JP7198917B2 - CLOTH PROCESSING APPARATUS CONTROL METHOD AND CLOTH PROCESSING APPARATUS - Google Patents

Description

TECHNICAL FIELD The present invention belongs to the technical field of clothes processing apparatuses, and more particularly, to a control method of a clothes processing apparatus and a clothes processing apparatus.

Currently, there are more and more multi-vessel clothes treatment devices, and the various combinations are also more and more novel. However, in the case of a clothes processing apparatus having a multi-tank simultaneous drying function, it is difficult to sufficiently utilize the heat quantity of the heat exchange system with the conventional drying control method, resulting in increased energy consumption. Also, the drying effect is not good.

Therefore, there is a need for a drying control method that is adapted to the multi-tank simultaneous drying function, increases the heat utilization rate, shortens the drying time, and improves the drying efficiency.

In view of the above, the present invention is proposed.

SUMMARY OF THE INVENTION A technical problem to be solved by the present invention is to provide a control method for a clothes processing apparatus and a clothes processing apparatus in order to overcome the defects of the prior art.

In order to solve the above technical problems, the basic idea of the technical solution adopted in the present invention is as follows.

In a method of controlling a clothes treating machine, the clothes treating machine includes a plurality of clothes drying zones sharing the same heat exchange system. Multiple drying zones begin drying at the same time. In this control method, the initial power required for each drying zone is calculated based on the environmental temperature and load, and heat is supplied to each drying zone at a constant ratio based on the initial power.

As an embodiment of the present invention, in the method for controlling the clothes processing device, a weighing structure for determining the magnitude of the load is provided in the clothes drying area of the clothes processing device. In this control method, the power required for each drying area is calculated based on the environmental temperature and the measured value, and the amount of heat supplied to each drying area is adjusted at a constant ratio based on the obtained power.

As an embodiment of the present invention, in the method for controlling a clothing processing apparatus, the clothing processing apparatus is provided with a power database corresponding to environmental temperatures and measured values. The correspondence relationship between the power, the environmental temperature, and the measured value is power P=K _i *G+B _j , where P is the power and G is the measured value of the drying area. Of these, K _i and B _j are constants corresponding to the environmental temperature, and the values taken by K _i and B _j differ depending on the difference in the environmental temperature.

Preferably, for the same load, the higher the ambient temperature, the smaller the values that K _i and B _j take.

As an embodiment of the present invention, in the method for controlling a clothes processing apparatus, a plurality of clothes drying areas of the clothes processing apparatus share the same air path. The air outlet of the air passage is provided with openings that communicate with the air inlets of the plurality of clothes drying areas, and the openings are provided with air branch valves that can control the degree of opening. By controlling the opening degree of the air branch valve based on the initial power required for each clothes drying area, the amount of hot air entering each drying area is adjusted.

As an embodiment of the present invention, in the method for controlling the clothes processing device, the clothes processing device includes a first drying area and a second drying area. The weight value of the first drying area is G1, the weight value of the second drying area is G2, the correction factor of the first drying area is M1, the correction factor of the second drying area is M2, the first drying area and the second drying area Assuming that the reference opening degree of the air branch valve corresponding to simultaneous drying is C and the initial opening degree of the air branch valve is D, D=(M1*G1/M2*G2)*C. Of these, C is the opening degree value of the wind branch valve when the drying efficiency is maximized in the case of the same load obtained in the experiment.

As one embodiment of the present invention, in the method for controlling the laundry processing apparatus, the opening degree of the air branch valve is adjusted based on the temperatures of the first drying area and the second drying area. A correspondence relationship between the degree of opening of the air branch valve and the temperatures of the first drying area and the second drying area is preset in the control unit of the clothes processing apparatus.

As one embodiment of the present invention, in the method for controlling the clothes processing apparatus, the opening degree of the air branch valve is adjusted based on the temperatures of the exhaust ports of the first drying area and the second drying area. When the temperature rise rate of one drying area is faster than that of the other drying area, control is performed so that the opening of the air branch valve directed to the drying area where the temperature rises faster is made smaller.

Preferably, the temperature of the exhaust port of the first drying area in a unit time is T1, the temperature of the exhaust port of the second drying area is T2, and the correspondence relationship between the difference value between T1 and T2 and the degree of opening of the air branch valve. is preset in the clothes processing apparatus. Then, based on the difference value between T1 and T2, the degree of opening of the corresponding wind branch valve is obtained and adjusted.

