KR101871270B1 - Dishwasher and method of controlling the same - Google Patents

Abstract

The present invention relates to a washing machine, a washing machine, a washing machine, a washing machine, a washing machine, a washing machine, a washing machine, a washing machine, a washing machine, A heater for heating washing water in the sump to generate steam; and a steam spray nozzle provided in the tub for spraying steam generated by the heater operation into the tub, And a filter mounting portion on which the filter is installed on the washing water inflow path communicated with the tub so that the washed washing water is filtered by the filter and collected into the sump when the washing water is injected into the tub through the heater, The steam generated by the operation is branched into the steam injection nozzle and the filter mounting portion Wherein the inner space of the sump containing the washing water is divided so that the operation and stop of the pump are repeated while the heater is operated for steam operation will be.

Description

[0001] Dishwasher and its control method [0002]

The present invention relates to a dishwasher and a control method thereof.

Generally, a dishwasher refers to a device for spraying washing water into a processing chamber such as a tub in which a tableware is stored, and removing dirt from the tableware (in the case of a dishwasher having a drying function, drying is performed).

In recent years, a function of spraying high-temperature water, mist, or stream is added to improve cleaning ability. In this case, not only can the dishware be sterilized, but also the dishwasher itself is advantageously sanitarily controlled.

In the dishwasher having the steam supply function as described above, there is a problem that noises are generated when the bubbles discharged together with steam are hit by structures located in the flow path of the dishwasher. When the user mistakes it for a malfunction, .

Particularly, when heat is applied to the water storage tank of the sump containing water for generating steam, the pressure in the water storage tank is increased and the overheating increases the generation of bubbles and thus the noise. At this time, if a sufficient flow passage for venting the bubbles is not secured, the flow rate of the bubbles increases, and accordingly, the hitting sound also increases. For example, the noise generated when the bubble hits the structure located on the flow path of the bubble is faster than the case where the flow velocity of the bubble is discharged through the one flow path is discharged through the plurality of flow paths . Therefore, it is necessary to take measures to disperse the impact between the bubbles and the structure and smoothly discharge the bubbles.

A problem to be solved by the present invention is, first, to provide a dishwasher in which noises generated during steam generation are reduced.

Second, it is an object of the present invention to provide a dishwasher capable of smoothly discharging bubbles generated during the process of generating steam.

The dishwasher of the present invention includes a tub in which a tableware is housed; A washing water spray nozzle provided for spraying wash water into the tub; A sump to receive wash water; A pump provided to pressurize the washing water in the sump to the washing water spray nozzle; A heater for heating wash water in the sump to generate steam; And a steam injection nozzle provided in the tub for spraying the steam generated by the heater operation into the tub, wherein when the sludge is sprayed with wash water through the wash water spray nozzle into the tub, And a filter mounting portion on which the filter is installed on the washing water inflow path communicated with the tub so that the sludge can be collected into the sump after being filtered by the filter. The steam generated by the heater operation is supplied to the steam injection nozzle and the filter The inner space of the sump containing the washing water is partitioned so that the steam can be branched and flowed to the mounting portion, and the operation and stoppage of the pump are repeated while the heater is operated for steam operation.

A control method of a dishwasher according to the present invention is a method of controlling a dishwasher in which steam generated by heating washing water contained in a sump is supplied to a tub through a steam injection nozzle provided in the tub, A steam generating step of heating wash water contained in the sump for steam generation; And a pump operation step of repeating the operation and stoppage of the pump so that the wash water in the sump is stirred.

The dishwasher of the present invention has an effect of reducing noise during steam generation.

In addition, the dishwasher of the present invention has the effect of smoothly discharging bubbles generated during steam generation.

1 shows a dishwasher according to an embodiment of the present invention.
2 is a block diagram illustrating the control relationship between the main components of the dishwasher according to one embodiment of the present invention.
Fig. 3 is a perspective view showing the inside of the tub of Fig. 1; Fig.
4 is an exploded perspective view of the sump shown in Fig.
5 is a cross-sectional view showing a partition wall formed inside the sump of FIG.
FIG. 6 illustrates a state in which the first injection nozzle connecting flow path is opened by the flow path switching portion of FIG. 1, and the second injection nozzle connecting flow path and the third injection nozzle connecting flow path are sealed.
FIG. 7 shows a state in which the first to third injection nozzle connecting flow paths are all opened by the flow path switching portion of FIG. 1;

1 shows a dishwasher according to an embodiment of the present invention. 2 is a block diagram illustrating the control relationship between the main components of the dishwasher according to one embodiment of the present invention. Fig. 3 is a perspective view showing the inside of the tub of Fig. 1; Fig. 4 is an exploded perspective view of the sump shown in Fig. 5 is a cross-sectional view showing a partition wall formed inside the sump 100 of FIG.

