KR20050122351A - A sealing apparatus of the water guide valve for a dish washer - Google Patents

Abstract

The present invention relates to a dishwasher, and more particularly, to a leak prevention structure of the flow path switching unit for switching the flow path so that the pumped wash water from the washing pump of the dishwasher is moved to the upper nozzle or the lower nozzle.

Leakage preventing structure of the flow path switching unit of the dish washing machine according to the present invention includes a sump housing in which the washing water is stored; A soil chamber seated on the sump housing and including a flow path switching valve seating groove formed at one side, and an upper nozzle guide flow path and a lower nozzle guide flow path branched from the flow path switching valve seating groove; And a flow path switching valve seated in the flow path switching valve seating groove and including a leakage preventing rib at an edge portion thereof.

By the leakage preventing structure of the flow path switching unit of the dish washing machine according to the present invention, the gap formed between the outer circumferential surface of the flow path switching valve and the flow path switching valve seating groove is removed, thereby eliminating the leakage phenomenon.

Description

A leakage apparatus of the flow switch of the dishwasher {a sealing apparatus of the water guide valve for a dish washer}

The present invention relates to a dishwasher, and more particularly, to a leak prevention structure of the flow path switching unit for switching the flow path so that the pumped wash water from the washing pump of the dishwasher is moved to the upper nozzle or the lower nozzle.

In general, the dishwasher is a household appliance that allows the dishes to be washed by removing dirt from the dishes by the pressure of the washing water sprayed through the spray nozzle.

1 is a perspective view showing a sump provided with a conventional general channel switching structure.

Referring to FIG. 1, a general sump 10 may have a substantially circular shape, and a washing water storage unit 15, which is a space for storing the washing water, may be recessed therein. In addition, the gasket 11 is attached along the rim so that the washing water stored in the washing water storage unit 15 does not leak to the outside.

In addition, the sump 10 has a heater connection hole 13 for introducing washing water heated by a heater (not shown) on one side thereof, and the heated washing water supplied from the heater connection hole 13 is upper part. A flow path switching valve 16 for switching the flow path to be guided to the nozzle or the lower nozzle is mounted. An upper nozzle guide flow passage 12 and a lower nozzle guide flow passage 14 are branched from both sides of the flow path switching valve 16 to guide the washing water to the upper nozzle or the lower nozzle.

In detail, the flow path switching valve 16 has a shape in which one side is opened and the other side is closed. In addition, the washing water is guided to the upper nozzle when the opening surface is stopped at a position facing the upper nozzle guide flow passage 12 and the heater connecting hole 13. On the other hand, the washing water is guided to the lower nozzle when the opening surface is stopped at the position facing the lower nozzle guide passage 14 and the heater connecting hole 13.

However, in the conventional flow path switching valve 16 which performs the above function, the washing water leaks due to a gap formed between the outer circumferential surface of the flow path switching valve 16 and the seating portion of the flow path switching valve 16. There is a problem.

In other words, with the opening face of the flow path switching valve 16 facing the upper nozzle guide flow path 14 so that the washing water is guided to the upper nozzle, a portion of the washing water flows in the lower nozzle guide flow path 14 along the gap. Flows toward the side.

In addition, as the gap is generated, a problem occurs in that the water pressure of the washing water guided to each nozzle guide flow path is reduced.

The present invention has been proposed in order to solve the above problems, and by improving the structure of the flow path switching unit, to provide a dishwasher that does not generate a gap through the gap to prevent the gap is generated in the flow path switching unit. do.

In addition, an object of the present invention is to provide a dish washing machine in which a gap is not generated in the flow path switching unit so that the water pressure of the washing water is not reduced.

Leakage prevention structure of the flow path switching unit of the dish washing machine according to the present invention for achieving the object as described above is a sump housing in which the washing water is stored; A soil chamber seated on the sump housing and including a flow path switching valve seating groove formed at one side, and an upper nozzle guide flow path and a lower nozzle guide flow path branched from the flow path switching valve seating groove; And a flow path switching valve seated in the flow path switching valve seating groove and including a leakage preventing rib at an edge portion thereof.

By the above configuration, the gap is not generated on the outer circumferential surface of the flow path switching valve, so that the water leakage phenomenon is removed and the water pressure of the pumped washing water is not reduced.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the spirit of the present invention is not limited to the embodiments presented, and other embodiments included within the scope of other inventive inventions or the scope of the present invention can be easily made by adding, changing, or deleting other elements. I can suggest.

2 is an exploded perspective view of the dishwasher sump provided with a leak-proof structure of the flow path switching unit according to the spirit of the invention.

