KR20160149674A - Dishwasher and Method for controlling it - Google Patents

Abstract

The present invention relates to a dishwasher capable of determine the amount of objects to be washed with only a temperature sensor, and a control method thereof. According to the present invention, the dishwasher comprises: a tub receiving objects to be washed and providing a washing space; a sump collecting washing water sprayed inside the tub, and including a temperature sensor and a heater; one or more spray arms to spray the washing water towards objects to be washed; a supply pump to supply the washing water stored in the sump to the one or more spray arms; and a control unit to control the temperature sensor and the water supply pump. The control unit controls the heater and the supply pump according to one of a plurality of washing courses based on a difference value between a first temperature detected in the temperature sensor after the washing water is sprayed towards the inside of the tub for a predetermined first time and a second temperature detected in the temperature sensor after the washing water is sprayed towards the inside of the tub for a predetermined second time.

Description

[0001] Dishwasher and its control method [0002]

The present invention relates to a dishwasher and a control method thereof, and more particularly to a dishwasher and a dishwasher capable of automatically determining a washing course based on an amount of a subject to be cleaned, And a control method thereof.

A general dishwasher is a device for washing foreign matter such as food waste attached to a surface of a tableware by spraying high-pressure washing water to a cleaning object (for example, a tableware) housed therein.

The dishwasher includes a water supply device for supplying wash water from the outside and a drain device for discharging the used wash water back to the outside. In the dishwasher, a tub is formed in which a space for washing dishes is stored, and a tub is provided with a spray nozzle capable of spraying wash water at a high pressure.

The washing water is collected by the sump installed on the lower side of the tub. In the sump, the foreign substances contained in the washing water are crushed and filtered during the washing process. Then, the dishware is washed while forming a circulating flow path which is pumped upward by the driving unit and sprayed to the tub through the spraying arm.

Further, the sump may be provided with a heater for heating the washing water, and the washing efficiency may be improved by heating the washing water.

On the other hand, the amount of washing water to be used, the heating temperature of the washing water, the washing time, the spraying power of the washing water, and the like can be controlled differently depending on the amount of the object to be cleaned stored in the tub as the washing space. This is to optimize the consumption of wash water and power used.

In a conventional dishwasher, a sensing value sensed by a turbidity sensor is used to determine the amount of a cleaning object accommodated in the tub.

That is, the turbidity sensor is installed in the sump, and the amount of the object to be cleaned is determined based on the turbidity of the washing water detected by the turbidity sensor when the washing water sprayed toward the object to be cleaned is collected into the sump.

However, in the case where a small amount of dishwasher is contaminated or a foreign substance (for example, milk or the like) which increases the turbidity is attached, the turbidity of the washing water detected by the turbidity sensor becomes high and a large amount of the washing object is housed inside the tub There is a problem that can be judged.

That is, although a relatively small amount of the cleaning object is accommodated in the tub, the sensing value sensed by the turbidity sensor may vary depending on the type of the foreign object attached to the object to be cleaned.

Further, when the turbidity sensor is used to determine the amount of the object to be cleaned, the manufacturing cost of the dishwasher may be increased as much as the price of the ballistic sensor.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a dishwasher capable of determining the amount of an object to be cleaned by using only a temperature sensor without a turbidity sensor.

It is another object of the present invention to provide a dishwasher capable of accurately and easily determining the amount of a cleaning object irrespective of the type of foreign matter attached to the object to be cleaned, by determining the amount of the object to be cleaned through the temperature sensor.

It is another object of the present invention to provide a dishwasher in which the turbidity sensor is not used in a dishwasher, thereby reducing the overall product cost.

The present invention provides a washing machine comprising: a tub for receiving a cleaning object and providing a cleaning space; A sump having a temperature sensor and a heater, the sump being configured to recover washing water sprayed into the tub; At least one spray gun formed to spray wash water toward the object to be cleaned; A supply pump configured to supply wash water stored in the sump to the at least one atomizer; And a controller configured to control the temperature sensor and the supply pump, wherein the controller controls the first temperature detected by the temperature sensor after the wash water is injected for a first predetermined time toward the inside of the tub, The controller controls the heater and the supply pump in accordance with one of the plurality of cleaning courses, based on the difference value of the second temperature sensed by the temperature sensing sensor after the washing water is sprayed for a second predetermined time toward the inside of the tub, The dishwasher according to the present invention controls the dishwasher.

At this time, the controller may control the feed pump and the heater such that the heater is also driven while the feed pump is driven.

In addition, the first time may be set to a time sufficient for the object to be cleaned in the tub and the washing water to be in a thermal equilibrium state.

Also, the washing water may be sprayed toward the inside of the tub during the second time after the first temperature is sensed by the temperature sensor, and the second time may be set longer than the first time.

Further, the difference value may vary depending on the amount of the object to be cleaned stored in the tub.

