JP2019502070A - Drainage control mechanism and washing machine - Google Patents

Abstract

A drainage control mechanism and a washing machine, wherein the drainage control mechanism includes a valve body (301) capable of sealing a drainage port, and a piston rod (302) that drives movement of the valve body (301). (301) and a piston rod (302) are provided with a valve body receiver (304), one end of which is fixedly connected to the valve body (301), and the other end is It is operatively connected to the piston rod (302). When the end of the valve body (301) and the bottom of the inner tub (100) are not parallel, the piston rod (302) and the valve body receiver (304) are operatively connected, so the end of the valve body (301) The angle can be adjusted so that the bottom of the inner tub (100) is brought into close contact. Therefore, it seals reliably, without a clearance gap between a valve body (301) and a drain outlet (101). [Selection] Figure 2

Description

  The present invention relates to the field of washing machines, and more particularly to a drainage control mechanism and a washing machine.

  In the conventional pulsator type washing machine, the inner tub and the outer tub communicate with each other through a water passage hole on the inner tub. Although the inner tank is a washing tank and the outer tank is a water injection tank, the water filled between the inner tank and the outer tank side wall is not used for cleaning, only the water in the inner tank is used for actual cleaning. As a result, a large amount of water resources are wasted. In addition, when there is too much water between the inner tank and the outer tank, the concentration of the liquid detergent / powder detergent in the cleaning liquid may decrease. In addition, since the water flow frequently moves between the inner tank and the outer tank, the region between the inner tank and the outer tank side wall becomes a place for collecting dirt as the use continues. For this reason, scales from tap water, loose substances from powder detergents, cellulose in clothing, organic matter in the human body, and dust and bacteria brought in by clothing are very easily retained between the inner and outer tank side walls. Mold grows because a large amount of dirt accumulated in a washing machine with a long use history is not effectively removed. If these stains that are not visible to the user are not removed, the bacteria will adhere to the clothing after the next wash and bring it to the human body, leading to a situation of cross-infection.

  Patent Document 1 refers to a fully automatic washing machine mainly including a housing, a washing and dewatering tank, a water injection tank, and a driving device. The water injection tank is attached to the outside of the washing and dewatering tank and fixedly connected to the housing. In addition, a sealing device is provided between the bottom surface of the inner wall of the water injection tank and the bottom surface of the outer wall of the washing / dehydrating tank, and a sealing chamber is formed in the sealing device. A through hole is not provided in the outer wall of the washing and dewatering tank, and a drain outlet communicating with the sealed chamber is provided at the bottom. The water injection tank has a drain opening communicating with the drain pipe, and the drain pipe is provided with a drain valve. The water injection tank is fixedly connected to the housing through a suspension rod. One end of the suspension rod is connected to the inner wall of the upper end of the housing, and the other end is connected to the outer wall of the water injection tank. However, during long-term operation, the sealing structure is worn out over long-term operation, and water leakage tends to occur. In addition, when the water quality is poor and the sand content is high, the service life is greatly shortened and the appropriate function cannot be exhibited. In addition, it is not suitable for use when the washing capacity is large, and is not reliable.

  Further, in the conventional research, there is a washing machine in which water is not interposed between the inner tub and the outer tub during cleaning. In this case, a plurality of drain holes are provided near the edge of the upper part of the inner tank, and at least one inner tank drain port is provided at the bottom of the inner tank. A drainage control mechanism capable of sealing the drainage hole is provided at the bottom of the outer tub. The drainage control mechanism includes at least a retractable valve body that moves upward to close the drainage hole and moves downward to open the drainage hole. However, such a drainage control mechanism that controls the drainage of the inner tank is different from the drainage control mechanism that controls the drainage of the outer tank. Although the inner tub is stationary at the time of washing, it rotates during dehydration, so that the thrown-in clothing may be eccentric and the inner tub may be inclined. As a result, a gap is generated in the engagement between the valve body and the inner tank, and sealing of the drain hole may fail.

  In view of the above, the present invention is proposed.

Chinese Patent Application No. 200402107890.8

  An object of this invention is to eliminate the wrinkle in a prior art, and to provide a drainage control mechanism and a washing machine.

  In order to achieve the above object, the present invention uses the following technical solution.

  In a drainage control mechanism including a valve body capable of sealing a drain outlet and a piston rod that drives the movement of the valve body, a valve body receiver is provided between the valve body and the piston rod, and the valve body receiver Is fixedly connected to one of the valve body and the piston rod, and is operably connected to the other of the valve body and the piston rod.

