KR20180077741A - Dishwasher - Google Patents

Abstract

Disclosed is a dishwasher, which comprises: a heat exchange flow path for connecting a direct water unit and a water intake unit to create water intake of the dishwasher; a heat exchange flow path including a hot water flow path installed in a rinse water tank and connected to the water intake unit by heat exchange with the rinse water by flowing direct water, and a first bypass flow path provided to bypass the heat exchange flow path; a flow regulating valve formed in the first bypass flow path for regulating the water intake temperature; and a control unit for controlling the heat exchange flow path in accordance with a state of the rinse water tank.

Description

Dishwasher {Dishwasher}

The present invention relates to a dishwasher which enables hot water, which can be generated in a dishwasher, to be used for applications other than dishwashing.

The dishwasher is designed to use hot water at room temperature for the efficiency of cleaning and rinsing of dishes. The hot water heated in the dishwasher is used only for the washing and rinsing of the dishware, so the use of the dishwasher for other purposes is limited. In the dishwasher, a suggestion is made to use the hot water used for dishwashing and rinsing for other purposes Is proposed in Korean Patent Registration No. 10-1466858 by the present applicant.

In the dishwasher with built-in water heater, the direct water is first heated through the heat exchanger, the heat is exchanged from the sub hex, and then the water is supplied to the rinse water tank. Therefore, when used as hot water for other purposes, have. Since the hot water of the dishwasher can be used as the hot water needed for the sink, etc., it is possible to save the cost of purchasing or operating the water heater and the installation cost of the water heater. However, there is a need for a system that efficiently produces and supplies hot water during operation of the dishwasher.

Patent Document 1: Korean Patent Registration No. 10-1466858 (Published on Dec. 03, 2014)

Patent Document 2: Korean Patent Registration No. 10-1273553 (Published on June 17, 2013)

One of the technical problems of the present invention is to supply hot water to a dishwasher without installing a water heater. It is in the dishwasher to facilitate hot water intake.

According to an aspect of the present invention, there is provided a dishwasher equipped to adjust a temperature and a water level in a rinse water tank, the dishwasher comprising: a heat exchange passage for connecting a direct water portion and a water intake portion to generate a water intake of the dishwasher; Wherein the heat exchange passage includes a hot water passage connected to the water intake portion and a first bypass passage provided to bypass the heat exchange passage, the hot water passage being provided in the rinse water tank for allowing direct water to flow therethrough and exchanging heat with the rinse water, A flow regulating valve formed in the flow path to regulate the intake temperature; And a control unit for controlling the heat exchange passage in accordance with the state of the rinse water tank.

According to the embodiment of the present invention, the first bypass passage is provided with the first heater.

According to an embodiment of the present invention, the hot water passage may include a second bypass passage, and the second bypass passage may include a second heater.

According to the embodiment of the present invention, the heat exchange channel can be installed either inside or outside the rinse water tank, or inside or outside the rinse water tank.

According to the embodiment of the present invention, the heat exchange passage may be a coil-shaped flow passage, an internal type which is mounted in the rinse water tank, and an external type which is installed along the outer wall of the rinse water tank.

According to the embodiment of the present invention, the heat exchange passage includes a temperature detection sensor for detecting a direct water temperature, a rinsing water, a water temperature of the heat exchanged hot water, and a water intake temperature; A direct water flowing through the heat exchange passage, a heat exchange water exchanged with the rinsing water, and a water inlet for interrupting the heat source of the heater.

According to the embodiment of the present invention, the control unit may include an MCU for controlling the flow rate of the heat exchange channel after determining whether the rinsing water temperature or the water level in the rinse water tank reaches a predetermined reference value.

According to an embodiment of the present invention, the control unit may include an MCU for controlling the heater and the flow rate of the heat exchange channel after determining whether the rinsing water temperature or the water level in the rinsing water tank reaches a predetermined reference value.

The hot water can be supplied easily through the dishwasher. The desired hot water can be supplied through the dishwasher.

It is possible to conveniently take the hot water or the rinsing water having undergone the heat exchange of the dishwasher and the heat-exchanged hot water into the hot water with a relatively simple structure.

The direct water or hot water can be supplied at a water intake temperature corresponding to the set water intake temperature.