Further, the plurality of courses include a strong course, a medium course, and a weak course, and the control unit compares the difference with a predetermined first value and a second value greater than the first value, The heater and the supply pump can be controlled according to one course.

Also, at least one of the washing water usage amount, the washing water heating temperature, the washing time, and the washing water spraying power may be different from each other in the plurality of courses.

According to another aspect of the present invention, there is provided a washing machine comprising: a first washing water spraying step of supplying washing water stored in a sump to an inside of a tub for a first predetermined time; A first temperature sensing step in which a first temperature of the wash water is sensed by a temperature sensor provided in the sump; A second wash water injection step of supplying the wash water stored in the sump to the inside of the tub for a predetermined second time; And a second temperature sensing step in which the second temperature of the washing water is sensed by the temperature sensing sensor, wherein, based on a difference between the second temperature and the first temperature, one of the plurality of courses preset by the control unit And a course performing step in which the course is selected and executed.

At this time, the first washing water spraying step is an initial spraying step in which the washing water in the sump is heated by the heater and simultaneously injected into the tub; And a first time determination step in which it is determined by the control unit whether or not the wash water has been heated and injected for a predetermined first time period.

Also, the first time may be set to a time sufficient for the object to be cleaned in the tub and the washing water to be in a thermal equilibrium state, and the first temperature measured in the first temperature sensing step may be a temperature As shown in Fig.

Also, the second washing water spraying step may include a latter spraying step in which the washing water in the sump is heated by the heater and simultaneously injected into the tub; And a second time determination step in which it is determined by the control unit whether or not the wash water has been heated and injected for a predetermined second time period.

At this time, the second time may be set longer than the first time.

Further, in the first temperature sensing step, the heater and the supply pump connected to the sump may be continuously driven.

Further, in the second temperature sensing step, the driving of the heater and the supply pump may be stopped.

Also, the second temperature is higher than the first temperature, and the difference value may vary depending on the amount of the object to be cleaned stored in the tub.

The course execution step may include: a food quality determination step of comparing the difference value with a predetermined first value and a second value by a control unit; And a course selection step in which one of the plurality of courses is selected by the controller based on the result of the determination of the amount of food to be cooked.

Determining whether the difference value is smaller than a predetermined first value; And a second eating capacity determining step of determining whether the difference value is smaller than a predetermined second value, and the second value may be set to be larger than the first value.

The plurality of courses include a river course, a middle course, and a weak course, and the plurality of courses may be different from each other in at least one of a wash water usage amount, a wash water heating temperature, a cleaning time, and a spraying power.

In addition, if it is determined that the difference value is smaller than the first value in the first eating capacity determination step, the controller may select and perform the strong course.

If it is determined that the difference value is smaller than the second value in the second eating amount determination step after the difference value is determined to be equal to or larger than the first value in the first eating amount determination step, The medium course can be selected and performed.

Further, if it is determined that the difference value is equal to or greater than the second value in the second eating capacity determination step, the weakness course may be selected and performed by the control unit.

Meanwhile, the control method of the dishwasher according to the embodiment of the present invention may further include a water supplying step of supplying a predetermined amount of washing water into the sump before the first washing water spraying step.

According to the present invention, it is possible to provide a dishwasher capable of determining the amount of the object to be cleaned only by the temperature sensor without the turbidity sensor.

According to the present invention, it is possible to provide a dishwasher capable of accurately and easily determining the amount of a cleaning object irrespective of the type of foreign object attached to the object, by determining the amount of the object to be cleaned through the temperature sensor have.

Further, according to the present invention, it is possible to provide a dishwasher in which the turbidity sensor is not used in the dishwasher, thereby reducing the overall product cost.

1 is a view showing a dishwasher according to an embodiment of the present invention.
FIG. 2 is a block diagram showing a connection relationship of major components of the dishwasher of FIG. 1;
3 is a graph showing the temperature change of the washing water sensed in the sump depending on the amount of the object to be cleaned.
4 is a flowchart illustrating a method of controlling a dishwasher according to an embodiment of the present invention.
5 is a flowchart showing a control method of the dishwasher following the flowchart of Fig.

Hereinafter, a cold water supply apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The accompanying drawings illustrate exemplary embodiments of the present invention and are provided to explain the present invention in detail.

In addition, the same or corresponding components are denoted by the same reference numerals regardless of the reference numerals, and redundant description thereof will be omitted. For convenience of explanation, the size and shape of each constituent member shown may be exaggerated or reduced have.

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

1, a dishwasher 100 according to an embodiment of the present invention includes a cabinet 1, a tub 11 for providing a washing space, a space for accommodating a washing object (for example, a tableware) At least one rack (191, 193) for spraying wash water, at least one spray gun (3, 5) for spraying wash water, a sump (13) , 5), and a filter device (2) installed in the sump.

