DE102005032499B4 - Damper for vibration damping and thus equipped washing machine - Google Patents

Abstract

A damper (600, 600a, 600b, 600c) comprising:
a damper cylinder (610);
a shaft (620) inserted into the damper cylinder (610) through one end of the damper cylinder and reciprocating in the longitudinal direction of the damper cylinder; and
a friction member (630) provided on the shaft (620) for damping vibration by friction with the inner wall of the damper cylinder (610) that is perpendicular to the longitudinal direction of the damper cylinder;
the shaft (620) including a friction force adjusting device for moving the friction member (630) to adjust the friction force between the friction member and the inner wall of the damper cylinder (610),
the friction force adjusting device includes a pressure unit (640) for pressurizing the friction member (630) to cause the friction member to move to a predetermined distance from the inner wall of the damper cylinder (610),
wherein the printing unit (640) includes:
a first pressure element (641);
a second pressure element (642) provided on one side of the first pressure element and opposite to the first one.

Description

BACKGROUND OF THE INVENTION

Field of the invention

The present invention relates to a damper for vibration damping, and more particularly, to a damper whose damping force is adjustable and to a washing machine equipped with the same. A damper according to the preamble of claim 1 is known from DE 30 16 915 A1 known.

Discussion of the related art

in the Generally leads a washing machine washing, rinsing and dehydration processes by putting the bottom part of the inside of a tub of water and Detergent filled, the laundry placed in a drum installed in the tub and the drum in Rotation is offset.

A Such a washing machine is a device for removing dirt from underwear Use of a suitable detergent and mechanical force.

Accordingly The washing machine usually includes a housing that looks like the outside forms an outer im Housing provided Tub for holding wash water and an inner tub that is rotatable in the outer tub for receiving the laundry is arranged.

Especially is a washing machine in which a rotating shaft of the inner Tub runs approximately horizontally to the ground, as a drum washing machine designated.

How out 1 is apparent, the drum washing machine is a device for removing dirt from laundry by a drum is rotated using the driving force of a motor, under the condition that detergent, washing water and laundry are in the drum, which is horizontal to the bottom of a Housing is installed. The drum washing machine minimizes interlocking and damage of the laundry, consumes a small amount of washing water and has the effects of washing and washing.

In particular, the drum type washing machine has the outer appearance forming case 10 , one in the housing 10 provided tub 20 and those in the tub 20 rotatably arranged drum 30 on.

An opening for inserting the laundry into the housing 10 is through the front surface of the case 10 formed and a door 11 for opening and closing the opening is attached to the opening.

A rotation device 40 , such as a motor, for rotating the drum 30 is at the back of the tub 20 Installed.

The tub 20 is horizontal in the housing 10 by suspension springs 50 for connecting the upper floor of the housing 10 and the upper part of the tub 20 installed and a damper 60 for connecting the bottom of the housing 10 and the lower part of the tub 20 is in the lower part of the case 10 Installed.

The damper 60 is a unit for damping the vibration of the tub 20 caused by the rotation of the drum 30 is produced. The damper 60 typically includes a damper cylinder of cylindrical shape, a shaft inserted and reciprocated into the damper cylinder, and a friction element secured to the shaft.

The friction element reduces the vibration of the tub 20 due to friction with the damper cylinder.

The above drum washing machine performs successively or selectively washing, rinsing and dehydration operations, causing the laundry is washed.

When the dewatering process of the drum washing machine is started, the drum becomes 30 from the rotary device 40 rotated at high speed, whereby the laundry is deprived of the water.

In the initial stage of the dehydration process, ie at the beginning of the drive of the rotary device 40 and the drum 30 , the tub will 20 subjected to extreme vibration (hereinafter referred to as "extreme vibration condition").

If the rotational speeds or spin speeds of the rotary device 40 and the drum 30 gradually increase, the vibration of the tub 20 gradually reduced.

When is the rotation device 40 and the drum 30 reach normal spin speeds, has the vibration of the tub 20 is greatly decreased in comparison to the initial stage of the dehydration process and is stabilized to reach a state of normal vibration.

The shaft of the damper 60 moves in the longitudinal direction of the damper cylinder in Dämpferzy linder by the vibration of the tub 20 back and forth and the friction element moves back and forth along with the reciprocation of the shaft and rubs against the inner wall of the damper cylinder.

The vibration of the tub 20 is damped by the frictional force between the friction member and the damper cylinder.

Hereinafter, the relationship between the number of vibrations of the tub and the spin speed of the drum and the relationship between the vibration transmission force (hereinafter referred to as TR force) of the damper and the spin speed of the drum according to the change of the damping force of the damper based on 2 and 3 described.

Here is 2 a graph illustrating the relationship between the number of vibrations of the tub and the spin speed of the drum according to the change of the damping force, and 3 FIG. 12 is a graph illustrating the relationship between the TR force of the damper and the spin speed of the drum according to the change of the damping force.

Regarding 2 vibrate when the spin speed of the drum 30 in the initial stage of the dehydration process is less than a predetermined value (ω ₁ ), the tub 20 on which a damper with high damping capacity is attached, and the tub 20 with a damper with low damping capacity, as in the graph of 2 is shown. The number of vibrations of the tub 20 are approximately the same after the state of extreme vibration, that is, in the state of normal vibration, regardless of the damping forces of the dampers.