  The valve body receiver is rotatably connected to a piston rod. Preferably, one end of the valve body receiver corresponding to the piston rod is a spherical protrusion, and the valve body receiver corresponds to the valve body receiver of the piston rod. One end is a spherical concave groove, and the spherical protrusion is placed in the spherical concave groove to form a connection that can rotate, or preferably, one end of the valve body receiver corresponding to the piston rod is a spherical surface One end of the piston rod corresponding to the valve body receiver is a spherical protrusion, and a connection that can be rotated is formed by installing the spherical protrusion in the spherical concave groove.

  The center of the spherical protrusion is connected to the center of the spherical groove, and lubricating grease is provided between the spherical protrusion and the spherical groove.

  The piston rod is connected to a drive motor, or the piston rod has a hollow structure, and one end facing the valve body receiver is a sealed end, and a first elastic member is disposed inside the piston rod. The first elastic member has one end connected to the sealed end and the other end connected to the drive motor.

  The piston rod has a hollow structure, and one end facing the valve body receiver is a sealed end, a first elastic member is provided inside the piston rod, and one end of the first elastic member is sealed. The other end is connected to the drive motor while being connected to the stop end and penetrating the sealed end to be connected to the valve body receiver.

  The valve body receiver includes a receiving plate connected to the valve body and a connecting portion connected to the piston rod, the receiving plate has a shape corresponding to the valve body, and the edge of the valve body is The edge of the valve body that is larger than the edge of the backing plate and that protrudes from the backing plate extends downward to wrap around the outer periphery of the backing plate, and the edge of the valve body extends downward and then curves inward And then wrap around the bottom of the backing plate.

  The drainage control mechanism is attached to the bottom of the outer tub of the washing machine, and a corrugated tube is connected to the valve body. The corrugated tube has one end connected to the valve body and the other end at the bottom of the outer tub. Preferably, the valve body and the corrugated tube are integrally formed.

  The ceiling surface of the valve body is made of an elastic material, and preferably, an elastic protruding rib larger than the drain outlet is provided at least around the ceiling surface of the valve body.

  A second elastic member is provided outside the piston rod, and one end of the second elastic member abuts on the valve body receiver and the other end is fixed. Preferably, the drainage control mechanism further includes a valve. A sliding path for the piston rod is provided inside the valve seat, a second elastic member is provided outside the piston rod, and one end of the second elastic member serves as a valve body receiver. While being in contact, the other end is in contact with the valve seat.

  The washing machine includes an inner tub and an outer tub, a plurality of drain holes are provided in the vicinity of the upper edge of the inner tub, and at least one inner tub is provided at the bottom of the inner tub. A drainage outlet is provided, and a drainage control mechanism according to any one of claims 1 to 9 for sealing the inner tank drainage outlet is provided at the bottom of the outer tank.

  Use of the technical scheme described in the present invention provides the following beneficial effects. That is, in the present invention, the valve body receiver is provided between the valve body and the piston rod. When the end of the valve body and the bottom of the inner tank are not parallel, the piston rod and the valve body receiver are operatively connected, so the angle can be adjusted so that the end of the valve body and the bottom of the inner tank are in close contact with each other. . Therefore, it seals reliably, without a clearance gap existing between a valve body and a drain outlet.

  Hereinafter, specific embodiments of the present invention will be described in more detail with reference to the drawings.

FIG. 1 is a structural diagram of a washing machine described in the present invention. FIG. 2 is a structural diagram of the drainage control mechanism described in the present invention.

  As shown in FIG. 1, the washing machine described in the present invention includes an inner tub 100 and an outer tub 200. The inner tank body does not have a water leakage hole communicating with the outer tank, and the inner tank bottom 103 is provided with a drain port 101. Further, a drain hole 102 is provided in the upper part of the inner tank body. At the time of washing, the drainage control mechanism controls to close the drainage port 101. At this time, the water level falls below the height of the drain hole 102, and water exists only in the inner tank 100 and does not intervene between the inner tank 100 and the outer tank 200. When the cleaning is completed, the drainage control mechanism controls to open the drainage port 101, and most of the water is discharged from the drainage port 101. At the time of dehydration, the inner tank 100 rotates, and the water discharged from the clothing rises along the tank wall by centrifugal force. And if it discharges | emits between an inner tank and an outer tank from the inner tank through the drain hole 102 of an inner tank upper part, it will be discharged | emitted from the drain outlet of the outer tank 200 continuously. As described above, since cleaning water is held only in the inner tank 100 during cleaning and is not interposed between the inner tank and the outer tank, water is saved. In addition, since no dirt is accumulated in the region between the inner tank 100 and the side wall of the outer tank 200, the space between the inner tank and the outer tank is kept clean, and bacterial growth is avoided. In the drainage and / or dehydration process, the drainage port 101 is opened, and most of the water and sediment such as mud sand and particles are discharged from the lower drainage port 101 to the outer tank. On the other hand, clothing water is discharged from the drain hole 102 at the top of the inner tub to the outer tub when dewatering due to the high-speed rotation of the inner tub, and is directly discharged from the drain outlet and drain pipe of the outer tub to the outside of the washing machine. . As a result, rapid drainage is realized, and drainage and pollution discharge effects are improved.

