KR101052391B1 - Sump structure of dishwasher - Google Patents

Abstract

The present invention relates to a dishwasher, and more particularly, to a sump structure equipped with a turbidity sensor mounted on a bottom surface of a dishwasher to sense washing water flow path and washing water in a sump in which washing water is stored.

The sump structure of the dishwasher according to the present invention includes a sump housing in which wash water is introduced and stored; A cleaning pump mounted inside the sump housing to pump wash water; A soilless chamber which is seated on an upper portion of the cleaning pump and includes a bleed valve which is inserted and seated at one side edge and a turbidity sensor which is inserted and seated at a position separated from the bleed valve by a predetermined distance; A filter covering the upper portion of the soil chamber; And a motor mounted on a lower end of the sump housing.

The sump structure of the dishwasher according to the present invention has an effect that the washing water flow path structure in which the washing water pumped by the washing pump is moved to the spray nozzle is improved.

Sump, Soil chamber, Impeller, Turbidity sensor

Description

[0001] The present invention relates to a sump structure of a dish washer,

1 is an exploded perspective view showing a sump structure of a dishwasher according to an embodiment of the present invention;

FIG. 2 is an exploded perspective view showing a structure of a lower nozzle arm holder according to an embodiment of the present invention. FIG.

3 is a plan view showing a filter covering an upper surface of a sump structure according to an embodiment of the present invention;

4 is a plan view showing a soilless chamber according to an embodiment of the present invention;

5 is a plan view of an impeller according to the teachings of the present invention.

6 is a rear perspective view of the impeller.

7 is a plan view of a pump case according to an embodiment of the present invention.

8 is a plan view showing a sump housing according to an embodiment of the present invention;

9 is a perspective view showing a sump structure equipped with a turbidity sensor according to an embodiment of the present invention.

10 is an enlarged perspective view showing a state in which the turbidity sensor is mounted.

11 is a front view showing a turbidity sensor according to an embodiment of the present invention.

12 and 13 are side views showing the operation state of the turbidity sensor according to the idea of the present invention.

Description of the Related Art

210: Lower nozzle arm holder 220: Filter 230: Soilless chamber

240: Pump case mounting part 250: Impeller 260: Bariro valve

270: mesh filter 280: disposer 290: sump housing

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

330: motor 400: turbidity sensor

The present invention relates to a dishwasher, and more particularly, to a sump structure equipped with a turbidity sensor mounted on a bottom surface of a dishwasher to sense washing water flow path and washing water in a sump in which washing water is stored.

Generally, the dishwasher is a household appliance that allows the dishware to be cleaned by allowing the dirt on the dishware to fall by the pressure of the washing water sprayed through the spray nozzle.

A typical dishwasher structure includes a tub which forms a space in which the dishwashing is performed inside the dishwasher, a dishwasher rack accommodated in the upper side and / or the lower side of the tub to accommodate the dishwasher, and a dishwasher accommodated in the dishwasher rack And a spraying nozzle for spraying.                         

A sump for storing wash water flowing from the outside is mounted on the bottom of the tub, and a washing pump is mounted on one side of the outer circumferential surface of the sump. In the sump, a washing pump connected to the motor shaft for pumping washing water and a filter for filtering dirt are provided. A heater for heating the washing water is installed at one side of the sump.

Further, in a conventional dishwasher, a turbidity sensor for measuring the degree of contamination of the washing water accumulated in the sump is installed on the upper surface of the heater or the sump bottom or the washing water flow path.

In the operation of the conventional dishwasher having the above-described structure, clean washing water flowing from the outside is stored in the sump. As the motor is operated, the pump is operated so that the washing water is pumped toward the injection nozzle. Then, the washing water sprayed to the outside through the spray nozzle collides against the tableware with strong pressure. The dirt is separated from the dishware by the jetting pressure of the washing water, and the separated dirt is dropped onto the bottom surface of the tub by the washing water. Then, the washing water mixed with the dirt is returned to the inside of the sump.

On the other hand, the contamination degree of the washing water which has returned to the inside of the sump is measured by the turbidity sensor. Depending on the degree of contamination of the washing water measured by the turbidity sensor, the washing water is drained or circulated to the spraying nozzle again by the washing pump.

