KR100908003B1 - Dish washer - Google Patents

Abstract

A dish washer is provided to reduce power use according to rinse water heating by using effluent of high temperature drained after washing to heat the water supply of the low temperature freshly flowed as rinse water. A dish washer comprises a washing tank, a rinsing tank(101), pumps(104,105), a wastewater recycling unit(103), a heating tank(102) and a convection valve. In the washing tank, washing water is stored. In the rinsing tank, rinse water is stored. The pumps transfer the washing water and the rinse water stored in the washing tank and the rinsing tank. The wastewater recycling unit comprises a hose. The water supply of the low temperature inputted to the rinsing tank is flowed in the hose. In the surrounding of the hose, the effluent of the high temperature ejected from the washing tank flows. The heating tank is equipped at the lower part of the washing tank and heats the water supplied from the rinsing tank.

Description

Dishwasher {DISH WASHER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dishwasher, and more particularly, to a dishwasher for recycling water drained after washing to increase thermal efficiency and to minimize supply of bubbles generated by a heater.

In general, the dish washer (Dish washer) in order to perform the washing of the dishes more hygienic and efficient, mainly the washing and rinsing water contained in the lower tanks of the washer is a spray pipe that is transported through the supply pipe by the pump and rotated The washing water and the rinsing water are sequentially sprayed with high pressure through the nozzles to wash dishes placed in the rack. Among them, the rinsing water is made of hot water of about 80 ° C. or higher to rinse the dishes at high temperature while finally rinsing the dishes.

The operation process of the above-described washing machine injects hot water of about 60 ° C. heated through a water heater into the rinsing water tank before starting work, and then heats the heater to maintain the temperature of the rinsing water at about 90 ° C. for 60 seconds. The washing step is completed by spraying the dishes, and after waiting for 5 seconds, hot rinsing water is sprayed on the dishes to complete the rinsing step.

Then, after the withdrawal of the rack to install the rack in which the new dishes are placed inside the washing machine to repeat the above-described process, the dishwasher made for commercial use as in the present invention, unlike the household washing machine continues to It is designed to be cleaned.

However, the conventional dishwasher having the above-described configuration is required to heat the newly supplied water after spraying the rinsing water every time, causing a huge cost of power use. In addition, when the dishes are continuously supplied and washed continuously, it is difficult to effectively heat the rinsing water because it is necessary to continuously supply high temperature rinsing water in a short time. Therefore, there is an urgent need for a method for continuously and effectively supplying high temperature rinsing water.

On the other hand, when rinsing water is heated using a heater as in the prior art, a large amount of bubbles are generated around the heater. Accordingly, since bubbles are formed on the surface of the outlet port of the rinsing tank, a large amount of bubbles are supplied together when the rinsing water is sucked from the rinsing pump, thereby causing a difficulty in smooth rinsing action.

The present invention is to solve the above problems, an object of the present invention is to provide a dishwasher for recycling hot wastewater by using the hot wastewater discharged after washing to warm the low-temperature water flowing into the rinsing water. .

According to an embodiment of the present invention, the hot wastewater discarded after washing is flowed around the low temperature water supply flowing through the 'L' tube formed in two stages, thereby maintaining the temperature of the rinsing water quickly by heating the low temperature water supply. An object of the present invention is to provide a dishwasher which can be efficiently performed.

In addition, according to an embodiment of the present invention, an object of the present invention is to provide a dishwasher capable of quickly and efficiently maintaining the temperature of the rinsing water by setting a circulation path of the rinsing water heated through the rinsing tank to maximize the thermal efficiency. .

In addition, according to an embodiment of the present invention, an object of the present invention is to provide a dishwasher capable of reducing the amount of air bubbles entering the rinsing tank by providing a discharge rod in the outlet for discharging the heated rinsing water from the rinsing tank to the rinsing pump. do.

In order to achieve the above object, the dishwasher according to the embodiment of the present invention, the washing water and the rinsing water stored in the inner lower washing tank 115 and the rinsing tank 101 of the dishwasher case, respectively, to the pumps 104 and 105. In the dishwasher 100 are respectively transported through the supply pipes, which are sequentially sprayed to the dishes placed in the rack through the nozzle of the injection pipe, the dishwasher 100 including a hose 126 is formed of two bends ) Is provided in the lower portion, and the low-temperature water supplied to the rinsing tank 101 flows into the hose 126, and the hot waste water discharged from the washing tank 115 flows around the hose 126. A wastewater recycling apparatus 103 for heating the low temperature water supply by the high temperature wastewater; A heating tank 102 provided at a lower end of the rinsing tank 101 to heat water supplied from the rinsing tank 101 by a heater 119; And a convection valve 120 for supplying the water of the heating tank 102b to the rinsing tank 101 by a ball that is opened and closed by steam generated by boiling the water of the heating tank 102b. It is done.