The heater can be downsized, the temperature of the water to be taken can be precisely controlled, and the set hot water can be taken in the rinse water tank even in the state where the heated rinse water can not be rinsed.

Figure 1 is an illustration of a dishwasher system.
2 is an illustration of a dishwasher control system.
3 is an illustration of a dishwasher system according to an embodiment of the present invention.
4 is an illustration of a built-in arrangement of a heat exchange channel according to an embodiment of the present invention. (a) is a plan view and (b) is a front view.
5 is an illustration of an external arrangement of a heat exchange channel according to an embodiment of the present invention. (a) is a plan view and (b) is a front view.
6 is an illustration of a housing-like arrangement of a heat exchange channel according to an embodiment of the present invention.
7 is an illustration of a dishwasher control system according to an embodiment of the present invention.

Hereinafter, a dishwasher according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The present invention is proposed to be able to supply hot water in a dishwasher. Preferably, when the temperature in the rinse water tank is sufficient for smooth rinsing, the heater is turned off and the amount of opening of the flow control valve is adjusted to adjust the set water intake temperature.

Since the temperature of the rinsing water tank is low or the temperature is low, the temperature of the rinsing water tank is lowered immediately after the rinsing, and the flow control valve of the first bypass passage is further opened, So that the rinse water tank is heated and can be raised to the water intake temperature corresponding to the set water temperature through the heater installed in the first bypass flow path.

In the case of using a heat exchanger for heating the rinsing water when the temperature of the rinsing water tank is low or the temperature is low or the temperature is low after the heat exchange immediately after the rinsing step, the temperature of the direct water is lower than the temperature after heat exchange, Since the heat exchanger for heating the rinse water has a heater for emitting a large amount of heat, there is a high probability of occurrence of overshoot and the like. However, since the heater provided in the second heat exchanged second bypass flow passage has a low? T, It is possible to precisely control the temperature of the water to be taken while allowing the hot water to be taken in the rinse water tank even in a state where the hot rinse water can not be rinsed.

Dishwashers vary in type. Figure 1 is a schematic diagram of a typical dishwasher system. The dishwasher system of Figure 1 is an example of a gas dishwasher that uses gas as a heat source. The present invention is not limited to the dishwasher type as shown in Fig.

As shown in FIG. 1, the dishwasher 100 is adapted to put a dish in the dishwasher 110 and clean the dishware by washing and rinsing. The supply time of the cold and hot water required for dish washing and rinsing, the supply and heating of the pump, the washing water and the rinse water, and the drainage control are controlled through the control unit 300 according to the water temperature,

In the dishwasher 100, a rinsing nozzle 120 and a cleaning nozzle 130 are positioned around a cleaning tank 110. The water supplied to the rinsing nozzle 120 and the cleaning nozzle 130 is divided into rinsing water and washing water and the water stored in the rinsing water tank 140 and the washing water tank 150 is supplied to the rinsing pump 160, And the washing water tank 150 is provided with a separate heating source 181.

A rinsing tank water level sensor 141 and a rinsing tank temperature sensor 142 are installed in the rinsing water tank 140 and a washing tank water level sensor 151 and a washing tank temperature sensor 152 are installed in the washing water tank 150 have.

The rinsing water pipe is divided into a rinsing water pipe and a rinsing water pipe. A rinsing pump 160 is installed in the rinsing water pipe and a rinsing pump 170 is installed in the rinsing water pipe to supply rinsing water and washing water necessary for rinsing and washing. Or the rinsing pump 160 in the rinsing water conduit may supply the heated hot water of the rinsing water tank 140 to the washing water tank 150 through the rinsing nozzle 120. The cold water supplied through the water supply unit 191 is supplied to the rinsing water tank 140. The hot water supplied through the water supply unit 191 is pumped through the circulation pump 190 and passes through the heat exchanger 180 as the first heater It turns into hot water and circulates. In the gas dishwasher, the heat source of the heat exchanger is a gas burner (not shown).

2 is a block diagram illustrating an example of dishwasher control. As shown in FIG. 2, the control of the dishwasher includes a water temperature detection sensor unit 210 for detecting the water temperature in the washing water tank 150 and the rinse water tank 140, a water level detection unit 210 for detecting the water level in the washing water tank and the rinse water tank, A sensor unit 220, a rinsing / cleaning / circulating pump driving unit 230 for pumping or circulating the washing water and the rinsing water into the washing tank, a heat source unit 240 for heating the washing water and the rinsing water, And a control unit 300 that receives a detection signal from the device unit 200 including the water supply and drainage units 250 and executes a control command to control the operation of each device.