If further, with reference to 3 , the dewatering process is continued so that the number of rotations of the motor, ie the number of rotations of the drum 30 exceeds a predetermined value (ω ₁ ), reaches the tub 20 the state of normal vibration.

If the tub 20 from the damper with low damping force in the state of normal vibration of the tub 20 is stored, the transmitted to a main body of the washing machine by the damper with low damping force TR force is kept below a predetermined level. If, on the other hand, the tub 20 is stored by the damper with high damping force, the TR force increases over time, whereby vibration and noise are continuously amplified.

Consequently So is in the state of extreme vibration of the tub, d. H. in the initial stage of the dehydration process, the damper with the high damping force advantageous for damping the vibrations and noises. Further, in the state of normal vibration of the tub, the damper with low damping force advantageous.

As a result, is the development of a damper for effective vibration damping using the variation of the damping force according to Extent of Vibration of an object to be vibrated, such as the tub of a washing machine, has become necessary.

SUMMARY OF THE INVENTION

Corresponding the present invention is directed to a damper for vibration damping and a washing machine with the same directed to essentially one or more problems due to the limitations and disadvantages of the related art to avoid.

A Object of the present invention is to provide a damper with a structure for minimizing vibration transmission and a washing machine equipped with the same.

Further Advantages, objects and features of the invention are partially in The following description sets forth and in part will become apparent to those of ordinary skill in the art during the exam of the following obvious or in the practical Realization of the invention. The goals and other benefits of Invention can be characterized by the particular in the written description and the claims as well as in the accompanying drawings highlighted structure realize and achieve.

Around to achieve these goals and other benefits and in accordance with the purpose of the invention as embodied herein and in detail is described a damper a damper cylinder; one in the damper cylinder through one end of the damper cylinder introduced Shank extending in the longitudinal direction of the damper cylinder moved back and forth; and a friction element, which on the shaft for vibration damping by Friction with the inner wall of the damping cylinder and by a movement perpendicular to the longitudinal direction of the damping cylinder is provided.

Preferably the shaft can be a setting device for the Contain frictional force to move the friction element to the Friction force between the friction element and the inner wall of the damping cylinder adjust.

More preferably, the friction force adjuster may include a pressure unit to which the friction element is pressurized is to move the friction element to a predetermined distance in the direction of the inner wall of the damping cylinder.

The Pressure unit contains a first pressure element, a second pressure element, which on a Side of the first pressure element and provided opposite the is positioned first printing element, and an interval adjusting device for moving at least one of the first and second printing elements in the axial direction of the shaft to move the friction member.

If the first and second pressure elements are close to each other takes the friction force between the friction element and the inner wall of the damper cylinder to.

Out For this reason, the first and second pressure element in the axial direction of the shaft and at least either the first or the second Contains pressure element at least one inclined section going inward to the other of either the first or second printing element is inclined.

For example is the side surface at least either the first or the second element inclined so that its Cross-sectional area in nearby of the other first or second element is reduced.

Preferably the printing unit may further comprise at least one sliding element, which is provided in the friction member to the inclined portion to correspond and move outward along the inclined portion, to exert pressure on the friction element when the first and second Pressure element lie close to each other.

The Friction element moves to the middle of the shaft and is moved by the Inner wall of the damper cylinder separated when the first and second pressure element away from each other are.

Preferably For example, the sliding member may include an elastic member to the Frictional element attributed to the center of the shaft, when the first and second Pressure element are removed from each other.

The elastic element is ring-shaped and on the outer cylinder surface of the Sliding element arranged.

In in the case where the printing unit includes a plurality of sliding members the printing unit also guide ribs included on the outer cylinder surface at least are provided either of the first or the second pressure element, around the concentrated movement of the sliding elements in the circumferential direction to prevent.

The Intervalseinstellvorrichtung shifts the second pressure element.

The Intervalseinstellvorrichtung contains at least one connecting rod, the first on the body the shaft attached pressure element extends and with the second pressure element is connected, and a drive unit for driving the connecting rod, to move the second pressure element.

The Drive unit can move the connecting rod straight to to move the second pressure element.

The Drive unit contains an electromagnet on the other side of the first pressure element is arranged to the connecting rod by means of magnetic force rectilinear to move, so that the second pressure element to the first pressure element moved when a current flows.

The Connecting rod contains a metal element disposed between the first pressure element and the Electromagnet is arranged.

The Drive unit contains one connected to the connecting rod wire and one with the Wire connected actuator.

The Drive unit contains a motor to rotate the connecting rod, and the second pressure element is rectilinear by the rotation of Connecting rod moves.

The Connecting rod runs through the second pressure element and is by means of screws with the connected to the second pressure element.

The Printing unit may further include a guide pin included, one of which end in the first pressure element and the other End is inserted into the second pressure element to the movement of the second To lead pressure element.

alternative For example, the interval setting device may be one at the first printing element arranged electromagnets, one on the second pressure element arranged metal element and one through the second pressure element extending guide rod, to guide the movement of the second pressure element.

Preferably, the guide rod may include a stopper, one end of which is connected to one side of the electromagnet, and the other end prevents the second pressure member ment is separated from the guide rod.

The Friction element can be annular his and the outer cylindrical surface surrounded by the shaft.