At this time, the wastewater recycling apparatus 103, characterized in that the low-temperature water supply and the high-temperature wastewater flows in the opposite direction to each other, the device cover 124 and the hose of the wastewater recycling apparatus 103 Rubber packing 125 is inserted between the 126 is characterized in that the fastening.

In addition, the dishwasher is provided at the lower end of the rinsing tank 101, characterized in that it further comprises a heating tank 102 for heating the water supplied from the rinsing tank 101 by the heater 119. .

The heating tank 102 receives water from the rinsing tank 101 and receives water from the first heating tank 102a and the first heating tank 102a that are heated by the first heater 119a. It is characterized in that it comprises a second heating tank 102b for supplying the heated water to the rinsing tank 101 after being supplied with the second heater 119b.

The heating tank 102 may further include: first shielding means 131 having a predetermined opening through which water passes between the first heating tank 102a and the second heating tank 102b and dividing a space; It is characterized by including.

The dishwasher may include a convection valve for supplying the water of the second heating tank 102b to the rinsing tank 101 by a ball that is opened and closed by steam generated by boiling the water of the second heating tank 102b ( It further comprises a 120, the dishwasher, a predetermined heat insulating space 130 between the second heating tank 102b and the washing tank 115, the heating tank 102 It is characterized in that the temperature of the water supplied to the water is not taken away by the washing water of the washing tank (115).

In this case, the second heating tank 102b has a predetermined opening through which water passes between the second heater 119b and the outlet 132, and the second shielding means 133 for dividing a space, a predetermined length. It is characterized in that it further comprises a discharge rod 134 is installed in the outlet 132 to discharge water.

On the other hand, the dishwasher, characterized in that it further comprises a solenoid valve 108 for supplying to the wastewater recycling apparatus 103 by adjusting the amount of water supplied to the dishwasher by an electrical signal, And a pressure reducing valve 107 which serves to maintain the water pressure of the water supply flowing into the dishwasher to a reference value or less.

In addition, the dishwasher is supplied with water to one end, the other end is located at the lower end of the rinsing tank 101, the water supply pipe 110 for supplying the water supplied from the one end to the rinsing tank (101) It characterized in that it further comprises, one end is located in the upper portion of the rinsing tank 101, the other end is located in the heating tank 102, the high temperature water in the upper portion of the rinsing tank 101 It characterized in that it further comprises a pipeline 118 for supplying to the heating tank (102).

In this case, the pipeline 118 is characterized in that the other end of the pipeline 118 is installed in close proximity to the flange of the heater 119a provided in the heating tank 102.

In order to achieve the above object, the dishwasher according to another embodiment of the present invention, the washing water and the rinsing water stored in the inner lower washing tank 115 and the rinsing tank 101 of the dishwasher case, respectively, the pumps (104, 105) In the dishwasher 100 is respectively transported through the supply pipes, which are sequentially sprayed to the dishes placed in the rack through the nozzle of the injection pipe, provided at the bottom of the rinsing tank 101, the rinsing tank 101 ) Is supplied with water from the first heating tank (102a) to be heated by the first heater (119a), the water is supplied from the first heating tank (102a) and heated by the second heater (119b), and then again And a second heating tank 102b for supplying the heated water to the rinsing tank 101, wherein the second heating tank 102b includes water between the second heater 119b and the outlet 132. A second for dividing the space having a predetermined opening therethrough; It characterized by comprising a waste unit 133, a discharge bar 134 that has a predetermined length is provided in the discharge port 132 discharging the water.

The dishwasher according to the present invention provides an effect of reducing power usage due to rinsing water heating by using the hot wastewater discharged after washing to warm the low temperature water introduced into the rinsing water.

The dishwasher according to the embodiment of the present invention allows the hot waste water discarded after washing to flow around the low temperature water supply flowing through the 'L' tube formed in two stages, thereby maintaining the temperature of the rinsing water by heating the low temperature water supply. It provides the effect of making it faster and more efficient.

In addition, the dishwasher according to the embodiment of the present invention provides an effect of quickly and efficiently maintaining the temperature of the rinsing water by setting the circulation path of the rinsing water heated through the rinsing tank to maximize the thermal efficiency.