The cabinet (1) forms the appearance of the dishwasher (100). The cabinet 1 may be provided with a door 16 formed to open and close the tub 11.

The tub 11 may be provided in the cabinet 1 and may be formed to provide a space for cleaning the object to be cleaned. Further, the tub 11 may be provided on the upper portion of the sump 13.

The one or more racks 191 and 193 may include a first rack 191 and a second rack 193 positioned below the first rack 191. At this time, the first rack 191 and the second rack 193 may be referred to as an upper rack and a lower rack.

The upper rack 191 and the lower rack 193 may be provided to be pulled out from the cabinet 1 when the door 16 opens the tub 11.

In other words, a rail (not shown) is provided on an inner circumferential surface of the tub 11 to guide the racks 191 and 193 toward the door 16, and the racks are supported by the rails (Not shown) may be further provided.

The at least one atomizer (3, 5) may be configured to spray the wash water supplied from the supply pump (8) toward the object to be cleaned in the tub (11).

For example, the one or more spray arms 3, 5 may include a lower arm 5, a first rack 191, and a second arm 193, which are provided inside the tub 11 and wash the object to be cleaned stored in the second rack 193, And an upper arm 3 for washing the object to be cleaned.

The lower arm 5 and the upper arm 3 can be supplied with the washing water through the supply pump 8 and the supply passage 7. [ The supply passage 7 is provided with a first supply passage 71 connected to the lower arm 5, a second supply passage 73 connected to the upper arm 3, (Not shown).

When the lower arm 5 is rotatably provided in the tub 11, the lower arm 5 is rotatably coupled to the holder 17 provided on the cover 15, (71) may be provided to supply wash water to the holder (17).

The upper arm 3 may be rotatably coupled to an end of the second supply passage 73 if the upper arm 3 is rotatably provided in the tub 11. [

The sump 13 may be formed to receive the washing water from the water supply source (not shown) of the fork through the water supply channel 135. That is, a water supply channel 135 may be connected to one side of the sump 13, and a water supply valve V may be provided to the water supply channel 135.

The sump 13 may be formed to recover washing water sprayed into the tub 11. [ Further, the sump 13 may be formed to store the recovered wash water.

The sump 13 includes a reservoir 133 for storing wash water, a cover 15 for separating the tub 11 and the reservoir 133 from the reservoir 133, And a bottom surface 132 constituting a lower end portion of the sump 13. The bottom surface 132 of the sump 13 may be connected to the side surface 131 of the cover 15, At this time, the cover 15 may form the upper surface of the sump 13. [

The storage unit 133 may be configured to receive washing water through a water supply channel 135 connected to a water supply source (not shown). That is, the sump 13 may be configured to receive the washing water through the water supply channel 135 connected to the water supply source.

In addition, the sump 13 may include a temperature sensor 134 and a heater H. That is, the sump 13 may be provided with a temperature sensor 134 and a heater H.

The temperature sensing sensor 134 may be configured to sense the temperature of the wash water stored in the sump 13. [ For example, the temperature sensor 134 may be installed on the side surface 131 of the sump 13. [

The heater (H) may be configured to receive the electric power from an external power source to heat the washing water stored in the sump (13). For example, the heater (H) may be disposed on the bottom surface (132) of the sump (13). However, if the heater H can heat the washing water in the sump 13, the arrangement of the heater H is not limited.

In addition, the sump 13 may further include a water level sensor 136 configured to sense the level of the wash water. The level sensor 136 may include a low level sensor 136-1 for sensing a low level and a high level sensor 136-2 for sensing a high level. Since the operation principle of the water level sensor 136 is already known, a detailed description thereof will be omitted.

The supply pump 8 may be configured to supply wash water stored in the sump 13 into the tub 11. [ That is, the supply plebe 8 sms may be configured to supply the wash water stored in the sump 13 to the at least one atomizer 3, 5. In other words, the supply pump 8 may be configured to inject wash water stored in the sump 13 into the tub 11 through the spray guns 3, 5.

For example, the inter-supply pump 8 may include an impeller 85 and a motor 87 configured to rotationally drive the impeller 85. The motor 87 may be configured to receive power from an external power source.

More specifically, the supply pump 8 includes a housing 81 provided with an impeller 85, an inlet 84 through which the washing water flows into the housing 81, and an inlet 84 through which the washing water in the housing 181 is discharged A discharge port 82 and a motor 87 provided outside the housing 181 to rotate the impeller 85.

The inlet 84 is connected to the reservoir 133 through an inlet connection tube 97 and the outlet 82 can be connected to the selector valve 75 via an outlet connection tube 99.