 In the conventional dishwasher, since the turbidity sensor is attached to one side of the heater case or the bottom of the sump, contamination degree of the washing water pumped to the injection nozzle can not be accurately measured.

In addition, there is a disadvantage that a separate case for mounting the turbidity sensor must be provided, or a separate flow path structure must be formed so that the flow of washing water contacts the turbidity sensor.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to improve the flow path of the washing water in the sump and to mount the turbidity sensor on the flow path to more accurately measure the contamination degree of the washing water pumped toward the spray nozzle The present invention has been made to solve the above problems.

Another object of the present invention is to provide a sump structure in which a turbidity sensor is provided inside the sump structure so that a separate case or flow path structure for the turbidity sensor is not required.

According to an aspect of the present invention, there is provided a sump structure for a dishwasher, comprising: a sump housing for receiving and storing wash water; A cleaning pump mounted inside the sump housing to pump wash water; A soilless chamber which is seated on an upper portion of the cleaning pump and includes a bleed valve which is inserted and seated at one side edge and a turbidity sensor which is inserted and seated at a position separated from the bleed valve by a predetermined distance; A filter covering the upper portion of the soil chamber; And a motor mounted on a lower end of the sump housing.

According to the above-described structure, the structure of the wash water flow path inside the sump is improved, and the turbidity sensor is attached to the flow path, whereby the turbidity of the wash water stored in the sump can be more accurately measured.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It should be understood, however, that there is no intention to limit the scope of the present invention to the embodiment shown, and that other embodiments falling within the scope of the present invention may be easily devised by adding, Can be proposed.

1 is an exploded perspective view showing a sump structure of a dishwasher according to an embodiment of the present invention.

Referring to FIG. 1, a sump 200 of a dishwasher according to the present invention includes a sump housing 290 for storing washing water supplied from a washing water supply pipe outside the washing machine, a motor (not shown) mounted on the bottom of the sump housing 290 And a disposer 280 connected to the motor shaft 331 protruding from the center of the motor 330 to disassemble the food while rotating.

A pump case 256 mounted on the upper side of the disposer 280 to pump wash water stored in the sump housing 290 and an impeller (250). In detail, the impeller 250 is inserted into the motor shaft 331 to pump the washing water while rotating together with the motor shaft.

In addition, it is possible to prevent bulky debris, which is mounted between the disposer 280 and the pump case 256, among the food waste ground by the disposer 280 from entering the pump case 256 A mesh filter 270 is included.

The pump chamber 256 further includes a soil chamber 230 covering the upper surface of the pump case 256 and having a pumping passage (to be described later) for guiding the flow of the washing water pumped in the pump case 256.

Further, a filter 220 having a central portion and an injection nozzle connecting port at one side of the edge is further provided on the upper side of the soil chamber 230. In detail, the injection nozzle connecting port is coupled to the injection nozzle so that the washing water moved along the pumping passage provided in the soil chamber 230 is guided to each injection nozzle. A bleed valve 260 is formed at one side of the soilless chamber 230 so that the washing water moved along the pumping passage is selectively guided to each of the spray nozzles.

In detail, a rinsing water through hole 221 and a mesh filter 227 are formed at the edge of the filter 220 to primarily filter food waste falling directly from the dish. A lower nozzle arm holder 210 coupled to the lower nozzle is mounted at the center of the filter 220.

On the other hand, the washing water dropped into the washing water through hole 221 is collected by the sump housing 290. The washing water dropped by the mesh filter 227 is collected by the sump housing 290 along the drainage passage provided below the mesh filter 227 after the contaminants are filtered by the mesh filter 227 .

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

As the motor 330 rotates, the washing water stored in the bottom surface of the sump is supplied to the impeller 250 (not shown) installed in the pump case 256, ). The washing water pumped by the rotation of the impeller 250 is primarily purified while passing through the mesh filter 270. The flow path formed by the pump case 256 and the soil chamber 230 is guided to the upper nozzle and the lower nozzle, respectively. Here, the wash water is guided to the upper nozzle or the lower nozzle by the delivery valve 260. Specifically, the bleed valve 260 allows the wash water to be opened only by either the upper nozzle or the lower nozzle for a predetermined time. Then, after a predetermined period of time, only the other nozzle is alternately opened, and the washing water is uniformly sprayed to the upper nozzle and the lower nozzle.

