KR20210025820A - Dishwasher system and control method - Google Patents

Abstract

Disclosed is a method for controlling a dishwasher system. The present invention comprises: an integrated temperature/water level sensor installed on an upper part of a wash water tank to detect wash water temperature and water level; and a control unit which measures the time from the time when temperature fluctuations are detected to no water level after detecting the temperature fluctuation through the integrated temperature/water level sensor, so that it is possible to distinguish between forced drainage and natural evaporation, and control to supply the required amount of washing water according to the judgment result.

Description

Dishwasher system and control method

The present invention relates to a dishwasher system and a control method for supplying a necessary amount of washing water according to a condition by dividing a state of natural evaporation of washing water and a state of forced drainage due to a long waiting period of washing.

A dishwasher is designed to wash dishes by washing and rinsing dishes in a washing tank. The timing of water supply required for dish washing and rinsing, pumps, supply and heating of washing water and rinsing water, and control of drainage are controlled through the control unit according to the water temperature and water level detection. In the dishwasher, a rinsing nozzle and a washing nozzle are located around a washing tank. The water supplied to the rinsing nozzle and the washing nozzle is divided into rinsing water and washing water, and the water stored in the rinsing water tank and the washing water tank is pumped by the rinsing pump and the washing pump, and supplied and circulated to the washing tank through the nozzle. The water supply pipe is connected to the rinsing water tank to supply rinsing water, and the supplied rinsing water is injected into the washing tank through the rinsing nozzle by the rinsing pump and then supplied to the washing water tank. The washing water is again injected into the washing tank through the washing pump and then returned to the washing water tank.

On the other hand, in order to control the washing water of the existing washing machine through the control unit, a water level electrode is installed on the full water level side of the washing tank, and it is determined whether the water level is full, and when the water level determination through the water level electrode is determined as'no water level', there is no water in the washing tank. It is judged as, and the operation of filling the washing water from the low water level to the full water level is instructed. This washing water control is the cause of supplying an excessive amount of washing water than the amount of washing water evaporated when the washing water is evaporated naturally according to the condition of waiting for washing for a long time. This is a situation that leads to a waste of water due to deterioration of the usability of users and over-operation of the washing machine. Accordingly, the natural evaporation of the washing water due to a long period of waiting for washing and the forced drainage condition due to the user's washing of the washing container are classified, and only the amount of washing water required according to each condition is additionally supplied to reduce the wastage of water due to over-operation of the washing machine. There is a need for proposals to reduce and improve the usability of users.

Patent Document 1. Korean Patent Publication 10-2006-0024511 (published on March 17, 2006)

Patent Document 2. Domestic Patent Publication No. 10-0813079 (announced on March 14, 2008)

One of the technical problems to be solved in the present invention is to use an integrated sensor that detects both the temperature and the water level, and separates the natural evaporation state of the washing water due to a long period of waiting for washing, and the forced drainage state due to washing of the user's washing container. The purpose is to reduce waste of resources due to over-operation of the washing machine and improve user usability by additionally supplying only as much washing water as necessary according to the condition.

The above objects are, according to the present invention, an integrated temperature/water level sensor installed on the top of the washing water tank to detect the washing water temperature and water level; And after detecting the temperature fluctuation through the integrated temperature/water level sensor, the time from the point when the temperature fluctuation is detected to the absence of the water level is measured to distinguish between forced drainage and natural evaporation, and the required amount of washing water is determined according to the determination result. It can be achieved from a dishwasher system, including; a control unit that controls to supply.

According to an embodiment of the present invention, the integrated temperature/water level sensor is installed in the washing water tank to detect temperature fluctuation through the integrated temperature/water level sensor, and then measure the time from the time when the temperature fluctuation is detected to no water level, and evaporate naturally. It may be configured to include a control unit that is controlled to separately determine a state and a forced drainage state, and to supply a necessary amount of washing water to the washing water tank according to the determination result.

According to an embodiment of the present invention, after detecting temperature fluctuation through the integrated temperature/water level sensor, it may be configured to include a control unit that determines whether the integrated temperature/water level sensor is exposed to the air by determining the degree of the temperature fluctuation. have.