Therefore, when power is supplied to the motor 87 and the impeller 85 rotates, the water flowing into the housing 81 from the sump 13 moves to the switch valve 75 through the discharge port 82, The water supplied to the upper arm 75 may be supplied to the upper arm 3 or the lower arm 5 along the supply flow paths 71 and 73 opened by the switching valve 75. [

The filter device 2 may be installed in the sump 13 to filter foreign substances contained in the washing water. For example, when washing water sprayed into the tub 11 is recovered into the sump 13, foreign substances separated from the object to be cleaned may be contained in the washing water.

At this time, the filter device 2 may be formed to filter foreign substances from the washing water collected into the sump 13. [

For example, the filter device 2 may be provided with a mesh member formed around the periphery of the filter device 2 to filter foreign substances contained in the washing water.

A drainage hole D may be formed on the bottom surface 132 of the sump 13 to drain wash water stored in the sump 13 and foreign substances contained in the filter device 2.

Specifically, the lower end of the filter device 2 can be opened. Further, the lower end of the filter device 2 may be formed to communicate with the drainage hole D.

That is, when the filter device 2 is installed in the sump 13, the lower end of the filter device 2 is connected to the bottom surface 132 of the sump 13, .

A drain line 137 is connected to the drain D and a drain pump 139 is connected to the drain line 137.

Meanwhile, the dishwasher according to the embodiment of the present invention may have various washing courses. In particular, the dishwasher may have an automatic cleaning course.

When the automatic cleaning course is selected by the user, the amount of cleaning object stored in the dishwasher (i.e., the amount of food to be cleaned) is determined and one of the plurality of cleaning courses can be selected and performed based on the amount of the cleaning object have.

At this time, the amount of the object to be cleaned stored in the dishwasher can be judged based on the turbidity of the washing water sensed through the turbidity sensor (not shown).

However, even when a small amount of dishware is stored in the tub of the dishwasher, when the contamination degree is high or the foreign substance (for example, milk or the like) which increases the turbidity is attached, the turbidity of the washing water detected by the turbidity sensor becomes high, There is a problem in that it can be judged that the object to be cleaned is housed inside the tub.

That is, although a relatively small amount of the cleaning object is accommodated in the tub, the sensing value sensed by the turbidity sensor may vary depending on the type of the foreign object attached to the object to be cleaned.

Further, when the turbidity sensor is used to determine the amount of the object to be cleaned, the manufacturing cost of the dishwasher may be increased as much as the price of the ballistic sensor.

In this case, the amount of the object to be cleaned can be more accurately determined by using the temperature of the washing water detected by the temperature sensor 134, not the turbidity sensor.

Hereinafter, with reference to the other drawings, it is assumed that the amount of the object to be cleaned is determined using the temperature of the cleaning water sensed by the temperature sensor 134, and the optimum cleaning course is selected and performed according to the determined amount of the object to be cleaned .

FIG. 2 is a block diagram showing a connection relationship of major components of the dishwasher of FIG. 1;

Hereinafter, a description will be given of a configuration in which the amount of the object to be cleaned is judged on the assumption that the command of the automatic washing course is inputted by the user, and a specific cleaning course (for example, a specific cleaning intensity) .

1 and 2, the dishwasher 100 according to the embodiment of the present invention includes a control unit C configured to control the temperature sensing sensor 134 and the supply pump 8 described above. That is, The controller C may be electrically connected to the temperature sensor 134 and the supply pump 8.

The controller C may be configured to control the water level sensor 136, the water feed valve V, and the heater H described above. That is, the controller C may be electrically connected to the water level sensor 136, the water supply valve V, and the heater H.

The control unit C controls the first temperature T ₁ sensed by the temperature sensor 134 after the washing water is sprayed for a predetermined first time T _set1 toward the inside of the tub 11, (T ₂ -T ₁ ) of the second temperature (T ₂ ) sensed by the temperature sensor (134) after the washing water is sprayed for a second predetermined time (T _set2 ) toward the inside of the tub (11) . ≪ / RTI >

The control unit C can control the heater H and the supply pump 8 in accordance with one of the plurality of cleaning courses, based on the difference value T ₂ -T ₁ .

That is, the controller C determines the amount of the object to be cleaned based on the difference value T ₂ -T ₁ , and determines the amount of the object to be cleaned, The supply pump 8 can be controlled.

In addition, the supply pump 8 and the heater H can be simultaneously driven. That is, the control unit C can control the supply pump 8 and the heater H so that the heater H is also driven while the supply pump 8 is driven.

That is, according to the driving of the supply pump 8 and the heater H, the temperature of the washing water and the object to be cleaned rises in the course of the washing water being sprayed to the inside of the tub 11.

The first time T _set1 may be preset to a time sufficient for the object to be cleaned in the tub 11 and the washing water to be in a thermal equilibrium state. For example, the first time (T _set1 ) may be from 1 minute to 3 minutes. Preferably, the first time (T _set1 ) may be 2 minutes.

That is, when the supply pump 8 and the heater H are driven during the first time (T _set1 ), the temperature of the object to be cleaned and the temperature of the washing water in the sump 13 can be substantially the same .