The control unit 300 includes a display unit 310a including a control unit 310 having a key such as a cleaning start button and a display panel indicating a driving condition and an input condition. So that it can be identified.

The water temperature and water level detection sensor units 210 and 220 are sensors or the like that detect or measure the temperature, the water level and the pressure and send the detection signal to the control unit 300. The water supply and drainage unit 250 controls the control unit 300 (Electromagnetic valves) including a flow control valve that is opened or closed in response to a signal. The heat source may be a gas burner, an electric heater, and any external heat source.

3 is an illustration of a dishwasher according to an embodiment of the present invention.

3, the dishwasher of the present invention includes a heat exchange channel 400 connecting the direct water portion W1 and the water intake portion W2 to generate a water intake of the dishwasher.

The heat exchange channel 400 is provided in the rinse water tank 140 and is connected to the hot water channel 450 connected to the water intake unit W2 through the direct water flow and the heat exchange with the rinsing water, And a flow path 420.

A flow control valve 252 formed in the first bypass passage 420 for controlling the intake water temperature; and a controller 300 for controlling the heat exchange passage 400 according to the state of the rinse water tank.

Preferably, the first bypass passage 420 may include a first heater 410, as shown in FIG.

3, the hot water passage 450 may include a second bypass passage 421, and a second heater 411 may be provided in the second bypass passage 421 have.

The first bypass path 420 provided with the first heater 410 and the second bypass path 420 branched from the heat exchange path 400 are formed by installing the heat exchange path 400 along the rinse water tank 140 and bypassing the heat exchange path 400, The dishwasher including the second bypass passage 421 in which the second heater 411 is installed in the hot water passage 450 is installed in the rinsing water tank 140 when the temperature in the rinsing water tank 140 is sufficient for smooth rinsing, The hot water can be easily taken while adjusting the opening amount of the flow control valve 252 in a state where the heater of the heat exchanger 180 is switched off.

In addition, when the rinse water tank level is low or the temperature is low, such as immediately after the rinse cycle, the temperature after the direct heat exchange is lowered. Therefore, the flow control valve 252 of the first bypass channel 420 is further opened, 400 can be reduced and the rinse water tank 140 can be heated and heated to the water intake temperature corresponding to the set water temperature through the heating of the first heater 410 of the first bypass flow path 420 .

When the rinsing water heat exchanger 180 is used when the water level of the rinsing water tank 140 is low or the temperature is low, such as immediately after the rinsing step, and the temperature after direct heat exchange is low, the direct- The heat exchanger 180 for heating the rinse water has to be provided with a heater for emitting a high heat quantity, so that there is a high probability of occurrence of overshoot and the like. However, in the first bypass heat exchanger 450, The second heater 411 is provided with a relatively small heater since Δt is low so that the temperature of the water to be taken can be precisely controlled and the rinsing water tank 140 can be heated without rinsing It is possible to make the set hot water intake possible.

The specific structure of the heat exchange channel of the dishwasher according to the embodiment of the present invention is as follows.

The dishwasher of the present invention may be constructed by installing a heat exchange channel 400 in a rinse water tank 140 so that the direct water can be introduced into the rinse water from the direct water supply unit 191 as shown in FIG.

The first heater 410 of the first bypass flow path 420 and the second heater 411 of the second bypass flow path 421 are connected to a heat source So that the supply can be controlled by the control unit 300.

The first and second heaters 410 and 411 installed in the first and second bypass flow paths 420 and 421 may be external heat sources including a heater.

Figs. 4 to 6 are examples of various arrangements of the heat exchange channels of the dishwasher according to the embodiment of the present invention.

4 and 5, the heat exchange passage 400 may be installed either inside or outside of the rinse water tank 140, or inside or outside the rinse water tank 140.

The heat exchange channel 400 may preferably be constituted by a coil-shaped channel. The coil-type flow path may include an internal type (FIG. 4) mounted in the internal space of the rinse water tank 140, and an external type (FIG. 5) installed around the external wall of the rinse water tank 140.

