KR19990065979A - Damper structure of washing machine - Google Patents

Abstract

The present invention relates to a damper structure of a washing machine. Conventional dampers have a problem in that noise is largely generated by damping force in a steady state. Accordingly, the present invention provides a damper of a washing machine in which a compression pressing member is coupled to an end side of a rod passing through a damper cap engaged with a pivot of a washing tank, and an upper side thereof is provided with a spring for elastically supporting the compression pressing member. An elastic pad in sliding contact with an inner surface of the damper cap; Spaced pads disposed on upper and lower surfaces of the elastic pad to determine an elastic deformation range of the elastic pad; A spring base provided on the upper side gap holding pad to support the upper side spring from below; The compressive pressure member is constituted by the elastic pad, the upper and lower spacing pads, and the damper base for supporting the spring base at the end side of the rod passing therethrough, thereby suppressing excessive vibration at the initial stage of dehydration. The noise generated by the present invention can be reduced, thereby improving the damper function and further increasing the performance and reliability of the device.

Description

Damper structure of washing machine

The present invention relates to a damper structure of a washing tank to absorb vibrations generated in the washing tank.

Generally, as shown in FIG. 1, a pulsator washing machine includes a washing tank (outer tank) 2 in which water is contained in the washing machine case 1, and laundry is contained in the washing tank 2. A dehydration tank (inner tank) 3 is provided in two layers. In addition, a motor 4 serving as a driving source is mounted inside the washing machine case 1, and a clutch 5 is installed on the bottom centerline of the washing tub 2 to transfer the driving force of the motor 4 to the belt 6. It is configured to be received and operated by. And a pulsator (7) is coupled to the shaft of the clutch (5) on the inner bottom surface of the dehydration tank (3), and a damper (4) supporting the washing tank (2) in all directions on the outer periphery of the lower end of the washing tank (2). 8) and rods 9 thereon are fixed to upper and lower pivots 10 and 11, respectively, so as to absorb vibrations generated in the washing tank 2, respectively. At the same time, a ring-shaped ball balancer 12 is fixed to the upper and lower inner circumferences of the dehydration tank 3.

On the other hand, a washing machine having such a configuration causes excessive vibration due to excitation due to an unbalanced mass of laundry during the initial dehydration. And this vibration is suppressed by the damper 8, the damper 8 is a compression member (8D) inside the damper cap (8A) as shown in Figure 2 through the damper cap (8A) As the structure coupled to the rod 9 end side, the compression member (8D) is elastically supported by the compression coil spring (8E), the air hole (8B) is formed on one side of the damper cap (8A). More specifically, this is a long cylindrical body that is clogged and opened to the bottom, and an insertion hole 8C is formed in the center of the blocked portion of the cylindrical body so that the rod 9 is inside the cylindrical body. The compression member (8D) is a disk formed in the same or somewhat smaller than the diameter of the damper cap (8A), the coupling hole (85A) is formed in the center. The rod 9 is fixed to the upper pivot 10 of the washing machine case 1, and the damper cap 8A is fixed to the lower pivot 11 of the lower periphery of the lower end of the washing tank 2. In the conventional damper configured as described above, when vibration occurs in the washing tank 2 due to the unbalance of the laundry during dehydration, frictional force and air pressure or a damping force by a combination of the two acts according to the vibration width to suppress the vibration. do. The frictional force is generated while the side portion of the compression member (8D) is in sliding contact along the inner surface of the damper cap (8A), the air pressure is the air of the upper side of the compression member (8D) air of the damper cap (8A) It is generated while exiting through the hole 8B. However, such a conventional damper can suppress excessive vibration generated during the initial stage of dehydration as described above, but there is a problem in that noise is generated largely due to the increased damping force. Accordingly, in recent years, many devices for solving the above problems have been proposed.

However, most of the proposed devices, as described above, are complicated in the process and require many parts, which leads to an increase in production cost, and it is difficult to ultimately prevent noise because the damping force remains at the same size even in a normal state. There is a problem. Therefore, an object of the present invention is to provide a simple structure and to suppress the initial vibration of the transient state, and to have a small amount of continuous damping force in the steady state.

1 is a schematic view showing the internal configuration of a typical pulsator washing machine.

Figure 2 is a cross-sectional view showing a damper structure of a conventional washing machine.

3 is a cross-sectional view showing a damper structure according to the present invention.

4a and 4b is a view showing the compression member of the present invention,

4A is a plan view.

4B is a sectional view.

5a and 5b show the operating state of the present invention,

5A is an initial vibration state diagram with large amplitude.

5B is a steady state diagram with a small amplitude.

Figure 6 is a cross-sectional view showing a spring base structure of the present invention.