As an embodiment of the present invention, in the method for controlling the clothes processing apparatus, the heat exchange system is a heat pump system or a heat pipe water cooling system. The power required for each drying zone is calculated and output by controlling the rotational speed of the compressor or the power of the heat pipe to adjust the power of the drying zone.

As an embodiment of the present invention, in the method for controlling the clothes processing apparatus, the heat exchange system is a heat pump system. A heat pump includes an evaporator, a compressor, and a condenser. If the difference between the temperature at the outlet of the drying zone and the temperature at the location between the evaporator and the condenser is greater than a predetermined value, it is determined that drying is complete.

Another object of the present invention is to provide a clothes processing apparatus. The clothes processing apparatus uses the control method of the clothes processing apparatus described in any of the above contents.

By using the above technical solutions, the present invention has the following beneficial effects compared with the prior art.

The control method of the clothes treating apparatus described in the present invention is applied to the simultaneous operation of multiple drying zones to fully utilize the amount of heat supplied from the heat exchange system. This improves heat utilization and shortens drying time. Also, the drying efficiency is improved, which saves energy consumption.

Specific embodiments of the present invention will be described in more detail below in combination with the drawings.

The drawings are part of the invention and are used for a further understanding of the invention. Also, the schematic embodiments of the invention and their descriptions are used for the interpretation of the invention, but do not unduly limit the invention. It should be understood that the drawings described below are only part of the examples, and those skilled in the art can derive further drawings from these drawings without creative effort.

FIG. 1 is a flow chart of a control method for a clothes processing apparatus as described in the present invention.

It should be noted that these drawings and written description are not intended to limit the scope of the inventive concept in any way, but rather to explain the inventive concepts to those skilled in the art with reference to specific embodiments. It is.

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments will be described clearly and concisely in combination with the drawings of the embodiments of the present invention. It should be noted that the following examples are for the purpose of explaining the present invention and do not limit the scope of the present invention.

In the description of the present invention, terms such as "top", "bottom", "front", "back", "left", "right", "vertical", "inside", "outside", etc. should be explained. The direction or positional relationship indicated by is the direction or positional relationship based on the illustration, and is only for the convenience and simplification of the description of the present invention, and the target device or member is in a specific direction. It does not express or imply that it has and must be configured and operated in a particular direction. As such, it should not be construed as limiting the invention.

In the description of the present invention, the terms "attached", "connected", and "connected" should be interpreted broadly, unless explicitly defined and limited otherwise. For example, it may be a fixed connection, a removable connection, or an integral connection. Also, the connection may be mechanical or electrical. Furthermore, it may be a direct connection or an indirect connection through an intermediate medium. Those skilled in the art can interpret the specific meanings of the above terms in the present invention according to specific situations.

In a method of controlling a clothes treating machine, the clothes treating machine includes a plurality of clothes drying zones sharing the same heat exchange system. Multiple drying zones begin drying at the same time. In this control method, the initial power required for each drying zone is calculated based on the environmental temperature and load, and heat is supplied to each drying zone at a constant ratio based on the initial power.

As an embodiment of the present invention, in the method for controlling the clothes processing device, a weighing structure for determining the magnitude of the load is provided in the clothes drying area of the clothes processing device. In this control method, the power required for each drying area is calculated based on the environmental temperature and the measured value, and the amount of heat supplied to each drying area is adjusted at a constant ratio based on the obtained power.

As an embodiment of the present invention, in the method for controlling a clothing processing apparatus, the clothing processing apparatus is provided with a power database corresponding to environmental temperatures and measured values. The correspondence relationship between the power, the environmental temperature, and the measured value is power P=K _i *G+B _j , where P is the power and G is the measured value of the drying area. Of these, K _i and B _j are constants corresponding to the environmental temperature, and the values taken by K _i and B _j differ depending on the difference in the environmental temperature.

Preferably, for the same load, the higher the ambient temperature, the smaller the values that K _i and B _j take.

As an embodiment of the present invention, in the method for controlling a clothes processing apparatus, a plurality of clothes drying areas of the clothes processing apparatus share the same air path. The air outlet of the air passage is provided with openings that communicate with the air inlets of the plurality of clothes drying areas, and the openings are provided with air branch valves that can control the degree of opening. By controlling the opening degree of the air branch valve based on the initial power required for each clothes drying area, the amount of hot air entering each drying area is adjusted.

