KR101318371B1 - Continuance variable oil damper - Google Patents

Abstract

PURPOSE: A continuously moving oil damper is provided to damp vibration from a washing machine and absorb shock. CONSTITUTION: A continuously variable equation oil damper damps vibration from a washing machine and absorbs shock using a piston part which reciprocates inside a cylinder. The piston part includes a piston and a piston rod. The piston is formed with a front and rear fluid through-hole (23-1) and an outer periphery fluid through-hole (23-2). A valve pin is inserted into the front and rear fluid through-hole to be able to move. The front end of the valve pin is formed with a front head part. Oil flows into a gap between the protrusions of the front head part. The rear end of the valve pin is formed with a rear head part. Oil flows into the outer periphery fluid through-hole and the front and rear fluid through-hole with the valve pin which moves backward in the compression of an oil damper. Oil flows into the outer periphery fluid through-hole without the front and rear fluid through-hole which is blocked with the rear head part when the valve pin moves forward in the tension of the oil damper. [Reference numerals] (AA) Flow passage blocking

Description

Continuous variable oil damper

The present invention is installed inside the device, the piston is reciprocating in the cylinder, the ball or valve pin is installed to the damping force during the damper compression and tension is formed by varying, effectively damping the vibration generated in the washing machine and impact The present invention relates to a continuously variable oil damper that alleviates the pressure.

In general, in a drum type washing machine such as a fully automatic washing machine, as described in the prior art in Japanese Patent Application Laid-Open No. 10-2005-0014717 (published on February 07, 2005), the laundry has a rotating shaft that is approximately horizontal to the ground. A spring and a damper are interposed between a substantially cylindrical water tank that accommodates the drum to be introduced and rotatably supported, and a body forming an outer portion of the washing machine, and the water tank is supported by these springs and dampers to be suspended. The vibration generated by the rotation of the drum is absorbed and damped.

As a general damper used in a drum type washing machine, friction dampers and oil dampers are known. The friction damper generates the damping force by the sliding friction of the friction member, but the change of the damping force due to the influence of wear of the friction member, etc. is large, and it is difficult to maintain a stable damping force for a long time. The oil damper is mounted in the cylinder in which the oil liquid is sealed so as to slide the piston connected to the piston rod to generate a damping force by the flow resistance of the oil liquid flowing through the orifice. A stable damping force can be obtained.

By the way, in the fully automatic drum type washing machine which automatically performs washing, rinsing and dewatering strokes, low-frequency vibrations with small amplitudes of rotation of the drum and large amplitudes occur at the start of the washing, rinsing and dehydration strokes. On the other hand, in the case of the dehydration stroke, when the rotational speed increases to some extent, the amplitude decreases and high frequency vibration is generated. In Japanese Patent Laid-Open No. 2001-214951, the seats are spaced apart at both end faces of the piston. By supporting the disk valve for opening and closing the oil liquid passage in the axial direction, during the small amplitude of the piston, the oil valve passage is opened without generating a small damping force when the disk valve is not seated on the piston. In the case of an amplitude, an oil damper is described in which the disc valve seats on the piston and the oil liquid passage is closed to generate a large damping force. As a result, a large damping force is generated for a large amplitude low frequency vibration at the start of the washing, rinsing, and dehydrating strokes to suppress the shaking of the drum, and the high frequency of the small amplitudes in the dehydrating stroke in which the rotational speed increases to some extent. Regarding the vibration, the vibration transmission to the body can be suppressed by generating a small damping force to absorb the vibration of the drum.

However, the oil damper described in JP 2001-214951 A has the following problems. During a large amplitude, when the disc valve contacts the piston, sound is generated, which causes noise. Since the disc valve is floatably supported by the piston rod and cannot be positioned relative to the piston, fluctuations occur in the actuation of the damping force, and a stable damping force cannot be obtained. The structure is complicated because the disk valve is floated by the piston rod, and the manufacturing cost is high because the sliding guide of the disk valve requires high dimensional accuracy.