1 to 3, a dishwasher 1 according to an embodiment of the present invention includes a cabinet 11 for forming an outer appearance, a cabinet 11 for storing dishes, A tub 12 for providing a treatment chamber 12a and a door 20 for opening and closing the treatment chamber 12a.

Inside the tub 11 are provided racks 16 and 17 for storing dishes, washing water spray nozzles 13, 14 and 15 for spraying wash water toward the tableware housed in the rack, And a steam spray nozzle 27 for spraying steam.

The rack may include a first washing water spraying nozzle 13 which can be disposed at the lower part and the upper part of the processing chamber 12a and spray washing water from the lower side to the upper side toward the lower rack 16 provided at the lower part of the processing chamber, A second washing water injection nozzle 14 for spraying washing water from the lower side to the upper side toward the upper rack 17 provided at the upper part of the processing chamber, and a third washing water spraying nozzle 14 for spraying the washing water from the upper side to the lower side toward the upper rack, (15) may be provided.

The steam injection nozzle 27 is connected to the sump 100 via the steam supply passage 26. Steam generated by heating the washing water contained in the sump 110 by a heater 22 To the steam injection nozzle.

It is preferable that the steam injection nozzle 27 is provided at a lower portion of the tub 12 so that the steam can be uniformly dispersed in the tub 12 when considering the synergistic action of the high temperature steam.

The first washing water spraying nozzle 13, the second washing water spraying nozzle 14 and the third washing water spraying nozzle 15 are connected to the first spraying nozzle connecting passage 18, the second spraying nozzle connecting passage 19, And the washing water is supplied from the sump 100 through the injection nozzle connecting passage 21.

The sump 100 includes a water collecting part 110 for containing wash water. The washing water stored in the collecting portion 110 is sent to the washing water spraying nozzles 13, 14 and 15 by the pump 150. Particularly, when the pump 150 is operated and washing water is sprayed into the tub 12, washing water collected at the bottom 12b of the tub flows back into the sump 100, thereby circulating washing water between the sump and the tub. Accordingly, the sump 100 communicates with the inside of the tub through the steam injection nozzle 26, and also communicates with the tub through a path through which the washing water flows from the tub.

More specifically, the dishwasher 1 includes a filter 140 for filtering foreign matter such as food waste floating in the washing water, and the filter is disposed on the flow path of the washing water flowing into the sump 100 do. The sump 100 is formed with a filter mounting portion 123 on which the filter 140 is mounted so that the sump communicates with the tub 12 through the filter mounting portion 27 as well as the filter mounting portion 27 . The flow path 170 is a flow path for communicating the filter mounting portion 123 and the water collecting portion 110.

The steam generated when the washing water in the sump 100 is heated by the heater 22 is supplied to the tub 12 through the steam supply nozzle 26 and the steam injection nozzle 27, And a second flow path that is supplied through the filter mounting portion 123. In particular, since the filter 140 is mounted on the second flow path, the filter is sterilized by steam.

The filter mounting portion 123 may be formed to be recessed inwardly of the sump 100 so that the washing water flowing from the tub 12 can be smoothly gathered and the structure of the filter mounting portion 123 facilitates detachment of the filter 140 .

The water supply unit 33 is connected to an external water source such as a faucet and supplies wash water into the sump 100. The water supply unit 33 includes a water supply channel 23 through which the wash water supplied from the external water source flows, (Not shown). In the present embodiment, the water supply channel is directly connected to the sump, flows through the filter 140, and then flows to the collection unit 110, but is not limited thereto. For example, water may be supplied directly into the tub 12 through the water supply passage 23, in which case the washing water flows from the turbine to the filter mounting portion 123 and the bottom portion after passing through the filter .

On the other hand, the filter mounting portion 123 is connected to the drainage passage 24, and when the drainage pump 25 is operated, the washing water that has passed through the filter 140 is drained to the outside of the dishwasher 1 through the drainage passage.