Referring to FIG. 2, the dishwasher sump 200 provided with a leakage preventing structure according to the present invention includes a sump housing 290 in which washing water supplied from a washing water supply pipe outside the washing machine is stored, and the sump housing 290. It is connected to the motor 330 mounted on the bottom of the) and the motor shaft 331 protruding in the center of the motor 330, the disposer 280 that rotates to decompose food.

In addition, the pump case 256 is mounted to the upper portion of the disposer 280, the washing water stored in the sump housing 290 is pumped, and the impeller accommodated in the pump case 256 to pump the washing water 250 is included. In detail, the impeller 250 is inserted into the motor shaft 331 to pump the washing water while rotating together as the motor shaft rotates.

In addition, it is mounted between the disposer 280 and the pump case 256, to prevent the bulky debris of the food waste crushed by the disposer 280 to enter the pump case (256). Mesh filter 270 is included.

In addition, a soil chamber 230 is formed to cover the upper surface of the pump case 256 and to form a pumping flow path (described below) for guiding the flow of the washing water pumped inside the pump case 256.

In addition, the upper surface of the soil chamber 230 further includes a filter 220 having a spray nozzle connector on one side of the center and the edge. In detail, the spray nozzle connector is combined with the spray nozzle to direct the washing water which has moved along the pumping flow path provided in the soil chamber 230 to each spray nozzle. In addition, a variuo valve 260 is formed at one side of the soil chamber 230 to selectively guide the washing water that has moved along the pumping flow path to each injection nozzle.

In detail, an edge portion of the filter 220 is provided with a washing water through hole 221 and a mesh filter 227 for primarily filtering food waste falling directly from the tableware. In addition, a lower nozzle arm holder 210 coupled to the lower nozzle is mounted at the center of the filter 220.

Meanwhile, the washing water falling into the washing water through hole 221 is collected by the sump housing 290. In addition, after the contaminants are filtered by the mesh filter 227, the washing water falling to the mesh filter 227 is collected to the sump housing 290 along a drain flow path provided at the lower side of the mesh filter 227. .

Meanwhile, a heater 320 for heating the washing water is inserted into the sump housing 290, and a drain pump 310 is attached to one side of the sump housing 290.

Briefly describing the flow of the washing water in the sump structure according to the present invention constituting the configuration as described above, first, as the motor 330 rotates, the washing water stored in the bottom of the sump is impeller 250 mounted in the pump case 256. Inhaled toward In addition, the washing water pumped by the rotation of the impeller 250 is primarily purified while passing through the mesh filter 270. The upper and lower nozzles are guided along the flow path formed by the pump case 256 and the small chamber 230, respectively. Here, the washing water is guided to the upper nozzle or the lower nozzle by the vario valve 260. In detail, the vario valve 260 allows the washing water to only open either the upper nozzle or the lower nozzle for a predetermined time. Then, after a certain time, only the other nozzles are alternately opened, so that the washing water is evenly sprayed on the upper nozzle and the lower nozzle.

Meanwhile, some of the washing water guided along the flow path passes through the turbidity sensor, which will be described later, and is moved to the drain pump along a drain flow path (to be described later) formed at the outside of the soil chamber 230.

In addition, the washing water sprayed through the upper nozzle and the lower nozzle is dropped to the tub bottom surface. Then, the falling washing water is moved back to the sump housing 290 through the filter 220. The dirt contained in the wash water moved to the sump housing 290 is crushed by the disposer 280 mounted below the mesh filter 270.

Functions and operations of the respective components will be described later in detail with reference to the accompanying drawings.

Figure 3 is a plan view of a soil chamber provided with a flow path switching unit according to the spirit of the present invention, Figure 4 is a perspective view showing the assembled state of the sump structure equipped with a flow path switching unit according to the spirit of the present invention.

3 and 4, a soil chamber 230 according to the present invention is inserted into the lower end of the filter 220.

In detail, the upper surface of the soil chamber 230 is a lower nozzle that is formed by bending the variuo valve seat 235 into which the vario valve 260 is inserted and the center of the vario valve seat 235. A guide flow path 236 and a water guide guide flow path 237 which are formed outward from the variio valve seat 235 and connected to the water guide insertion sleeve 226 are included. In detail, a lower nozzle arm holder seating groove 239 for seating the lower nozzle arm holder 210 is formed at the end of the lower nozzle guide passage 236.

In addition, the edge side of the soil chamber 230 includes a drain passage 241 having a predetermined width and depth and formed along the shape of the soil chamber 230. One end of the drain passage 241 is connected to a turbidity sensor (to be described later), and a bottom hole of the other end is provided with a drain hole 242 connected to the drain pump. Here, the drain hole 242 forms a cylindrical shape extending downward to a predetermined length, and is inserted into a small chamber drain hole to be described later.