Further, after the first temperature T ₁ is sensed by the temperature sensor 134, washing water may be further injected toward the inside of the tub 11 during the second time T _set2 .

Therefore, the amount of the object to be cleaned through the temperature change of the washing water during the second time (T _set2 ), based on the first temperature (T ₁ ), which is the thermal equilibrium temperature of the object to be cleaned, . ≪ / RTI >

Also, the second time (T _set2 ) may be longer than the first time (T _set1 ). For example, the second time (T _set2 ) may be from 9 minutes to 11 minutes, preferably 10 minutes.

The first time T _set1 corresponds to the time for making the object to be cleaned and the washing water in the tub 11 into a thermal equilibrium state through the injection of the washing water and the second time T _set2 corresponds to the temperature of the washing water It is time to determine the amount of the object to be cleaned through the change.

Therefore, in order to determine a more accurate amount of the object to be cleaned, it is preferable that the second time (T _set2 ) is set longer than the first time (T _set1 ).

As described above, the amount of the object to be cleaned can be determined based on the difference (T ₂ -T ₁ ) between the first temperature T ₁ and the second temperature T ₂ .

That is, the difference value (T ₂ -T ₁ ) may vary depending on the amount of the object to be cleaned stored in the tub 11.

For example, FIG. 3 is a graph showing the temperature change of the washing water detected in the sump according to the amount of the object to be cleaned.

Referring to FIG. 3, the amount of the object to be cleaned and the difference value (T ₂ -T ₁ ) may be in inverse proportion. That is, the greater the amount of the object to be cleaned, the smaller the difference value (T ₂ -T ₁ ).

Specifically, if the amount of the object to be cleaned is relatively large, the heat of the washing water is transmitted to the object to be cleaned. Therefore, when the amount of the object to be cleaned is relatively large, the temperature change with time of the washing water collected in the sump 13 becomes smaller than when the amount of the object to be cleaned is relatively small.

On the contrary, when the amount of the object to be cleaned is relatively small, the temperature change with time of the washing water collected in the sump 13 becomes larger than when the amount of the object to be cleaned is relatively large.

As described above, the amount of the object to be cleaned can be determined based on the temperature change of the washing water collected in the sump 13, while the washing water is sprayed toward the object to be cleaned for the second predetermined time (T _set2 ).

Meanwhile, the plurality of washing courses provided in the dishwasher of the present invention may include a river course, a middle course, and a weak course.

The controller C compares the difference value T ₂ -T ₁ with a predetermined first value S ₁ and a second value S _{2 that} is greater than the first value S ₁ , The heater (H) and the supply pump (8) can be controlled in accordance with one course among the plurality of courses.

Specifically, when the controller (C) determines that the difference (T ₂ -T ₁ ) is smaller than the first value (S ₁ ), the heater (H) and the feed pump (8) Can be controlled by the control unit (C).

If it is determined in the controller C that the difference value T ₂ -T ₁ is equal to or greater than the first value S ₁ and smaller than the second value S ₂ , (H) and the feed pump (8) can be controlled by the control unit (C).

When the controller (C) determines that the difference value (T ₂ -T ₁ ) is greater than or equal to the second value (S ₂ ), the heater (H) and the supply pump 8) can be controlled by the control unit (C).

At this time, at least one of the washing water usage amount, the washing water heating temperature, the washing time, and the washing water spraying power may be set to be different from each other.

For example, at least one of the washing water use amount, the washing water heating temperature, the washing time, and the washing water spraying power may be greater than the heavy course and the weak course. Also, at least one of the washing water use amount, the washing water heating temperature, the washing time, and the washing water spraying power may be larger than the above course.

The control of the wash water usage can be performed through the control of the water supply valve (V) and the drain pump (139) by the controller (C).

In addition, the control of the washing water heating temperature may be performed through the control of the heater (H) by the controller (C). For example, the adjustment of the washing water heating temperature may be performed through control of at least one of power supplied to the heater H and driving time of the heater H. [

Further, the control of the washing water spraying force may be performed through the control of the supply pump 8 by the control unit C. [ For example, adjustment of the washing water spraying force can be performed through control of the rpm of the supply pump 8.

Also, the control of the cleaning time can be performed through the control of the power supply unit (not shown) by the control unit C.

As described above, according to the present invention, even if the turbidity sensor is not provided, the amount of the object to be cleaned can be determined using only the temperature sensor.

Further, according to the present invention, based on the amount of the object to be cleaned, the most suitable course among a plurality of courses can be automatically performed.

Hereinafter, a method of controlling a dishwasher according to an embodiment of the present invention will be described with reference to other drawings.

4 is a flowchart illustrating a method of controlling a dishwasher according to an embodiment of the present invention. 5 is a flowchart showing a control method of the dishwasher following the flowchart of Fig.