7 is a cross-sectional view showing a damper base structure of the present invention.

8a, 8b, 8c is a plan view showing an elastic pad embodiment of the present invention.

9A, 9B, 9C, and 9D are cross-sectional views illustrating embodiments of the elastic pad contact surface of the present invention.

** description of the symbols for the main parts of the drawings **

80: Damper Cap 80A: Insertion Hole

80B: Rod 80C: Compression member

80D: Spring 81: Elastic pad

81A: Through hole 81B, 81C: Bending deformation groove

81D: Contact surface 81E, 81F: Projection

82,83: Spacing pad 82A, 83A, 84A: Through hole

84: spring base 84B: support

85: Damper base 85A: Coupling hole

In order to achieve the object of the present invention, the compression pressing member is coupled to the end side of the rod passing through the damper cap engaged with the pivot of the washing tank, and the upper side thereof has a spring for elastically supporting the compression pressing member. A damper, comprising: an elastic pad in sliding contact with an inner surface of the damper cap; Spaced pads disposed on upper and lower surfaces of the elastic pad to determine an elastic deformation range of the elastic pad; A spring base provided on the upper side gap holding pad to support the upper side spring from below; A damper structure of a washing machine is provided, wherein the compressive pressure member is configured as a damper base for supporting the elastic pad, the upper and lower spacing pads, and the spring base at the end side of the rod passing therethrough. In addition, it characterized in that the elastic pad and the both sides of the gap maintaining pads are integrated, and the bending deformation grooves are formed symmetrically to each other on the outer edges of both sides of the circular elastic pad. And it characterized in that the shape of the bending deformation groove is formed in a circular or oval, characterized in that it is provided with a gap maintaining pad on both sides thereof in a state in which the elastic pad is laminated in multiple layers. In addition, the protrusions are formed on both sides of the contact surface of the elastic pad in contact with the inner surface of the damper cap, and the contact surfaces of the elastic pad in contact with the inner surface of the damper cap are formed to be point symmetrical at the center of the surface. It is characterized by one. In addition, the contact surface of the elastic pad is characterized in that formed in a pair of semi-circularly symmetrical to both sides at the arc-shaped shunt or the center of the surface passing through the center of the surface.

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

Figure 3 is a cross-sectional view showing a damper structure according to the present invention, Figures 4a and 4b is a compression member of the present invention, Figures 5a, 5b is an operating state of the present invention, Figure 6 is a spring base of the present invention Figure 7 is a cross-sectional view showing a structure, Figure 7 is a cross-sectional view showing a damper base structure of the present invention, Figures 8a, 8b, 8c is a plan view showing an elastic pad embodiment of the present invention, Figures 9a, 9b, 9c, 9d Sectional drawing showing the elastic pad contact surface example of this invention. As shown therein, the present invention is provided with a damper cap 80 having a space therein. The damper cap 80 is a cylindrical body of which the upper portion is blocked and opened to the lower portion, a rod 80B is inserted therein, and an upper portion of the damper cap 80 for insertion of the rod 80B. The insertion hole (80A) is formed in the center of the. In addition, a compression member (80C) is provided on the end side of the rod (80B), the compression member (80C) is elastically supported by its upper side spring (80D). And the compression member (80C) is provided on the elastic pad 81 in sliding contact with the inner surface of the damper cap 80, the upper and lower surfaces of the elastic pad 81, the elastic deformation of the elastic pad 81 A spacing pad (82) (83) for determining the range, a spring base (84) provided on the upper spacing pad (82) to support the upper spring (80D) thereof from below; The elastic pad 81, upper and lower space keeping pads 82 and 83, and a damper base 85 for supporting the spring base 84 at the end side of the rod 80B penetrating them. The elastic pad 81 is a disc body having elastic force, has a diameter equal to the diameter of the damper cap 80, and a through hole 81A is formed at the center thereof so that the rod 80B can pass therethrough. In addition, the space maintaining pads 82 and 83 provided on the upper and lower surfaces of the elastic pad 81 are formed of a disc body smaller than the diameter of the elastic pad 81, and the center portion of the elastic pad 81 is disposed like the elastic pad 81. Through-holes 82A and 83A are formed. The elastic pads 81 and the spacing pads 82 and 83 may be separately provided as described above, or may be manufactured by injection molding integrally as shown in FIGS. 4A and 4B. In addition, bending deformation grooves 81B and 81C are formed symmetrically with respect to both sides of the elastic pad 81 around the through hole 81A of the elastic pad 81. The bending deformation grooves 81B and 81C are intended to form a thickness therebetween to a minimum thickness that can be freely bent, and the shapes of the bending deformation grooves 81B and 81C are illustrated in FIGS. 8A, 8B, and FIG. It may be formed in various forms as shown in 8c. And the spring base 84 has a through hole (81A) is formed through the rod 80B is inserted through the center as shown in Figure 6, the outer side to form a support (84B) to protrude outward a certain length thereof It is configured to limit the upward elastic deformation range of the elastic pad 81 at the same time to support the spring (80D) provided on the upper side, wherein the spring base 84 is sufficient to the spring (80D) It is formed of a material having a strength that can be supported. In addition, the damper base 85 is a plate-shaped circular plate as shown in Figure 7, the center portion is formed with a coupling hole (85A) is inserted and coupled to the rod (80B). And the diameter is formed to a size that can limit the downward elastic deformation range of the elastic pad (81). On the other hand, the contact surface 81D of the elastic pad 81, that is, the surface in sliding contact with the inner surface of the damper cap 80 is formed to be point-symmetrical in the center of the surface, another embodiment thereof is Figure 9a, Figure 9b, 9c and 9d. 9A is an arc-shaped helical line passing through the center of the contact surface 81D of the elastic pad 81, and FIGS. 9B and 9C are projections 81E and 81F at both side-symmetric positions of the contact surface 81D. 9D is formed in a pair of semi-circles so as to be symmetrical to both sides from the center of the contact surface 81D.