In detail, the soil chamber 230 is formed on the turbidity sensor guide flow path 233 connected to one side of the turbidity sensor 400 (see FIG. 4) and the pumping flow path 231, and is formed on the side of the pumping flow path 231. The turbidity sensor flow path groove 234 is further included to allow the washing water to flow through the turbidity sensor guide flow path 233.

In addition, a pump case seating portion 240 having the same shape as the outer shape of the pump case 256 is formed on the rear surface of the soil chamber 230 so as to allow the upper surface of the pump case 256 to be seated. In addition, an impeller seating portion 238 for mounting the impeller 250 is formed at the center of the pump case seating portion 240.

In detail, the pump case seating part 240 and the impeller seating part 238 are formed along the shape of the pump case 256 and the impeller 250, and protrude to a predetermined height from the rear surface of the soil chamber 230. To form a rib shape.

More specifically, the space formed between the pump case seating portion 240 and the impeller seating portion 238 in order to guide the washing water pumped by the rotation of the impeller 250 to the variuo valve 260 This pumping flow path 231 becomes. In addition, an end of the pumping flow path 231 which meets the vario valve 260 is formed to be inclined at a predetermined angle, and the turbidity sensor flow path groove 234 is formed at a side of the inclined surface. Therefore, the washing water pumped in the pump case 256 is moved along the pumping flow path, and a small amount of the washing water is branched toward the turbidity sensor flow path groove 234 and flows along the turbidity sensor guide flow path 233. The branched wash water flows along the drain passage 241 formed at an upper edge of the soil chamber 230 after the turbidity of the wash water is sensed by the turbidity sensor while passing through the turbidity sensor. In addition, the washing water is discharged through the drain hole 242 formed at the end of the drain passage 241 and stored in the sump housing 290.

In addition, the soil chamber 230 is a filter stiffening member insertion boss 243 is formed to protrude to a predetermined height in a position spaced a predetermined distance from the lower nozzle arm holder seating groove 239, and the filter stiffening formed on the edge portion Member insertion boss 244 is included. In addition, the front support boss insertion groove 245 is formed at least one of the outer edge portion of the variuo valve seat 235 is further included.

In addition, the variio valve 260 corresponding to the flow path switching unit according to the present invention is seated in the soil chamber 230, respectively, to wash water to the lower nozzle guide flow path 236 and the water guide guide flow path 237, respectively. To distribute.

Referring to the flow of the washing water occurring in the soil chamber 230, first, the washing water pumped inside the pump case 256 is rotated along the pumping flow path 231 to the variuo valve seat 235 Is moved. A portion of the washing water moving along the pumping flow path 231 is moved along the turbidity sensor guide flow path 233. In addition, most of the washing water moved to the variio valve seat 235 is moved along the lower nozzle guide passage 236 and the water guide guide passage 237. Then, the inside of the tub is sprayed through the lower nozzle and the upper nozzle, respectively.

On the other hand, the washing water flowing along the turbidity sensor guide flow path 233 passes through the turbidity sensor and then flows along the drainage flow path 241. In addition, the contaminated washing water flowing along the drain passage 241 is collected into the sump housing 290 through the drain hole 242.

FIG. 5 is a perspective view of a vario valve equipped with a leakage preventing structure according to the spirit of the present invention, and FIG. 6 is an enlarged perspective view of a flow path switching unit showing a state in which the vario valve is mounted on a sump.

5 and 6, the variuos valve 260 having a leak prevention structure according to the present invention is connected to a rotating shaft 261 connected to a motor shaft of a vario valve motor (not shown) provided below the sump. Repeat the forward and reverse rotation.

In detail, the vario valve 260 is fitted to the vario valve seating portion 235 formed at one side of the soil chamber 230 and forms a cylindrical shape having a predetermined diameter and height.

More specifically, the variuo valve 260 has a predetermined diameter, the lower disk 262 and the upper disk 263 through which the rotating shaft 261 penetrates in the center, the lower disk 262 and the, A blocking plate 264 is formed at the edge between the upper discs 263. In addition, an empty hollow part is formed between the upper disc 263 and the lower disc 262 to allow the washing water to flow therein. In addition, a communication hole is formed in the edge portion to allow the washing water to flow in and out. In detail, the communication hole includes a first communication hole 266 formed along the circumference of the discs 262 and 263 with a predetermined width from one end of the blocking plate 264, and the first communication hole 266. A width of the second communication hole 267 formed at a predetermined width at a distance spaced apart from the second communication hole 267 and the other end of the blocking plate 264 at a distance separated from the second communication hole 267. Three communication holes 268 are included.