Specifically, FIG. 4 is a flowchart showing a method of detecting the first temperature and the second temperature of the washing water in the control method of the dishwasher, and FIG. 5 is a flowchart Fig. 6 is a flowchart showing a method of selecting one course; Fig.

Hereinafter, the control method of the dishwasher according to the embodiment of the present invention will be described. It is apparent that the configurations of the dishwasher explained with reference to FIGS. 1 to 3 can be similarly applied to the control method of the dishwasher.

4 and 5, a method of controlling a dishwasher according to an embodiment of the present invention includes the steps of supplying washing water stored in the sump 13 to the inside of the tub 11 for a first predetermined time (T _set1 ) A first temperature sensing step S300 in which a first temperature T ₁ is sensed by a temperature sensing sensor 134 provided in the sump 13, a second washing water spraying step (S400), and detects a second temperature the second temperature (T ₂₎ is detected in the wash water at the temperature sensor 134 to supply for a second time (Tset2) predetermined towards the inside of the tub Step S500.

The control method of the dishwasher according to the embodiment of the present invention may further include the step of controlling the controller C based on the difference T ₂ -T ₁ between the second temperature T ₂ and the first temperature T ₁ , (S600) in which one of the plurality of courses preset by the user is selected and performed (refer to FIG. 5).

In addition, it may further include a water supply step (S100) in which a predetermined amount of wash water is supplied into the sump (13) before the first wash water injection step (S200). In the water supplying step S100, the washing water may be supplied into the sump 13 from an external water source.

The washing water stored in the sump 13 in the first washing water spraying step S200 may be heated by the heater H and may be supplied toward the inside of the tub 11 by the feeding pump 8. [ That is, the heater H and the supply pump 8 may be simultaneously driven in the first wash water injection step (S200).

Specifically, the first washing water spraying step S200 includes an initial spraying step S210 in which the washing water in the sump 13 is heated by the heater H and is injected into the tub 11, (S210) in which it is determined by the control unit (C) whether or not the wash water has been heated and injected during the set time (T _set1 ).

That is, the heater H and the supply pump 8 may be driven together during the first time T _{set1 in} the first washing water injection step S200. Accordingly, the temperature of the washing water in the sump 13 and the temperature of the object to be cleaned in the tub 11 may gradually increase during the first time (T _set1 ).

The first time T _set1 may be set to a time sufficient for the washing object inside the tub 11 and the washing water in the sump 13 to be in a thermal equilibrium state.

For example, the first time (T _set1 ) may be from 1 minute to 3 minutes, preferably 2 minutes.

Therefore, as the washing water is injected into the tub 11 during the first time (T _set1 ), the temperature of the washing water in the sump 13 and the temperature of the object to be cleaned in the tub 11 can be substantially the same.

That is, the first temperature (T ₁ ) measured or sensed in the first temperature sensing step (S300) may be a temperature at which the washing water and the object to be cleaned are thermally balanced. At this time, the first temperature T ₁ may be a reference value for determining the amount of the object to be cleaned, which will be described later, and for determining the cleaning course according to the amount of the object to be cleaned.

Meanwhile, if the driving of the heater H and the supply pump 8 is stopped in the first temperature sensing step S300, the second temperature T ₂ may be changed. When the second temperature T ₂ is changed, the judgment accuracy of the amount of the object to be cleaned by the comparison of the difference value T ₂ -T ₁ with the first value S 1 and the second value S 2 It can fall.

Therefore, in the first temperature sensing step S300, the heater H and the supply pump 8 connected to the sump 13 can be continuously driven. That is, even when the temperature of the washing water is sensed by the temperature sensor 134 in the first temperature sensing step S300, the driving of the heater H and the supplying pump 8 can be continued without stopping.

The washing water stored in the sump 13 is heated by the heater H and is supplied to the tub 11 by the supply pump 8 at the same time as the first washing water spraying step S200, To the inside.

However, in the second washing water injection step (S400), the washing water may be injected toward the inside of the tub during a second predetermined time (T _set2 ) longer than the first time (T _set1 ).

More specifically, the second washing water spraying step S400 includes a later spraying step S410 in which the washing water in the sump 13 is heated by the heater H and is injected into the tub 11, (S420) in which it is judged by the control unit (C) whether or not the wash water has been heated and injected during the set time (T _set2 ).

That is, the heater H and the supply pump 8 may be driven together during the second time T _{set2 in} the second cleaning water injection step S400. Accordingly, the temperature of the washing water in the sump 13 and the temperature of the object to be cleaned in the tub 11 can be gradually increased during the second time (T _set2 ).

At this time, the temperature of the washing water and the object to be cleaned at the starting point of the second time (T _set2 ) may be the first temperature (T ₁ ). That is, the temperature of the washing water and the object to be cleaned during the second time (T _set2 ) may be raised from the first temperature (T ₁ ) to a second temperature (T ₂ ) higher than the first temperature.

