KR20190128462A - Apparatus for controlling laundry treating apparatus and laundry treating apparatus - Google Patents

Abstract

The present specification provides a heating device and a heat dissipation means on one side on a circuit board on which a control device is provided, and a heat treatment and heat dissipation of the control device are concentrated on the one side. will be.

Description

APPARATUS FOR CONTROLLING LAUNDRY TREATING APPARATUS AND LAUNDRY TREATING APPARATUS}

The present invention relates to a control apparatus of a clothes treating apparatus having a plurality of inverters and converters and performing a drying function, and a clothes treating apparatus including the same.

The clothes treating apparatus that performs the drying function supplies hot air into the drum to remove moisture absorbed by the drying object while the drying object is put into the rotating drum. The hot air supplied into the drum is generated by combustion heat using electric resistance heat or gaseous fuel, or by a condenser constituting a heat pump cycle, and the generated hot air is supplied into the drum by a blowing fan.

In addition, the clothes treating apparatus that performs the drying function may be classified into a circulation dryer and an exhaust dryer according to a hot air supply method. First, the circulation dryer is a dryer in which heating and cooling are repeated while hot air supplied into the drum is circulated inside the dryer. The exhaust dryer is a dryer in which hot air supplied into the drying drum exits the drying drum and is discharged to the outside of the dryer.

Meanwhile, Korean Patent Laid-Open Publication No. 10-2013-0101914 (published September 16, 2013, hereinafter "prior art") discloses a dryer having a drying mode selection means. Since the drum and the blowing fan included in the dryer disclosed in the prior document are connected to the same motor, the drum and the blowing fan are driven in synchronization with each other.

As described above, in the case of the dryer in which the drum and the blowing fan are connected to the same motor, the rotation control of the drum and the operation control of the blowing fan cannot be independently performed, thereby limiting the control method of the dryer.

In general, the control unit of the dryer is designed to drive a single motor connected to the drum and the blowing fan, and the compressor of the heat pump system, the problem of the dryer can not be solved by simply adding a separate motor.

In recent years, consumers are demanding a larger capacity dryer, and in order to provide a dryer capable of meeting the above-mentioned problems and solving the above-described problems, research on a dryer having a plurality of motors has been conducted.

In order to control the dryer, the controller includes a plurality of inverters for controlling a plurality of motors and a converter for transmitting DC power to the plurality of inverters. It will include a circuit element. In particular, the plurality of inverters and converters include a plurality of semiconductor devices, such as diodes and switching elements, which are susceptible to heat. When the plurality of inverters and converters are configured as an integrated module on a single substrate, a plurality of inverters Heat is generated. As such, when a control device including a plurality of inverters and converters is configured on one substrate, the heat generation problem of the control device is inevitably intensified. In addition, when a plurality of heat generating elements are provided on one circuit board, a heat dissipation means for each of the heat generating elements should be provided. A plurality of heat generating elements and a corresponding heat dissipation means are provided on a single circuit board to provide a circuit. There are also structural difficulties in constructing this. If the heat dissipation means is not properly provided, the element is easily burned out due to heat, and the function of the control device is not properly performed.

As a result, the control device including the plurality of inverters and converters has a large structural / functional limitation in itself that constitutes a circuit on one substrate, and this circuit configuration itself is very resistant to heat generated by a plurality of heat generating elements. There was a weak limit. In addition, these limitations and limitations do not guarantee the reliability and utility of the control device, and the manufacturing and configuration of such a control device, various functions using the control device, and the configuration of the dryer are not provided.

The present invention is to provide a control apparatus and a clothes processing apparatus of the clothes processing apparatus that can solve the above problems.

In particular, it is usefully applied to the control device of the clothes processing apparatus including a PFC (Power Factor Correction) applied converter and a plurality of inverters for controlling the plurality of motors and the clothes processing apparatus including the same, thereby solving the above problems. It is intended to provide embodiments of a control apparatus and a clothes processing apparatus of the clothes processing apparatus.