The pump 150 feeds the washing water collected in the catching part 110 to at least one of the plurality of washing water spraying nozzles 13 and 14 and 15 and the washing motor 152 and the impeller 151 rotated by the washing motor, . ≪ / RTI >

On the other hand, FIG. 1 schematically shows the arrangement relationship between the main components of the dishwasher 1, but the arrangement relationship of the components is not necessarily limited to this. For example, it can be seen (and of course that such a construction is possible) that a cleaning motor 152 is disposed within the sump 100 as seen in Figure 1, in terms of placement among the components, But it will be possible to carry out various other operations.

In this embodiment, the cleaning motor 152 is disposed outside the sump 100, in particular, between the water collecting portion 110 and the water collecting plate 121 (see Fig. 4) to increase the space utilization in the cabinet 11 So that the capacity of the cleaning chamber 12a is also increased.

The water level sensor 31 detects the water level of the washing water for washing the dishwasher. The water level sensor 31 is installed in the sump to sense the level of the water in the sump 100, And the like.

Alternatively, it may be installed on the flow path of the wash water supplied to the sump 100 to sense the flow rate of the wash water, and to estimate the wash amount required for washing or rinsing the tablet based on the sensed flow rate.

The temperature sensor 32 senses the temperature of the washing water or the air in the tub 12, and it is possible to control the heater 22 based on the temperature sensed by the temperature sensor.

The control unit 29 is for controlling each part constituting the dishwasher 1 and controls the overall operation of the dishwasher 1 and the term control or setting used in connection with the operation of each part is hereinafter referred to as & And is controlled or set by the control unit 29.

Referring to FIG. 4, the sump 100 may include a sump housing 120 and a sump cover 160. The sump cover 160 may be provided on the upper side of the sump housing 120 and may extend from the tub 12 to the sump housing 120. [ A plurality of micropores 164 may be formed to allow the incoming wash water to pass therethrough.

The sump cover 160 is provided with a first connection port 161 connected to the first injection nozzle connection flow passage 18, a second connection port 162 connected to the second injection nozzle connection flow passage 19, And a third connection port 163 connected to the connection channel 21 is formed.

The flow path switching unit 130 selectively supplies the washing water pumped by the pump 150 to at least one of the first washing water injection nozzle 13, the second washing water injection nozzle 14 and the third washing water injection nozzle 15 will be.

More specifically, the sump housing 120 is formed with a wash water supply passage 180 through which the wash water pumped by the pump 150 is guided. The flow path switching portion 130 is connected to the wash water spray nozzle 13 , 14, 15). As described above, a plurality of washing water spray nozzles 13, 14, 15 may be provided. In this case, by controlling the operation of the flow path switching portion 130, at least one of the plurality of washing water spray nozzles is selectively supplied with washing water Can be supplied.

The flow path switching unit 130 includes a flow path switching motor 132 and a rotating plate 131 that is rotated by the flow path switching motor. At least one hole (131a, 131b) is formed in the rotary plate (131).

If the at least one hole 131a or 131b formed on the rotary plate is positioned at a position corresponding to at least one of the plurality of connection ports 161, 162 and 163 in accordance with the rotation control of the flow path switching motor 132, 180) is injected through at least one of the plurality of wash water injection nozzles (13, 14, 15). That is, the wash water injection from among the plurality of wash water injection nozzles 13, 14, 15 is a wash water spray nozzle communicated with the wash water supply flow passage 180 through the holes formed in the rotary plate 131.

On the other hand, the rotation of the rotary plate 131 is controlled stepwise by the passage switching motor 132, and the passage switching motor advances by a certain angle every time the excitation state is changed by the input pulse signal, A stepping motor, a stepping motor, or a stepping motor, which stops and stops at a predetermined position.

Referring to FIGS. 1 and 5, the sump housing 160 is formed with a flow guide portion 116 which surrounds the impeller 151 and guides the flow of the washing water discharged through the impeller blades, The flow guide portion is connected to the wash water supply passage 180. The connection port 180a formed in the flow guide portion 116 of FIG. 5 is for connection with the wash water supply flow path 180.

The steam generated in the sump 100 by the operation of the heater 22 is sprayed into the tub 12 through the steam injection nozzle 27 as described above and the other part is sprayed through the filter mounting portion 123 Into the tub. At this time, it is preferable that the inner space of the sump 100 is partitioned so that the steam generated in the sump 100 can be branched and flowed to the steam injection nozzle 27 and the filter mounting portion 123. For this, a partition wall 115 is formed on the rear surface of the flow guide portion 116 surrounding the impeller 151, and the partition wall protrudes from the back surface of the flow guide portion toward the catch portion 110. A part of the partition 115 is formed around the inlet 116h of the pump 150 so that the inlet 150h of the pump 150 is positioned at one side of the inner space of the sump 100 partitioned by the partition, The other side of the sump inner space partitioned by the partition wall communicates with the steam supply passage 26. The connection port 26a of FIG. 5 is connected to the steam supply passage 26.