Accordingly, Korean Patent Publication No. 10-2005-0014717 (published Feb. 7, 2005) has been made in view of the above point, and has a simple structure to reduce the damping force for high frequency vibration and to increase the damping force for low frequency vibration. The present invention provides a damper for a washing machine capable of obtaining stable damping force characteristics, and the technical configuration is a damper for a washing machine interposed between a water tank and a body accommodating a drum of a washing machine, and a piston having a piston rod connected thereto. A cylinder having a piston operating chamber to operate, and a communication path provided between the two chambers in the piston operating chamber, which is installed at the piston and is partitioned by the piston, wherein the piston operating chamber is mixed with oil and gas. It is characterized by being sealed.

Further, the cylinder is interposed between the drum and the body so that the piston rod protruding side of the cylinder faces downward, and the operating stroke of the piston in the state interposed between the water tank and the body. In the range, the piston is immersed in the oil liquid, and in the flow path area of the communication path, bubbles generated in the basement under the piston in the cylinder by aeration pass through the communication path, The bubble of the basement disappears within 60 second, and the pressure of the gas enclosed in the said cylinder is 1-3 kgf / cm <^2> .

A damping force adjustment mechanism for adjusting the flow path area of the communication path is provided, wherein the communication path is formed to be inclined with respect to the axial direction of the cylinder.

However, the conventional technology has a communication path is installed in the central portion of the piston, the flow of fluid is divided into the flow between the cylinder and the rod and the flow of the communication path is a vortex phenomenon occurs that the noise and vibration reduction effect is not great There was this.

Therefore, the present applicant solved the above problems and applied for a patent application No. 10-2011-0114757, which is the piston damping plate is installed in the damper, the rod 60 is installed inside the tube 50, the damper to reciprocate In, the piston damping plate 70 is attached to one end of the rod (60). A plurality of damping grooves 71 are formed on the outer circumference of the piston damping plate 70.

In addition, the upper end of the tube is formed with a cap bolt 81 is attached to the lower portion of the upper device, such as a washing machine tub, the rod 60 is inserted into the tube 50 is the piston damping plate 70 The inner guide 65 is installed at the lower part of the rod and spaced apart from each other, and the first and second oil chambers 61 and 62 are installed at the lower inner guide.

A damper case 63 is installed at a lower portion of the second oil chamber 62 to seal the lower portion of the tube 50, and an end bolt 82 is installed at the other end of the rod 60, and an end bolt 82 is provided. Is attached to the bottom of the appliance case.

And if necessary, the coil sheet is inserted into the lower portion of the tube and the compression coil spring is mounted between the lower portion of the tube and the coil sheet. Therefore, the damping force of the damper can be compensated for by the elastic force of the compression coil spring.

The vibration and noise damping mechanism caused by the piston damping plate is described as follows. The piston damping plate has a low damping force caused by oil flow through the damping groove of the piston damping plate due to the movement of the rod in the tube for low frequency vibration and noise caused by washing and rinsing operations of the washing machine. Therefore, the vibration and noise of the washing machine are attenuated.

On the other hand, the high frequency vibration and noise generated by the dehydration operation or starting of the washing machine generate air bubbles in the oil liquid due to the aeration phenomenon, and the damping force of the piston damping plate is reduced by the compression of the air bubbles.

Since the damping holes formed in the piston damping plate is a factor for determining the damping force of the piston damping plate, an appropriate number is required, and the present invention forms three to four. If the number of damping holes is large, the aeration is lost too quickly. If the number is small, the aeration continues and the damping force decreases.

If the damping hole diameter is large, the aeration is lost too quickly. If the diameter is small, the aeration continues and the damping force decreases.

Therefore, three to four damping holes are formed, and the diameter is 1/300 to 1/250 of the diameter of the piston damping plate.