In addition, the dishwasher according to the embodiment of the present invention provides an effect of reducing the amount of bubbles introduced into the rinsing tank by having a discharge rod at the outlet for discharging the heated rinsing water from the rinsing tank to the rinsing pump.

The present invention proposes a wastewater recycling apparatus of a dishwasher for recycling hot wastewater by reusing hot wastewater that is drained after washing in a dishwasher to warm the low temperature water newly introduced into the rinsing tank.

To this end, a predetermined waste water recycling apparatus is installed in the lower part of the dishwasher, and the high temperature wastewater drained from the washing tank and the low temperature water newly introduced into the rinsing tank flow in the waste water recycling apparatus so as to cross each other. It can be heated to low temperature without water.

At this time, the water supply hose of the wastewater recycling apparatus is formed in two stages to increase the thermal efficiency by increasing the contact area with the hot wastewater.

As such, by supplying water to the rinsing tank after the primary heating by the hot wastewater, the time for heating the water supplied to the rinsing tank can be shortened, and the power consumption required for heating can be reduced.

In addition, the present invention enables to maintain the temperature of the rinsing water quickly and efficiently by setting the circulation path of the rinsing water heated through the rinsing tank to maximize the thermal efficiency. To this end, a water supply pipe for supplying water to the rinsing tank and a pipeline for supplying water from the rinsing tank to the heating tank are arranged to optimize thermal efficiency, and the path is set so that the area of rinsing water reaches the heater is maximized even in the heating tank. do.

In addition, the present invention can reduce the amount of bubbles flowing into the rinsing tank by having a discharge rod at the outlet for discharging the heated rinsing water from the rinsing tank to the rinsing pump.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4 is a view showing a dish washer according to an embodiment of the present invention.

1 is a front view of a dish washer according to an embodiment of the present invention. In the dishwasher 100 according to the embodiment of the present invention, a rack on which a table is placed on an upper portion covered with a case, and a spray pipe for washing and rinsing by washing with high pressure and sequentially washing water and rinsing water, respectively, are disposed above and below the rack.

The rinsing tank 101 storing the rinsing water and the washing tank storing the washing water are installed in the lower part of the dishwasher, and supplying water from the rinsing tank 101 and the washing tank 115 to the spray pipe during rinsing or washing, respectively. Is provided with a rinsing pump 105 and a washing pump 104.

On the other hand, according to an embodiment of the present invention, the waste water recycling apparatus 103 is further installed in the lower part of the dishwasher, and the high temperature wastewater that is drained after washing by the wastewater recycling apparatus 103 according to an embodiment of the present invention. It will be reused to warm the new low temperature feedwater into the furnace rinse tank.

More specifically, first, water supplied through the first hose 106 may be a reducing valve 107 and a solenoid valve (ie, a solenoid valve) ( It is introduced into the wastewater recycling apparatus 103 through the second hose 109 via 108.

The water warmed by the waste water of the high temperature in the wastewater recycling apparatus 103 is supplied to the rinsing tank 101 through the water supply pipe 110. Meanwhile, the wastewater discharged from the washing tank through the elbow tube 111 is supplied to the wastewater recycling apparatus 103 through the third hose 112, and the wastewater recycling apparatus 103 heats the low temperature water supply. Through 113).

Meanwhile, the wastewater recycling apparatus 103 is formed in two stages so as to be sufficiently warmed by the low temperature water supplied through the second hose 109 and the high temperature wastewater supplied through the third hose 112. 'It's designed to be adjacent to form a channel.

A detailed description of the wastewater recycling apparatus 103 will be described later with reference to FIG. 7.

As such, the water supplied by the wastewater recycling apparatus 103 and supplied to the rinsing tank is supplied to the rinsing water injection pipe by the rinsing pump 105, and the water supplied to the washing tank is washed by the washing pump 104. It is supplied to the injection pipe.

2 is a left side view of the dish washing machine described above with reference to FIG. 1. Referring to FIG. 2, it can be seen that water supplied to the first hose 106 is supplied through the water inlet 114.

3 is a rear view of the dishwasher according to the embodiment of the present invention. Referring to FIG. 3, it can be seen that the washing tank 115 is installed on the rear surfaces of the rinsing tank 101 and the heating tank 102 shown in FIG. 1. As such, it can be seen that the wastewater discharged after washing in the washing tank 115 is supplied to the wastewater recycling apparatus 103 through the elbow pipe 111 and the third hose 112.