As an embodiment of the present invention, in the method for controlling the clothes processing device, the clothes processing device includes a first drying area and a second drying area. The weight value of the first drying area is G1, the weight value of the second drying area is G2, the correction factor of the first drying area is M1, the correction factor of the second drying area is M2, the first drying area and the second drying area Assuming that the reference opening degree of the air branch valve corresponding to simultaneous drying is C and the initial opening degree of the air branch valve is D, D=(M1*G1/M2*G2)*C. Of these, C is the opening degree value of the wind branch valve when the drying efficiency is maximized in the case of the same load obtained in the experiment.

As one embodiment of the present invention, in the method for controlling the laundry processing apparatus, the opening degree of the air branch valve is adjusted based on the temperatures of the first drying area and the second drying area. A correspondence relationship between the degree of opening of the air branch valve and the temperatures of the first drying area and the second drying area is preset in the control unit of the clothes processing apparatus.

As one embodiment of the present invention, in the method for controlling the clothes processing apparatus, the opening degree of the air branch valve is adjusted based on the temperatures of the exhaust ports of the first drying area and the second drying area. When the temperature rise rate of one drying area is faster than that of the other drying area, control is performed so that the opening of the air branch valve directed to the drying area where the temperature rises faster is made smaller.

Preferably, the temperature of the exhaust port of the first drying area in a unit time is T1, the temperature of the exhaust port of the second drying area is T2, and the correspondence relationship between the difference value between T1 and T2 and the degree of opening of the air branch valve. is preset in the clothes processing apparatus. Then, based on the difference value between T1 and T2, the degree of opening of the corresponding wind branch valve is obtained and adjusted.

As an embodiment of the present invention, in the method for controlling the clothes processing apparatus, the heat exchange system is a heat pump system or a heat pipe water cooling system. The power required for each drying zone is calculated and output by controlling the rotational speed of the compressor or the power of the heat pipe to adjust the power of the drying zone.

As an embodiment of the present invention, in the method for controlling the clothes processing apparatus, the heat exchange system is a heat pump system. A heat pump includes an evaporator, a compressor, and a condenser. If the difference between the temperature at the outlet of the drying zone and the temperature at the location between the evaporator and the condenser is greater than a predetermined value, it is determined that drying is complete.

Another object of the present invention is to provide a clothes processing apparatus. The clothes processing apparatus uses the control method of the clothes processing apparatus described in any of the above contents.

By using the above technical solutions, the present invention has the following beneficial effects compared with the prior art.

The control method of the clothes treating apparatus described in the present invention is applied to the simultaneous operation of multiple drying zones to fully utilize the amount of heat supplied from the heat exchange system. This improves heat utilization and shortens drying time. Also, the drying efficiency is improved, which saves energy consumption.

This embodiment further limits or rationalizes the first embodiment.

In a method of controlling a clothes treating machine, the clothes treating machine includes a plurality of clothes drying zones sharing the same heat exchange system. Multiple drying zones begin drying at the same time. In this control method, the initial power required for each drying zone is calculated based on the environmental temperature and load, and heat is supplied to each drying zone at a constant ratio based on the initial power.

As an embodiment of the present invention, in the method for controlling the clothes processing device, a weighing structure for determining the magnitude of the load is provided in the clothes drying area of the clothes processing device. In this control method, the power required for each drying area is calculated based on the environmental temperature and the measured value, and the amount of heat supplied to each drying area is adjusted at a constant ratio based on the obtained power.

As a method for detecting the environmental temperature, the environmental temperature is directly detected by an environmental temperature sensor or indirectly determined by a temperature sensor of the compressor system.

Preferably, it is indirectly determined by a temperature sensor of the compressor system. If the environmental temperature is obtained by comprehensively analyzing the exhaust temperature of the compressor and the outlet temperature of the condenser, there is no need to install a special temperature sensor outside the clothes processing apparatus to detect the external environmental temperature. It saves occupied space.

As an embodiment of the present invention, in the method for controlling a clothing processing apparatus, the clothing processing apparatus is provided with a power database corresponding to environmental temperatures and measured values. The correspondence relationship between the power, the environmental temperature, and the measured value is power P=K _i *G+B _j , where P is the power and G is the measured value of the drying area. Of these, K _i and B _j are constants corresponding to the environmental temperature, and the values taken by K _i and B _j differ depending on the difference in the environmental temperature.

The stage corresponding to the environmental temperature is divided into three stages of a low temperature environment, a medium temperature environment, and a high temperature environment. The power database includes sub-databases respectively corresponding to low temperature environment, medium temperature environment and high temperature environment.