Further For example, the friction element may be made of an elastic material consist.

The Frictional element contacts the inner wall of the damper cylinder when the number the vibration of an object to be vibrated is larger as a predetermined value, and is from the inner wall of the damper cylinder disconnected if the number of vibrations of the object is smaller as the default value.

If the spin speed of an object to produce the vibration is higher as a given speed, the friction force between the Friction element and the inner wall of the damper cylinder less than when the spin speed of the object is lower than the predetermined one Rotation speed.

Either the damper cylinder or the shaft is connected to a tub of a washing machine and the other of the damper cylinder or the shaft is connected to a housing of the washing machine.

It It is understood that both the above general description and also the following detailed description of the present invention exemplary and explanatory are and intend to further explain the claimed invention to deliver.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are included in order to better understand the To provide invention, and incorporated in this application and form part of the same, constitute (an) embodiment (s) of the invention and together with the description serve to explain the principle of the invention; show it:

1 a schematic sectional view of a conventional drum washing machine;

2 a graph illustrating the relationship between the number of vibrations of a tub and the spin speed of a drum according to the change of the damping capacity;

3 a graph illustrating the relationship between the TR force of a damper and the spin speed of the drum according to a change in the damping capacity;

4 a sectional view of a damper according to a first embodiment of the present invention;

5A and 5B a partial and longitudinal sectional view and a cross-sectional view of a friction element of in 4 illustrated damper, which is separated from the inner wall of a damper cylinder;

6A and 6B a partial and longitudinal sectional view and a cross-sectional view of the friction element of in 4 illustrated damper, which contacts the inner wall of the damper cylinder;

7 a sectional view of an embodiment of a pressure unit of the damper of the present invention;

8th a perspective view of another embodiment of the pressure unit of the damper of the present invention;

9A and 9B Sectional views of a damper according to a second embodiment of the present invention;

10A and 10B Sectional views of a damper according to a third embodiment of the present invention; and

11A and 11B Sectional views of a damper according to a fourth embodiment of the present invention.

DETAILED DESCRIPTION THE INVENTION

On the preferred embodiments the present invention, in the accompanying drawings by way of example, reference will now be made in detail.

Where always possible is, become the same or similar Parts over all drawings with identical reference numerals.

First, based on the 4 to 8th a damper according to a first embodiment of the present invention is described.

4 Fig. 10 is a sectional view of the damper according to the first embodiment of the present invention. The 5A and 5B are a partial and longitudinal sectional view and a cross-sectional view of a friction element of the in 4 Darge placed damper, which is separated from the inner wall of a damper cylinder. The 6A and 6B are a partial and longitudinal sectional view and a cross-sectional view of the friction element of in 4 shown damper, which contacts the inner wall of the damper cylinder. 7 Fig. 10 is a sectional view of another embodiment of a pressure unit of the damper of the present invention. 8th Fig. 15 is a perspective view of still another embodiment of the pressure unit of the damper of the present invention.

Of the damper of the present invention which will be described below generally in washing machines or devices that vibration produce, and be used in the above drum washing machine. In the following description of the present invention is based on a detailed description of known functions and configurations a washing machine in which the damper of the present invention is used, dispensed and the same or similar elements of the washing machine are denoted by reference numerals identical to those of usual the damper used washing machine.

First of all, with reference to 4 , includes the damper 600 According to the first embodiment of the present invention, a damper cylinder 610 , one in the damper cylinder 610 inserted shaft 620 and one on the shaft 620 provided friction element 630 ,

The damper cylinder 610 has a hollow cylindrical structure. An end of the shaft 620 is in an open end of the damper cylinder 610 introduced, and the shaft 620 moves in the longitudinal direction of the damper cylinder 610 back and forth when the tub 20 is put into vibration.

The other end of the damper cylinder 610 is here with the lower part of the tub 20 connected and the other end of the shaft 620 is with the bottom of the case 10 connected to the tub 20 to absorb generated vibration.

Alternatively, the other end of the damper cylinder 610 with the bottom of the case 10 be connected, and the other end of the shaft 620 can with the lower part of the tub 20 get connected.

In the following, to simplify the description, the damper 600 with an upper section 610a that with the lower part of the tub 20 connected, and a lower section 610b that with the bottom of the case 10 is connected described.

The friction element 630 is perpendicular to the longitudinal direction of the damper cylinder 610 Movable and dampens the vibration of the tub 20 by the friction with the inner wall of the damper cylinder 610 ,

Accordingly, the shaft contains 620 a device for adjusting the friction force, the friction force between the friction element 630 and the inner wall of the damper cylinder 610 by moving the friction element 630 adjust.

The friction force adjusting apparatus will be described below with reference to FIGS 5A and 5B such as 6A and 6B described in more detail. The device for adjusting the frictional force of the damper 600 The first embodiment includes a printing unit 640 to the friction element 630 to the inner wall of the damper cylinder 610 to press to the friction element 630 by a predetermined path in the direction of the inner wall of the damper cylinder 610 to move.

In this embodiment, the printing unit includes 640 a first pressure element 641 , a second pressure element 642 on one side of the first pressure element 641 is provided, and an interval adjusting device for adjusting the distance between the first pressure element 641 and the second pressure element 642 ,

The first printing element 641 is at one end of the shaft 620 ie the upper end of the shaft 620 , provided and the second pressure element 642 is above the first pressure element 641 arranged so that the second pressure element 642 opposite the first pressure element 641 is positioned.

