KR101202312B1 - Variable valve type damper system - Google Patents

Abstract

The present invention relates to a variable valve type damper system, in which a piston is reciprocally mounted at one end of a cylinder having a working fluid therein, thereby reducing noise and vibration, wherein the cylinder 200 has a bypass structure ( 210 is formed separately to reduce the noise and vibration by controlling the flow rate of the working fluid flowing in and out of the piston 300, the present invention is vibrating control is sure due to the variable damper force function, at high speed rotation Since the generated vibration noise is removed, it can increase the rotation speed of the drum, which shortens the dehydration time, reduces the overall washing time, and reduces the noise during dehydration.

Description

Variable Valve Type Damper System {VARIABLE VALVE TYPE DAMPER SYSTEM}

The present invention mainly relates to a variable valve damper system mounted to the lower part of the device, and in particular, to improve the structure of the damper connected to the tub to absorb the vibration of the washing machine tub generated during operation of the washing machine, adjusting the damping force according to the situation The present invention relates to a variable valve damper system capable of reducing resonance and noise of a washing machine.

In general, a washing machine is classified into a drum washing machine having a horizontal rotating shaft, a pulsator and a loop washing machine having a vertical rotating shaft. The washing machine disclosed in the prior art of the Patent Publication No. 10-2006-0005581 is a device for washing the laundry by rotating the drum or the inner tank by the driving force of the motor in a state in which detergent, washing water and laundry in the drum or inner tank. FIG. 1 is a structural view of a conventional drum type washing machine, and FIG. 2 is a sectional view showing the damper of FIG.

     Referring to FIG. 1, the conventional drum washing machine of the prior art is provided with a laundry loading port in a cabinet 1 forming an external appearance. The laundry inlet is provided to open and close the door (D). In addition, a tub 2 is installed inside the cabinet to store the wash water, and the tub 3 is provided with a driving device 3 for generating a driving force.

     A drum 4 is rotatably installed inside the tub, and the driving device is connected to the drum by a washing shaft, and the washing shaft is connected to the drum 4. As the driving device, a direct driving method for directly transmitting the driving force generated from the motor to the washing shaft, and an indirect driving method for transmitting the driving force generated from the motor to the washing shaft by power transmission means such as a belt are applied.

     The tub is supported by a damping device, which is composed of a damper 6 and a suspension spring 5. The damper 6 is installed to support the bottom of the tub 2, the suspension spring 5 is installed to support the top of the tub.

     In addition, the suspension spring has a structure in which the upper end is fixed to the cabinet 1, the lower end is fixed to the tub (2). 2, the damper 6 includes a cylinder 7, a piston 8, and a friction member 9. As shown in Fig. The upper end of the cylinder is installed in the tub 2 as shown in Fig. 1, and the piston 8 is inserted into the cylinder.

     At this time, the upper end portion (T) of the cylinder is installed in the tub (2), the lower end portion (B) of the piston is installed in the base forming the lower portion of the cabinet (1). One end of the piston 8 is provided with a friction ring 9 (friction ring). The friction member reduces vibration by friction with the cylinder. The washing machine configured as described above washes the laundry while sequentially or selectively performing washing, rinsing, and dehydration strokes.

     However, in the conventional washing machine damper, the bush installed between the damper tube and the rod is merely installed between the components to support the load of the shaft or seal the oil so that it does not leak. It did not function as a friction damper to reduce the resonance and noise of the washing machine.

Therefore, the present invention has been made to solve the above problems, the vibration control is sure due to the function of the variable damper force, and the vibration noise generated during the high-speed rotation can be eliminated to increase the rotational speed of the drum to shorten the dehydration time It is to provide a variable valve damper system that reduces the overall washing time and reduces noise during dehydration.

The present invention relates to a variable valve type damper system, in which a piston is reciprocally mounted at one end of a cylinder having a working fluid therein, thereby reducing noise and vibration, wherein the cylinder 200 has a bypass structure ( 210 is formed separately to reduce the noise and vibration by controlling the flow rate of the working fluid flowing in and out of the piston (300).

Therefore, the present invention is a vibrating control is sure due to the function of the variable damper force, the vibration noise generated during high-speed rotation is eliminated can increase the rotational speed of the drum to shorten the dehydration time, reduce the overall washing time and reduce the noise during dehydration Note has a significant effect.

1 is a perspective view showing a conventional drum washing machine
Fig. 2 is a cross-sectional view of the damper of Fig. 1
Figure 3 is an assembly view of the variable valve damper system of the present invention
Figure 4 is a detailed view of the bypass structure of the variable valve damper system of the present invention
5 is a view showing a change in the F (N) value of the solenoid valve opening and closing of the variable valve damper system according to the present invention.

The present invention relates to a variable valve type damper system, in which a piston is reciprocally mounted at one end of a cylinder having a working fluid therein, thereby reducing noise and vibration, wherein the cylinder 200 has a bypass structure ( 210 is formed separately to reduce the noise and vibration by controlling the flow rate of the working fluid flowing in and out of the piston (300).

