension cap 9, and the suspension cap 9 moves up and down along the snubber bar 12 according to the degree of vibration. Ascend to.

At this time, the elastic member installed in the suspension cap 9 acts as a cushioning action with the compressed air formed inside the cap, and also the frictional force between the cap and the snubber base 11 also acts as a damping force against vibration. Vibration of the outer tub 3 is prevented from being transmitted to the outer case 1.

That is, the vibration of the system is reduced by the compressed air in the suspension cap 9 constituting the suspension device, the buffering action of the compression spring 10, and the sliding friction between the suspension cap 9 and the snubber base 11, and the like. By this stabilization, washing can proceed smoothly.

On the other hand, when dewatering, as described in the description of the prior art, the vibration of the washing machine shows a different form depending on the transient state and the normal state, and the vibration damping action of the suspension is also a state of transition and a state of As shown below, other aspects will be shown.

First, FIG. 10A is a diagram of a suspension state in a transient state, in which the snubber base 11 is moved with respect to the inner circumferential surface of the suspension cap 9 in accordance with the elevation of the suspension cap 9 in the transient state before the amplitude of the system maintains a constant magnitude. Sliding friction results in vibration dampening of the system.

That is, in the transient state, the up and down movement of the snubber base 11 is performed in the upper region of the expansion portion 900 of the suspension cap 9, and the inner circumferential surface of the suspension cap 9 and the snubber base generated at this time are generated. Vibration of the outer tub 3 is reduced by sliding friction with the outer peripheral surface of (11).

At this time, since a plurality of slit grooves 110 are formed on the outer circumferential surface of the snubber base 11 at equal intervals along the circumferential direction, the snubber base 11 slides along the inner circumferential surface of the suspension cap 9. When the friction rises, the air inside the suspension cap 9 compressed by the snubber base 11 escapes to the outside through the slit groove 110.

On the other hand, Figure 10b is a suspension state diagram in a steady state, in the steady state in which the amplitude of the system maintains a constant magnitude, when the suspension cap 9 is lifted, the snubber base 11 is located in the expansion portion 900 By virtue of being spaced apart from the inner circumferential surface of the suspension cap 9, the vibration damping action of the system is achieved only by the elasticity of the compression spring 10 without the sliding friction between the suspension cap 9 and the snubber base 11.

That is, in the steady state, as shown in FIG. 5, the snubber base 11 is elevated only in the expansion 900 area of the suspension cap 9, and thus the sliding between the suspension cap 9 and the snubber base 11 is increased. Since there is no friction, the transmission force transmitted from the outer tub 3 to the outer case 1 is small, which is ideal for vibration damping of the system.

As described above, the suspension assembly 2 according to the embodiment of the present invention, while the sliding friction force acts in the transient state, the sliding friction force does not act in the normal state irrespective of the vibration characteristics of the transient state and the steady state By reducing the vibration of the vibration can be maximized by the vibration damping performance it is possible to improve the reliability of the washing machine.

Furthermore, the present invention increases the overall damping force of the suspension device, thereby providing a structure of the suspension device suitable for a large-capacity washing machine.

Claims (2)

As the suspension cap supported by the outer tub is lifted with the outer tub, the snubber base located inside the suspension cap slides frictionally with the inner circumferential surface of the suspension cap, while the compression spring installed in the suspension cap buffers the vibration of the outer tub. In the suspension of the washing machine to attenuate the vibration to prevent the vibration of the outer tank is transmitted to the outer case of the outer shell; The expansion part having a diameter larger than the diameter of the snubber base is formed in the lower part of the suspension cap, so that the snubber base is suspended according to the lifting and lowering of the suspension cap in a transient state before the amplitude of the system during dehydration maintains a constant size. The vibration attenuation effect on the system is achieved by sliding friction against the inner circumferential surface, and in a steady state in which the amplitude of the system is maintained at a constant magnitude, the snubber base is located in the expansion part when the suspension cap is raised and lowered from the inner circumferential surface of the suspension cap. Suspension device of the washing machine, characterized in that the vibration damping action of the system by the buffering action of the compression spring without friction. The method of claim 1, A plurality of slit grooves are formed on the outer circumferential surface of the snubber base at equal intervals along the circumferential direction. Compressed air inside the suspension cap escapes through the slit groove when sliding and sliding up, and air outside the suspension cap flows through the slit groove when the snubber base is sliding and sliding down. Suspension of the washing machine.