As a result, the first pressure element 641 and the second pressure element 642 in the axial direction of the shaft 620 , ie arranged in the longitudinal direction.

The interval setting device moves at least either the first pressure element 641 or the second pressure element 642 in the axial direction of the shaft 620 to the distance between the first pressure element 641 and the second pressure element 642 adjust, whereby the friction element 630 with the inner wall of the damper cylinder 610 is brought into contact with a given force.

In this embodiment, the first pressure element 641 on a body of the shaft 620 attached and the second pressure element 642 is on the body of the shaft 620 mounted so that the second pressure element moves in the vertical direction. Therefore, the friction force between the friction member decreases 630 and the inner wall of the damper cylinder 610 to when the first Druckele ment 641 and the second pressure element 642 lie close to each other.

Alternatively, the second pressure element 642 on the body of the shaft 620 attached and the first pressure element 641 on the body of the shaft 620 be attached so that the first pressure element 641 moved in the vertical direction.

Although this embodiment is the first pressure element 641 and the second pressure element 642 at the top of the body of the shaft 620 are arranged, are the positions of the first pressure element 641 and the second pressure element 642 not limited to this.

At least either contains the first pressure element 641 or the second pressure element 642 at least one inclined portion facing inward to the other of the first first pressing member 641 or the second pressure element 642 is inclined.

For example, a plurality of inclined portions extending from the lower part of the first pressure element 641 to the upper part of the first pressure element 641 are inclined inwards, on the lateral surface of the first pressure element 641 be formed so that the inclined portions are spaced at the same interval in the circumferential direction. A plurality of inclined portions of symmetrical shape to the inclined portions of the first pressure element 641 can on the side surface of the second pressure element 642 be formed.

In this embodiment, the first pressure element 641 a shape such that the cross-sectional area of the first pressure element 641 from its lower portion to its upper portion to which the second pressure element 642 is provided, decreases, and a side surface which is inclined inwardly from its lower portion to its upper portion. The second pressure element 642 is symmetrical to the first pressure element 641 , Accordingly, the inclined sections 641a respectively. 642a on the side surfaces of the first and second pressure members 641 respectively. 642 educated.

Although not shown in the drawings, either only the first pressure element 641 or only the second pressure element 642 have the above form.

Here are the vertical cross sections of the inclined sections 641a and 642a have different shapes, such as straight and concave shapes. 7 shows an embodiment of the printing unit, wherein the first and second pressure element 741 and 742 inclined sections 741a and 742a have, whose cross-sections have a concave shape.

Preferably, in the friction element 630 at least one sliding element 643 provided to the friction element 630 to move outward, leaving the inclined section 641a of the first pressure element 641 with the inclined section 642a of the second pressure element 642 matches.

Each of the sliding elements 643 contains upper inclined planes that coincide with the sloped sections 642a of the second pressure element 642 match, and lower inclined planes, with the inclined sections 641a of the first pressure element 641 to match.

So if accordingly the first pressure element 641 and the second pressure element 642 Close to each other, the lower and upper inclined planes of the sliding elements become 643 through the inclined sections 641a of the first pressure element 641 and the inclined sections 642a of the second pressure element 642a pressurized.

In particular, slide when the first pressure element 641 and the second pressure element 642 Close to each other, the lower and upper inclined planes of the sliding elements 643 along the inclined sections 641a of the first pressure element 641 and the inclined sections 642a of the second pressure element 642 ,

As a result, the sliding elements move 643 outward to the inner wall of the damper cylinder 610 towards and on the inner surface of the friction element 630 Pressure off, causing the friction element 630 with the inner wall of the damper cylinder 610 is brought into contact with a given force.

Preferably, the inclined portions 641a of the first pressure element 641 , the inclined sections 642a of the second pressure element 642 and the upper and lower inclined planes of the sliding elements 643 made of a material having a smoother surface than the friction element 630 and the inner wall of the damper cylinder 610 ,

When the first pressure element 641 and the second pressure element 642 away from each other, ie, when the second pressure element 642 moved upward, preferably moves the friction element 630 to the middle of the shaft 620 , As a result, the frictional force between the friction element decreases 630 and the inner wall of the damper cylinder 610 Gradually, so that the damping capacity of the damper 600 is reduced.

Preferably, at least one sliding element contains 643 an elastic element 643a to the friction element 630 to the middle of the shaft 620 attributed when the first pressure element 641 and the second pressure element 642 away from each other.

The elastic element 643a For example, it may be an annular metal spring or a rubber band attached to the outer cylindrical surface of the slider 643 is arranged.

A groove 643b is in the outer cylindrical surface of the slider 643 formed in the circumferential direction and the annular elastic element 643a gets into the groove 643b inserted.

When in the friction element 630 a plurality of the sliding elements 643 are provided, as in 8th shown, guide ribs 641b for preventing the concentrated movement of the sliding elements 643 in the circumferential direction in the outer cylindrical surface of at least one of the first pressure member 641 or the second pressure element 642 educated.

The guide ribs 641b are preferably separated equidistantly in the circumferential direction of each other. This makes it possible to find the right distance between the sliding elements 643 observed.