On the other hand, a part 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 drainage passage (described later) formed on the outer periphery of the soil chamber 230.

In addition, the washing water sprayed through the upper and lower nozzles drops onto the tub bottom surface. The falling wash water is transferred to the sump housing 290 through the filter 220. The dirt contained in the washing water transferred to the sump housing 290 is pulverized by the disposer 280 mounted on the lower side of the mesh filter 270.

The functions and actions of the respective components will be described in detail with reference to the drawings.

2 is an exploded perspective view showing a structure of a lower nozzle arm holder according to an embodiment of the present invention.

Referring to FIG. 2, the lower nozzle arm holder 210 according to the present invention is formed by coupling a lower nozzle connecting portion and a washing water inflow portion as shown in FIG.

The lower nozzle connecting portion includes a cylindrical lower nozzle insert 211 mounted at a central portion of the filter 220 and rising to the upper portion of the lower nozzle insert 211, 220 and a fastening wing 212 for fastening the same.

Further, the washing water inflow portion is inserted into the bottom surface of the lower nozzle connecting portion. The washing water inflow section includes a washing water inlet 214 through which the pumped wash water is introduced and an insertion rib 216 formed on the upper side of the washing water inlet 214 and inserted into the bottom surface of the lower nozzle insert 211. [ And a washing water raising port 215 for raising the washing water introduced through the washing water inlet 214 toward the lower nozzle. The washing water inlet 214 is formed such that the inner wall surface is smoothly rounded so that the loss due to the flow friction while the incoming washing water rises vertically is reduced. The washing water inlet 214 is connected to an end of a lower nozzle guide passage 236 to be described later. Accordingly, the washing water flowing along the lower nozzle guide passage 236 flows into the washing water inlet 214 and moves up to the lower nozzle.

3 is a plan view showing a filter covering an upper surface of a sump structure according to an embodiment of the present invention.

Referring to FIG. 3, the filter 220 according to the present invention has a disk shape having a predetermined diameter and covers the upper surface of the sump housing.

In detail, the filter 220 is formed with a lower nozzle arm holder insertion port 223 through which the lower nozzle arm holder 210 is inserted. On both sides of the lower nozzle arm holder insertion opening 223, fastening member insertion grooves 222 for coupling with the soilless chambers to be described later are formed.

In addition, the filter 220 has a plurality of washing water through holes 221 formed at the outer circumferential edge thereof at regular intervals. In detail, when the washing water sprayed on the tableware drops onto the bottom surface of the tub, it is moved to the bottom surface of the sump through the washing water through hole 221. In addition, the bulky dirt contained in the washing water can not pass through the washing water through groove 221 and is caught on the upper surface of the filter 220. On the other hand, the dirt passing through the washing water through hole 221 is crushed by the disposer 280 mounted inside the sump.

In addition, a plurality of band-shaped grooves having a predetermined width are formed inside the filter 220, and a mesh filter 227 is mounted in the groove. Here, the strip-shaped grooves are formed along the shape of a drainage passage formed in a soilless chamber to be described later. Accordingly, a part of the washing water falling down to the tub bottom surface is filtered by the mesh filter 227, and then falls into the drainage passage and is collected on the bottom of the sump along the drainage passage.

The filter 220 includes a bleed valve support groove 224 for supporting the bleed valve 260 so that a protrusion protruding from the central portion of the bleed valve 260 is seated thereon and the bleed valve 260 A lower nozzle guide passage 225 for guiding a part of the washing water branching from the lower nozzle 260 to the lower nozzle and a cylindrical nozzle member 250 formed on the edge side of the delivery valve 260 and protruding at a predetermined height And a water guide insertion sleeve 226 of the water guide.

Part of the wash water branched from the delivery valve 260 is guided to the upper nozzle through the water guide insertion sleeve 226.

4 is a plan view showing a soilless chamber according to an embodiment of the present invention.