According to an embodiment of the present invention, when the water level determination state of the washing water tank is in a natural evaporation state, the control unit supplies washing water having a capacity determined as the full water level of the washing water tank, and in the forced drainage state, the control unit supplies the water level from the bottom of the washing water tank. It may be configured to supply the washing water of a predetermined capacity.

According to an embodiment of the present invention, the control unit includes: a temperature/water level determination unit for determining a temperature and a water level detected from the integrated temperature/water level sensor; And a washing water state determination unit that detects the temperature fluctuation determined by the temperature/water level determination unit and then measures the time from when the temperature fluctuation is detected to no water level to distinguish between a natural evaporation state and a forced drainage state. Can be configured.

In addition, the above objects, according to the present invention, the step of detecting the washing water temperature and water level through the integrated temperature / water level sensor installed on the upper portion of the washing water tank; And after detecting the temperature fluctuation through the integrated temperature/water level sensor, the time from the point when the temperature fluctuation is detected to the absence of the water level is measured to distinguish between forced drainage and natural evaporation, and the required amount of washing water is determined according to the determination result. It may be achieved from a method of controlling a dishwasher system, including a washing water supply control step of controlling the supply to be supplied.

According to an embodiment of the present invention, the washing water supply control step includes: when the water level determination state of the washing water tank is in a natural evaporation state, the amount of washing water is supplied to the full water level of the washing water tank, and in the case of the forced drainage state, the washing water level is set to a full water level. It may be configured to include; controlling to supply a volume of washing water.

According to an embodiment of the present invention, the washing water supply control step may include a temperature/water level determination step of determining a temperature and a water level detected from the integrated temperature/water level sensor; And a washing water state determination step of detecting a temperature fluctuation determined in the temperature/water level determination step and then measuring a time from the point when the temperature fluctuation is detected to no water level to distinguish between a natural evaporation state and a forced drainage state. Can be configured.

The present invention distinguishes between a natural evaporation state and a state caused by the user's forced drainage, and thereby prevents indiscriminate supply of washing water by additionally supplying only a necessary amount of washing water, thereby eliminating wasted washing water and improving the usability of the user.

1 is an example of a dishwasher system according to an embodiment of the present invention.
2 is an example of a control unit constituting the dishwasher system according to an embodiment of the present invention.
3(a)(b) is a temperature/water level detection integrated sensor according to an embodiment of the present invention in which temperature fluctuations due to natural evaporation (A) and a drainage state due to forced drainage (B) are distinguished. This is an example of a temperature/water level graph.
4 is an exemplary flowchart illustrating a control routine of a dishwasher system according to an embodiment of the present invention.

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

The dishwasher used a water level electrode on the side of the washing tank full water level to determine whether the water level was full. For this reason, when the water level determination through the water level electrode is determined as'no water level', the washing water is stored at a low water level regardless of conditions such as evaporation or forced drainage. The pump control operation was performed to fill the water level at full water level, and this means that an excessive amount of washing water is supplied than the amount of washing water evaporated during the natural evaporation of the washing water, thereby reducing the usability of the user and wasting financial resources due to overoperation of the washing machine (e.g. For example, it leads to unnecessary water/electricity use).

The dishwasher system and control method according to the present invention utilizes a temperature fluctuation phenomenon that occurs when a part of an integrated sensor that detects both temperature and water level is exposed to the air, and a state of natural evaporation of washing water and a state of drainage due to forced drainage of the user. It is presented so that the indiscriminate supply of washing water can be effectively controlled by separately determining and supplying only the necessary amount of washing water according to the determination result.

The dishwasher system and control method according to the present invention uses an integrated sensor that detects temperature and water level together, and separates the state of natural evaporation of washing water due to waiting for washing for a long time and the state of forced drainage due to washing of the user's washing container. Accordingly, it is suggested to reduce the waste of financial resources due to over-operation of the washing machine and improve the usability of the user by additionally supplying the necessary amount of washing water.

1 is a schematic diagram of a dishwasher system. Dishwashers differ by type. The dishwasher system of FIG. 1 is an example of a gas dishwasher using gas as a heat source. The present invention is not limited to the dishwasher type as shown in FIG. 1.

2 is an example of a control unit constituting the dishwasher system according to an embodiment of the present invention.

