KR100531826B1 - Damper using magnetic force and washing machine having the same - Google Patents

Abstract

The present invention relates to a damper using a magnetic force and a washing machine having the same. A damper using a magnetic force according to the present invention, the first body to form a receiving space therein at least one side in the longitudinal direction therein; A second body inserted into the first body in a relative length with respect to the first body such that one side thereof overlaps a predetermined length section within the first body; A magnetic body disposed in an overlapping region of the first body and the second body; The magnetic body is spaced apart from the magnetic body by a predetermined gap horizontally in the stretching direction of the first body and the second body, and is disposed to be relatively movable along the stretching direction of the first body and the second body with respect to the magnetic body. A magnetic force generating unit for generating; A first friction member coupled integrally with any one of the magnetic body and the magnetic force generating unit and frictionally contacting any one of the first body and the second body with a greater frictional force than the suction force between the magnetic body and the magnetic force generating unit; The first friction member is moved when the first body or the second body is moved more than a predetermined distance by being disposed on both sides of the first friction member in the stretching direction of the first body and the second body, respectively. It characterized in that it comprises a pressing unit to be. As a result, different damping forces are generated according to the displacement, thereby effectively suppressing the transmission of vibration.

Description

Damper using magnetic force and washing machine with same {DAMPER USING MAGNETIC FORCE AND WASHING MACHINE HAVING THE SAME}

The present invention relates to a damper using a magnetic force and a washing machine having the same, and more particularly, a damper using a magnetic force to effectively suppress transmission of vibration by generating different damping forces according to displacement, and having the same. It's about a washing machine.

1 is a view showing an example of a conventional drum washing machine, Figure 2 is an enlarged cross-sectional view of the damper of FIG. As shown in these drawings, the drum washing machine includes a cabinet 11 forming an accommodating space therein, a tub 21 arranged along the front and rear direction inside the cabinet 11 and accommodating the washing water therein; And a drum 22 disposed in the tub 21 so as to be rotatable with respect to the tub 21.

The cabinet 11 has a rectangular parallelepiped shape in which an opening 13 is formed on a front surface thereof so that laundry can enter and exit, and a door 15 is provided at one edge of the opening 13 to open and close the opening 13. Inside the cabinet 11, a tub 21 having a cylindrical shape in which one side is opened to allow laundry to enter and exit is accommodated, and a rotation shaft formed along the front and rear directions of the cabinet 11 in the tub 21. A drum 22 having a cylindrical shape about a line is rotatably coupled.

The rear end of the tub 21 is formed with a spider 23 provided with a bearing 24 so as to rotatably support the rotating shaft 28 of the drum 22, the rear side of the spider 23 drum The drum driving motor 25 is integrally coupled so as to rotate the 22.

Drum drive motor 25, the stator 26 is integrally fixed to the spider 23, and arranged concentrically with each other with a predetermined gap on the outside along the radial direction of the stator 26 and the drum 22 It is provided with a rotor 27 rotatably coupled to the rotation axis of the.

The upper region of the tub 21 is provided with a plurality of support springs 29, one end of which is fixed to the cabinet 11 so that the tub 21 can be suspended from the tub 21, and the tub 21 is disposed below the tub 21. The damper 31 is provided to reduce the vibration width in the vertical direction.

On the other hand, the damper 31, one side is coupled to the cabinet 11 so that the relative movement, the other side has a cylindrical body having a friction surface 33 formed therein, and one side tub 21 The second body 34 is coupled to the relative movement and the other side is predetermined inserted into the first body 32, and between the friction surface 33 of the second body 34 and the first body 32 It is provided with a pair of friction members 36 interposed and in contact with the friction surface 33. An outer groove surface of the second body 34 inserted into the first body 32 is provided with a receiving groove 35 recessed to allow the friction member 36 to be inserted into a predetermined insertion.

By the way, in such a conventional drum washing machine, the first body 32 and the second body 34 are formed to be connected to each other via the friction member 36, the large and small generated when the drum 22 is driven Vibration is transmitted to the cabinet 11 through both the tub 21 and the damper 31 has a problem that causes vibration and noise.

