KR101104542B1 - A sump structure of a dish washer - Google Patents

Abstract

The present invention relates to a dishwasher, and more particularly, to a sump structure of a dishwasher, which is provided with a device for sensing the residual water inside the tub, so as to confirm whether the drainage is completed in the drainage process.

The sump structure of the dish washing machine according to the present invention includes a sump housing in which washing water is stored; A residual water detection device mounted on a bottom of the sump housing and including at least one detection sensor for detecting whether the washing water remains; A washing motor mounted to a bottom of the sump housing; Included is a washing pump mounted in the sump housing for pumping the washing water.

By the sump structure of the dishwasher according to the present invention, it is possible to detect whether there is residual water after draining, and thus there is an effect of confirming whether draining is completed.

In addition, it is possible to detect whether the residual water in the sump after the drainage process, there is an effect that can know whether the drainage pump is fixed.

Residual water detection device, detection sensor, waterproof material

Description

Sump structure of a dish washer

1 is a cross-sectional view schematically showing a dishwasher equipped with a residual water detection device according to the spirit of the present invention.

Figure 2 is an exploded perspective view showing a sump structure of the dishwasher equipped with a residual water detection device according to the spirit of the present invention.

3 is a perspective view showing a residual water detection device according to the spirit of the present invention.

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

100: dishwasher 110: tub 111: door

120: upper rack 130: lower rack 140: water guide

150: upper nozzle 160: lower nozzle 200: sump

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 500 residual water detection device 510 housing

520: detection sensor 530; Meninge Rib

The present invention relates to a dishwasher, and more particularly, to a sump structure of a dishwasher, which is provided with a device for sensing the residual water inside the tub, so as to confirm whether the drainage is completed in the drainage process.

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.

In detail, the dishwasher is a tub that is a space for washing dishes stored therein, a sump mounted on the bottom of the tub to store the washing water, and attached to one side of the sump to pump the washing water stored in the sump with the spray nozzle. And a motor for driving the washing pump.

On the other hand, in the general dishwasher as described above, the washing water stored in the sump is pumped by the washing pump is sprayed through the spray nozzle. Then, the dirt on the tableware is removed by the washing water sprayed through the spray nozzle. In addition, the washing water together with the dirt falls to the bottom of the tub and collects again into the sump. In addition, the washing water soiled with food waste is drained to the outside by operating the drain pump, and again clean washing water is introduced into the sump.

Here, since the conventional dishwasher does not have a function of detecting whether or not drainage is completed, there is a disadvantage in that it does not detect when an abnormality occurs in the drainage pump and the drainage does not occur.

In addition, since the conventional dishwasher does not have a function to detect whether there is residual water in the sump, there is a disadvantage that the washing is not stopped when there is no water in the sump due to leakage occurs during the washing process.

The present invention has been proposed to solve the above problems, by attaching a device that can detect whether the wash water remains in the sump, to provide a sump structure of the dishwasher capable of detecting whether the drainage is complete and whether there is a leak It aims to do it.

The sump structure of the dishwasher according to the present invention for achieving the object as described above is a sump housing in which the washing water is stored; A residual water detection device mounted on a bottom of the sump housing and including at least one detection sensor for detecting whether the washing water remains; A washing motor mounted to a bottom of the sump housing; Included is a washing pump mounted in the sump housing for pumping the washing water.

By the configuration as described above, it is possible to determine whether the washing water is completely drained in the sump, there is an effect that can determine whether or not leaking in the washing process.

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

1 is a cross-sectional view schematically showing a dish washer equipped with a residual water detection device according to the spirit of the present invention.

Referring to FIG. 1, the dishwasher 100 according to the present invention has an outer shape, a tub 110 having a dish washing tank formed therein, and a door 111 formed on a front surface of the tub 110 to open and close the washing tank. And a sump 200 formed at the center of the bottom surface of the tub 110 to store the washing water.

In addition, the water guide 140 and the lower nozzle 160 which is provided on the upper surface of the sump 200, the lower nozzle 160 is formed on the bottom surface of the washing tank and sprays the washing water upward. And an upper nozzle 150 attached to an upper portion of the water guide 140 and extending in a vertical direction from the water guide 140 and positioned at a central portion of the washing tub, and on a ceiling of the tub. Top nozzle 155 for spraying the washing water vertically downward is included.

In addition, the upper rack 120 is mounted on the upper side of the upper nozzle 150 so that the dishes are washed by the upper nozzle 150, and the lower nozzle 160 so that the dishes are washed by the lower nozzle 160. Lower rack 130 is mounted to the upper side of the) is included.

In detail, the upper rack 120 is supported by a rail (not shown) provided on the inner surface of the tub 110, and performs the front and rear movement.

Hereinafter will be described the operation of the dishwasher 100 according to the present invention.

First, the user opens the door 111 of the dishwasher 100 and pulls the upper rack 120 and / or lower rack 130 to the outside of the washing tank. In addition, dishes are stored in the racks 120 and 130. Then, the door 111 is closed and power is applied to the dishwasher.