Referring to FIG. 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 has a basin valve seating portion 235 into which the basin valve 260 is inserted, and a bottom nozzle 234 bent from the basin valve seating portion 235 to the center, A guide passage 236 and a water guide guide passage 237 formed outwardly from the reservoir valve seat 235 and connected to the water guide insertion sleeve 226. In detail, a lower nozzle arm holder receiving groove 239 for receiving the lower nozzle arm holder 210 is formed at an end of the lower nozzle guide passage 236.

In addition, a drainage passage 241 formed along the shape of the soil chamber 230 with a predetermined width and depth is included at the rim of the soil chamber 230. One end of the drainage passage 241 is connected to a turbidity sensor (described later), and a drainage hole 242 connected to a drainage pump is provided on the bottom surface of the other end. Here, the drain hole 242 has a cylindrical shape extending downward to a predetermined length, and is inserted into a shallow chamber drain hole to be described later.

Specifically, the soil chamber 230 includes a turbidity sensor guide passage 233 connected to one side of the turbidity sensor 400 (see FIG. 11) and a pumping passage (to be described later) And a turbidity sensor flow path groove 234 for allowing wash water to flow through the turbidity sensor guide path 233.

A pump case seating part 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 that the upper surface of the pump case 256 is seated. An impeller seating part 238 for receiving the impeller 250 is formed at the center of the pump case seating part 240.

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 from the back surface of the soilless chamber 230 to a predetermined height Thereby forming a rib shape.

More specifically, a space formed between the pump case seating portion 240 and the impeller seating portion 238 to guide the washing water pumped by the rotation of the impeller 250 to the delivery valve 260 Thereby forming the pumping passage 231. An end of the pumping passage 231 that meets the delivery valve 260 is formed to be inclined at a predetermined angle and the turbidity sensor flow path groove 234 is formed at a side surface of the inclined surface. Accordingly, the washing water pumped in the pump case 256 is moved along the pumping passage, and a small amount of the washing water is branched toward the turbidity sensor flow passage groove 234 and flows along the turbidity sensor guiding passage 233 . The turbidity of the washing water is sensed by the turbidity sensor after passing through the turbidity sensor, and then flows along the drainage passage 241 formed on the upper side edge of the soil chamber 230. The washing water is discharged through the drain hole 242 formed at the end of the drainage passage 241 and stored in the sump housing 290.

The soil chamber 230 includes a filter bathering member insertion boss 243 protruding at a predetermined height at a predetermined distance from the lower nozzle arm holder receiving groove 239, Member insertion boss 244 is included. Further, a shear support boss insertion groove (245) formed at least one in an outer rim portion of the barrier valve seat (235) is further included.

First, the washing water pumped in the pump case 256 rotates along the pumping path 231 while the washing water flowing into the balloard valve seat 235 . A part of the washing water moving along the pumping passage 231 is moved along the turbidity sensor guide passage 233. Most of the rinse water that has been moved to the barrier valve seat 235 is moved along the lower nozzle guide channel 236 and the water guide guide channel 237. Then, they are injected into the tub through the lower nozzle and the upper nozzle, respectively.

On the other hand, the washing water flowing along the turbidity sensor guide passage 233 flows along the drainage passage 241 after passing through the turbidity sensor. The contaminated washing water flowing along the drainage passage 241 is collected into the sump housing 290 through the drain hole 242.

FIG. 5 is a plan view of an impeller according to an embodiment of the present invention, and FIG. 6 is a rear perspective view of the impeller.

5 and 6, the impeller 250 according to the present invention includes a rotation axis 253 extending vertically downward from the center of the upper surface to a predetermined length. In detail, a motor shaft inserting hole 252 for inserting a motor shaft is formed at the center of the rotating shaft 253. A circular washing water inlet 254 having a predetermined diameter is formed at the lower end of the impeller 250, and a plurality of blades 251 curved at a predetermined curvature are formed on the side surface. A washing water outlet 255 is formed between the blade 251 and the blade 251.

7 is a plan view of a pump case according to an embodiment of the present invention.

Referring to FIG. 7, the pump case 256 according to the present invention is mounted at the center of the impeller 250. A groove having the same diameter as the washing water inlet 254 formed at the bottom of the impeller 250 is formed at the center of the pump case 256. Therefore, when the impeller 250 rotates, the washing water flows into the impeller 250 through the groove. The mesh filter 270 is installed on the lower side of the groove, and the washing water in the state where the dust is filtered flows into the impeller 250.