The heat exchange passage 400 may be of a housing type surrounding the outside of the rinse water tank 140 as shown in FIG.

The heat exchange passage 400 may be formed of a coil internal / external type coiled in a coil shape with respect to the rinse water tank 140, or a housing type surrounding the outside of the tank. In any structure, during the operation of the dishwasher, the heat of the rinsing water conducted from the rinsing water tank 140 and the direct water supplied from the direct water supply unit 191 can be exchanged.

7 is a block diagram for explaining a dishwasher control example according to an embodiment of the present invention.

For controlling the dishwasher according to the embodiment of the present invention, as shown in FIG. 7, the heat exchange passage 400 is provided with a direct water temperature detection sensor 211 for detecting the direct water temperature of the direct water portion W1, A rinsing water temperature detection sensor 213 for detecting the water temperature of the rinsing water, a water intake water temperature detection sensor 214 for detecting the water intake water of the water intake portion W2, And water intake water temperature sensors 215 for sensing the water intake water taken via the path oil passages 420 (421).

The temperature of the direct water or hot water flowing through the heat exchange channel 400 is determined by the water temperature determination unit 330 of the controller 300 and the opening amount of the water containing the flow rate control valve is determined and the opening and closing of the water is controlled.

The water level controlled by the water level switching unit 360 is controlled by a flow rate control valve 251 for controlling the supply of direct water to the heat exchange channel 400, A flow control valve 252 for controlling the flow rate of the intake water warmed up by the first bypass flow path 421 and a water flow control valve 252 provided in the hot water flow path 450 for supplying hot water to the intake part W2, The control unit 300 controls the opening and closing amounts of the flow control valves 251 and 252 according to the control signal of the water valve opening and closing unit 360 of the control unit 300, W2 may be led to the second bypass flow passage 421 through the water valve 253 or may be controlled to be taken to the water intake section W2 directly.

The control unit 300 may include an MCU 320 that determines whether the rinsing water temperature or the water level in the rinse water tank 140 reaches a predetermined reference value and then controls the flow rate of the heat exchange channel.

The control unit 300 determines whether the rinsing water temperature or the water level in the rinsing water tank 140 reaches a predetermined reference value and then determines whether the rinsing water temperature or the water level in the first and second heaters 410, And an MCU 320 for controlling the flow rate.

Alternatively, the control unit 300 may determine whether the reference value of the designated water intake temperature can be divided into the low temperature / high temperature and reach the reference value of the set water intake water temperature. Then, the controller 300 determines the current operation mode of the dishwasher, A flow rate control valve 251, and an MCU 320 for controlling the water discharge valves 253.

Alternatively, the reference value of the designated intake water temperature set in the MCU 320 may be a value that the user arbitrarily inputs by operating the intake temperature control unit 312 of the operation unit 310. [ For example, a higher temperature can be freely selected and set, including the current temperature.

The reference value of the designated intake water temperature set in the MCU 320 can be freely input and set in the program memory of the control unit 300. [

The control of the heat exchanging passage 400 by the control unit 300 is not specifically shown in the drawings but may be performed by detecting the rinse tank temperature sensor 141 and the rinse tank temperature sensor 142 provided in the rinse water tank 140 Signals may be integrated and controlled by reflecting the detection signals of the cleaning tank water level sensor 151 and the cleaning tank temperature sensor 152 to the temperature of the water intake water. Similarly, the heating sources of the washing tank heating source 181 and the rinsing water heating heat exchanger 180 can be integrally controlled according to the temperature of the hot water to be taken, the present tank level and the operating state.

The control unit 300 further includes a water temperature determination unit 330 for detecting the temperature of the direct water, hot water, and heat exchange water detected by the water temperature detection sensor unit 210, a driving mode determination unit 340 for determining the current operation mode of the dishwasher, A designated intake water temperature determination unit 350 and a water-side opening / closing unit 360 for determining whether or not a predetermined intake water temperature reference value inputted from the operation unit 310 by the user has been reached.