In addition, leakage preventing ribs 265 are formed at both sides of the blocking plate 264 to prevent leakage of the washing water. In addition, the leakage preventing rib 265 may be integrally injection-molded at the time of manufacturing the variuo valve 260, and a separate member may be coupled by an adhesive method. In addition, the leakage preventing rib 265 is preferably a triangular pillar shape having a predetermined length, the gap generated between the end of the blocking plate 264 and the inner circumferential surface of the vario valve seating portion 235 is properly sealed. Various types of ribs can be proposed to make it possible.

Hereinafter, with reference to the drawings will be described the function and operation of the vario valve.

First, as described above, the rotation shaft 261 of the vario valve 260 is connected to the motor shaft of the vario valve motor, and the vario valve motor repeats forward rotation and reverse rotation at predetermined time intervals.

Therefore, the wash water is selectively distributed to the lower nozzle guide flow path 236 and the water guide guide flow path 237 by the vario valve 260 for a predetermined time.

In detail, the third communication hole 268 communicates with the pumping flow path 231 in a state in which the blocking plate 264 of the vario valve 260 blocks the lower nozzle guide flow path 236. The first communication hole 266 communicates with the water guide guide passage 237. Therefore, the washing water that has been moved along the pumping flow path 231 flows through the center of the vario valve 260 to the water guide guide flow path 237.

In addition, the vario motor is rotated after a predetermined time elapses, and the blocking plate 264 blocks the entrance of the water guide guide flow path 237. Then, the third communication hole 268 communicates with the lower nozzle guide flow path 236, and the second communication hole 267 communicates with the pumping flow path 231. Therefore, the washing water moved along the pumping flow path 231 is moved to the lower nozzle guide flow path 236 through the center of the vario valve 260.

Here, a gap generated at both ends of the blocking plate 264 and both ends of the lower nozzle guide flow path 236 or the water guide guide flow path 237 is sealed by the leakage preventing rib 265. Therefore, a part of the washing water leaks through the gap in the related art, or a phenomenon in which the water pressure of the washing water is reduced by the washing water leaking into the gap does not occur.

By the leakage preventing structure of the flow path switching unit of the dish washing machine according to the present invention having the above configuration, the gap formed between the outer circumferential surface of the flow path switching valve and the flow path switching valve seating groove is removed to remove the phenomenon.

In addition, there is an effect of maintaining a constant pressure without reducing the water pressure of the washing water pumped from the washing pump by the flow path switching unit leakage prevention structure according to the present invention.

1 is a perspective view showing a sump provided with a conventional general channel switching structure.

Figure 2 is an exploded perspective view of the dishwasher sump provided with a leak-proof structure of the flow path switching unit according to the spirit of the invention.

3 is a plan view of a soil chamber provided with a flow path switching unit according to the spirit of the present invention.

Figure 4 is a perspective view showing the assembled state of the sump structure equipped with a flow path switching unit according to the spirit of the present invention.

5 is a perspective view of the variuos valve is provided with a leak-proof structure according to the spirit of the present invention.

6 is an enlarged perspective view of a flow path switching unit showing a state in which the variio valve is mounted on a sump.

<Description of the symbols for the main parts of the drawings>

210: lower nozzle arm holder 220: filter 230: soil chamber

240 pump seating part 250 impeller 260 Vario valve

270: mesh filter 280: disposer 290: sump housing

300: shear support boss 310: drain pump 320: heater

330 motor 400: turbidity sensor

Claims (4)

A sump housing in which washing water is stored; A flow path switching valve seating groove seated on the sump housing and formed at one side; A soil chamber including an upper nozzle guide flow path and a lower nozzle guide flow path branched from the flow path switching valve seating groove; And And a flow path switching valve seated in the flow path switching valve seating groove and including a leakage preventing rib at an edge portion thereof. The method of claim 1, The flow path switching valve is formed in a cylindrical shape having a predetermined diameter and height, the blocking plate is formed in a predetermined width along the circumferential surface of the side edge portion; Leakage prevention structure of the flow path switching unit of the dishwasher including a leakage preventing rib formed on both ends of the blocking plate. The method of claim 1, The leakage preventing rib is a flow path switching unit leakage prevention structure of the dishwasher, characterized in that the triangular pillar shape. The method of claim 1, The leakage preventing rib is injection-molded structure of the dishwasher, characterized in that the injection molding integrally with the flow path switching valve.