  In the present invention, a drainage control mechanism 300 that controls opening / closing of the drainage port 101 is provided at the bottom of the drainage port 101. The drainage control mechanism 300 is attached to the outer tank, and the drainage port 101 is located in the inner tank. In order to seal the drainage port 101, the inner tank is controlled to rotate to a position where the drainage port 101 and the drainage control mechanism 300 face each other, and the operation of the drainage control mechanism 300 is controlled to control the drainage port 101. Seal. On the other hand, when it is desired to open the drain port 101, the inner tank can be rotated by controlling the operation of the drain control mechanism 300 to open the drain port 101. In the washing process, the drainage control mechanism 300 controls the drainage port 101 to be closed and the drainage port 101 to be closed during water supply / washing. Further, during drainage / dehydration, the drainage control mechanism 300 controls to open the drainage port 101.

  As shown in FIG. 2, the drainage control mechanism 300 includes a valve body 301 that can seal the drainage port, and a piston rod 302 that drives the movement of the valve body 301. The drainage control mechanism 300 is attached to the outer tank 200, and the drainage port 101 is located in the inner tank 100. When it is desired to seal the drain port 101, the inner tank is controlled to rotate to a position where the drain port 101 and the drainage control mechanism 300 face each other, and gradually until the valve body 301 seals the drain port 101. The movement of the valve body 301 by the piston rod 302 is controlled so as to be close to the drain port 101. Further, when it is desired to open the drain port 101, the internal movement of the valve body 301 by the piston rod 302 is controlled so that the valve body 301 is gradually separated from the drain port 101 until the drain port 101 is opened. The tank 100 can be rotated. A valve body receiver 304 is provided between the valve body 301 and the piston rod 302. One end of the valve body receiver 304 is fixedly connected to the valve body 301, and the other end is operably connected to the piston rod 302. Alternatively, one end of the valve body receiver 304 is operatively connected to the valve body 301, and the other end is fixedly connected to the piston rod 302. In some cases, the clothes put in the inner tub 100 are decentered to cause the inner tub 100 to be inclined, and the inner tub bottom 103 is not horizontal. When the piston rod 302 is driven to move the valve body 301 to the drain port 101, the end of the valve body 301 and the bottom of the inner tank are not parallel, and the inner tank bottom 103 or between the drain port 101 and the valve body 301 As a result of the gap, water leakage occurs. On the other hand, in the present invention, a valve body receiver 304 is provided between the valve body 301 and the piston rod 302. When the end of the valve body 301 and the bottom of the inner tank are not parallel, the piston rod 302 and the valve body receiver 304 are operatively connected, so that the end of the valve body 301 and the bottom of the inner tank 100 are in close contact with each other. Can be adjusted. Accordingly, the valve body 301 and the drain port 101 are securely sealed without a gap.

  The valve body receiver 304 and the piston rod 302 may be connected so as to be rotatable. According to this, no matter which direction the inner tank bottom is inclined, the valve body 301 can seal the drain outlet 101 in parallel with the inner tank bottom.

  In one embodiment of the present invention, one end of the valve body receiver 304 corresponding to the piston rod 302 is selected to be a spherical protrusion 306 and one end of the piston rod 302 corresponding to the valve body receiver 304 is spherically concave. A connection that can be rotated may be formed by selecting the groove 305 and installing the spherical protrusion 306 in the spherical groove 305. By rotating the spherical protrusion 306 and the spherical concave groove 305 in all directions, the valve body 301 can seal the drain port 101 in parallel with the inner tank bottom 103 regardless of the direction in which the inner tank bottom is inclined.