In order to more accurately determine the amount of the object to be cleaned based on the difference between the second temperature T ₂ and the first temperature T ₁ to be described later, the second time T _set2 is set to the first time T 1 T _set1 ).

For example, the second time (T _set2 ) may be from 9 minutes to 11 minutes, preferably 10 minutes.

Accordingly, the temperature of the washing water in the sump 13 and the temperature of the object to be cleaned in the tub 11 can gradually increase as the washing water is injected into the tub 11 during the second time (T _set2 ).

Therefore, the second temperature T ₂ measured or sensed in the second temperature sensing step S500 is higher than the first temperature T ₁ sensed in the first temperature sensing step S300. Also, the second temperature T ₂ may be another reference value for determining the amount of the object to be cleaned, which will be described later, and for determining the cleaning course according to the amount of the object to be cleaned.

That is, the determination of the amount of the object to be cleaned (or the amount of food to be cleaned) to be described below can be made based on the difference (T ₂ -T ₁ ) between the second temperature T ₂ and the first temperature T ₁ have.

For example, the difference (T ₂ -T ₁ ) may vary depending on the amount of the object to be cleaned stored in the tub 11. The relationship of the difference value (T ₂ -T ₁ ) according to the amount of the object to be cleaned has been described with reference to FIG. 3, and a detailed description thereof will be omitted.

Meanwhile, after the second temperature sensing step (S500), the determination of the amount of the object to be cleaned and the selection and execution of the cleaning course according to the amount of the object to be cleaned may be performed. In addition, the control method of the heater H and the supply pump 8 may vary depending on the amount of the object to be cleaned and the selected cleaning course.

Therefore, in the second temperature sensing step S500, the driving of the heater H and the supply pump 8 may be stopped.

5, a method of controlling a dishwasher according to an embodiment of the present invention is based on the difference (T ₂ -T ₁ ) between the second temperature T ₂ and the first temperature T ₁ (S600) in which one of a plurality of courses predetermined by the controller (C) is selected and executed

In the course execution step S600, the amount of the object to be cleaned can be determined by the control unit C based on the difference value T ₂ -T ₁ , and the cleaning course according to the amount of the object to be cleaned is selected and .

Specifically, the step of performing the course (S600) may include a step of determining whether or not the difference value (T ₂ -T ₁ ) is compared with the predetermined first value (S1) and the second value (S2) (S610), and a course selection step (S620) in which one of the plurality of courses is selected by the control unit (C) based on the result determined in the determining step (S610).

Furthermore, the expression amount determination step (S610) is the difference (T ₂ -T ₁₎ is the first value of the first expression amount determination step (S611) and the difference value that determines whether or not less than (S ₁₎ (T ₂ -T ₁₎ can comprise a second value of a second expression where the amount is determined whether or not smaller than the (S ₂₎ determining step (S612).

In addition, the first eating capacity determination step (S611) and the second eating capacity determination step (S612) may be sequentially performed.

At this time, the second value S ₂ may be greater than the first value S ₁ . For example, the second value S ₂ may be 19 to 21, and the first value S ₁ may be 9 to 11. Preferably, the second value S ₂ is 20, and the first value S ₁ may be 10.

On the other hand, the plurality of courses may include a river course (first course), a middle course (second course), and a weak course (third course). Also, at least one of the washing water usage amount, the washing water heating temperature, the washing time, and the spraying power may be different from each other in the plurality of courses.

For example, at least one of the washing water use amount, the washing water heating temperature, the washing time, and the washing water spraying power may be greater than the heavy course and the weak course. Also, at least one of the washing water use amount, the washing water heating temperature, the washing time, and the washing water spraying power may be larger than the above course.

If it is determined in step S611 that the difference value T ₂ -T ₁ is smaller than the first value S ₁ , the control unit C determines whether or not the strongest course Course) can be selected and performed (S621).

In addition, after the difference value (T ₂ -T ₁ ) is determined to be equal to or greater than the first value (S ₁ ) in the first eating amount determination step (S611), the second eating amount determination step If it is determined that the difference value T ₂ -T ₁ is smaller than the second value S ₂ , the middle course (i.e., the second course) may be selected and performed by the controller C (S 622) .

If it is determined in step S612 that the difference value T ₂ -T ₁ is equal to or greater than the second value S ₂ , the control unit C determines the rough course (course) May be selected and performed (S623).

As described above, according to the present invention, even if the turbidity sensor is not provided, the amount of the object to be cleaned (i.e., the amount of food to be cleaned) can be determined based on the temperature of the washing water detected by the temperature sensor, Can be automatically selected and performed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, The present invention may be modified in various ways. Therefore, modifications of the embodiments of the present invention will not depart from the scope of the present invention.