As shown in FIG. 1, the dishwasher 100 is configured to wash dishes by washing and rinsing dishes in the washing tub 110. The timing of supplying cold and hot water required for washing and rinsing dishes, pumps, supplying and heating of washing water and rinsing water, and controlling drainage are controlled by the controller 200 according to the water temperature and water level detection of the water.

The dishwasher 100 includes a rinsing nozzle 120 and a washing nozzle 130 in the washing tub 110. The water supplied to the rinsing nozzle 120 and the washing 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 rinsed with a rinsing pump 160 and a washing pump. Each pumped to 170 is to be supplied into the washing tank 110.

The feed water pipe connected to the nozzle is divided into a rinsing water pipe and a washing water pipe, and a rinsing pump 160 is installed in the rinsing water pipe and a washing pump 170 is installed in the washing water pipe. Can supply. The direct water supplied through the water supply side (W1) is supplied to the rinsing water tank 140 when the water supply valve is opened, and the direct water supplied is pumped from the rinsing water tank 140 through the rinsing pump 160 to a heat exchanger ( (Not shown), it can be converted into hot water and circulated. In a gas dishwasher, the heat source of the heat exchanger may be a gas burner (not shown) that generates combustion heat.

The dishwasher system may be set to be controlled by the controller 200. The device part constituting the dishwasher system includes a water temperature detection unit that detects the water temperature in the washing water tank 150 and the rinsing water tank 140, a water level detection unit that detects the water level in the washing water tank and the rinsing water tank, and the washing water and rinsing water as a washing tank. It consists of a pump driving unit for pumping or circulating, a heat source unit including a heater for heating the washing water and the rinsing water, and a water supply and drain unit for supplying or draining the washing water and the rinsing water.

Here, in the washing water tank 150, a drain bar 180 designated with an overflow area 181 that overflows the washing water when the water level is exceeded is installed in a vertical direction.

The water temperature and water level detection unit may be configured with sensors that detect or measure the temperature and water level and transmit a detection signal to the control unit 200. The water supply and drainage units may be electronic valves composed of various types of electronic valves including a flow control valve that is opened and closed according to a control signal from the control unit 200. The heat source may be a gas burner, an electric heater, and an external heat source. Reference numeral '141', which is not described, is a rinsing heating unit installed in the rinsing tank, 151 is a washing heating unit installed in the washing water tank, and 182 is a drain connection unit including a drain valve installed below the drain bar.

As shown in FIG. 2, the control part is composed of a control part 200 that receives a detection signal from the device part and executes a program control command to determine and control the operation timing and order of each device. The temperature reference value of the washing water set in the control unit 200, the reference value of the set water level, the set flow rate value, etc. may be a comparison reference value stored in a program or a reference value arbitrarily set by the user through the operation device 250.

The control unit 200 may include a display unit that displays through a display panel that displays the start of washing, the current driving situation, and the input situation through the operation device 250, and the dishwasher control input and the current washing state and driving situation, etc. To be able to identify.

A detailed description of a dishwasher system 100 according to an embodiment of the present invention with reference to FIGS. 1 and 2 is as follows.

The present invention may be configured by installing an integrated temperature/water level sensor 300 on the upper portion of the washing water tank 150 to detect the washing water temperature and water level, as shown in FIG. 1.

And, the control unit 200 detects the temperature fluctuation through the integrated temperature/water level sensor 300 and then measures the time from the point when the temperature fluctuation is detected to the absence of the water level to distinguish between the natural evaporation state and the forced drainage state, and It may be configured to supply a necessary amount of washing water to the washing water tank 150 according to the determination result.

In addition, an integrated temperature/water level sensor 300 is installed in the rinse water tank 140 to detect temperature fluctuation through the integrated temperature/water level sensor 300, and then measure the time from the point when the temperature fluctuation is detected to no water level. Accordingly, the natural evaporation state and the forced drainage state may be classified and configured to supply the necessary amount of washing water to the rinsing water tank 140 according to the determination result.

In addition, when the water level determination state of the washing water tank 150 is a natural evaporation state, the control unit 200 has a capacity determined as the full water level of the washing water tank 150 (for example, a capacity sufficient to be filled up to the overflow area 181). ), and in the case of forced drainage, from the bottom of the washing water tank 150 to the full water level of the washing water tank 150 (for example, the capacity to be filled to the overflow area 181). It can be configured to control the pump to supply the wash water.