The technical problem to be solved by the present invention, in the circuit configuration of the control device including a plurality of heat generating elements, control of the clothing processing apparatus that can prevent the burn out of the circuit configuration from a large amount of heat generated in the plurality of heat generating elements. An apparatus and a clothes processing apparatus are provided.

It is also an object of the present invention to provide a control apparatus and a clothes processing apparatus of a clothes treating apparatus in which the heat dissipation of the plurality of heat generating elements can be effectively performed in a circuit configuration of a control apparatus including a plurality of heat generating elements.

In addition, an object of the present invention, in the circuit configuration of a control device including a plurality of heat generating elements, the control of the clothes processing apparatus that can be blown and cooled to the heat radiating means for radiating heat generated by the plurality of heat generating elements An apparatus and a clothes processing apparatus are provided.

In addition, an object of the present invention, in the circuit configuration of a control device including a plurality of heat generating elements, the control device and the clothes processing device of the clothes processing apparatus that can configure the circuit by classifying and arranging the elements according to the characteristics of the circuit elements. To provide.

The control apparatus and the clothes processing apparatus of the clothes processing apparatus which concern on this invention make it a solution to provide a heat generating element and a heat dissipation means in one side on the circuit board with a control apparatus.

That is, the control apparatus and the clothing processing apparatus of the clothes processing apparatus according to the present invention includes a heating element and a heat dissipation means on one side on a circuit board on which the control device is provided, so that the heat generation and heat dissipation of the control device is at one side. It is a technical feature to make it intensive.

More specifically, the heat generating element that requires heat dissipation among the circuit elements of the control device is concentrated on the one side, and integral heat dissipation means is provided on the one side to heat the heat generated by the heat generating element through the heat dissipation means. Heat dissipate at once.

Further, the heat dissipation and heat dissipation is concentrated in the one side of the circuit board in this manner, further comprising a heat dissipation fan for blowing the heat dissipated in the heat dissipation means, the heat dissipated in the heat dissipation means You can.

In addition, the circuit board may be provided adjacent to the exhaust means of the clothes treating apparatus to exhaust the heat radiated from the heat radiating means.

Through these technical features, heat generation and heat dissipation of the control apparatus of the clothes treating apparatus including a plurality of heat generating elements are centralized / collectively performed at a part of the circuit board, and blowing and cooling of the heat dissipation means are multidirectional. In this case, it is possible to improve the limits of the heat dissipation structure of the inside of the clothes handling apparatus and the control device of the clothes handling apparatus.

Technical features as described above, the drum is a drying object is accommodated to perform a drying operation, a blowing fan for promoting the flow of air in the clothes processing apparatus, to remove the moisture in the air drawn from the drum and exchange heat A plurality of motors driving the heat pump, the drum, the blower fan, and the heat pump, a converter for converting AC power input from an external power source into a DC power source, and receiving the DC power from the converter to drive the plurality of motors. It can be usefully applied to the clothes processing apparatus including a plurality of inverters converted to a driving power for outputting to the plurality of motors and a control unit for controlling the operation of the converter and the inverter.

Technical features as described above, may be applied to a control device for controlling a clothes processing apparatus, a circuit board on which such a control device is implemented, or a clothes processing apparatus including such a control device.

The control apparatus and the garment processing apparatus of the clothing processing apparatus which concerns on the technical feature as mentioned above as a means of solving a subject implement the circuit board of the control apparatus of a clothing processing apparatus, the control apparatus of a clothing processing apparatus, and the clothing processing apparatus. Provide an example.

An embodiment of a circuit board of a control apparatus of a clothes processing apparatus according to the present disclosure is a circuit board on which a control apparatus of a clothes processing apparatus is implemented, the plurality of circuit elements performing a function for driving control of the clothes processing apparatus. A plurality of heat generating elements disposed on one side of the circuit board and integral heat dissipation means disposed on the one side so as to be adjacent to the plurality of heat generating elements to radiate heat generated by the plurality of heat generating elements.