1: cabinet 2: filter device 8: feed pump
11: tub 13: sump 87: motor
134: Temperature sensor C: Control part V: Water supply valve
H: Heater

Claims (20)

A tub receiving the object to be cleaned and providing a washing space;
A sump having a temperature sensor and a heater, the sump being configured to recover washing water sprayed into the tub;
At least one spray gun formed to spray wash water toward the object to be cleaned;
A supply pump configured to supply wash water stored in the sump to the at least one atomizer; And
And a controller configured to control the temperature sensor and the feed pump,
Wherein the control unit controls the first temperature detected by the temperature sensor after the washing water is sprayed for a first predetermined time toward the inside of the tub and the temperature detected after the washing water is sprayed for a predetermined second time toward the inside of the tub, Wherein the controller controls the heater and the supply pump according to one of the plurality of cleaning courses, based on a difference value of the second temperature detected by the detection sensor. The method according to claim 1,
Wherein the controller controls the supply pump and the heater so that the heater is also driven while the supply pump is being driven. The method according to claim 1,
Wherein the first time is set to a time sufficient for the object to be cleaned in the tub and the washing water to be in a thermal equilibrium state. The method according to claim 1,
The washing water is sprayed toward the inside of the tub for the second time after the first temperature is sensed by the temperature sensor,
Wherein the second time is longer than the first time. 5. The method of claim 4,
And the difference value varies depending on the amount of the object to be cleaned stored in the tub. 6. The method of claim 5,
Wherein the plurality of courses include a river course, a middle course, and a weak course,
Wherein the controller compares the difference with a predetermined first value and a second value that is greater than the first value and controls the heater and the supply pump according to one of the plurality of courses. syringe. The method according to claim 6,
Wherein at least one of the washing water use amount, the washing water heating temperature, the washing time, and the washing water spraying power is different from each other in the plurality of courses. A first wash water spraying step of supplying wash water stored in the sump to the inside of the tub for a predetermined first time;
A first temperature sensing step in which a first temperature of the wash water is sensed by a temperature sensor provided in the sump;
A second wash water injection step of supplying the wash water stored in the sump to the inside of the tub for a predetermined second time; And
And a second temperature sensing step in which the second temperature of the washing water is sensed by the temperature sensing sensor,
Further comprising a course performing step in which one of a plurality of courses predetermined by the controller is selected and performed based on a difference value between the second temperature and the first temperature. 9. The method of claim 8,
Wherein the first washing water spraying step comprises:
An initial injection step in which the wash water in the sump is heated by the heater and simultaneously injected into the tub; And
And a first time judging step of judging by the control unit whether or not the wash water has been heated and injected for a predetermined first time period. 10. The method of claim 9,
The first time is set to a time sufficient for the object to be cleaned in the tub and the washing water to be in a thermal equilibrium state,
Wherein the first temperature measured in the first temperature sensing step is a temperature in a state where the washing water and the object to be cleaned are thermally balanced. 9. The method of claim 8,
The second washing water spraying step may include:
A post-injection step in which the wash water in the sump is heated by the heater and simultaneously injected into the tub; And
And a second time determining step in which it is determined by the control unit whether or not the wash water has been heated and injected for a predetermined second time period. 12. The method of claim 11,
Wherein the second time is longer than the first time. 9. The method of claim 8,
Wherein in the first temperature sensing step, the heater and the supply pump connected to the sump are continuously driven. 14. The method of claim 13,
Wherein in the second temperature sensing step, driving of the heater and the supply pump is stopped. 9. The method of claim 8,
Wherein the second temperature is higher than the first temperature,
Wherein the difference value varies depending on the amount of the object to be cleaned stored in the tub. 9. The method of claim 8,
The course-
Wherein the difference value is compared with a predetermined first value and a second value by a control unit; And
And a course selecting step in which one of the plurality of courses is selected by the control unit based on the result of the determination in the cooking utensil quantity determining step. 17. The method of claim 16,
The method of claim 1,
Determining whether the difference value is smaller than a predetermined first value; And
And determining whether the difference value is smaller than a predetermined second value,
Wherein the second value is greater than the first value. 18. The method of claim 17,
Wherein the plurality of courses include a river course, a middle course, and a weak course,
Wherein at least one of the washing water usage amount, the washing water heating temperature, the washing time, and the spraying power is different among the plurality of courses. 19. The method of claim 18,
If the difference value is determined to be smaller than the first value in the first eating capacity determination step, the strong course is selected and performed by the controller,
If it is determined in the first eating capacity determination step that the difference value is equal to or greater than the first value and that the difference value is less than the second value in the second eating capacity determination step, The course is selected and performed,
And the weakness course is selected and performed by the control unit when it is determined that the difference value is equal to or greater than the second value in the second eating quality determining step. 9. The method of claim 8,
Further comprising a water supply step of supplying a predetermined amount of wash water into the sump prior to the first wash water spraying step.

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