For example, when the environmental temperature is between m1 and m2, it is a low temperature environment and power P=K ₁ *G+B ₁ .

When the environment temperature is between m2 and m3, it is a medium temperature environment, and power P=K ₂ *G+B ₂ .

When the environment temperature is between m3 and m4, it is a high temperature environment and power P=K ₃ *G+B ₃ .

When multiple drying zones start drying at the same time, first determine the stage to which the environmental temperature belongs, and then call the power calculation method of the sub-database accordingly.

As an embodiment of the present invention, in the method for controlling a clothes processing apparatus, a plurality of clothes drying areas of the clothes processing apparatus share the same air path. The air outlet of the air passage is provided with openings communicating with the air inlets of the plurality of clothes drying areas, and the air inlet of the air passage is provided with openings communicating with the air outlets of the plurality of clothes drying areas. It is In addition, an air branch valve whose opening degree can be controlled is provided at each of the openings of the exhaust port and the intake port of the air passage. By controlling the opening degree of the air branch valve based on the initial power required for each clothes drying area, the amount of hot air entering each drying area or the amount of air entering the air passage from the drying area is adjusted.

In the method for controlling a clothes processing device, the clothes processing device includes a first drying zone and a second drying zone. G1 is the weight value of the first drying area, G2 is the weight value of the second drying area, M1' is the correction factor of the first drying area, M2' is the correction factor of the second drying area, the first drying area and the second drying Assuming that the reference opening degree of the air branch valve corresponding to the simultaneous drying of the area is C' and the initial opening degree of the air branch valve is D', D=(M1'*G1/M2'*G2)*C'. Of these, C' is the opening degree value of the wind branch valve when the drying efficiency is maximized in the case of the same load obtained in the experiment.

As a preferred method of the present invention, a stepping motor is used to control the opening degree of the air diverter valve so as to flexibly adjust according to the drying conditions of each drying zone in real time.

By using the above technical solutions, the present invention has the following beneficial effects compared with the prior art.

The control method of the clothes treating apparatus described in the present invention is applied to the simultaneous operation of multiple drying zones to fully utilize the amount of heat supplied from the heat exchange system. This improves heat utilization and shortens drying time. Also, the drying efficiency is improved, which saves energy consumption.

This example further limits or rationalizes the first or second example.

As shown in FIG. 1, in the method for controlling a clothes treating machine, the clothes treating machine includes two clothes drying areas placed one above the other sharing the same heat exchange system. Specifically, when the drying areas start drying at the same time, the following steps are included.

S1: Two drying zones start drying at the same time.

S2: Calculate the initial power required for each drying zone based on the environmental temperature and load.

S3: Calculate the upper and lower opening degrees of the wind branch valve.

S4: Acquire the temperature value of the temperature sensor installed in the drying area.

S5: Adjust the opening of the air branch valve based on the temperature of the drying area, and operate for a certain period of time.

S6: Determine whether or not there is a drying area that satisfies the drying conditions, and if not, execute step S4.

Also, if it exists, the operation of the drying area is terminated, and the air branch valve is switched to the other drying area. Then, the one-area drying program is executed until the drying conditions are satisfied, and then the operation is terminated.

A method of calculating the initial power in step S2 is as follows. If P is the power and G is the weight of the dry area, the power P=K _i *G+B _j . Of these, K _i and B _j are constants corresponding to the environmental temperature, and the values taken by K _i and B _j differ depending on the difference in the environmental temperature.

In step S3, the vertical opening of the wind branch valve is obtained by the following method. The weight value of the first drying area is G1, the weight value of the second drying area is G2, the correction factor of the first drying area is M1, the correction factor of the second drying area is M2, the first drying area and the second drying area Assuming that the reference opening degree of the air branch valve corresponding to simultaneous drying is C and the initial opening degree of the air branch valve is D, D=(M1*G1/M2*G2)*C. Of these, C is the opening degree value of the wind branch valve when the drying efficiency is maximized in the case of the same load obtained in the experiment.

In step S5, the opening degree of the air branch valve is adjusted based on the temperatures of the exhaust ports of the first drying area and the second drying area. When the temperature rise rate of one drying area is faster than that of the other drying area, control is performed so that the opening of the air branch valve directed to the drying area where the temperature rises faster is made smaller.

Preferably, the adjustment of the degree of opening of the air branch valve is performed by the following method. Let T1 be the temperature of the exhaust port of the first drying area per unit time, and T2 be the temperature of the exhaust port of the second drying area. Set in advance in the device. Then, based on the difference value between T1 and T2, the degree of opening of the corresponding wind branch valve is obtained and adjusted.