In addition, the pump case 256 is formed with an impeller mounting groove 257 which is recessed to a certain depth in order to mount the impeller 250 thereon. A pumping passage 258 is formed between the outer circumferential surface of the impeller seating groove 257 and the outer circumferential surface of the pump case 256. In detail, the pumping passage 258 has a predetermined depth by the outer wall of the pump case 256. The washing water flowing out through the washing water outlet 255 formed on the side of the impeller 250 is moved to the delivery valve 260 along the pumping passage 258.

An end of the pumping passage 258 forms an inclined surface 259 inclined at a predetermined angle and is formed to extend a predetermined length in a tangential direction from the outer circumferential surface of the pump case 256.

8 is a plan view showing a sump housing according to an embodiment of the present invention.

Referring to FIG. 8, the sump housing 290 according to the present invention functions to store wash water flowing into the dishwasher.

In detail, the sump housing 290 has a water supply connection port 291 protruding from a lower side, a drain pump case 296 formed in a substantially opposite side of the water supply connection port 291, And a heater accommodating portion 292 formed to be recessed is included.

A motor shaft through groove 293 is formed at the center of the heater accommodating portion 292 to allow the motor shaft to pass therethrough and a heater inlet for inserting the heater 320 is formed at one side of the sump housing 290, (298) are formed.

The drain pump case 296 is connected to the soil chamber drainage groove 297 and the sump drainage groove 302 is formed in a side surface of the soil chamber drainage groove 297. In detail, at least one rib is vertically formed in the sump drain groove 302 so as to prevent bulky food waste from flowing into the drain pump. A drain hose connection port 299 is formed on the side surface of the drain pump case 296 with a predetermined length and diameter.

On one side of the sump housing 290 there are provided a valve seat 260 for receiving the valve 260 and a turbidity sensor housing 294 formed on the side of the valve seat seating groove 295 And a plurality of rear end support bosses 301 and a shear support boss 300 are included.

In detail, the shear support boss 300 is formed in the barrier valve seat groove 295, and the rear end support boss 301 is formed at a position spaced from the shear support boss 300 by a predetermined distance. Therefore, the wish chamber 230 fastened by the boss can be firmly mounted within the sump housing 290 without rocking.

 The flow of washing water occurring in the sump housing 290 having the above-described structure will be described.

First, washing water flows into the heater accommodating portion 292 through the water supply connection port 291. The temperature of the washing water is increased by the heater 320 accommodated in the heater accommodating portion 292. When the amount of the washing water reaches the set amount, the motor 330 mounted on the bottom surface of the sump housing 290 is operated.

Here, as the motor shaft 331 rotates, the impeller 250 placed in the sump housing 290 rotates together. By the rotation of the impeller 250, the washing water is pumped to the upper nozzle and the lower nozzle. The washing water pumped into the upper nozzle and the lower nozzle is sprayed onto the dish, and then falls down to the bottom of the tub. The washing water dropped to the bottom of the tub is stored again in the sump housing 290 along the washing water through hole 221 of the filter 220.

On the other hand, the washing water passing through the mesh filter 227 is moved along the drainage passage 241 formed in the upper portion of the soil chamber 230. The washing water moved along the drainage passage 241 drops into the soil chamber drainage groove 297 and is stored in the drainage pump case 296. The inside of the sump housing 290 and the drain pump case 296 are communicated by the sump drainage groove 302.

When the drain pump 310 is operated to discharge the washing water containing the dirt after the washing is completed, the washing water stored in the drain pump case 296 is discharged to the outside through the drainage hose connector 299 .

FIG. 9 is a perspective view showing a sump structure equipped with a turbidity sensor according to an embodiment of the present invention, and FIG. 10 is an enlarged perspective view showing a state where the turbidity sensor is mounted.

9 and 10, the turbidity sensor 400 according to the present invention is formed at the beginning of the drainage channel 241 formed on the upper surface of the soil chamber 230. And is connected to the turbidity sensor guide passage 233 starting from the end side surface of the pumping passage 231 formed at the lower end of the soil chamber 230.