The following describes the operation and operation of the present invention configured as described above.

First, in the initial stage of dehydration, vibration occurs in the washing tank 2 due to excitation due to the unbalanced mass of the laundry. The vibration is transmitted to the damper cap 80 engaged with the lower pivot 11 of the washing tank 2 to generate a damping force, which is caused by the damper cap 80 moving up and down. (80) The elastic pad 81 inside the sliding contact along the inner surface of the damper cap 80 causes friction, the damper cap 80 is compressed to generate air pressure therein. Accordingly, the vibration generated in the washing tank is suppressed by an increase in the damper force due to the friction force and air pressure. In the steady state in which the vibration width is small, the elastic pad 81 is not slidly contacted along the inner surface of the damper cap 80, but supports one contact and is formed in the upper and lower outer edges of the elastic pad 81. Since only a simple bending motion by 81B and 81C occurs, only a very small amount of damping force due to frictional force is generated. That is, the frictional damping force hardly occurs in the movement of the small displacement, and only the damping force is generated by the small amount of air pressure, and the frictional damping force is generated together with the damping force due to the air pressure in the large displacement motion such as the initial stage of dehydration. Damping force is increased.

As described above, the present invention can reduce the noise generated by the damping force in the normal state while suppressing the transient vibration during the initial stage of dehydration, thereby improving the damper function and further increasing the performance and reliability of the device. .

Claims (10)

In the damper of the washing machine in which a compression member is coupled to an end side of a rod passing through a damper cap engaged with a pivot of a washing tank, and an upper side thereof is provided with a spring for elastically supporting the compression member. An elastic pad in sliding contact; Spaced pads disposed on upper and lower surfaces of the elastic pad to determine an elastic deformation range of the elastic pad; A spring base provided on the upper side gap holding pad to support the upper side spring from below; The damper structure of the washing machine, characterized in that the compression member is composed of the elastic pad, the upper and lower spacing pads, and a damper base for supporting the spring base at the end side of the rod passing therethrough. The damper structure of a washing machine according to claim 1, wherein the elastic pad and the pad for maintaining gaps on both sides thereof are integrated. The damper structure of a washing machine according to claim 1 or 2, wherein bending deformation grooves are formed symmetrically with each other on outer side portions of both sides of the circular elastic pad. The damper structure of a washing machine according to claim 3, wherein the bending deformation groove is formed in a circular shape. The damper structure of a washing machine according to claim 3, wherein the bending deformation groove is formed in an elliptical shape. The damper structure of a washing machine according to claim 1, wherein a space keeping pad is provided on both sides of the elastic pad in a state of being laminated in multiple layers. The damper structure of a washing machine according to claim 1, wherein protrusions are formed at point-symmetrical positions on both sides of the contact surface of the elastic pad in contact with the inner surface of the damper cap. The damper structure of a washing machine according to claim 1, wherein the contact surface of the elastic pad in contact with the inner surface of the damper cap is formed to be point-symmetrical at the center of the surface. The damper structure of a washing machine according to claim 1, wherein the contact surface of the elastic pad in contact with the inner surface of the damper cap is formed by an arc-shaped shunt through the center of the surface. The damper structure of a washing machine according to claim 1, wherein a contact surface of the elastic pad in contact with the inner surface of the damper cap is formed in a pair of semi-circular shapes so as to be symmetrical to both sides from the center of the surface.