By using the above technical solutions, the present invention has the following beneficial effects compared with the prior art.

The control method of the clothes treating apparatus described in the present invention is applied to the simultaneous operation of multiple drying zones to fully utilize the amount of heat supplied from the heat exchange system. This improves heat utilization and shortens drying time. Also, the drying efficiency is improved, which saves energy consumption.

This embodiment is a further limitation, rationalization or replacement of the schemes of embodiments 1-3. In addition, the measures of each embodiment can be used in combination.

The method of controlling the clothes processing apparatus described in this embodiment includes determining whether any of the drying areas are dry. The method for judging dryness is as follows.

Step A: The temperature of the exhaust port is sampled once every X seconds, and when the number of consecutive occurrences of any temperature value is N, that temperature value is taken as the current equilibrium temperature value TempA1.

Step B: Obtain the relationship between the equilibrium temperature value TempA and the equilibrium difference value ΔT stored in the clothes processing apparatus, and obtain the equilibrium difference value ΔT1 corresponding to the current equilibrium temperature value TempA1.

Step C: Continue heating, detect and calculate the difference value between the temperature of the exhaust port and the equilibrium temperature value TempA1 in real time, and determine that the clothes are dry when the difference value is equal to or greater than the equilibrium difference value ΔT1. .

As an embodiment, the following is further provided before said step A.

Step A1: Carry out a drying test for each load to obtain a drying temperature-time curve for each load.

Step A2: Calculate the equilibrium temperature value TempA and the end point temperature value T corresponding to various loads based on the drying temperature/time curve.

Step A3: Calculate the equilibrium difference value ΔT corresponding to each equilibrium temperature value TempA from the formula T=TempA+ΔT.

As an embodiment, after step A and before step B, the following is further provided.

Step A4: The temperature of the exhaust port is continuously sampled, and if the number of consecutive appearances of any temperature value is greater than the number of appearances of TempA1 in the previous time, this temperature value is set again as TempA1.

In step A, if TempA1 is not obtained within an arbitrary set time, the temperature value that appears most frequently within that time is taken as TempA1.

In step A, the value of X is adjusted according to the difference in structural model. The range of values that X takes is 1≦X≦30.

In step A above, the value N takes is adjusted for different load types and load weights. Note that the range of values that N takes is 3≦N≦15.

In step A, when the load is large, when it is detected that the number of consecutive occurrences of any temperature value reaches N, the temperature value is set as the current equilibrium temperature value TempA1. Further, when the load is small, when it is detected that the number of consecutive appearances of any temperature value becomes Na, the temperature value is set as the current equilibrium temperature value TempA1. Note that a is an experimental constant.

As an embodiment, in step B, the relationship between the equilibrium temperature value TempA and the equilibrium difference value ΔT is 24°C when 40°C ≤ TempA ≤ 42°C, and ΔT is 24°C when 43°C ≤ TempA ≤ 46°C. , ΔT is 21°C, and ΔT is 16°C when 47°C ≤ TempA ≤ 50°C.

A temperature sensor is attached to the exhaust port of the drying area of the clothes processing apparatus, and is used to detect the exhaust temperature of the drying area.

The present embodiment provides a clothes treating apparatus that includes a heat pump system, a plurality of clothes drying zones and an air channel for supplying hot air to the drying zones. A heat pump system includes an evaporator, a compressor, and a condenser. The heat exchange medium circulates in a circulation circuit formed by connecting the evaporator, the compressor, and the condenser in order, thereby heating the air passing through the air passage.

The clothes processing apparatus includes an outer tub, an air passage, and an inner tub provided within the outer tub. The air inlet and outlet of the air passage are respectively connected to the rear and front parts of the outer tub. The air passage and the outer tank form a closed circuit. A fan is provided in the air passage. The evaporator is provided at the air inlet of the air passage and is used to condense the air passing through the air passage. Also, the condenser is located in the air path between the fan and the evaporator and is used to heat the air passing through the air path.

A plurality of clothes drying areas share the same air path. The exhaust port of the air passage is provided with openings that communicate with the air intake ports of the plurality of clothes drying areas, and the openings are provided with air branch valves that can be controlled to open and close. Further, the air inlet of the air passage is provided with openings communicating with the air outlets of the plurality of clothes drying areas, respectively, and the openings are provided with air branch valves capable of controlling opening and closing.