In addition, the control unit 200, as shown in Figure 2, the temperature / water level determining unit 210, 220 and a temperature / water level determining unit for determining the temperature and water level detected from the integrated temperature / water level sensor 300 (210) Including a washing water state determination unit 230 that separates the natural evaporation state and the forced drainage state by measuring the time from when the temperature fluctuation is detected to no water level after detecting the temperature fluctuation determined in (210) 220. It can be configured.

In addition, the control unit 200 includes a washing water supply unit 240 for controlling the supply of washing water through the washing water pump 170, and a combustion control unit for controlling combustion of a burner (not shown) that provides a heat source to the heating unit 270 ( 260).

The operation of the dishwasher system 100 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3 as follows.

3 is an example of a temperature/water level graph in which a temperature fluctuation (A) due to natural evaporation detected by a temperature/water level detection integrated sensor according to an embodiment of the present invention and a drainage state due to forced drainage (B) are determined separately. .

As shown in FIG. 1, in the washing water tank 150 of the dishwasher, an integrated temperature/water level sensor 300 capable of simultaneously detecting a water level and a temperature is provided at a position capable of detecting a full water level. After the washing water is filled in the washing water tank 150 to the full water level, the washing water is heated to complete the preparation for washing, and when the washing water is left in the washing standby state for a long time, the washing water naturally evaporates, so that the washing water level may be gradually lowered.

At this time, when a part of the integrated temperature/water level sensor 300 installed in the washing water tank 150 is exposed to the air due to evaporation of the washing water, the temperature of the washing water and the room temperature are simultaneously recognized and the temperature of'A' in FIG. 3(a). /There is a phenomenon in which the temperature fluctuates as shown in the water level graph. That is, when there is evaporation of the washing water, the temperature fluctuation caused by the natural evaporation can be detected through the temperature/water level detection integrated sensor 300.

In the washing standby state, since the integrated temperature/water level sensor 300 is immersed in water in the washing water tank 150, it is possible to detect that the temperature of the naturally heated washing water falls without temperature fluctuation. However, from the moment a part of the integrated sensor is exposed to the air due to spontaneous evaporation or forced drainage, the temperature data detected by the integrated sensor fluctuates. Here, temperature fluctuation refers to a set number of times (for example, 10 minutes) within a set time (for example, 10 minutes) from a positive number to a negative number, or from a negative number to a positive number, exceeding the value (differential value) of the specified temperature change over time. ) In case of abnormal change, it may be determined that temperature fluctuation has occurred, and the temperature fluctuation may be a shake because part of the integrated temperature/water level sensor 300 detects the temperature of air and part of the water.

Since the temperature of the water in the washing water tank 150 is controlled to be heated and maintained above a certain temperature (for example, 65 degrees Celsius) even in the state of waiting for washing, there is a large difference from the temperature of room temperature (for example, 5 degrees to 30 degrees Celsius). Accordingly, as the area where the integrated temperature/water level sensor 300 is exposed to the air increases, the vibration of the temperature may increase.

On the other hand, in the case of the integrated temperature/water level sensor 300 immersed in the washing water of the washing water tank 300, the temperature measurement value may be shaken due to convection or vibration of the washing water, or the shaking of the oil level due to dripping water. The amount of temperature change (differential value) according to the time that is judged as natural evaporation is shaken or less, or the temperature change amount is from positive to negative or from negative to positive within a set time (e.g., 10 minutes) a set number of times (e.g. For example, if it is measured as a case of changing less than 10 times), the corresponding temperature fluctuation may be determined as a vibration noise while the integrated temperature/water level sensor 300 is immersed in water.

Using such a temperature fluctuation phenomenon, it is possible to distinguish between the state of natural evaporation of the washing water and the state of forced drainage by the user's manipulation.

Subsequently, if the temperature fluctuation at the temperature detected by the integrated temperature/water level sensor 300 is recognized through the control unit 200, it is determined whether the current state is natural evaporation or forced drainage, and the timer starts counting. After the integrated temperature/water level sensor 300 is exposed to the air and the temperature fluctuates, the time when it is determined that there is no water level detected by the integrated temperature/water level sensor 300 is measured through the timers of the controller 200 .