The of the sliding elements 643 pressurized and displaced friction elements 630 can be in the same number as the sliding elements 643 or may be an annular elastic member forming the outer cylindrical surface of at least one sliding member 643 surrounds, as will be described in this embodiment.

The interval adjusting device of the damper of the first embodiment moves the second pressing member as described above 642 in the direction of the first pressure element 641 ,

For this purpose, the interval adjusting device includes connecting rods 644 extending through the first pressure element 641 extend and move vertically, and a drive unit for driving the connecting rods 644 ,

Upper ends of connecting rods 644 are with the second pressure element 642 connected and move vertically along guide holes 641c passing through the first pressure element 641 are formed. When the connecting rods 644 move straight up or down, moves the second pressure element 642 down or up.

Accordingly, the friction element becomes 630 from the sliding elements 643 pressurized and moves to the inner wall of the damper cylinder 610 towards or in the opposite direction. This will cause the frictional force between the friction element 630 and the inner wall of the damper cylinder 610 set.

In this embodiment, the drive unit of the interval adjusting device moves the connecting rods 644 by magnetic force.

In particular, the drive unit includes an electromagnet 645 that under the first pressure element 641 is provided.

The electromagnet 645 moves the connecting rods 644 by means of magnetic force straight down, so that the second pressure element 642 to the first pressure element 641 is shifted when a current flows.

For this purpose, the electromagnet contains 645 one in the upper part of the shaft 620 installed core 645a , a bobbin 645b that's outside the core 645a is installed and a winding (not shown) with several turns around the bobbin 645b , When electricity to the electromagnet 645 is supplied to generate magnetic force, the connecting rods 644 by the magnetic force of the electromagnet 645 pulled down.

Preferably, each of the connecting rods includes 644 a metal element 644a , which at its lower end between the first pressure element 641 and the electromagnet 645 is formed.

The first printing element 641 is at the core 645a attached. In particular, the first pressure element contains 641 a fixing rod 641d moving through the metal elements 644a the connecting rods 644 extends and its lower end to the core 645a connected is.

The friction element 630 contacts the inner wall of the damper cylinder 610 by the above-described frictional force selective device.

That means that when the tub 20 is in the state of extreme vibration, the friction element 630 the inner wall of the damper cylinder 610 touches the damping force of the damper 600 to increase. If then the tub 20 reaches the state of normal vibration, becomes the friction element 630 from the inner wall of the damper cylinder 610 separated to the damping capacity of the damper 600 to reduce.

in the Following is a process for damping the vibration of a washing machine using the above damper the present invention described.

First, put the rotation device 40 at startup of the washing machine the drum 30 in rotation and the laundry is through the rotation of the drum 30 washed.

Then the tub 20 by the rotation of the rotary device 40 and the drum 30 vibrated.

This will cause the vibration of the tub 20 through the damper 600 damped and the transmission of vibration of the tub 20 to the housing 10 is minimized.

When the dehydration process for the laundry is started, the tub experiences 20 extreme vibration in the initial stage of the dehydration process.

In the state of extreme vibration of the tub 20 becomes the electromagnet 645 energized to generate a magnetic force, and the metal elements 644a attached to the lower parts of the connecting rods 644 are installed, move by the magnetic force in the direction of the electromagnet 645 ,

At the same time, the second pressure element moves 642 with the upper ends of the tie rods 644 is connected, down and the sliding elements 643 be through the first pressure element 641 and the second pressure element 642 subjected to force, so that the sliding elements 643 to the inner wall of the damper cylinder 610 move.

Accordingly, the friction element 630 through the sliding elements 643 Pressure exerted, leaving it the inner wall of the damper cylinder 610 contacted and the vibration of the tub 20 by the frictional force between the friction element 630 and the inner wall of the damper cylinder 610 is dampened.

When the dehydration process lasts for a predetermined time, so that the spin speed of the engine 40 rotated drum 30 is higher than a predetermined speed, reaches the tub 20 the state of normal vibration.

When in the state of normal vibration of the tub 20 the friction element 630 with the same force as in the state of extreme vibration to the inner wall of the damper cylinder 610 is pressed, the vibration of the tub 20 that over the damper 600 to the housing 10 the washing machine is transmitted, still reinforced.

Accordingly, if the tub 20 reaches the state of normal vibration, the electromagnet 645 not energized, causing the on the metal elements 644a acting magnetic force is eliminated.

As a result, the force for pressurizing the friction element 630 that is outside the sliding elements 643 is provided, eliminated and the sliding elements 643 be through the elastic elements 643a , which are provided on the outer cylindrical surfaces of the sliding elements, in their initial positions to the center of the shaft 620 recycled. Furthermore, the friction element pulls 630 elastically together and moves to its original position, ie to the center of the shaft 620 ,

This means that the friction element 630 from the inner wall of the damper cylinder 610 separated, a predetermined distance (t) between the friction element 630 and the inner wall of the damping cylinder 610 formed and the TR force of the pan 20 on a structure of the washing machine, in particular the housing 10 , through the damper 600 is reduced. Thus, the dehydration process runs quietly and evenly.