The clothes processing apparatus is a clothes dryer having two rotating tubs, a washing machine having a clothes drying function, or an integrated washing/drying machine.

Alternatively, the clothes processing apparatus is a clothes drying cabinet having two or more drying areas, or a clothes processing apparatus combining a drying cabinet and a washing machine having a clothes drying function, or a clothes having a drying function. Other devices that combine processing structures.

Temperature sensors are provided at both the air inlet and outlet of each drying area, and are used to detect the supply air temperature and the exhaust air temperature of the drying area.

The above clothes processing apparatus uses any of the control methods for the clothes processing apparatus described in the present invention.

The foregoing are merely preferred embodiments of the invention and are not intended to limit the invention in any form. Although the present invention has been disclosed above through preferred embodiments, it is not intended to limit the present invention. Within the scope of the technical solution of the present invention, slight variations or supplements that can be implemented by those skilled in the art using the technical content presented above are regarded as equally modified equivalent embodiments, and any It does not deviate from the content of the technical plan. In addition, any simple modifications, equivalent variations and supplements added to the above embodiments based on the technical essence of the present invention are all within the scope of the scheme of the present invention.

Claims (10)

A method of controlling a clothes processing machine, said clothes processing machine comprising a plurality of clothes drying zones sharing the same heat exchange system, the method comprising:
Multiple drying zones start drying at the same time, the initial power required for each drying zone is calculated based on the environmental temperature and load, and heat is supplied to each drying zone at a constant ratio based on the initial power. control method. The clothes drying area of the clothes processing apparatus is provided with a weighing structure that determines the magnitude of the load, calculates the power required for each drying area based on the environmental temperature and the measured value, and calculates the power based on the obtained power. 2. The method of controlling a clothes processing apparatus according to claim 1, wherein the amount of heat supplied to each drying area is adjusted at a constant ratio. The clothes processing apparatus is provided with a power database corresponding to the environmental temperature and the measured value. Power P=K _i *G+B _j , wherein K _i and B _j are constants corresponding to the environmental temperature, and the values taken by K _i and B _j differ depending on the environmental temperature. Item 3. A method of controlling a clothes processing apparatus according to item 2. A plurality of clothes drying areas of the clothes processing apparatus share the same air passage, and an exhaust port of the air passage is provided with an opening communicating with an air intake port of each of the plurality of clothes drying areas. An air branch valve whose opening can be controlled is provided, and the amount of hot air entering each drying area is adjusted by controlling the opening of the air branch valve based on the initial power required for each clothes drying area. 4. The method of controlling a clothes processing apparatus according to claim 2 or 3, characterized in that: In the case of the same load, the higher the environmental temperature, the higher the K _i and B _j 3. The method of controlling a clothes processing apparatus according to claim 2, wherein the value taken by is smaller. The clothes processing apparatus includes a first drying area and a second drying area, adjusts the opening degree of the air diverter valve based on the temperatures of the first drying area and the second drying area, and adjusts the opening of the air diverter valve. 5. The control of the clothes processing apparatus according to claim 4, wherein the correspondence relationship between the temperature and the temperatures of the first drying area and the second drying area is preset in a control unit of the clothes processing apparatus. Method. The opening degree of the air branch valve is adjusted based on the temperatures of the exhaust ports of the first drying area and the second drying area, and when the temperature rise rate of one drying area is faster than that of the other drying area, the temperature Control so that the opening of the air branch valve toward the fast rising dry area is small,
Preferably, the temperature of the exhaust port of the first drying area in a unit time is T1, the temperature of the exhaust port of the second drying area is T2, and the correspondence relationship between the difference value between T1 and T2 and the degree of opening of the air branch valve. is preset in the clothes processing apparatus, and based on the difference value between T1 and T2, the opening degree of the corresponding wind branch valve is obtained and adjusted. How to control the device. The heat exchange system is a heat pump system or a heat pipe water cooling system, which calculates the power required for each drying zone, and controls the rotation speed of the compressor or the power of the heat pipe to output, thereby adjusting the power of the drying zone. 8. The method for controlling a clothes processing apparatus according to any one of claims 1 to 7, characterized in that: The heat exchange system is a heat pump system, and the heat pump includes an evaporator, a compressor, and a condenser. 8. The method of controlling a clothes processing apparatus according to any one of claims 1 to 7, characterized in that it is determined that drying is completed when the value is greater than the value. A clothing processing apparatus using the control method for a clothing processing apparatus according to any one of claims 1 to 9.

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