When it is determined that the state is due to natural evaporation, it may be determined that a long time has elapsed until the integrated temperature/water level sensor 300 is completely exposed to the air and judged that there is no water level. In the case of the drainage state, the time when the integrated temperature/water level sensor 300 determines that there is no water level may be determined relatively short.

If the time measured by the state determination timer after detecting the temperature fluctuation phenomenon and then detecting the absence of the water level exceeds the maximum time (about 40 seconds) for forced drainage at the flushing water level, the corresponding state is It is determined not by the user's forced drainage but by the temperature fluctuation due to natural evaporation, and when it is less than the maximum time (about 40 seconds), it may be determined as the user's forced drainage operation.

Thereafter, when the washing water is resupplied to maintain the washing standby state, the operation time of the rinse water pump may be changed according to the forced drainage state or the natural evaporation state determined above, and the amount of washing water supplied may be controlled to be supplied differently. If the judgment state is forced drainage, the washing water pump is operated for the time from the low water level to the full water level (about 42 seconds) to supply the washing water. After being submerged, the washing water pump is operated for the time (about 5 seconds) until the washing water supplied to the washing water tank does not overflow due to excessive supply, or until the washing water state of the specified capacity at the specified full water level is reached. When the supply of the washing water is completed according to the determination state, the washing water is operated again in a washing standby state, and the operation may be repeatedly controlled through a series of control routines.

Here, the maximum time of the state determination timer and the supply time according to the determination state may vary depending on the size of the washing tank and the position of the integrated temperature/water level sensor, and the corresponding values may vary differently according to environment settings rather than a fixed value.

A method for controlling a dishwasher system according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3 as follows.

A method for controlling a dishwasher system according to an embodiment of the present invention includes the step of detecting a washing water temperature and a water level through an integrated temperature/water level sensor installed on an upper portion of the washing water tank, and detecting temperature fluctuation through the integrated temperature/water level sensor. It can be controlled as a washing water supply control step in which the time from the time when shaking is detected to no water level is measured to determine the state of forced drainage and natural evaporation separately, and to supply the necessary amount of washing water according to the determination result.

In addition, in the washing water supply control step, when the water level determination state of the washing water tank 150 is in a natural evaporation state, a capacity determined by the full water level of the washing water tank 150 (for example, a capacity sufficient to be filled to the overflow area 181). ), and in the case of forced drainage, the amount of washing water is supplied from the bottom of the washing water tank 150 to the full water level (e.g., the capacity to be filled to the overflow area 181 of the washing tank) It may include controlling to do so.

In addition, the washing water supply control step may include a temperature/water level determination step of determining a temperature and a water level detected from the integrated temperature/water level sensor 300; And a washing water state determination step of discriminating between a natural evaporation state and a forced drainage state by measuring a time from the point when the temperature fluctuation is detected to no water level after detecting the temperature fluctuation determined in the temperature/water level determination step. have

Meanwhile, a control routine of the dishwasher system according to an embodiment of the present invention may be executed, for example, as shown in FIG. 4.

4 is an exemplary flowchart illustrating a control routine of a dishwasher system according to an embodiment of the present invention.

When the dishwasher is turned on, and in a washing standby state, temperature fluctuation may be detected through an integrated temperature/water level sensor installed in the washing water tank (S110 to S111).

As a result of the determination in step S111, if the temperature fluctuation is not detected, it waits in a washing standby state (S110), and when the temperature fluctuation is detected, the controller 200 starts counting the state determination time (S112).

Subsequently, it is determined whether the maximum time for forced drainage has been exceeded (S113).

As a result of the determination in step S113, when it is determined that the maximum time for forced drainage has been exceeded, it is determined as a state of natural evaporation of the washing water (S114), and when the maximum time for forced drainage has not been exceeded, it is determined as a state of forced drainage (S115).

After the natural evaporation state and the forced drainage state are classified through the step S113, the water level off of the washing water tank is detected (S116).

Subsequently, it is determined whether it is in a natural evaporation state (S117).

As a result of the determination in step S117, when it is determined that the natural evaporation state is determined, the counting for the natural evaporation washing water supply time is started (S118), and when it is determined that the natural evaporation state is not, the forced drainage washing water supply time count is started (S119). ).