     In addition, a cylinder is coupled to a lower cap bolt installed at a lower portion of the apparatus to which the variable valve damper system is attached, and a piston is reciprocally mounted to the cylinder, and an upper spring is respectively provided at the lower end of the cylinder and the lower end of the piston. A seat and a lower spring seat are installed, and a spring is installed between the upper spring seat and the lower spring seat, and an end bolt is installed at the bottom of the lower spring seat and fixed to the bottom. Also, a radial space between the cylinder and the piston is provided. It is characterized in that the inner guide and the oil seal with a bush is installed.

     And the bypass structure 210 is the fluid flows through the fluid outlet 220 of the cylinder 200, it is returned to the inside of the cylinder 200 through the fluid inlet 230, the intermediate pipe is a fluid opening and closing device The solenoid valve 240 is installed to control the flow rate by adjusting the cross-sectional area of the bypass pipe.

     The present invention will be described in detail with reference to the accompanying drawings. 1 is a perspective view showing a conventional drum washing machine, Figure 2 is a cross-sectional view showing the damper of Figure 1, Figure 3 is an assembly view of the variable valve damper system of the present invention, Figure 4 is a detailed bypass structure of the variable valve damper system of the present invention 5 is a view showing a change in the F (N) value of the solenoid valve opening and closing of the variable valve damper system according to the present invention.

     The variable valve damper system of the present invention has a piston reciprocally mounted at one end of a cylinder containing a working fluid, in particular oil, to reduce noise and vibration generated in the machine. In addition, the bypass structure 210 is separately formed in the cylinder 200 to allow the flow rate control of the working fluid flowing in and out of the piston 300.

     The cylinder is coupled by TIG welding to the end of the lower cap bolt, which is connected to the device to which the variable valve damper system is attached, especially the lower part of the washing machine. A piston is reciprocally mounted to the cylinder, and the upper spring seat and the lower spring seat are installed at the lower end and the lower end of the piston, respectively. A coil spring is installed between the upper spring seat and the lower spring seat, and an end bolt is installed at the lower part of the lower spring seat to fix it to the bottom, thereby reducing shock and vibration generated by the spring together with oil in the cylinder. Assist the function.

     In addition, an inner guide and an oil seal having a bush are installed in the radial space between the cylinder and the piston. Inner cylinders are installed in the cylinder in concentric circles, and bushes are installed in the inner guides. In addition, a plurality of oil seals are installed in the axial direction adjacent to the bush and the inner guide to serve as an airtight function. And a piston is installed in the inner guide and the oil seal in which the bush is built to reciprocate up and down.

     In the bypass structure 210, oil fluid flows out of the cylinder 200 through the fluid outlet 220 of the cylinder 200, and then returns to the inside of the cylinder 200 through the fluid inlet 230. An intermediate solenoid of the bypass structure 210 is provided with an electrically operated solenoid valve 240 that is an oil fluid opening and closing device to adjust the flow rate by adjusting an area through which the fluid in the bypass line passes.

     In addition, when the solenoid valve of the variable valve type damper system of FIG. 5 is opened and closed, the F (N) value changes, and the damping force changes depending on the stroke of the piston, and the solenoid valve is turned on or off. As the damping force is changed. When the solenoid valve is powered on, the solenoid valve is activated, the bypass flow path is opened and the damping force is reduced.When the solenoid valve is powered off, the solenoid valve is not operated, the bypass flow path is closed and the damping force is increased. do.

     Therefore, the present invention is a vibrating control is sure due to the function of the variable damper force, the vibration noise generated during high-speed rotation is eliminated can increase the rotational speed of the drum to shorten the dehydration time, reduce the overall washing time and reduce the noise during dehydration Note has a significant effect.

200; Cylinder 210: Bypass Structure
220: fluid outlet 230: fluid inlet
240: solenoid valve 300: piston
410: lower cap bolt 420: upper spring seat
430: lower spring seat 440: spring
450: End bolt 510: Bush
520: inner guide 530: oil seal

Claims (3)

In a variable valve damper system in which a piston is reciprocally mounted at one end of a cylinder in which a working fluid is embedded to reduce noise and vibration, a bypass structure 210 is separately formed in the cylinder 200 so that the piston ( 300) to reduce the noise and vibration by controlling the flow rate of the working fluid flowing in and out of the inside,
The cylinder 200 is coupled to the lower cap bolt 410 connected to the lower portion of the device to which the variable valve type damper system is attached, and the piston 300 is reciprocally mounted to the cylinder 200. An upper spring seat 420 and a lower spring seat 430 are installed at the lower end and the lower end of the piston 300, respectively, and a spring 440 is disposed between the upper spring seat 420 and the lower spring seat 430. ) Is installed, and the end bolt 450 is installed at the lower portion of the lower spring seat 430 to be fixed to the bottom, and a bush 510 is embedded in the radial space between the cylinder 200 and the piston 300. Inner guide 520 and the oil seal 530 is installed,
The bypass structure 210 fluid flows out of the cylinder 200 through the fluid outlet 220 of the cylinder 200, and is returned to the inside of the cylinder 200 through the fluid inlet 230, and the intermediate pipe line. The solenoid valve 240, which is a fluid opening and closing device, is installed to adjust the flow rate by adjusting the cross-sectional area of the bypass pipe. When the solenoid valve is turned on, the solenoid valve is activated, the bypass flow path is opened, and the damping force is reduced. When the solenoid valve is turned off, the solenoid valve is not operated, the bypass flow path is closed, and the damping force is increased. delete delete

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