And considering the washing operation, it is important that the aeration lasts about 30 seconds to 1 minute, after which the bubble is lost to return to its original state. That is, about 30 seconds in the dehydration step and about 1 minute in the start-up step.

And by forming the damping hole on the outer periphery of the piston damping plate, it is possible to smoothly flow the oil without the vortex phenomenon than when formed on the upper and lower surfaces of the piston damping plate.

     However, the prior arts still suffer from the rapid shock that extends to the damper and the washing machine as a whole, resulting in damage to the damper and the washing machine parts, and also to the noise and vibration caused by the impact.

The present invention has been devised to solve the above problems, the sliding ring is moved back and forth, and to adjust the opening degree of the oil flow path, during compression the sliding ring is moved to the rear to open the flow path by opening the flow path to the rear In order to provide a continuously variable oil damper that increases the number of times, the sliding ring moves forward to close part of the flow path so that the passage flow rate decreases, thereby damping the vibration generated in the washing machine and mitigating the impact.

The present invention relates to a continuously variable oil damper, the piston unit 20 in the cylinder 10 in the reciprocating movement to damp the vibration generated in the washing machine and to reduce the shock in the continuously variable oil damper, the piston portion 20 is composed of a piston 21 and the piston rod 25 is installed on the rear of the piston 21, the stepped portion 24 is formed behind the piston 21, before and after the piston 21 Front and rear fluid passage holes 23-1 and outer periphery fluid passage holes 23-2 formed at the outer periphery of the piston are formed, and a cross section is formed in the front and rear fluid passage holes 23-1. A valve pin 41 having a shape is inserted and installed to be movable, and the height of any one of the '+' shaped protrusions 45 is the diameter of the front and rear fluid passage holes 23 at the front end of the valve pin 41. A larger front head portion 42 is formed, so that oil flows between the projections 45 of the front head portion 42, At the rear end of the valve pin 41, a rear head 43 formed larger than the diameter of the front and rear fluid passage holes 23 is formed. It flows through the fluid passage hole (23-2) and the front and rear fluid passage hole (23-1), the valve pin 41 is advanced at the time of tension, the rear head 43 is the front and rear fluid passage hole (23) -1) is blocked, so that the oil flows through only the outer circumferential fluid passage hole 23-2.

Therefore, in the present invention, the sliding ring is moved back and forth, and the opening degree of the oil flow path is adjusted. When the compression is performed, the sliding ring moves backward and opens the flow path to increase the flow rate, and the sliding ring moves forward. As the flow path is partially closed, the passage flow rate decreases, thereby reducing the vibration generated in the washing machine and relieving the shock.

1 is a cross-sectional plan view of the valve pin is installed in the continuous variable oil damper of the present invention
Figure 2 is a front sectional view of the valve pin is installed in the continuous variable oil damper of the present invention
Figure 3 is a detailed view of the valve pin in the continuous variable oil damper of the present invention
Figure 4 is a cross-sectional plan view of the valve pin and the sliding ring installed in the continuous variable oil damper of the present invention
Figure 5 is a front sectional view of the valve pin and the sliding ring is installed in the continuous variable oil damper of the present invention
Figure 6 is a detailed view of the valve pin and the sliding ring in the continuous variable oil damper of the present invention
Figure 7 is a perspective view of the valve pin and the sliding ring in the continuous variable oil damper of the present invention
Figure 8 is a cross-sectional plan view of the through-hole and ring installed in the continuous variable oil damper of the present invention
Figure 9 is a front sectional view of the through-hole and ring installed in the continuous variable oil damper of the present invention
10 is a perspective view of a conventional continuous variable oil damper
11 is a cross-sectional view of the coil spring mounted in the conventional continuous variable oil damper