So the above damper 600 can operate in the optimum state, preferably a vibration sensor device (not shown) for detecting the vibration of the tub 20 and a control unit (not shown) for controlling the damper 600 according to the vibration condition of the tub 20 installed at predetermined positions of the washing machine.

When the vibration sensor device detects the vibration of the washing machine and sends a signal to the control unit, the control unit controls the to the electromagnet 645 supplied power, reducing the damping capacity of the damper 600 is set.

Otherwise, another method for adjusting the damping force of the damper 600 be applied. In this method, a period of time until reaching the state of normal vibration of the tub 20 is required, entered in advance in the control unit. Before the tub 20 reaches the state of normal vibration, electricity becomes the electromagnet 645 delivered to the damping force of the damper 600 increase, and after the tub 20 has reached the state of normal vibration, no current to the electromagnet 645 delivered to the damping capacity of the damper 600 to reduce.

In the following, damper according to their embodiments of the present invention with reference to the 9A to 11B described.

Some Parts of the dampers these embodiments, which are substantially the same as those of the damper of the first embodiment, are denoted by identical reference numerals even if they shown in various drawings, and on a detailed Description is therefore omitted because it is considered unnecessary.

First, a damper 600a according to the second embodiment of the present invention with reference to FIGS 9A and 9B described.

With reference to the 9A and 9B , points the damper 600a a connecting rod 744 on, extending through the first pressure element 641 and the second pressure element 642 extends and moves in the vertical direction.

For this purpose, guide holes (not shown) are vertically formed respectively through central portions of the first and second pressing members 641 and 642 educated.

The diameter of the first and second pressure element 641 and 642 formed guide holes here is larger than that of the connecting rod 744 ,

The lower end of the connecting rod 744 is with an actuator (not shown) and with a wire 745 connected to the connecting rod 744 to pull down.

A head 744a with a larger diameter than that of the guide hole of the second pressure member 642 is at the top of the connecting rod 744 educated.

If the wire 745 Pull on the connecting rod 744 by the drive of the actuator, accordingly, the upper surface of the second pressure element 642 through the head 744a pressurized, so that the second pressure element 642 moved down.

Then the sliding elements 643 through the first pressure element 641 and the second pressure element 642 pressurized, slide along the inclined sections 641a and 642a the first and second pressure element 641 and 642 outwards and push the friction element 630 to the inner wall of the damper cylinder 610 out.

The connecting rod 744 can on the second pressure element 642 be attached. In this case, contains the connecting rod 744 the head 744a Not.

Other configurations and functions of the damper 600a are substantially the same as those of the damper of the first embodiment, and a detailed description will be omitted because it is not considered necessary.

The following is a damper 600b according to the third embodiment of the present invention with reference to FIGS 10A and 10B described.

With reference to the 10A and 10B , points the damper 600b a connecting rod 844 on, extending through the first pressure element 641 extends and with the second pressure element 642 connected to the second pressure element 642 to move in a vertical direction.

More specifically, the connecting rod extends 844 perpendicular through the second pressure element 642 ,

For this purpose, vertical guide holes (not shown) are respectively through central portions of the first and second pressing members 641 and 642 educated.

In particular, an internal screw thread is in the guide hole of the second pressure element 642 formed and a female screw thread corresponding to the female screw thread is in the outer cylindrical surface of the connecting rod 844 educated. The internal screw thread of the guide hole of the second pressure element 642 stands with the male screw thread of the outer cylinder surface of the connecting rod 844 engaged.

The connecting rod 844 is powered by a rotary device, such as a motor 845 set in rotation.

Although in this embodiment the engine 845 under the first pressure element 641 is shown provided is the position of the motor 845 not limited to this. The motor 845 can z. B. on the inside of the first pressure element 641 be attached.

Although the connecting rod 844 directly with a rotating shaft (not shown) of the engine 845 is connected, the connection method of the connecting rod 844 not limited to this. The connecting rod 844 For example, with the rotating shaft of the engine 845 be connected by a belt.

To prevent the first pressure element 641 through the connecting rod 844 is affected when the connecting rod 844 through the engine 845 is rotated, the diameter of the through the first pressure element 641 formed through guide holes preferably larger than the diameter of the connecting rod 844 ,

The first printing element 641 and the second pressure element 642 are through a guide pin 846 connected, one end of which is in the first pressure element 641 and its other end in the second pressure element 642 is introduced.

For this purpose, a first groove (not shown) having a predetermined depth into which the lower end of the guide pin 846 is introduced, in the upper surface of the first pressure element 641 formed and a second groove (not shown) having a predetermined depth, in which the upper end of the guide pin 846 is introduced in the lower surface of the second pressure element 642 educated.

Preferably, the diameter of at least one of the first and second grooves is greater than that of the guide pin 846 ,

The guide pin 846 leads the vertical movement of the second pressure element 642 while preventing the second pressure element 642 along with the rotation of the connecting rod 844 is turned.

When the connecting rod 844 turns in one direction, becomes the second pressure element 642 accordingly not by the guide pin 864 but moves up or down, ie straight in the longitudinal direction of the damper cylinder 610 ,

As described for the damper of the first embodiment, the frictional force between the friction member becomes 630 and the inner wall of the damper cylinder 610 by the vertical movement of the second pressure element 642 set.

Other configurations and functions of the damper 600b are substantially the same as those of the damper of the first embodiment, and a detailed description will be omitted because it is not considered necessary.