According to each time counted in the steps S118 to S119, the rinse water pump is operated to start the supply of washing water, and the pump operation is controlled according to a predetermined time, so that the washing water supply ends and the pump operation is stopped, and the water level on state is detected ( S120 to S122), it is controlled to wait by returning to the initial washing standby state (S110).

The dishwasher system and control method according to an embodiment of the present invention utilizes a temperature fluctuation phenomenon that occurs when a part of an integrated sensor that detects both temperature and water level is exposed to the air, and prevents the natural evaporation of washing water and the user's forced drainage. There is an advantage in that it is possible to effectively control the indiscriminate supply of washing water by separately determining the drainage state due to and supplying only the necessary amount of washing water according to the determination result.

The dishwasher system and control method according to an embodiment of the present invention uses an integrated sensor that detects both temperature and water level to distinguish between a state of natural evaporation of washing water due to waiting for washing for a long time and a state of forced drainage due to washing of the user's washing container. Accordingly, there is an advantage of reducing waste of resources due to over-operation of the washing machine and improving user usability by additionally supplying washing water as needed according to the condition.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but is not limited to the embodiments, and can be carried out with modifications and variations without departing from the gist of the present invention. Included in thought.

100: dishwasher 110: washing tank
120: rinsing nozzle 130: washing nozzle
140: rinse water tank 150: wash water tank
160: rinse water pump 170: wash water pump
180: drain bar 181: overflow area
200: control unit 210: temperature determination unit
220: water level determination unit 230: washing water condition determination unit
240: washing water supply control unit 250: operation device

Claims (8)

An integrated temperature/water level sensor installed on the top of the washing water tank to detect the washing water temperature and water level; And
After detecting temperature fluctuation through the integrated temperature/water level sensor, the time from when the temperature fluctuation is detected to no water level is measured to distinguish between forced drainage and natural evaporation, and supply the necessary amount of washing water according to the determination result. Containing, a dishwasher system; The method of claim 1,
The integrated temperature/water level sensor is installed in the washing water tank to detect temperature fluctuation through the integrated temperature/water level sensor, and then measure the time from the point when the temperature fluctuation is detected to no water level to distinguish between the state of natural evaporation and the state of forced drainage. And a control unit controlled to supply a necessary amount of washing water to the washing water tank according to the determination result. The method of claim 1,
And a control unit configured to determine whether or not the integrated temperature/water level sensor is exposed to air by detecting a temperature fluctuation through the integrated temperature/water level sensor and then determining a degree of the temperature fluctuation. The method of claim 1,
When the water level determination state of the washing water tank is in a natural evaporation state, the control unit supplies washing water having a capacity determined at the full water level of the washing water tank, and in the forced drainage state, supplying the washing water having a capacity determined at the full water level from the bottom of the washing water tank. Controlling, dishwasher system. The method of claim 1,
The control unit may include a temperature/water level determination unit for determining a temperature and a water level detected from the integrated temperature/water level sensor; And a washing water state determination unit configured to distinguish between a natural evaporation state and a forced drainage state by measuring a time from the point when the temperature fluctuation is detected to no water level after detecting the temperature fluctuation determined by the temperature/water level determination unit. , Dishwasher system. Detecting the washing water temperature and the water level through the integrated temperature/water level sensor installed on the upper part of the washing water tank; And
After detecting temperature fluctuation through the integrated temperature/water level sensor, the time from when the temperature fluctuation is detected to no water level is measured to distinguish between forced drainage and natural evaporation, and supply the necessary amount of washing water according to the determination result. A method for controlling a dishwasher system, including; washing water supply control step of controlling to be performed. The method of claim 6,
In the washing water supply control step, when the water level determination state of the washing water tank is in a natural evaporation state, the washing water having a capacity set to the full water level of the washing water tank is supplied, and in the case of the forced drainage state, controlling to supply the washing water of a predetermined capacity to the full water level Containing; method for controlling a dishwasher system. The method of claim 6,
The washing water supply control step may include a temperature/water level determination step of determining a temperature and a water level detected from the integrated temperature/water level sensor; And a washing water state determination step of detecting a temperature fluctuation determined in the temperature/water level determination step and then measuring a time from the point when the temperature fluctuation is detected to no water level to distinguish between a natural evaporation state and a forced drainage state. , Dishwasher system control method.

Images