4 is a bottom view of the dishwasher according to the embodiment of the present invention. Referring to FIG. 4, the low temperature water is introduced into the wastewater recycling apparatus 103 through the second hose 109, heated by the high temperature wastewater, and then discharged through the water supply pipe 110 to rinse the tank 101. Is supplied. In addition, the high temperature wastewater introduced through the third hose 112 is discharged to the drain port 113 after heating the low temperature water supply through the wastewater recycling apparatus 103.

5 and 6 are views showing the water supply tank of the dishwasher according to the embodiment of the present invention.

5 is a cross-sectional view of the water supply tank of the dishwasher according to the embodiment of the present invention, and FIG. 6 is a perspective view of the water supply tank of the dishwasher according to the embodiment of the present invention.

5 and 6, the rinsing tank 101 is provided on the left side, and the washing tank 115 is provided on the right side. In addition, two heating tanks 102 are provided below the rinsing tank 101, and the rinsing water is heated by the heater 119 (for example, a flange-type heater) for each heating tank 102. At this time, the two heating tanks 102 installed in the lower part become the main tank, and the rinsing tank 101 installed in the upper part becomes the auxiliary tank.

The heating tank 102, which is the main tank, heats the rinsing water to 100 ° C. by the two flange-type heaters 119, and the heated rinsing water is supplied to the rinsing tank 101, which is the auxiliary tank, at 90 ° C. To maintain the temperature.

Hereinafter, the circulation and convection of the water supplied to the rinsing tank 101 and the washing tank 115 will be described in detail with reference to FIGS. 5 and 6.

First, water supplied primarily to about 40 ° C. by the wastewater recycling apparatus 103 according to an embodiment of the present invention is introduced into the rinsing tank 101 through the water supply pipe 110. At this time, the water supplied to the rinsing tank 101 is accumulated in the upper portion of the rinsing tank 101, the water accumulated in this way through the pipeline 118, the first heating tank 102a of the lower left of the rinsing tank 101 Watered by In addition, water supplied to the first heating tank 102a flows into the second heating tank 102b through the opening of the first shielding means 131. Water reheated in the second heating tank 102b is supplied to the rinsing pump 105 through the outlet 132.

At this time, when the tanks of the rinsing tank 101, the first heating tank 102a and the second heating tank 102b are filled with water, the first sensor 117 detects the water, and each heating tank 102. The heater 119 provided in the is to operate. As such, while the heater 119 is operated, water is supplied to the washing tank 115 through the supply pipe 122 above the rinsing tank 101, and water is supplied to the second sensor 121 provided in the washing tank 115. When this detection is detected, the water supply to the washing tank 115 is stopped.

In addition, the water of the first heating tank 102a and the second heating tank 102b continues to be heated and boiled by the heaters 119a and 119b, respectively, wherein the water of the rinsing tank 101 through the convection valve 120 is heated. And convection. The function of the convection valve 120 will be described later in the description of FIG. 10. The convection is automatically rotated three times when the temperature of the rinsing tank 101 is 90 ℃ and from this time it is to use the washing and rinsing functions of the dishwasher normally.

The waste water discarded while using the machine is introduced into the wastewater recycling apparatus 103 through the elbow pipe 111 and the third hose 112 according to the present invention as described above. The low temperature water supply of 10 ° C. is heated to 40 ° C. by the waste water introduced into the waste water recycling apparatus 103, and the warmed low temperature water is again filled in the rinsing tank 101 through the water supply pipe 110.

On the other hand, according to an embodiment of the present invention, the water tank (ie, the rinsing tank 101, the heating tank 102, the washing tank 115) and the water supply path are optimally arranged to maximize thermal efficiency. Hereinafter, the arrangement of each component to maximize the thermal efficiency will be described in detail.

First, the water supplied to the rinsing tank 101 by the water supply pipe 110 is water at 40 ° C., which is lower than 90 ° C., which is the temperature of the rinsing water stored in the rinsing tank 101. When directly supplied to the 101, the temperature of the water in the rinsing tank 101 warmed by the supplied water may be lowered. At this time, the water of the high temperature rises by the convection in the rinsing tank 101, so that the upper layer shows a higher temperature than the lower end.

Therefore, by placing the discharge port of the water supply pipe 110 at the lower end of the rinsing tank 101, it is possible to prevent the high temperature rinsing water from being deprived of heat by the low temperature water supply.