In addition, while the drum 22 is dehydrated, the drum 22 passes through an excessive speed section in which vibration is excessively generated in the process of reaching a normal dehydration speed, but the frictional force between the first body 32 and the friction member 36 is always constant. When the frictional force of the friction member 36 is increased according to the relatively large damping force required in the transient speed section, the vibration of the first body 32 is transmitted to the second body 34 in the normal dehydration speed section. There is a problem that the transmission rate of the vibration is excessively large, and the transmission rate of the vibration is relatively increased in the transient speed section when the frictional force of the friction member 36 is reduced in accordance with the damping force required in the normal dehydration speed section.

Accordingly, an object of the present invention is to provide a damper using a magnetic force capable of effectively suppressing the transmission of vibration by causing different damping forces to be generated according to the displacement, and a washing machine having the same.

The above object, according to the present invention, the first body to form a receiving space therein at least one side opening in the longitudinal direction therein; A second body inserted into the first body in a relative length with respect to the first body such that one side thereof overlaps a predetermined length section within the first body; A magnetic body disposed in an overlapping region of the first body and the second body; The magnetic body is spaced apart from the magnetic body by a predetermined gap horizontally in the stretching direction of the first body and the second body, and is disposed to be relatively movable along the stretching direction of the first body and the second body with respect to the magnetic body. A magnetic force generating unit for generating; A first friction member coupled integrally with any one of the magnetic body and the magnetic force generating unit and frictionally contacting any one of the first body and the second body with a greater frictional force than the suction force between the magnetic body and the magnetic force generating unit; The first friction member is moved when the first body or the second body is moved more than a predetermined distance by being disposed on both sides of the first friction member in the stretching direction of the first body and the second body, respectively. It is achieved by a damper using a magnetic force, characterized in that it comprises a pressurizing portion.

Here, the first friction member is preferably integrally coupled to the circumference of the magnetic body is in friction contact with the first body.

Interposed between the first body and the second body and having a frictional force less than a difference between a frictional force of the first friction member and a suction force between the magnetic body and the magnetic force generating unit, and any one of the first body and the second body; It is effective to further include a frictional second friction member.

The second friction member is preferably integrally coupled to the second body.

The magnetic force generating unit preferably includes a core disposed to have a predetermined gap with the magnetic body, and a coil disposed to generate a magnetic force in the core.

The magnetic force generating unit is effective to include a permanent magnet.

The permanent magnet is preferably composed of a plurality of spaced apart at a predetermined distance along the stretch direction of the first body and the second body.

It is effective that the magnetic body has protrusions protruding toward the permanent magnet in the transverse direction of the first body and the second body so as to correspond to the respective permanent magnets.

It is preferable to further include an iron core made of a magnetic member passing through the shaft center of each of the permanent magnets to integrally connect the pressing parts disposed on both sides of the magnetic body.

The distance between the magnetic body and the pressing portion is less than the separation distance along the stretching direction of the first body and the second body of the protrusion, the length along the stretching direction of the permanent magnet is less than the separation distance along the stretching direction of the protrusion. It is effective to have

On the other hand, according to another field of the present invention, and a case forming an accommodation space therein; A tub accommodated in the case to accommodate washing water; One side between the case and the tub is connected to any one of the case and the tub and the other side to form an open receiving space, the other side is accommodated overlapping along the longitudinal direction inside the first body The other side includes a second body connected to the other of the case and the tub, a magnetic body disposed in an overlapping region of the first body and the second body, and the magnetic body and a predetermined gap horizontally in the longitudinal direction of the first body. The first body having a frictional force greater than the magnetic force generating portion and the magnetic force generating portion for generating a magnetic force and the magnetic body and the magnetic force generating portion integrally coupled to the suction force between the magnetic body and the magnetic force generating portion Or each of the first friction member in frictional contact with any one of the second bodies, and on both sides of the first friction member along the stretch direction of the first body and the second body. Washing machine having a damper using a magnetic force, characterized in that it comprises a damper having a pressing portion to be spaced apart a predetermined distance and the first friction member is moved when the first body or the second body is moved more than a predetermined distance Is provided.

Here, the first friction member is integrally coupled to the circumference of the magnetic body is in friction contact with the first body, interposed between the first body and the second body and the frictional force of the first friction member and the magnetic body and It is preferable to further include a second friction member in friction contact with any one of the first body and the second body having a frictional force less than the difference of the suction force between the magnetic force generating portion.

The magnetic force generating unit may effectively include a core disposed to have a predetermined gap with the magnetic body, and a coil disposed to generate a magnetic force on the core.

The magnetic force generating unit preferably includes a permanent magnet.