The dishwasher according to the embodiment of the present invention includes the first bypass passage 420 provided with the first heater 410 by bypassing the heat exchange passage 400 by providing the heat exchange passage 400 along the rinse water tank 140, And the second bypass passage 421 in which the second heater 411 is provided in the hot water passage 450 branched from the heat exchange passage 400. This ensures that the temperature in the rinse water tank 140 is sufficient for smooth rinsing It is possible to adjust the opening amount of the flow rate control valve 252 in a state where the heater of the rinsing water heating heat exchanger 180 is switched to the off state, .

When the temperature of the rinsing water tank 140 is low or the temperature is low, the dishwasher according to the embodiment of the present invention controls the flow rate of the first bypass flow channel 420 The rinse water tank 140 is heated by further opening the valve 252 and reducing the amount of water flowing through the heat exchange passage 400. The rinse water tank 140 is heated by heating the first heater 410 of the first bypass passage 420 There is an advantage in that it is possible to raise the temperature to the water intake temperature suited to the intake water temperature and supply the water to the water intake.

The dishwasher according to the embodiment of the present invention may be used in a case where the rinsing water tank 140 has a low water level or a low temperature immediately after the rinsing cycle and a heat exchanger 180 for heating the rinsing water is used when the temperature after direct heat exchange is low , Since the temperature of the direct water is lower than the temperature after the heat exchange, Δt becomes high. As a result, the heat exchanger 180 for heating the rinse water needs to have a heater for emitting a high heat quantity, The second heater 411 provided in the second bypass flow path 450 has a low Δt, which is advantageous in that a relatively small heater can be used. Thus, the temperature of the water to be taken can be precisely controlled, and the set hot water can be taken in the rinse water tank 140 even in the state where the heated rinse water can not be rinsed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Included in thought.

100: dishwasher 110: washing tank
120: rinse nozzle 130: cleaning nozzle
140: rinse water tank 150: wash water tank
160: Rinsing pump 170: Cleaning pump
180: Rinse water heating heat exchanger 190: circulation pump
210: Water temperature detection sensor unit
211: Direct water temperature detection sensor (Direct: W1 side)
212: Cleaning water temperature detection sensor
213: rinse water temperature detection sensor (rinse tank temperature sensor: 142)
214: intake water temperature detection sensor (intake portion: W2 side)
215: intake water temperature detection sensor (first and second bypass flow paths 410 and 411)
300: control unit 310:
320: MCU 330: Water temperature judging unit
340: Operation mode judging unit
350: designated intake water temperature determination unit 360: water side opening / closing unit
400: heat exchange channel 410: first heater (heat source)
411: second heater (heat source) 420: first bypass channel
421: second bypass channel

Claims (8)

1. A dishwasher for adjusting a temperature and a water level in a rinse water tank,
A heat exchange passage for connecting the direct water portion and the water intake portion to generate a water intake of the dishwasher;
Wherein the heat exchange flow path includes a hot water flow path which is installed in the rinse water tank and flows into the rinsing water and is heat-exchanged with the rinsing water and connected to the water intake portion, and a first bypass flow path provided to bypass the heat exchange flow path,
A flow control valve formed in the first bypass flow path to regulate the intake water temperature; And
And a control section for controlling the heat exchange flow path according to the state of the rinse water tank. The method according to claim 1,
Wherein the first bypass passage is provided with a first heater. The method according to claim 1,
Wherein the hot water passage includes a second bypass passage and the second bypass passage is provided with a second heater. The method according to claim 1,
The heat exchanging flow path is installed either inside or outside the rinse water tank, or inside or outside the rinse water tank. The method according to claim 1,
Wherein the heat exchange flow path includes a coil type flow path including an external type installed along an outer wall of a built-in rinse water tank mounted in the rinse water tank. The method according to claim 1,
The heat exchange channel includes a temperature detection sensor for detecting a direct water temperature, a water temperature of the hot water exchanged with the rinsing water, and a water intake temperature; Wherein the dishwasher includes a water line that flows through the heat exchange passage, a heat exchange water that is heat-exchanged with the rinsing water, and a water column that controls the heat source of the heater. The method according to claim 1,
Wherein,
And an MCU for controlling the flow rate of the heat exchange channel after determining whether the rinse water temperature or the water level in the rinse water tank reaches a predetermined reference value, The method according to claim 1,
Wherein,
And an MCU for controlling the heater and the flow rate of the heat exchange channel after determining whether the rinsing water temperature or the water level in the rinsing water tank reaches a predetermined reference value.

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