Next, water is supplied through the pipeline 118 so that water of the rinse tank 101 may be supplied to the lower heating tank 102 at a relatively high temperature. That is, by placing one end of the pipeline 118 in the upper portion of the rinsing tank 101 and the other end in the heating tank 102, the high temperature water in the upper portion of the rinsing tank 101 is heated And can be supplied to 102. Here, the lower end of the pipeline 118 (located in the heating tank) is located below the interface between the rinsing tank 101 and the heating tank 102. The lower end of the pipeline 118 is preferably located 4 cm or more below the boundary surface (the reason thereof will be described later in the description of FIG. 10).

In addition, the other end in contact with the heating tank 102 in the pipeline 118 is installed close to the flange side of the first heater 119a provided in the heating tank 102, the heating tank 102 By setting the movement path of the water supplied to the heaters 119a and 119b to be the maximum, the effective heating can be achieved.

That is, the water supplied to the flange side of the first heater 119a provided in the heating tank 102 causes the first heater 119a to flow from the flange side to the end and through the opening of the first shielding means 131. It is supplied to the 2nd heater 119b side. In addition, the water supplied to the second heater 119b flows toward the flange at the end of the second heater 119b and then is supplied to the rinsing pump 105 through the outlet 132.

At this time, a predetermined heat insulating space 130 is provided between the second heating tank 102b and the washing tank 115 so that the temperature of the water supplied to the heating tank 102 is not taken away by the washing water of the washing tank 115. It is desirable to. That is, it is preferable that the water of the heating tank 102 and the water of the washing tank 115 are designed so as not to lose heat from the washing tank 115 because of a large temperature difference.

If there is no adiabatic space 130, the temperature rise of the heating tank 102 is delayed, and may drop sharply even if the temperature rises.

7A to 7E are six views of the wastewater recycling apparatus for the dishwasher according to the embodiment of the present invention. 7A to 7E, it is preferable that the drainage and the water supply are designed to be adjacent to each other through the largest area so that the hot water flowing into the wastewater recycling apparatus 103 can supply the heat to the low temperature water supply as much as possible. .

Therefore, according to the embodiment of the present invention, the low-temperature water flowing into the wastewater recycling apparatus 103 flows through the 'L'-shaped pipe, and the hot water flows along the periphery of the pipe in opposite directions to each other. The heat can be supplied to the water supply as much as possible.

In addition, according to an embodiment of the present invention by configuring the 'r' shaped tube flowing low temperature water supply in two stages, it is possible to widen the area between the low temperature water supply and the high temperature drainage compared to when configured in one stage do. As a result, the heat absorption can be accelerated to increase the thermal efficiency by 50% or more. For example, in the case of the first stage, the water is increased to 30 ° C. through the water at 10 ° C. and discharged, but the temperature of the water can be increased to 40 ° C. in the second stage.

If, according to an embodiment of the present invention is used without supplying water at 40 ° C and supplying water at 30 ° C to the rinsing tank 101, more time and power are required to raise the rinsing water to 90 ° C to 100 ° C. Is consumed. In addition, when the heating time is additionally taken, serious problems may occur, such that when a continuous washing operation is to be performed, the high temperature rinse water or the washing water cannot be supplied effectively. Therefore, when the hose of the wastewater recycling apparatus is formed in two stages according to an embodiment of the present invention, the continuous washing function becomes possible.

For example, even if the washing is operated more than 30 times continuously, the normal operation is possible only when the temperature of the rinsing water is maintained at 80 ° C. Therefore, such continuous washing is impossible when water of 30 ° C. is supplied to the rinsing tank 101.

Meanwhile, the rinsing tank 101 and the washing tank 115 may be installed adjacent to each other to maintain a high temperature of the washing water filled in the washing tank 115 by the high temperature rinsing water filled in the rinsing tank 101.

8 and 9 are views showing the structure and principle of the water supply according to an embodiment of the present invention. Referring to FIGS. 8 and 9, as described above, the water supplied through the water inlet 114 may include the first hose 106, the pressure reducing valve 107, the sole valve 108, and the second hose 109. The wastewater is input to the wastewater recycling apparatus 103, and heated by the wastewater having a high temperature through the wastewater recycling apparatus 103, and then supplied to the rinsing tank 101 through the water supply pipe 110.

Meanwhile, referring to FIG. 8, the pressure reducing valve 107 serves to maintain a constant water pressure of the supplied water supply. For example, water is supplied for 40 seconds during a one minute wash time, when low temperature water is introduced at a time with high water pressure, low temperature water that is not heated to a constant temperature is supplied to the wash water or rinsing water to smoothly wash the water. And rinsing operations are not performed. Therefore, the water pressure is adjusted so that the water supply is not supplied above the predetermined water pressure through the pressure reducing valve 107.