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

3 is a cross-sectional view of a damper using a magnetic force according to an embodiment of the present invention, Figure 4 is an enlarged view of the main portion of Figure 3, Figures 5 and 6, respectively, along the lines V-V and VI-VI of FIG. 7 is an enlarged cross-sectional view of a main portion of a damper using a magnetic force according to another embodiment of the present invention. The same and equivalent parts as those described above and illustrated in the drawings will be omitted for convenience of description and will be described with reference to the same reference numerals. As shown in these figures, the damper 41 using the present magnetic force has a first body 42 that forms an accommodating space in which one side is opened along the longitudinal direction, and one side of the damper 41. The second body 52 which is inserted to be able to move relative to the predetermined length section therein, the magnetic body 71 disposed in the overlapping region of the first body 42 and the second body 52, and the first body ( 42 and the magnetic body 71 and the magnetic body generating portion 74 and the magnetic body 71 and the magnetic force generated in the stretching direction of the second body 52 to be spaced apart with a predetermined gap (c) It is integrally coupled to any one of the portions 74 and has a greater frictional force than the suction force between the magnetic body 71 and the magnetic force generating portion 74 and friction with any one of the first body 42 and the second body 52. The first friction member 77 and the first body 42 and the second body 52 in contact with each other along the stretch direction of the first friction member 77 is disposed a predetermined distance apart from the first The body 42 and the second body 52 is configured to include a pressing portion (55, 65) to move the first friction member 77 when the movement over a predetermined distance.

Hereinafter, a case in which the damper 40 using the present magnetic force is applied to the drum washing machine in the washing machine, for example, the first body 42 is coupled to the cabinet 11 so as to be relatively movable, and the second body 52 is a tub. The following description will be regarded as movably combined with (21).

The first body 42 is formed to have an open cylindrical shape on one side, the coupling hole 43 is formed through the other side so as to be fixedly coupled to the cabinet 11 so as to be relatively movable. The friction surface 44 is formed inside the first body 42 over a predetermined length section.

The second body 52 has a rod or pipe shape of a circular cross section having an outer diameter that is reduced compared to the inner diameter of the second body 52 so that one side may be inserted to overlap a predetermined length section inside the first body 42. Is formed, the coupling hole 53 is formed in one side so as to be fixedly coupled to the relative movement relative to the tub (21).

An insertion end portion inserted into the first body 42 serves as a first pressing part 55 for pressing the magnetic body 71 and a first body 42 on an outer diameter surface of the first pressing part 55. Receiving groove 57 is formed so that the second friction member 79 in friction contact with the friction surface 44 of the housing can be received. One end of the iron core 61 formed of a magnetic member and disposed to extend in the longitudinal direction is integrally inserted in the center of the first pressing part 55, and the other end of the iron core 61 is radially along the other end. A second pressing portion 65 is formed to extend and press the magnetic body 71 to be described later together with the insertion side end portion. An outer circumference of the second pressing part 65 is provided with a receiving groove 67 to accommodate the second friction member 79.

On the other hand, a pair of permanent magnets 75 formed around the iron core 61 to have a circular ring shape with a magnetic force generating portion 74 for generating a magnetic force are spaced apart from each other by a predetermined distance along the longitudinal direction of the iron core 61. It is disposed, the outer ring of the permanent magnet 75 along the radial direction of the first body 42, the permanent magnet 75 and a predetermined gap (c) with a circular ring-shaped magnetic body 71 to enable relative movement It is arranged.

A pair of protrusions 72 protruding to correspond to each permanent magnet 75 is formed on the inner diameter surface of the magnetic body 71, and between the magnetic body 71 and the permanent magnet 75 on the outer circumferential surface of the magnetic body 71. A pair of first friction members 77 in frictional contact with the friction surface 44 of the first body 42 is coupled with a suction force that acts and a friction force greater than that of the second friction member 79. The magnetic body 71 has a pair of receiving grooves 73 so as to be recessed along the radial direction so that the pair of first friction members 77 spaced apart from each other along the longitudinal direction of the first body 42 can be accommodated. Each is formed.

Here, as shown in FIG. 7, the magnetic force generating unit 74 forms a pole portion 82 protruding to correspond to each protrusion 72 of the magnetic body 71 to form the core 81 together with the iron core 61. The coil 83 may be configured in the form of an electromagnet in which the coil 83 is wound so as to form a magnetic force and to generate a magnetic force around the iron core 61 between the two pole portions 82. In this case, the strength of the suction force acting between the magnetic bodies 71 can be controlled by adjusting the strength of the current applied to the coil 81.