In detail, as shown in the drawing, a small amount of washing water guided along the pumping passage 231 is branched into the turbidity sensor guide passage 233 and passes through the turbidity sensor 400. Turbidity is detected by the turbidity sensor 400, and is moved to the sump bottom surface along the drainage flow path 241.

As described above, the turbidity sensor 400 according to the present invention is installed on the bottom surface of the sump or on the washing water flow path inside the sump, unlike the one attached to one side of the heater installed outside the sump. have. Therefore, there is an advantage that the turbidity of the washing water can be measured at every moment when the washing water injection occurs.

Hereinafter, the structure and function of the turbidity sensor 400 will be described in more detail with reference to the drawings.

11 is a front view showing a turbidity sensor according to an embodiment of the present invention.

Referring to FIG. 11, the turbidity sensor 400 according to the present invention has a cylindrical shape having a predetermined diameter and a height, and includes a case bottom 490 having a center portion separated by a predetermined width and depth 410 and a ball 420 which is seated on the ball seating point 490 and reciprocates in the forward and backward directions.

A PCB substrate 450 which is inserted and seated inside the case 410 which is symmetrically separated by the ball seating trough 490 and a ball receiving groove 490 which is seated on the PCB substrate 450, A light emitting part 430 inserted into one side of the case 410 separated by the light emitting part 430 to emit light and a light emitting part 430 mounted inside the opposite case 410 of the light emitting part 430, And a light receiving portion 440 for receiving the divergent light. In detail, the light emitting unit 430 and the light receiving unit 440 are both fixed to the PCB 450.

In addition, a barrier 460 formed at a predetermined height is provided at both ends of the ball seating bone 490 to prevent the ball 420 moving forward and backward in the ball seating bone 490 from falling off .

A cover 470 that hermetically seals the lower end of the case 410 and a signal transmitting unit 450 that extends through the cover 470 and transmits the signal transmitted from the light receiving unit 440 to the PCB 450 to a controller The terminal 480 is provided.

In detail, according to the position of the ball 420, whether the light emitted from the light emitting unit 430 is sensed by the light receiving unit 440 is transmitted to the PCB board 450. Then, the degree of contamination of the washing water passing through the ball seating groove 490 is measured and transferred to the PCB 450. The transmitted information is transmitted to the control unit through the terminal 480. [ The operation of the washing pump or the drain pump is determined according to the transmitted signal.

12 and 13 are side views showing the operation state of the turbidity sensor according to an embodiment of the present invention.

Referring to FIG. 12, there is shown a state where there is no washing water passing through the ball seating groove 490 of the turbidity sensor 400 according to the present invention. The ball 420 is located at the center of the turbidity sensor 400 . In detail, the bottom surface of the ball seating trough 490 in which the ball 420 reciprocates is formed to be inclined at a predetermined angle from the center to both ends as shown in the figure. Therefore, when there is no washing water for pushing the ball 420, the ball 420 is always positioned at the center. The light emitting part 430 and the light receiving part 440 are also inserted into the central part of the turbidity sensor. Therefore, when the ball 420 is positioned at the center, the light emitted from the light emitting unit 430 can not be transmitted to the light receiving unit 440.

In other words, when the ball 420 is positioned at the central portion during the normal cleaning process and the light emitted from the light emitting portion 430 can not be transmitted to the light receiving portion 440, it means that the washing water is not circulated. That is, the washing water is not circulated because the washing motor 330 is not operated and the washing water is not pumped or the washing water does not exist in the sump 200.

Therefore, when the light emitted from the light emitting unit 430 can not be detected by the light receiving unit 440, a failure signal is generated by detecting the failure of the motor, so that the user can check whether the motor is operated or not do.

Alternatively, it is programmed to sense that there is no washing water in the sump 200 to generate a leak signal, and simultaneously stop power supply to the heater 320. In detail, when a leakage signal is generated in the control unit, the user can check whether or not leakage is occurring in the sump portion of the dishwasher. In addition, since the program is programmed to stop the power supply to the heater 320, a fire due to overheating of the dishwasher is prevented.

13, the ball 420 is positioned at one end of the turbidity sensor 400, and the washing water flows along the turbidity sensor guide passage 233, .

In detail, during normal cleaning, the ball 420 should be positioned at the edge of the turbidity sensor. Therefore, the light emitted from the light emitting unit 430 is easily transmitted to the light receiving unit 440.