Referring to FIG. 9, according to the present invention introduced into the rinsing tank 101, the first heated water is secondarily heated by the heater 119 of the heating tank 102, and according to the function of the convection valve 120. By convection, rinsing water and washing water of a desired temperature are supplied.

8 and 9, as described above, according to the embodiment of the present invention, the structure of the wastewater recycling apparatus 103 is formed in a two-stage structure, so that a lower temperature water supply is supplied at a higher temperature (e.g., , 40 ° C.).

10A and 10B illustrate a convection valve 120 according to an embodiment of the invention.

If the water in the first floor heating tank 102 does not boil, the convection valve 120 is blocked by a ball, as shown in FIG. 10A. To do this, the specific gravity of the ball must be greater than that of water. Therefore, when the water does not boil, since the convection valve 120 is closed by the weight of the ball having a higher specific gravity than water, convection is not performed. By the above configuration, when the temperature of the heating tank 102 is not sufficiently high, the temperature of the rinsing water in the heating tank 102 can be prevented from being lowered by the convection phenomenon.

However, when steam is generated while the water is boiling, as shown in FIG. 10b, the ball rises and serves to supply boiling steam to the two-stage rinsing tank 101 (for details, see FIG. 10C. It will be described later through). At this time, the cold water of the two-stage rinsing tank 101 flows down to the lower layer by the amount of hot water of the one-stage heating tank 102 to the two-stage rinsing tank 101, and convection is performed. This movement is repeated while the first floor heating tank 102 is boiling. Therefore, convection occurs between the hot water of the first layer and the cold water of the second layer, resulting in a smaller temperature difference between the first and second layers. In addition, the convection valve 120 discharges the bubbles generated by the second heater 119b to the upper rinsing tank 101, thereby preventing the bubbles from being discharged through the outlet 132.

10C is a conceptual diagram illustrating an operating principle of the convection valve 120 according to an embodiment of the present invention. FIG. 10C is not a rinsing tank 101 and a heating tank 102 according to an embodiment of the present invention, but is simplified for operational principle description and physical calculation. Therefore, the divided first heating tank 102a and the second heating tank 102b are regarded as one heating tank, and the shape of the convection valve 120 and its balls is cylindrical for simplicity of calculation. Assumed, the location of convection valve 120 and pipeline 118 was also simplified.

When the water boils in the heating tank 102, water vapor is generated, and since the water vapor is much lower in specific gravity than the water, the water and the water vapor in the heating tank 102 are located together in FIG. 10C. As described above with reference to FIGS. 5 and 6, the lower end of the pipeline 118 is located below the interface between the rinsing tank 101 and the heating tank 102, so that the generated water vapor forms the pipeline 118. Some water vapor generated below the bottom of the pipeline 118 of the steam generated around the bottom of the pipeline 118 may flow back through the pipeline 118, but this is not the I would say very little compared to the amount.

In the arrangement of the water vapor and water positioned as shown in FIG. 10C, the condition for supplying the water vapor generated from the heating tank 102 to the rinsing tank 101 through the convection valve 120 is determined.

First, the pressure PA for escaping water vapor in the A direction is obtained as in Equation 1. (Specific gravity of water is ρ, specific gravity of ball is ρ _B , area of ball is S)

The pressure P _B for evacuating the steam in the B direction (and eventually the pipeline 118) is obtained from Equation 2 below.

이어야 하므로,In order for the water vapor to escape to the A side

Must be

Therefore, the specific gravity equation 3 of the ball for the steam to escape to the A side.

Same as

The boiling point of water is the temperature at which the water vapor pressure on the water surface is equal to the external air pressure, and when the specific gravity of the ball satisfying the conditions as shown in Equation 3 is adopted, the temperature of the water inside the heating tank 102 is gradually increased so that the water vapor pressure is P _A. when (P _a is smaller than P _B before it reaches the P _B) water is a boil, steam is generated and exits through the convection valve 120.

11 is an exploded view of the wastewater recycling apparatus for the dishwasher according to the embodiment of the present invention. Referring to FIG. 11, the wastewater recycling apparatus 103 according to an embodiment of the present invention includes a fourth hose 126 having a second stage 'L' shape for efficient heat transfer, and includes an apparatus cover 124 and a rubber packing. Between the 125 may be fastened by a fastening means such as a bolt 123.