Meanwhile, when power is applied to the dishwasher 100 and a washing step is performed, washing water flows into the sump 200, and when the washing water inflow step is completed, the motor 330 operates. In addition, by rotating an impeller (not shown) provided in the washing pump (not shown) connected to the motor 330, the washing water is pumped to the lower nozzle 160 and the water guide 140.

In addition, the wash water pumped to the water guide 140 is finally moved to the top nozzle 155, the upper nozzle 150 is injected into the washing tank. In addition, the dishes stored in the racks 120 and 130 are washed by the sprayed washing water.

Here, the top nozzle 155 sprays the washing water vertically downward, and the upper nozzle 150 sprays the washing water vertically upward, thereby washing the dishes stored in the upper rack 120.

In addition, the lower nozzle 160 is sprayed the washing water vertically upward, the dishes stored in the lower rack 130 is washed. In addition, by forming an injection hole in the bottom surface of the upper nozzle 150, the washing water is sprayed in both the up and down directions, it can be configured to simultaneously wash the upper side of the tableware accommodated in the lower rack (130).

In addition, when the washing step is completed, the dirty washing water collected in the sump 200 is discharged to the outside of the dishwasher 100 through a drain pump (not shown).

In addition, when the washing water is discharged to the outside, clean washing water is introduced into the sump 200 again through an inlet, and sprayed through the spray nozzles 150 and 160 in the same manner as the washing step. The dishware is rinsed by the sprayed clean water.

In addition, when the rinsing step is completed, by going through the drying step, the washing operation is completed.

Figure 2 is an exploded perspective view showing a sump structure of the dishwasher equipped with a residual water detection device according to the spirit of the present invention.

Referring to FIG. 2, the sump 200 of the dish washing machine according to the present invention includes a sump housing 290 in which the washing water supplied from the washing water supply pipe outside the washing machine is stored, and a motor mounted on the bottom of the sump housing 290. 330 and a disposer 280 connected to the motor shaft 331 protruding from the center of the motor 330 and rotating 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, the soil chamber 230 is formed to cover the upper surface of the pump case 256, the pumping flow path is formed for guiding the flow of the washing water pumped in 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, an insertion hole 223 for mounting the lower nozzle arm holder 210 coupled to the lower nozzle is formed at the center of the filter 220. In addition, a water guide insertion sleeve 226 for connecting to the water guide 140 is formed at one edge with a predetermined height and diameter.

In addition, the soil chamber 230 is formed on one side of the variuo valve seat 235 on which the vario valve 260 is seated, is bent from the variuo valve seat 235 on the upper side is formed The lower nozzle guide flow path 236 is formed. In addition, a water guide guide flow path 237 is formed to allow the washing water to be guided to the water guide insertion sleeve 226 starting from the variio valve seat 235.

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. And, one end of the drain passage 241 is formed with a turbidity sensor insertion groove 232 for mounting the turbidity sensor, the bottom surface of the other end is formed with a drain hole 242 connected to the drain pump and the sump bottom do. In addition, a turbidity sensor guide flow path 233 is formed to allow the washing water pumped from the pump case 256 to be guided to the turbidity sensor inserted into the turbidity sensor insertion groove 232.

Meanwhile, the washing water falling into the washing water through hole 221 of the filter 220 is collected by the sump housing 290. In addition, after the contaminants are filtered by the mesh filter 227, the washing water falling into the mesh filter 227 is disposed on the sump housing 290 along the drain passage 241 provided below the mesh filter 227. Is captured.

In addition, the pump case 256 is formed with an impeller seating groove 257 for mounting the impeller 250 in the center. In addition, a pumping flow path 258 formed between the outer circumferential surface of the impeller seating groove 257 and the outer circumferential surface of the pump case 256 is formed. In addition, the pumping flow path 258 has a predetermined depth by the outer wall of the pump case 256. In addition, the washing water introduced into the pump case 256 is moved to the vario valve 260 along the pumping flow path 258.

Meanwhile, the sump housing 290 has a water supply connector 291 protruding from one side of the lower part, a drain pump case 296 formed in an approximately opposite side of the water supply connector 291, and a predetermined depth at an inner center thereof. A heater accommodating portion 292 is formed to be recessed.

In detail, a motor shaft through groove 293 is formed at the center of the heater accommodating portion 292, and a heater inlet for inserting the heater 320 at one side of the sump housing 290. 298 is formed. In addition, a residual water detection device 500 is mounted at one side of the heater accommodating part 292. Details of the remaining water detection device 500 will be described later with reference to the accompanying drawings.

In addition, the drain pump case 296 is connected to the small chamber drain groove 297 and a drain motor 310 is mounted to the drain pump case 296. In detail, a drain impeller 311 is mounted to the front of the drain motor 310 to pump the washing water to be discharged through the drain hose while rotating in the drain pump case 296.

In addition, the sump housing 290 has a variio valve seating groove 295 formed outside the heater accommodating part 292, and the turbidity sensor seating groove is spaced apart from the variio valve seating groove 295 by a predetermined distance. 294 is formed.