The present invention relates to a continuously variable oil damper, the piston unit 20 in the cylinder 10 in the reciprocating movement to damp the vibration generated in the washing machine and to reduce the shock in the continuously variable oil damper, the piston portion 20 is composed of a piston 21 and the piston rod 25 is installed on the rear of the piston 21, the stepped portion 24 is formed behind the piston 21, before and after the piston 21 Front and rear fluid passage holes 23-1 and outer periphery fluid passage holes 23-2 formed at the outer periphery of the piston are formed, and a cross section is formed in the front and rear fluid passage holes 23-1. A valve pin 41 having a shape is inserted and installed to be movable, and the height of at least one of the '+' shaped protrusions 45 is a diameter of the front and rear fluid passage holes 23 at the front end of the valve pin 41. A larger front head 42 is formed, so that oil flows between the projections 45 of the front head 42. At the rear end of the valve pin 41, a rear head 43 formed larger than the diameter of the front and rear fluid passage holes 23 is formed. It flows through the outer circumferential fluid through hole (23-2) and the front and rear fluid through hole (23-1), the valve pin 41 is advanced at the time of tension, the rear head 43 is the front and rear fluid through hole (23-1) is blocked, characterized in that the oil flows through only the outer peripheral fluid passage hole (23-2).

In addition, the front end of the piston rod 25 is formed with a sliding ring 50 on the outer circumference, the rear end of the valve pin 41 is integrally coupled to the front of the sliding ring 50,

During compression, the sliding ring 50 and the valve pin 41 are reversed so that oil flows through the outer peripheral fluid passage hole 23-2 and the front and rear fluid passage holes 23-1. As the sliding ring 50 and the valve pin 41 are advanced, the sliding ring 50 blocks the front and rear fluid passage holes 23-1, so that oil flows only through the outer peripheral fluid passage hole 23-2. It is characterized by.

In addition, the present invention is installed in the device, the piston 10 in the cylinder 10 reciprocating movement in the continuous variable oil damper to dampen the vibration generated in the washing machine and to mitigate the impact, the piston portion ( 20 is a piston 21 in which the front and rear fluid passage holes 23-1 are formed, and a piston rod 25 installed at the rear of the piston 21 and having a step 24 formed at the rear of the piston 21. It is composed of a), around the stepped sliding ring 50 is installed to be movable, the stepped hole 28 in the vertical direction is formed in the stepped portion 24 between the piston 21 and the sliding ring 50 In the piston rod 25 between the piston 21 and the sliding ring 50, a hole 29 is formed therein, and fluid flows through the rod hole 29 through the through hole 28. In addition, the ring 30 is formed on the front of the sliding ring 50, the sliding ring 50 is reversed during compression And the ring 30 opens the through hole 28 so that the fluid can flow through the through hole 28 together with the front and back fluid through holes 23-1, and the sliding ring 50 during tensioning. The advancing is the ring 30 to block the through hole 28 is characterized in that the fluid flows through only the front and rear fluid passage hole (23-1).

The present invention will be described in detail with reference to the accompanying drawings. 1 is a plan sectional view in which the valve pin is installed in the continuously variable oil damper of the present invention, FIG. 2 is a front sectional view in which the valve pin is installed in the continuously variable oil damper of the present invention, and FIG. 3 is a detail of the valve pin in the continuously variable oil damper of the present invention. Figure 4 is a planar cross-sectional view of the valve pin and the sliding ring is installed in the continuous variable oil damper of the present invention, Figure 5 is a front sectional view of the valve pin and the sliding ring is installed in the continuous variable oil damper of the present invention, Figure 6 is a continuous invention of the present invention Detailed view of the valve pin and the sliding ring in the variable oil damper, Figure 7 is a perspective view of the valve pin and the sliding ring in the continuous variable oil damper of the present invention, Figure 8 is a cross-sectional plan view of the through-hole and ring installed in the continuous variable oil damper of the present invention 9 is a front sectional view of a through hole and a ring installed in the continuous variable oil damper of the present invention, FIG. 10 is a perspective view of a conventional continuous variable oil damper, and FIG. 11 is a nose in a conventional continuous variable oil damper. A cross-sectional view the spring loaded.