12 and 13 are views showing the structure and principle of drainage according to an embodiment of the present invention. 12 and 13, as described above with reference to FIGS. 8 and 9, the wastewater may be reused by heating the water supplied to hot wastewater to be drained. That is, the high temperature wastewater discharged through the elbow tube 111 and the third hose 112 after washing is heated through the wastewater recycling apparatus 103 to heat the low temperature water supply, and then discharged through the drain port 113.

14 is a perspective view of a water supply tank of the dishwasher for reducing bubble supply according to another embodiment of the present invention. Referring to FIG. 14, a second shielding means 133 is installed between the second heater 119b and the outlet 132 in the second heating tank 102b according to another embodiment of the present invention, and the outlet 132 is provided. The discharge rod 134 is further provided.

That is, in this configuration, the water heated by the second heater 119b is not directly discharged to the discharge port 132, but is discharged through the discharge rod 134 through the opening of the second shielding means 133. Accordingly, there is an effect of preventing bubbles generated in the second heater 119b from directly flowing into the outlet 132.

In addition, preferred embodiments of the present invention are disclosed for the purpose of illustration, those skilled in the art will be able to various modifications, changes, additions, etc. within the spirit and scope of the present invention, such modifications and modifications belong to the following claims You will have to look.

1 is a front view of the dishwasher according to the embodiment of the present invention.

2 is a left side view of the dishwasher according to the embodiment of the present invention.

3 is a rear view of the dishwasher according to the embodiment of the present invention.

4 is a bottom view of the dishwasher according to the embodiment of the present invention.

5 is a cross-sectional view of the water supply tank of the dishwasher according to the embodiment of the present invention.

Figure 6 is a perspective view of the water supply tank of the dishwasher according to the embodiment of the present invention.

7a to 7e is a six-dimensional view of the wastewater recycling apparatus for dishwasher according to the embodiment of the present invention.

8 and 9 are views showing the structure and principle of water supply according to an embodiment of the present invention.

10A and 10B illustrate a convection valve, in accordance with an embodiment of the invention.

10C is a conceptual diagram for explaining the operation principle of the convection valve 120 according to the embodiment of the present invention.

11 is an exploded view of the wastewater recycling apparatus for the dishwasher according to the embodiment of the present invention.

12 and 13 illustrate the structure and principle of drainage according to an embodiment of the invention.

14 is a perspective view of a water supply tank of the dishwasher for reducing bubble supply according to another embodiment of the present invention.

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

100: dishwasher 101: rinse tank

102: heating tank 103: wastewater recycling device

104: washing pump 105: rinsing pump

106: first hose 107: pressure reducing valve

108: solenoid valve 109: second hose

110: water supply pipe 111: elbow pipe

112: third hose 113: drain

114: feed water inlet 115: washing tank

116: washing drain 117: first sensor

118: pipeline 119a: first heater

119b: second heater 120: convection valve

121: second sensor 122: supply pipe

123: Bolt 124: Device Cover

125: rubber packing 126: fourth hose

130: heat insulation space 131: first shielding means

132: outlet 133: second shielding means

134: discharge rod

Claims (22)