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 into In addition, the washing water pumped by the rotation of the impeller 250 is primarily purified while passing through the mesh filter 270. The pump case 256 and the small chamber 230 are guided to the upper nozzle 150 and the lower nozzle 160, respectively, along the pumping flow path 258. Here, the washing water is branched by the vario valve 260 and guides to the upper nozzle 150 and the lower nozzle 160 along the lower nozzle guide passage 236 and the water guide guide passage 237. do. In detail, the vario valve 260 allows the washing water to be opened by only one of the upper nozzle 150 and the lower nozzle 160 for a predetermined time. Then, after a predetermined time, only the other nozzles are alternately opened, so that the washing water is evenly sprayed on the upper nozzle 150 and the lower nozzle 160.

Meanwhile, some of the washing water guided along the flow path passes through a turbidity sensor (not shown), and is collected at the bottom of the sump along a drain flow path 241 formed at the outside of the soil chamber 230. In addition, the washing water is moved to the drain pump case 296 in the draining process, and when the drain motor 310 is operated, the drain impeller 311 is rotated and drained.

Here, in the residual water detection device 500, when the washing water is filled in the sump 290, electricity flows by the washing water. Therefore, when the drainage is completely completed, since the electricity does not flow to the residual water detection device 500, it is possible to know whether the drainage is completed.

3 is a perspective view showing a residual water detection device according to the spirit of the present invention.                     

Referring to FIG. 3, the residual water detection apparatus 500 according to the present invention includes a housing 510 and at least one detection sensor 520 mounted perpendicularly to a central portion of the housing 510. Two conductors can be mounted. The water film removing rib 530 is mounted between the detection sensors 520, and the water film removing rib 530 is used to prevent the water film phenomenon from occurring between the detection sensors 520 due to the surface tension of the washing water. to be. In detail, if the water film removing rib 530 does not exist between the detection sensors 520, the residual water remaining at the bottom of the bottom of the sump 290 may form a water film by the surface tension between the detection sensors 520. do. As a result, electricity flows between the sensing sensors 520, and thus, erroneously detects that the washing water remains inside the sump. Therefore, it is preferable to mount the water film removing rib 530 having a predetermined height as described above between the detection sensors 520.

On the other hand, the sensor 520 and the water film removing rib 530 is tightly coupled to the housing 510, and the waterproof member 540 is filled to prevent leakage of the lower end of the housing, preferably An epoxy resin may be used as the waterproof material 540. In addition, a fastening member through hole 511 may be formed at an edge of the housing 510 to engage the sump case 290.

Here, one end of the detection sensor 520 is a connection terminal 521 penetrating the bottom surface of the housing 510 to protrude outside the sump housing 290. A conductive line is connected to the connection terminal 521. Therefore, when a current flows in the sensing sensor 520 protruding into the sump housing 290 and formed vertically, the current is transmitted to the controller along a conductive line connected to the connection terminal 521.

Hereinafter, the function and operation of the residual water detection device 500 will be described.

First, when washing water is present in the sump housing 290, a current flows through the detection sensor 520. When the drainage process is completed and no wash water remains in the sump housing 290, no current flows through the detection sensor 520, and in this case, the controller determines that there is no residual water.

However, if it is determined by the control unit that no current flows through the detection sensor 520 in the normal washing process, the controller may generate a leak signal.

On the contrary, if a signal indicating that current flows through the detection sensor 520 and the wash water remains after the draining process starts and passes for a predetermined time or more is transmitted to the control unit, the control unit may generate a drain pump failure signal.

On the other hand, the shape, configuration, and operation method of the residual water detection device 500 is not limited to the embodiment of the present invention, it will be revealed that the residual water detection device of any method included in the spirit of the present invention can be proposed.

By the sump structure of the dishwasher according to the present invention having the above configuration, it is possible to detect whether the water remains after draining, and thus it is possible to check whether the drainage is completed.

In addition, it is possible to detect whether the residual water in the sump after the drainage process, there is an effect that can know whether the drainage pump is fixed.                     

In addition, it is possible to detect the presence of the washing water in the sump during the washing process, there is an effect that can know whether the sump leaks.

Claims (6)

A sump housing in which washing water is stored; A residual water detection device mounted on a bottom of the sump housing and including at least one detection sensor for detecting whether the washing water remains; A washing motor mounted to a bottom of the sump housing; And a washing pump mounted inside the sump housing to pump the washing water, wherein at least one water film removing rib is formed between the sensing sensors to suppress the occurrence of water film due to the surface tension of the washing water. delete The method of claim 1, The detection sensor is a sump structure of a dishwasher, characterized in that the current flowing conductive object. The method of claim 1, The sump structure of the dishwasher, characterized in that the control unit generates a drain pump failure signal when the detection sensor detects that the wash water remains inside the sump after the draining process is completed. The method of claim 1, The sump structure of the dishwasher, characterized in that when the detection sensor detects that there is no washing water in the sump during the washing and / or rinsing process, a leakage signal is generated by the control unit. The method of claim 1, The remaining water detection device is sump structure of the dishwasher, characterized in that connected to the control unit.

Images