On the other hand, the distance (d1) between the pressing portions (55, 65) disposed at both ends of the magnetic body 71, respectively, a predetermined distance apart from each other, the distance d2 between the two projections (72) of the magnetic body 71 The length L along the longitudinal direction of the first body 42 of each permanent magnet 75 is a separation distance d2 along the longitudinal direction of the first body 42 of the two protrusions 72. It is preferable to comprise so that it may become below).

By this configuration, when the drum 22 starts to rotate when dewatering, vibration occurs in the tub 21, and the second body 52 integrally coupled to the tub 21 is connected to the first body 42. Relative movement so as to stretch along the longitudinal direction. At this time, when the vibration width of the tub 21 is smaller than the separation distance between the magnetic body 71 and the pressing portions 55, 65, the frictional force of the second friction member 79 and the protrusion 72 of the magnetic body 71 And the suction force between the permanent magnet 75 acts as a resistance in the advancing direction of the first body 42 to mitigate the vibration of the tub 21. Here, when the magnetic force generating unit 74 is configured in the form of an electromagnet, the strength of the suction force with the magnetic body 71 may be controlled by adjusting the intensity of the current applied to the coil 83.

On the other hand, in the transient speed section in which the rotational speed of the drum 22 is increased so that the vibration width of the tub 21 becomes larger than the separation distance d1 between the magnetic material 71 and the pressing portions 55 and 65, each pressurization is performed. The portions 55 and 65 are in contact with the magnetic body 71 to press the magnetic body 71 in the advancing direction of the second body 52. At this time, the first friction member 77 having a relatively large frictional force is relatively slid relative to the first body 42 so as to appropriately resist the progress of the second body 52 to mitigate vibration.

When the rotational speed of the drum 22 is increased to reach the normal dehydration speed section, the vibration width of the tub 21 becomes smaller than the separation distance d1 between the magnetic material 71 and each pressing part 55, 65. At this time, the magnetic body 71 is fixed to the first body 42 by the frictional force of the first friction member 77, the permanent magnet 75 is integral with the second body 52, the magnetic body 71 By relative movement with respect to the vibration of the second body 52 by the frictional force of the second friction member 79 and the suction force between the magnetic body 71 and the permanent magnet (75).

In the above-described and illustrated embodiments, the permanent magnets are described as a pair spaced apart from each other along the longitudinal direction of the first body, but the permanent magnets may be composed of a single piece or three or more.

In the above-described and illustrated embodiments, the case where the friction surface is formed inside the first body is exemplified, but the friction surface may be formed on the second body.

In the above-described and illustrated embodiments, the case in which the first body and the second body are configured to have a circular cross section is described as an example, but may be configured to have a different cross-sectional shape.

As described above, according to the present invention, the first body and the second body coupled to overlap each other along the longitudinal direction, and the magnetic body and the magnetic force generated in the overlapping region of the first body and the second body so as to be relative to each other The first friction member, which is disposed in frictional contact with the overlapping region with a greater frictional force than the suction force acting between the magnetic body and the magnetic force generating portion, and the first body and the second body are spaced apart from each other by a predetermined distance. By providing a pressing unit for moving the first friction member when the body is moved more than a predetermined distance, the damper using a magnetic force capable of generating a different damping force selectively in response to the displacement to mitigate the transmission of vibration and the same One washing machine is provided.

1 is a view showing an example of a conventional drum washing machine,

2 is an enlarged cross-sectional view of the damper of FIG. 1;

3 is a cross-sectional view of a damper using a magnetic force according to an embodiment of the present invention,

4 is an enlarged view illustrating main parts of FIG. 3;

5 and 6 are cross-sectional views taken along lines V-V and VI-VI of FIG. 3, respectively;

Figure 7 is an enlarged cross-sectional view of the main portion of the damper using a magnetic force according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

11: cabinet 21: tub

22: drum 42: the first body

44: friction surface 52: second body

55: first pressing portion 61: iron core

65: second pressing portion 71: magnetic material

72: protrusion 74: magnetic force generating portion

75: permanent magnet 77: the first friction member

79: second friction member

Claims (14)