More specifically, the barrier ribs 115 may be provided on the upper portion of the inner space of the reservoir portion 110. The partition 115 is not completely divided into the inner space of the reservoir 110 but may be partitioned so that the divided spaces communicate with each other. As shown in FIG. 5, the partition wall 115 may extend a predetermined length downward from the defecation of the flow guide portion 116 forming the upper surface of the reservoir portion 110. The first space 5 and the second space 7 partitioned by the partition wall 115 are mutually communicated through a gap between the lower end of the partition wall 115 and the bottom surface of the reservoir portion 110, The wash water that has passed through the assembly 140 fills both the first space and the second space.

The heater 22 may be heated to the washing water contained in the water storage part 110 and may be exposed to the washing water contained in the water storage part and may be buried in the sump housing 120 It is possible.

6 shows a state in which the first injection nozzle connecting flow path 18 is opened by the flow path switching part 130 of FIG. 1 and the second injection nozzle connecting flow path 19 and the third injection nozzle connecting flow path 21 are closed FIG. FIG. 7 shows a state in which the first to third injection nozzle connecting flow paths 18, 19 and 21 are all opened by the flow path switching part 130 of FIG.

The first communication hole 131a and the second communication hole 131b are formed in the rotation plate 131 of the flow path switching portion 130 and the second communication hole is longer than the first communication hole . Here, the lengths of the first communication hole 131a and the second communication hole 131b are compared along the circumferential direction. For example, as shown in FIGS. 6 to 7, the first communication hole may be a square The second communication hole may be elongated along the circumferential direction of the rotary plate 131. In this case,

Depending on the positions of the first communication hole 131a and the second communication hole 131b determined by the flow path switching motor 132, any one of the plurality of cleaning water injection nozzles 13, 14, ) Is determined.

6 shows that the second communication hole 131b is located at a position corresponding to the first connection hole 161 of the sump cover 160 and the second connection hole 162 and the third connection hole 163 are connected to each other by the rotation plate 131 The cleaning water is supplied only through the first injection nozzle connecting flow passage 18 and the supply to the second injection nozzle connecting flow passage 19 and the third injection nozzle connecting flow passage 21 is blocked in a shielded state, And the washing water is injected into the tub 12 only through the washing water injection nozzle 13.

7 shows that the first communication hole 131a is located at a position corresponding to the first connection hole 161 of the sump cover 160 and the second communication hole 131b is located at a position corresponding to the second connection hole 162 and the third connection hole 163 And the cleaning water is supplied through both the first injection nozzle connecting passage 18, the second injection nozzle connecting passage 19 and the third injection nozzle connecting passage 21, The second spray nozzle 14, and the third spray nozzle 15, as shown in FIG.

The washing water supply passage 180 is in communication with the water collecting section 110 of the sump 100. The washing water supplying passage 180 is connected to the washing water supply passage 130 of the plurality of washing water injection nozzles 13, The pressure of the steam generated in the water collecting part 110 by the operation of the heater 22 is increased by the pressure of the steam generated in the water collecting part 110 communicated with the water collecting part It can be largely suppressed by the ventilation effect through the wash water injection nozzle. Particularly, when both the first injection nozzle connecting flow passage 18, the second injection nozzle connecting flow passage 19 and the third injection nozzle connecting flow passage 21 are opened by the flow path switching portion 130, The pressure rise inside the sump 100 can be suppressed most effectively. In this case, the bubbles generated together with the steam in the sump can be discharged most smoothly.

Meanwhile, the dishwasher control method according to an embodiment of the present invention repeats the operation and stop of the pump 150 while the heater 22 is operated for generating steam. The impeller 151 is rotated to stir the washing water in the sump 100 so that the air bubbles generated together with the steam can be smoothly discharged from the sump 100 and the air bubbles are periodically .