The washing water and the rinsing water stored in the inner lower washing tank 115 and the rinsing tank 101 of the dishwasher case, respectively, are transferred through the supply pipes by the pumps 104 and 105, and the dishes placed in the rack through the nozzles of the spray pipe. In the dishwasher 100 which is sprayed sequentially in the field, Including a hose 126 having a two-stage bending is provided in the lower portion of the dishwasher 100, the low-temperature water supplied to the rinsing tank 101 flows into the hose 126, the washing tank A wastewater recycling apparatus (103) for flowing hot wastewater discharged from (115) around the hose (126) to heat the low temperature water supply by the hot wastewater; A heating tank 102 provided at a lower end of the rinsing tank 101 to heat water supplied from the rinsing tank 101 by a heater 119; And And a convection valve (120) for supplying the water in the heating tank (102b) to the rinsing tank (101) by a ball that is opened and closed by steam generated by boiling the water in the heating tank (102b). Dishwasher. The wastewater recycling apparatus 103 of claim 1, And the hot water and the hot waste water cross in opposite directions. The wastewater recycling apparatus 103 of claim 1, And a rubber packing (125) is inserted between the device cover (124) of the waste water recycling device (103) and the hose (126). The method of claim 1, wherein the heating tank 102, A first heating tank 102a which receives water from the rinsing tank 101 and heats it by the first heater 119a, And a second heating tank 102b which receives water from the first heating tank 102a and heats it by the second heater 119b and then supplies the heated water to the rinsing tank 101 again. Dishwasher, characterized in that. The method of claim 4, wherein the heating tank 102, And a first shielding means (131) having a predetermined opening through which water passes between the first heating tank (102a) and the second heating tank (102b) to divide the space. . According to claim 4, The dishwasher, A predetermined heat insulating space 130 is provided between the second heating tank 102b and the washing tank 115, so that the temperature of the water supplied to the heating tank 102 is taken away by the washing water of the washing tank 115. Dishwasher, characterized in that not to. The method of claim 4, wherein the second heating tank 102b, Second shielding means 133 having a predetermined opening through which water passes between the second heater 119b and the outlet 132, and dividing a space; Dishwasher having a predetermined length further comprises a discharge rod (134) is installed in the discharge port (132) for discharging water. According to claim 1, The dishwasher, And a solenoid valve (108) for controlling the amount of water supplied to the dishwasher by an electrical signal to supply the wastewater recycling apparatus (103). According to claim 1, The dishwasher, And a pressure reducing valve (107) which serves to maintain the water pressure of the water supply flowing into the dishwasher to a reference value or less. According to claim 1, The dishwasher, Water supply is supplied to one end, and the other end is located at the lower end of the rinsing tank 101, characterized in that it further comprises a water supply pipe 110 for supplying the water supplied from the one end to the rinsing tank 101 Dishwasher. According to claim 1, The dishwasher, One end is positioned above the rinsing tank 101, the other end is located in the heating tank 102, the pipeline for supplying the water in the upper portion of the rinsing tank 101 to the heating tank 102 A dishwasher further comprising (118). The method of claim 11, wherein the pipeline 118, The other end of the pipeline (118) is a dishwasher, characterized in that installed in close proximity to the flange of the heater (119a) provided in the heating tank (102). The washing water and the rinsing water stored in the inner lower washing tank 115 and the rinsing tank 101 of the dishwasher case, respectively, are transferred through the supply pipes by the pumps 104 and 105, and the dishes placed in the rack through the nozzles of the spray pipe. In the dishwasher 100 which is sprayed sequentially in the field, A first heating tank 102a provided at a lower end of the rinsing tank 101 and receiving water from the rinsing tank 101 to be heated by the first heater 119a, A second heating tank 102b that receives water from the first heating tank 102a and is heated by the second heater 119b, and then supplies the heated water to the rinsing tank 101 again. , The second heating tank 102b has a predetermined opening through which water passes between the second heater 119b and the outlet 132, and second shielding means 133 for dividing the space, and has a predetermined length. Dishwasher installed in the outlet 132, characterized in that it comprises a discharge rod for discharging water (134). The method of claim 13, wherein the dishwasher, And a first shielding means (131) having a predetermined opening through which water passes between the first heating tank (102a) and the second heating tank (102b) to divide the space. . The method of claim 13, wherein the dishwasher, And a convection valve 120 for supplying the water of the second heating tank 102b to the rinsing tank 101 by a ball that is opened and closed by steam generated by boiling the water of the second heating tank 102b. Dishwasher, characterized in that. The method of claim 13, wherein the dishwasher, A predetermined heat insulating space 130 is provided between the second heating tank 102b and the washing tank 115, so that the temperature of the water supplied to the heating tank 102 is taken away by the washing water of the washing tank 115. Dishwasher, characterized in that not to. The method of claim 13, wherein the second heating tank 102b, Second shielding means 133 having a predetermined opening through which water passes between the second heater 119b and the outlet 132, and dividing a space; Dishwasher having a predetermined length further comprises a discharge rod (134) is installed in the discharge port (132) for discharging water. The method of claim 13, wherein the dishwasher, And a solenoid valve (108) for controlling the amount of water supplied into the dishwasher by an electrical signal to supply the rinse tank (101). The method of claim 13, wherein the dishwasher, And a pressure reducing valve (107) which serves to maintain the water pressure of the water supply flowing into the dishwasher to a reference value or less. The method of claim 13, wherein the dishwasher, Water supply is supplied to one end, and the other end is located at the lower end of the rinsing tank 101, characterized in that it further comprises a water supply pipe 110 for supplying the water supplied from the one end to the rinsing tank 101 Dishwasher. The method of claim 13, wherein the dishwasher, One end is positioned above the rinsing tank 101, and the other end is positioned at the first heating tank 102a, so that water in the upper part of the rinsing tank 101 is flushed with the first heating tank 102a. Dishwasher, characterized in that it further comprises a pipeline (118) for supplying. The method of claim 21, wherein the pipeline 118, And the other end of the pipe line (118) is installed close to a flange of a heater (119a) provided in the first heating tank (102a).

Images