A first body forming an accommodating space having at least one side opened in the longitudinal direction therein; A second body inserted into the first body in a relative length with respect to the first body such that one side thereof overlaps a predetermined length section within the first body; A magnetic body disposed in an overlapping region of the first body and the second body; The magnetic body is spaced apart from the magnetic body by a predetermined gap horizontally in the stretching direction of the first body and the second body, and is disposed to be relatively movable along the stretching direction of the first body and the second body with respect to the magnetic body. A magnetic force generating unit for generating; A first friction member coupled integrally with any one of the magnetic body and the magnetic force generating unit and frictionally contacting any one of the first body and the second body with a greater frictional force than the suction force between the magnetic body and the magnetic force generating unit; The first friction member is moved when the first body or the second body is moved more than a predetermined distance by being disposed on both sides of the first friction member in the stretching direction of the first body and the second body, respectively. Damper using a magnetic force, characterized in that it comprises a pressing unit to be. The method of claim 1, The first friction member is integrally coupled to the circumference of the magnetic body is a damper using a magnetic force, characterized in that the first body in friction contact with. The method of claim 1, Interposed between the first body and the second body and having a frictional force less than a difference between a frictional force of the first friction member and a suction force between the magnetic body and the magnetic force generating unit, and any one of the first body and the second body; Damper using a magnetic force, characterized in that it further comprises a frictional contact second friction member. The method of claim 3, The second friction member is a damper using a magnetic force, characterized in that coupled to the second body integrally. The method according to any one of claims 1 to 4, The magnetic force generating unit is a damper using a magnetic force, characterized in that it comprises a core disposed with a predetermined gap with the magnetic body, and a coil arranged to generate a magnetic force on the core. The method according to any one of claims 1 to 4, The magnetic force generator is a damper using a magnetic force, characterized in that it comprises a permanent magnet. The method of claim 6, The permanent magnet damper using a magnetic force, characterized in that composed of a plurality of spaced apart at a predetermined distance along the stretch direction of the first body and the second body. The method of claim 7, wherein The magnetic material is a damper using a magnetic force, characterized in that the protrusions protruding toward the permanent magnet in the transverse direction of the first body and the second body corresponding to each of the permanent magnets are formed. The method of claim 8, Damper using a magnetic force, characterized in that further comprising an iron core made of a magnetic member for passing through the shaft center of each of the permanent magnets integrally connecting the pressing portions disposed on both sides of the magnetic body. The method of claim 9, The distance between the magnetic body and the pressing portion is equal to or less than the separation distance along the stretching direction of the first body and the second body of the protrusion, and the length along the stretching direction of the permanent magnet is the separation distance along the stretching direction of the protrusion. A damper using a magnetic force, characterized by having the following. A case forming an accommodation space therein; A tub accommodated in the case to accommodate washing water; One side between the case and the tub is connected to any one of the case and the tub and the other side to form an open receiving space, the other side is accommodated overlapping along the longitudinal direction inside the first body The other side includes a second body connected to the other of the case and the tub, a magnetic body disposed in an overlapping region of the first body and the second body, and the magnetic body and a predetermined gap horizontally in the longitudinal direction of the first body. The first body having a frictional force greater than the magnetic force generating portion and the magnetic force generating portion for generating a magnetic force and the magnetic body and the magnetic force generating portion integrally coupled to the suction force between the magnetic body and the magnetic force generating portion Or each of the first friction member in frictional contact with any one of the second bodies, and on both sides of the first friction member along the stretch direction of the first body and the second body. Washing machine having a damper using a magnetic force, characterized in that it comprises a damper having a pressing portion to be spaced apart a predetermined distance and the first friction member is moved when the first body or the second body is moved more than a predetermined distance . The method of claim 11, The first friction member is integrally coupled to the circumference of the magnetic body to be in frictional contact with the first body, interposed between the first body and the second body, and the frictional force of the first friction member and the magnetic body and the magnetic force. Washing machine having a damper using a magnetic force, characterized in that it further comprises a second friction member in friction contact with any one of the first body or the second body having a frictional force less than the difference in suction force between the generator. The method according to claim 11 or 12, wherein The magnetic force generating unit is a washing machine having a damper using a magnetic force, characterized in that it comprises a core disposed with a predetermined gap with the magnetic body, and a coil arranged to generate a magnetic force on the core. The method according to claim 11 or 12, wherein The magnetic force generating unit is provided with a damper using a magnetic force, characterized in that it comprises a permanent magnet.