If the ball 420 deviates from the light emitting unit 430 and the light receiving unit 440, the degree of contamination of the washing water depends on the degree of the light emitted from the light emitting unit 430 reaches the light receiving unit 440. [ .

In detail, the light receiving unit 440 senses the intensity of the light, and the light intensity value is transmitted to the controller of the dishwasher through the PCB 450 and the terminal 480. Then, the degree of contamination of the washing water is determined according to the intensity of the transmitted light, and the washing time, the washing time, the washing time, and the number of times of washing are determined.

In other words, if the amount of light reached to the light receiving unit 440 is very small, it means that the washing water is very contaminated. It means that the washing water is extended at least once according to the intensity value of the light reaching the light receiving unit 440, And may be programmed to increase at least once.

As described above, the conventional turbidity sensor merely performs a function of detecting only the contamination degree of the washing water and delivering it to the control unit. However, the turbidity sensor according to the present invention is capable of detecting whether the cleaning motor is malfunctioning, whether there is washing water in the sump, or detecting the leakage of water, in addition to the function of detecting the washing water contamination degree as described above.

According to the sump structure of the dishwasher according to the present invention, the washing water flow path structure in which the washing water pumped by the washing pump is moved to the spray nozzle can be improved.

Further, since the turbidity sensor is mounted on the washing water passage inside the sump according to the present invention, the turbidity of the washing water directed to the spray nozzle can be detected more accurately.

Further, since the turbidity sensor is mounted inside the sump structure, the assembly process is simplified and the material cost is reduced.

Claims (11)

A sump housing into which wash water is introduced and stored; A cleaning pump mounted inside the sump housing to pump wash water; A bleed valve which is seated on the upper side of the cleaning pump and is inserted and seated at one side edge, A soilless chamber including a turbidity sensor inserted and positioned at a predetermined distance from the delivery valve; A filter covering the upper portion of the soil chamber; And And a motor mounted on a lower end of the sump housing. The method according to claim 1, And a mesh filter is mounted on the lower end of the washing pump. The method according to claim 1, And a disposer for crushing dirt is installed at the lower end of the washing pump. The method according to claim 1, Wherein the soil chamber includes a pumping passage formed along a line which is in contact with an upper surface of the cleaning pump on the back surface. 5. The method of claim 4, And an end of the pumping passage is connected to the delivery valve. The method according to claim 1, The soilless chamber is provided with a lower nozzle guide passage for allowing wash water to branch from the delivery valve to a lower nozzle, And a water guide guide passage for branching wash water from the delivery valve to the upper nozzle. The method according to claim 1, Wherein the soil chamber includes a turbidity sensor guide passage for allowing a part of washing water pumped from the washing pump to branch and flow to the turbidity sensor. The method according to claim 1, Wherein the soil chamber is formed along an outer circumferential surface of a drain passage for allowing wash water passing through the turbidity sensor to move to the sump housing. The method according to claim 1, Wherein a plurality of grooves are formed in the vicinity of edges of the filter so that the washing water sprayed into the tub is collected by the sump housing. The method according to claim 1, Wherein the filter is equipped with a mesh filter which covers an upper surface of a drainage passage formed on the soil chamber, so that a part of the washing water sprayed into the tub is collected into the sump housing along the drainage passage. Sump structure. The method according to claim 1, The washing water stored in the sump housing is moved to the delivery valve along a pumping path formed between the soil chamber and the cleaning pump by the pumping action of the cleaning pump, The lower nozzle or the upper nozzle is moved along the lower nozzle guide passage or the water guide guide passage formed on the upper surface of the soil chamber by the action of the delivery valve, A small amount of washing water moved along the pumping passage is moved to the turbidity sensor along the turbidity sensor guiding flow path branched from the side of the pumping passage, The washing water passing through the turbidity sensor is collected into the sump housing through a drainage path formed by curving along the outer peripheral surface of the soil chamber, The washing water injected into the tub through the lower nozzle or the upper nozzle forms a flow path which is collected in the sump housing along a drainage passage on a soil chamber covered with a plurality of grooves or mesh filters which are formed in the edge portion of the filter Features a dishwasher sump structure.

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