  In another embodiment of the present invention, one end of the valve body receiver 304 corresponding to the piston rod 302 is selected to be a spherical concave groove 305 and one end of the piston rod 302 corresponding to the valve body receiver 304 is selected. A connection that can be rotated may be formed by selecting the spherical protrusion 306 and placing the spherical protrusion 306 in the spherical concave groove 305. By rotating the spherical protrusion 306 and the spherical concave groove 305 in all directions, the valve body 301 can seal the drain port 101 in parallel with the inner tank bottom 103 regardless of the direction in which the inner tank bottom is inclined.

  The center of the spherical protrusion 306 is connected to the center of the spherical concave groove 305. When the piston rod 302 pulls the valve body 301 downward, the valve body receiver 304 pulls the valve body 301 downward by pulling the valve body receiver 304 downward by the piston rod 302. Further, when the valve body 301 is pushed upward by the second elastic member 309, the valve body 301 moves the valve body receiver 304 upward, so that the valve body receiver 304 operates the piston rod 302 upward.

  Lubricating grease 307 is provided between the spherical protrusion 306 and the spherical concave groove 305. Thereby, a smooth hinge connection between the spherical protrusion 306 and the spherical concave groove 307 is ensured, and a reliable adhesion of the valve body 301 to the periphery of the inner tank bottom 103 or the drain port 101 is ensured.

  The piston rod 302 is connected to a drive motor 313 and is driven by the drive motor 313 so as to reciprocate.

  Alternatively, the piston rod 302 has a hollow structure, and a first elastic member 308 is provided inside the piston rod 302 with one end facing the valve body receiver 304 as a sealing end. The first elastic member 308 has one end connected to the sealed end and the other end connected to the drive motor 313. When the drive motor 313 drives the first elastic member 308, the first elastic member 308 reciprocates the piston rod 302. Thereby, the impact to the drive motor 313 by the drive motor 313 being directly connected to the rigid piston rod 302 is avoided. The first elastic member 308 may be a spring.

  The piston rod 302 has a hollow structure, and a first elastic member 308 is provided inside the piston rod 302 with one end facing the valve body receiver 304 as a sealed end. One end of the first elastic member 308 is connected to the sealing end, and the first elastic member 308 is connected to the valve body receiver 304 through the sealing end, while the other end is connected to the drive motor 313. Thus, the piston rod 302 and the valve body receiver 304 are connected by extending the end portion of the first elastic member 308 from the sealing end.

  The valve body receiver 304 includes a receiving plate connected to the valve body 301 and a connection portion connected to the piston rod 302. The receiving plate has a shape corresponding to the valve body 301. The edge of the valve body 301 is larger than the edge of the receiving plate, and the edge of the valve body 301 that protrudes from the receiving plate extends downward to wrap around the outer periphery of the receiving plate. Further, the edge of the valve body 301 extends downward and then curves and extends inward to wrap around the bottom of the receiving plate. The valve body receiver can push the valve body 301 upward or pull it downward.

  The drainage control mechanism 300 is attached to the bottom of the outer tub of the washing machine. A corrugated tube 303 is connected to the valve body 301. The corrugated tube 303 has one end connected to the valve body 301 and the other end connected to the bottom of the outer tub. Preferably, the valve body 301 and the corrugated tube 303 are integrally formed. The corrugated tube 303 has a certain stretchability, and the sealing of the outer tub can always be maintained while the piston rod 302 has a certain reciprocating movable range.

  Since the ceiling surface of the valve body 301 is made of an elastic material, the valve body 301 is engaged with the drain port 101 or the valve body 301 is in close contact with the inner tank bottom 103 around the drain port to achieve sealing. . When the valve body 301 is in close contact with the inner tank bottom 103 around the drainage port 101, at least a protruding rib 314 having elasticity larger than that of the drainage port is provided on the ceiling surface of the valve body 301. Then, the protruding rib 314 comes into contact with the inner tank bottom 103 around the drain outlet and is compressed so that sealing is realized.

  A second elastic member 309 is provided outside the piston rod 302. The second elastic member 309 has one end abutting on the valve body receiver 304 and the other end fixed. The second elastic member 309 can apply a certain driving force when the valve body 301 moves upward. The drainage control mechanism 300 further includes a valve seat 312. The valve seat 312 is a mounting base of the drainage control structure 300 and is mounted outside the bottom of the outer tub 200. A sliding path for the piston rod 302 is provided inside the valve seat 312. A second elastic member 309 is provided outside the piston rod 302. One end of the second elastic member 309 abuts on the valve body receiver 304 and the other end abuts on the valve seat 312. Accordingly, when the valve body 301 moves downward, the second elastic member 309 is compressed, and when the valve body 301 moves upward, the second elastic member 309 recovers. Further, when the valve body 301 moves upward, the second elastic member 309 can apply a certain propulsive force. The second elastic member 309 may be a spring.