The present invention is a continuously variable oil damper to dampen the vibration generated in the washing machine and to mitigate the impact of the piston 20 reciprocating inside the cylinder (10).

The piston 20 is provided with a piston 21 and a piston rod 25 installed at the rear of the piston 21 and having a step 24 formed at the rear of the piston 21.

Front and rear fluid passage holes 23-1 and front and rear fluid passage holes 23-2 formed at the outer periphery of the piston are formed before and after the piston 21, and the front and rear fluid passage holes 23-1 are formed. Inside the valve pin 41 of the '+' shape is inserted into the moveable.

At the front end of the valve pin 41, the front head 42 having a vertical height of any one of the '+' shaped projections 45 is larger than the diameter of the front and rear fluid passage holes 23-1. Is formed, the oil flows between the projections 45 of the front head 42.

Since the valve pin 14 is made of a soft synthetic resin such as silicone and is elastic, the valve pin 41 is inserted into the front and rear fluid passage hole 23-1 from the back, so that the vertical height is the front and rear fluid. The vertical top and bottom ends of the front head 42 formed larger than the diameter of the passage hole 23-1 are bent backwards and pass through the front and rear fluid passage holes 23-1, and the front and rear fluid passage holes 23-1. The valve pin does not escape from the front and rear fluid passage holes 23-1 while being unfolded after exiting.

On the other hand, the rear head 43 is formed at the rear end of the valve pin 41 larger than the diameter of the front and rear fluid passage hole 23.

Therefore, when the valve pin 41 is reversed during compression, oil flows through the outer circumferential fluid passage hole 23-2 and the front and rear fluid passage holes 23-1, and the valve pin 41 during tension. This advancement causes the rear head 43 to block the front and rear fluid passage holes 23-1, so that the oil flows only through the outer circumferential fluid passage holes 23-2.

Meanwhile, as another embodiment of the present invention, a sliding ring 50 is formed at an outer circumference of a front portion of the piston rod 25, and a rear end portion of the valve pin 41 is integrally formed on the front surface of the sliding ring 50. Are combined.

Therefore, during compression, the sliding ring 50 and the valve pin 41 are reversed so that oil flows through the outer circumferential fluid through hole 23-2 and the front and back fluid through holes 23-1. The sliding ring 50 and the valve pin 41 are advanced to block the front and rear fluid passage holes 23-1 so that oil flows only through the outer circumferential fluid passage holes 23-2. Will be.

In addition, as another embodiment of the present invention, the sliding ring 50 is installed around the piston rod step. The through hole 28 is formed in the vertical direction 24 between the piston 21 and the sliding ring 50, and the piston rod 25 between the piston 21 and the sliding ring 50 is formed on the stepped portion 24. A hole 29 is formed therein so that fluid flows through the rod hole 29 through the through hole 28. In addition, the ring 30 is formed on the front of the sliding ring 50,

When compressed, the sliding ring 50 is reversed and the ring 30 opens the through hole 28 so that the fluid can flow through the through hole 28 together with the front and rear fluid through holes 23-1. In tensioning, the sliding ring 50 is advanced to block the through hole 28 so that fluid flows only through the front and rear fluid passage holes 23-1.

 On the other hand, the present invention, as in the conventional patent application No. 10-2011-0114757 and other prior art, the upper end of the cylinder is formed a cap bolt 81 is attached to the lower part of the upper object of the machine, such as a washing machine tub The piston rod inserted into the cylinder is spaced apart from the piston, and an inner guide 65 is installed below the piston rod, and first and second oil chambers 61 and 62 are installed below the inner guide.

A damper case 63 is installed at the lower part of the second oil chamber 62 to seal the lower part of the cylinder, but an end bolt 82 is installed at the other end of the lower part of the piston rod 60, so that the end bolt 82 is installed. It is attached to the bottom of the case.