At this time, while the operation of the washing motor 152 is repeated and the circulation of the washing motor 152 is repeated, it is possible to control the flow switching unit 130 to open all the flow paths connected to the plurality of washing water injection nozzles (refer to FIG. 7). The bubbles collide with various structures located on the movement path of the bubbles to generate noise. In particular, when the bubbles strike the sump cover 160, a lot of noise is generated. Therefore, by opening all of the flow paths connected to the plurality of cleaning water injection nozzles 13, 14, and 15 and allowing the bubbles to be guided to the open flow path side, the collision ratio between the bubbles and the sump cover 160 can be reduced, Thereby, the noise generation is reduced.

On the other hand, when the operation and repetition of the pump 150 are repeated while the heater 22 is being heated to generate steam, a certain amount of washing water is supplied to the injection nozzle connecting flow paths 18, 19 and 21 It is preferable that the pump is operated within a range in which the washing water pumped by the pump is not sprayed through the washing water spray nozzles 13, 14, 15. In consideration of the capacity of the ordinary pump 150, the single operation time of the pump does not exceed several seconds, and preferably approaches 1 second. In addition, the stopping time of the pump 150 can be set to be substantially equal to the operating time.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted.

Claims (11)

A tub in which foodware is stored;
A washing water spray nozzle provided for spraying wash water into the tub;
A sump to receive wash water;
A pump provided to pressurize the washing water in the sump to the washing water spray nozzle;
A heater for heating wash water in the sump to generate steam; And
And a steam injection nozzle provided in the tub for spraying the steam generated by the heater operation into the tub,
The sump,
A filter mounting portion on which the filter is installed on a washing water inflow path communicated with the tub so that the washing water injected into the tub through the washing water spraying nozzle is collected by the filter after being filtered by the filter, Including,
The inner space of the sump containing the washing water is partitioned so that the steam generated by the heater operation can be branched and flowed to the steam injection nozzle and the filter mounting portion,
Wherein operation and stoppage of the pump are repeated while the heater is operated to generate steam. The method according to claim 1,
Wherein operation of the pump performed while the heater is operated for generating steam is performed within a range in which no washing water is sprayed through the washing water spray nozzle. The method according to claim 1,
The washing water spraying nozzle is provided in plurality,
Further comprising a flow path switching unit provided on a path through which the washing water pumped by the pump flows so that the washing water pumped by the pump is selectively supplied to the plurality of washing water spraying nozzles,
Wherein the flow-
And opens all the channels communicating with the plurality of wash water injection nozzles while the heater is operated for generating steam. The method of claim 3,
Wherein the flow-
A flow switching motor; And
And a rotating plate formed with at least one hole and rotated by the flow path switching motor,
And the plurality of wash water injection nozzles are selectively communicated with the inside of the sump via holes formed in the rotary plate in accordance with rotation control of the rotary plate by the flow path switching motor. The method according to claim 1,
Wherein the operating time and the stopping time of the pump are the same when the operation and stop of the pump are repeated while the heater is operated to generate steam. The method according to claim 1,
The pump includes:
A cleaning motor disposed outside the sump; And
An impeller disposed below the cleaning motor and disposed within the sump and rotated by the cleaning motor,
The sump,
And a flow guide portion for guiding the wash water pushed by the impeller to the wash water spray nozzle side,
And a partition wall for partitioning the sump inner space into a first space communicating with the steam injection nozzle and a second space communicating with the filter mounting portion is formed on the back surface of the flow guide portion. A method of controlling a dishwasher, comprising: a heater for heating wash water contained in a sump to generate steam; and a heater for supplying steam heated by the heater to the tub through a steam injection nozzle and a filter mounting part formed on the sump,
A steam generating step of generating steam by operating the heater; And
And a pump operation step of repeating the operation and stoppage of the pump so that the wash water in the sump is stirred while the steam generating step is being performed. 8. The method of claim 7,
The pump operating step comprises:
And the washing water injected by the pump is not sprayed through the washing water spray nozzle. 8. The method of claim 7,
Wherein all the channels connecting the pump and the plurality of wash water injection nozzles provided in the tub are controlled to be in an open state during the pump operation step. 10. The method of claim 9,
In the dishwasher,
And a flow switching unit that is provided on the flow path through which the washing water pumped by the pump is moved so that the washing water pumped by the pump is selectively supplied to the plurality of washing water spray nozzles disposed in the tub Including,
And controlling the flow path switching unit so that all the flow paths communicated with the plurality of cleaning water injection nozzles are opened while the pump operation step is being performed. 8. The method of claim 7,
Wherein the operation time and the stop time of the pump in the pump operation step are controlled in the same manner.

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