The following is a damper 600c according to the fourth embodiment of the present invention with reference to FIGS 11A and 11B described.

With reference to the 11A and 11B , the second pressure element moves 642 of the damper 600c by the magnetic force of an electromagnet 945 in a similar way to the damper 600 the first embodiment.

In particular, the damper contains 600c at the first pressure element 641 provided electromagnet 945 and a first one on the second pressure element 642 provided metal element 946 ,

The electromagnet 945 here extends through the first pressure element 641 , so that the surface of the upper end of the electromagnet 945 with the surface of the upper end of the first pressure element 641 coincides.

The electromagnet 945 contains a nucleus 945a which is attached to a body of the shaft 620 is arranged, a bobbin 945b that's outside the core 945a is installed and a winding (not shown) with several turns around the bobbin 945b ,

Although the core 945a of the damper 600c this embodiment at the upper end of the body of the shaft 620 is attached, is the position of the core 945a not limited to this.

The electromagnet 945 also includes a second metal element 945c that the outer cylindrical surface of the bobbin 945b surrounds with the winding wound on it.

The second metal element 945c Evenly distributes the magnetic force generated at a current flowing along the winding, and improves the magnetic force of the electromagnet 945 ,

The first metal element 946 serves to the second pressure element 642 to the first pressure element 641 to move when electricity through the electromagnet 945 flows.

For this reason, the first metal element 946 preferably on the second pressure element 642 attached. Even more preferred is the first metal element 946 at the lower part of the second pressure element 642 attached.

To the vertical movement of the second pressure element 642 to guide according to the power supply of the electromagnet or the disconnected power supply, is a guide rod 944 provided so by the second pressure element 642 that extends one end of the guide rod 944 with one end of the electromagnet 945 connected is.

In particular, the guide rod runs 944 perpendicular through the central section of the second pressure element 642 so that the lower end of the guide rod 944 at the core 945a of the electromagnet 945 is attached.

To the second pressure element 942 to move smoothly, is preferably a guide hole through which the guide rod 944 passes through the second pressure element 642 educated. The guide hole has a larger diameter than the guide rod 944 ,

Preferably, a stop 944a on the guide rod 944 formed to a separation from the second pressure element 642 to prevent.

The stop 944a is at the other end of the guide bar 944 ie at the top of the guide bar 944 , provided and has a larger diameter than the guide hole.

When the power supply to the electromagnet 945 is switched off, is accordingly the second pressure element 642 due to the friction element 630 acting force from the first pressure element 641 removed, and a predetermined distance between the second pressure element 642 and the first pressure element 641 gets through the stop 944a respected. That is, the second pressure element 642 moves upwards by a predetermined distance and then stops 944a stopped.

Other configurations and functions of the damper 600c are substantially the same as those of the damper of the first embodiment, and a detailed description will be omitted because it is not considered necessary.

Even though the above embodiments the friction element is separated in the state of normal vibration of the tub from the inner wall of the damper cylinder illustrate, the position of the friction element is not on it limited.

The is called, that according to the vibration characteristics of one in vibration object to be displaced, the friction element, the inner wall of the damper cylinder with a small force in the state of normal vibration of the object contrary to the state of extreme vibration of the object can touch.

The Effects of the damper The present invention will be described as follows.

First puts the damper According to the present invention, damping capacity corresponding to the amount of vibration of an object to be vibrated and / or the number of Revolutions of the object, causing a vibration-damping and a noise preventing effect is improved.

Secondly reduces the damper the present invention, the transmission the vibration of the object, causing damage to peripheral components is prevented.

thirdly has the damper the present invention, the simple configuration of a printing unit, To exert pressure on a friction element, making it easy on Make way.

Fourth requires the damper the present invention, no power device to the damping capacity of the damper reduce production costs.

Fifth, reduced or eliminate the damper the present invention, the frictional force between a damper cylinder and the friction member in the state of normal vibration of a tub, thereby the life of the friction element is extended.

For the expert It is obvious that various modifications and changes of can be made without departing from the spirit or the Deviating scope of the invention.

It Thus, it is intended that the present invention be the modifications and changes of this invention, provided they fall within the scope the attached claims and their equivalents.

Claims (22)