And if necessary, the coil seat is inserted into the lower part of the cylinder and a compression coil spring is mounted between the lower part and the coil seat. Therefore, the damping force of the damper can be compensated for by the elastic force of the compression coil spring.

Therefore, in the present invention, the sliding ring is moved back and forth, and the opening degree of the oil flow path is adjusted. When the compression is performed, the sliding ring moves backward and opens the flow path to increase the flow rate, and the sliding ring moves forward. As the flow path is partially closed, the passage flow rate decreases, thereby reducing the vibration generated in the washing machine and relieving the shock.

10 cylinder 20 piston portion
21: Piston
23-1: Front and back fluid passage hole
23-2: Outer peripheral fluid through hole
24: step 25: piston rod
28: through hole 29: hole
30: ring
41: valve pin
42: front head 43: rear head
45: protrusion 50: sliding ring

Claims (3)

In the continuously variable oil damper installed inside the device, the piston 20 is reciprocating to dampen the vibration generated in the washing machine and to mitigate the impact, the piston 20 is the piston 21 and the piston (21) is provided in the rear portion, consisting of a piston rod 25, the stepped portion 24 is formed behind the piston 21, the front and rear fluid passage hole (23-1) before and after the piston 21, An outer circumferential fluid passage hole 23-2 is formed on the outer circumference of the piston, and a valve pin 41 having a '+' shape in the front and rear fluid passage holes 23-1 is movably inserted therein. Is installed, the front of the valve pin 41, the front head portion 42 is formed in the vertical height of any one or more of the '+' shaped projections 45 larger than the diameter of the front and rear fluid passage hole (23-1) Is formed, oil is introduced between the projections 45 of the front head 42, the rear end of the valve pin 41 The rear head 43 is formed to be larger than the diameter of the rear fluid passage hole 23-1, so that the valve pin 41 is retracted during compression so that the oil may flow out of the outer peripheral fluid passage hole 23-2. The fluid flows through the front and rear fluid passage holes 23-1, and when the tension is applied, the valve pin 41 is advanced so that the rear head 43 blocks the front and rear fluid passage holes 23-1. Continuously variable oil damper, characterized in that flow through only the outer peripheral fluid passage hole (23-2) The front end of the piston rod 25, the sliding ring 50 is formed on the outer periphery, the rear end of the valve pin 41 is integrally coupled to the front of the sliding ring 50 ,
During compression, the sliding ring 50 and the valve pin 41 are reversed so that oil flows through the outer peripheral fluid passage hole 23-2 and the front and rear fluid passage holes 23-1. As the sliding ring 50 and the valve pin 41 are advanced, the sliding ring 50 blocks the front and rear fluid passage holes 23-1, so that oil flows only through the outer peripheral fluid passage hole 23-2. Continuously variable oil damper, characterized in that In the continuously variable oil damper that is installed inside the device, the piston portion 20 reciprocates inside the cylinder 10 and dampens the vibration generated in the washing machine and alleviates the shock, the piston portion 20 is the front and rear surfaces Piston 21 is formed in the fluid passage hole (23-1), and the piston rod 25 is installed on the rear of the piston 21, the stepped portion 24 is formed behind the piston 21, The sliding ring 50 is installed to be movable around the stepped jaw, and the through hole 28 is formed in the vertical step 24 between the piston 21 and the sliding ring 50 in the vertical direction, and the piston 21 In the piston rod 25 between the sliding ring 50 and the hole 29 is formed therein, the fluid flows through the rod hole 29 through the through hole 28, and the sliding ring ( 50, the ring 30 is formed on the front surface, the sliding ring 50 is reversed when the compression 30 opens the through hole 28 so that the fluid can flow through the through hole 28 together with the front and rear fluid through holes 23-1, and the sliding ring 50 moves forward during tension. Continuously variable oil damper, characterized in that the ring 30 is blocked the through hole 28, the fluid flows only through the front and rear fluid passage hole (23-1).

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