  The above are only preferred embodiments of the present invention. Those skilled in the art can make various modifications and improvements without departing from the principle of the present invention, and these are also regarded as the scope of protection of the present invention.

DESCRIPTION OF SYMBOLS 100 Inner tank 101 Drain outlet 102 Drain hole 103 Inner tank bottom 200 Outer tank 300 Drain control mechanism 301 Valve body 302 Piston rod 303 Corrugated tube 304 Valve body receptacle 305 Spherical groove 306 Spherical protrusion 307 Lubrication grease 308 First elastic member 309 First 2 elastic member 312 valve seat 313 drive motor 314 protruding rib

Claims (10)

In a drainage control mechanism including a valve body that can seal the drainage port and a piston rod that drives the movement of the valve body,
A valve body receiver is provided between the valve body and the piston rod. The valve body receiver is fixedly connected to one of the valve body and the piston rod, and is operable to the other of the valve body and the piston rod. A drainage control mechanism characterized by being connected. The valve body receiver is connected to the piston rod so as to be rotatable,
Preferably, one end of the valve body receiver corresponding to the piston rod is a spherical protrusion, and one end of the piston rod corresponding to the valve body receiver is a spherical groove, and the spherical protrusion is installed in the spherical groove. To form a connection that can rotate,
Alternatively, preferably, one end of the valve body receiver corresponding to the piston rod is a spherical groove, one end of the piston rod corresponding to the valve body receiver is a spherical protrusion, and the spherical protrusion is placed in the spherical groove. The drainage control mechanism according to claim 1, wherein the drainage control mechanism forms a connection capable of rotating operation by being installed in the drainage mechanism.   The drainage control mechanism according to claim 2, wherein the center of the spherical protrusion is connected to the center of the spherical groove, and lubricating grease is provided between the spherical protrusion and the spherical groove.   The piston rod is connected to a drive motor, or the piston rod has a hollow structure, and one end facing the valve body receiver is a sealed end, and a first elastic member is disposed inside the piston rod. The drainage control mechanism according to claim 1, wherein one end of the first elastic member is connected to a sealed end and the other end is connected to a drive motor.   The piston rod has a hollow structure, and one end facing the valve body receiver is a sealed end, a first elastic member is provided inside the piston rod, and one end of the first elastic member is sealed. The drainage control mechanism according to claim 4, wherein the drainage control mechanism is connected to the stop end and penetrates the sealing end and is connected to the valve body receiver, while the other end is connected to the drive motor.   The valve body receiver includes a receiving plate connected to the valve body and a connecting portion connected to the piston rod, the receiving plate has a shape corresponding to the valve body, and the edge of the valve body is The edge of the valve body that is larger than the edge of the backing plate and that protrudes from the backing plate extends downward to wrap around the outer periphery of the backing plate, and the edge of the valve body extends downward and then curves inward The drainage control mechanism according to claim 1, wherein the drainage control mechanism extends and wraps the bottom of the receiving plate.   The drainage control mechanism is attached to the bottom of the outer tub of the washing machine, and a corrugated tube is connected to the valve body. The corrugated tube has one end connected to the valve body and the other end at the bottom of the outer tub. The drainage control mechanism according to any one of claims 1 to 6, wherein the valve body and the corrugated tube are preferably integrally molded. The ceiling surface of the valve body is made of an elastic material,
8. The drainage control mechanism according to claim 7, wherein at least a resilient protruding rib larger than the drainage port is provided around the ceiling surface of the valve body. A second elastic member is provided outside the piston rod, and the second elastic member has one end abutting on the valve body receiver and the other end fixed.
Preferably, the drainage control mechanism further includes a valve seat, a piston rod sliding path is provided inside the valve seat, a second elastic member is provided outside the piston rod, 2. The drainage control mechanism according to claim 1, wherein one end of the two elastic members abuts on the valve body receiver and the other end abuts on the valve seat. In a washing machine including an inner tub and an outer tub, wherein a plurality of drain holes are provided in the vicinity of the upper edge of the inner tub, and at least one inner tub drain is provided at the bottom of the inner tub.
The washing machine according to any one of claims 1 to 9, wherein a drainage control mechanism according to any one of claims 1 to 9 is provided at a bottom portion of the outer tub.