Damper ( 600 ; 600a ; 600b ; 600c ), comprising: a damper cylinder ( 610 ); one in the damper cylinder ( 610 ) inserted through an end of the damper cylinder and reciprocating in the longitudinal direction of the damper cylinder shaft ( 620 ); and one on the shaft ( 620 ) provided friction element ( 630 ) for vibration damping by friction with the inner wall of the damper cylinder ( 610 ), which moves perpendicular to the longitudinal direction of the damper cylinder, wherein the shaft ( 620 ) a friction force adjusting device for moving the friction element ( 630 ) in order to reduce the frictional force between the friction element and the inner wall of the damper cylinder (FIG. 610 ), the frictional force adjusting device is a pressure unit ( 640 ) to the friction element ( 630 ) to apply pressure, so that the friction element up to a predetermined distance to the inner wall of the damper cylinder ( 610 ) be moves, whereby the printing unit ( 640 ) contains: a first printing element ( 641 ); a second pressure element ( 642 ) provided on one side of the first pressing member and positioned opposite to the first pressing member; and an interval adjusting device for moving at least one of the first and second pressing members in the axial direction of the shaft (FIG. 620 ) to the friction element ( 630 ) to move; wherein the first and second pressure elements ( 641 . 642 ) in the axial direction of the shaft ( 620 ) and at least one of the first and second pressure members includes at least one inclined portion inclined inwardly to the other of the first and second pressure members, the pressure unit (12) 640 ) at least one sliding element ( 643 ) contained in the friction element ( 630 ) is provided so as to correspond to the inclined portion and to move outwardly along the inclined portion to exert pressure on the friction member when the first and second pressure members (16) 641 . 642 ) are close to each other; characterized in that the printing unit ( 640 ) a plurality of sliding elements ( 643 ), the printing unit further comprises guide ribs ( 641b ) on the outer cylindrical surface of at least one of the first and second pressure elements ( 641 . 642 ) are provided to prevent the concentrated movement of the sliding elements in the circumferential direction. A damper according to claim 1, wherein when the first and second pressure elements ( 641 . 642 ) are close to each other, the frictional force between the friction element ( 630 ) and the inner wall of the damper cylinder ( 610 ) increases. A damper according to claim 1, wherein the lateral surface of at least one of the first and second elements ( 641 . 642 ) is inclined so that the cross-sectional area thereof is reduced in the vicinity of the respective other first or second element. Damper according to claim 1, wherein the friction element ( 630 ) to the middle of the shaft ( 620 ) and from the inner wall of the damper cylinder ( 610 ) is separated when the first and second pressure elements ( 641 . 642 ) are away from each other. A damper according to claim 4, wherein the sliding element ( 643 ) an elastic element ( 643a ) to the friction element ( 630 ) to the middle of the shaft ( 620 ), when the first and second pressure elements ( 641 . 642 ) are away from each other. A damper according to claim 5, wherein the elastic element ( 643a ) has a ring shape and on the outer cylindrical surface of the sliding element ( 643 ) is provided. A damper as claimed in claim 1, wherein the interval setting means comprises the second pressure element (12). 642 ) emotional. A damper according to claim 7, wherein the interval adjusting device comprises: at least one connecting rod ( 644 ; 744 ; 844 ), which is defined by the first one on the body of the stem ( 620 ) attached pressure element ( 641 ) and with the second pressure element ( 642 ) connected is; and a drive unit for driving the connecting rods ( 644 ; 744 ; 844 ) to the second pressure element ( 642 ) to move. A damper according to claim 8, wherein the drive unit is the connecting rod ( 644 ; 744 ) moved in a straight line to the second pressure element ( 642 ) to move. A damper according to claim 9, wherein the drive unit comprises an electromagnet ( 645 ) located on the other side of the first printing element ( 641 ) is provided to the connecting rod ( 644 ) by means of magnetic force to move in a straight line, so that the second pressure element ( 642 ) to the first printing element ( 641 ) moves when a current flows. A damper according to claim 10, wherein the connecting rod ( 644 ) a metal element ( 644a ) between the first printing element ( 641 ) and the electromagnet ( 645 ) is provided. A damper according to claim 9, wherein the drive unit includes: one with the connecting rod ( 744 ) connected wire ( 745 ); and an actuator connected to the wire. A damper according to claim 8, wherein the drive unit is a motor ( 845 ) for turning the connecting rod ( 844 ) and the second printing element ( 642 ) by the rotation of the connecting rod ( 844 ) moved in a straight line. A damper according to claim 13, wherein the connecting rod ( 844 ) by the second pressure element ( 642 ) and is connected by a screw with the second pressure element. A damper according to claim 12, wherein the printing unit further comprises a guide pin ( 846 ), one end of which is in the first pressure element ( 641 ) and the other end in the second pressure element ( 642 ) is introduced to guide the movement of the second pressure element. A damper according to claim 7, wherein the interval setting means comprises: one on the first pressure element ( 641 ) arranged electromagnets ( 945 ): one on the second pressure element ( 642 ) arranged metal element; and a guide rod extending through the second pressure element ( 944 ) to guide the movement of the second pressure element. Damper according to claim 16, wherein the guide rod ( 944 ) a stop ( 944a ), one end of which is connected to one side of the electromagnet ( 945 ) and the other end prevents the pressure element from being separated from the guide bar. Damper according to claim 1, wherein the friction element ( 630 ) has a ring shape which the outer cylindrical surface of the shaft ( 620 ) surrounds. Damper according to claim 18, wherein the friction element ( 630 ) consists of an elastic material. Damper according to claim 1, wherein the friction element ( 630 ) the inner wall of the damper cylinder ( 610 ) is contacted when the number of vibrations of an object to be vibrated is greater than a predetermined value, and is separated from the inner wall of the damper cylinder when the number of vibrations of the object is smaller than the predetermined value. A damper according to claim 1, wherein the frictional force between the friction element (15) 630 ) and the inner wall of the damper cylinder ( 610 ) at a spin speed of an object for generating vibrations higher than a predetermined speed is lower than that when the spin speed of the object is lower than the predetermined speed. Damper according to claim 1, wherein either the damper cylinder ( 610 ) or the shaft ( 620 ) is connected to the tub of a washing machine, and the other of the damper cylinder or shaft is connected to a housing of the washing machine.