In addition, the embodiment of the control device of the clothes processing apparatus disclosed herein is a control device of the clothes processing apparatus provided on a circuit board, the plurality of circuit elements performing a function for controlling the drive of the clothes processing apparatus A plurality of heat generating elements disposed on one side of the circuit board and integral heat dissipation means disposed on the one side so as to be adjacent to the plurality of heat generating elements to radiate heat generated by the plurality of heat generating elements.

In addition, an embodiment of the clothes treating apparatus disclosed in the present specification includes a drum in which a drying object is accommodated to perform a drying operation, a blowing fan for promoting the flow of air in the clothes treating apparatus, and moisture in the air drawn from the drum. A plurality of motors and circuit boards for driving each of the heat pump for removing and exchanging heat, the drum, the blower fan, and the heat pump, and controlling the driving of the plurality of motors to control the operation of the clothes treating apparatus. And a control device, wherein the control device converts an AC power input from an external power source into a DC power source, receives the DC power from the converter, and converts the DC power into driving power for driving the plurality of motors. A plurality of inverters output to each of the plurality of motors and a plurality of heat generations included in the converter and the inverter It is provided in a position adjacent to the element, and includes integral heat dissipation means for dissipating heat generated by the plurality of heat generating elements, wherein the plurality of heat generating elements and the heat dissipation means are disposed on one side of the circuit board.

As described above, embodiments of the circuit board of the control apparatus of the clothes processing apparatus, the control apparatus of the clothes processing apparatus, and the clothes processing apparatus are particularly provided for controlling a power factor correction (PFC) applied converter and a plurality of motors. It can be a useful solution of the control device of the clothes handling apparatus including the inverter and the clothes handling apparatus including the same.

The control apparatus and clothes processing apparatus of the clothes treating apparatus according to the present invention includes a heating element and a heat dissipation means on one side on a circuit board on which the control apparatus is provided, so that heat generation and heat dissipation of the control apparatus is concentrated in the one side. There is an effect that can be achieved.

That is, the control device and the clothes processing device of the clothes processing apparatus according to the present invention, by partially arranging some heat generating elements that require heat dissipation among the circuit elements of the control device on the one side, by providing an integrated heat dissipation means on the one side By using the heat radiating means, there is an effect that the heat generated from the heat generating element can be radiated in a batch.

Accordingly, in the circuit configuration of the control apparatus including a plurality of heat generating elements, including a converter and a plurality of inverters, there is an effect that the heat dissipation of heat generated by the plurality of heat generating elements can be effectively and easily performed.

In addition, by preventing the burnout of the circuit configuration from a large amount of heat generated in the plurality of heat generating elements, it is possible to protect the circuit configuration from burnout caused by heat generated in the plurality of heat generating elements, the control device including a plurality of circuit elements The stability and reliability can be increased, as well as the life of the control device can be increased.

In addition, the control apparatus and the clothes processing apparatus of the clothes processing apparatus according to the present invention further has a heat radiation fan for blowing the heat radiated by the heat radiating means, there is an effect that can blow the heat radiated by the heat radiating means.

In addition, by providing the control device adjacent to the exhaust means of the clothes treating apparatus, the heat radiated by the heat radiating means may be exhausted.

Accordingly, the blowing and cooling of the heat dissipation means for dissipating the heat generated by the plurality of heat generating elements can be made, as well as the effect of further increasing the heat dissipation effect of the heat dissipation means.

In addition, the control device and the clothes processing apparatus of the clothes processing apparatus according to the present invention includes the plurality of heat generating elements and heat dissipation means on the one side, so that the circuit elements in the circuit configuration of the control device including a plurality of circuit elements. The circuit can be configured by classifying and arranging elements according to the characteristics of the circuit.

That is, the control device and the clothes processing device of the clothes processing apparatus according to the present invention, the circuit configuration of the control device including a plurality of inverters and converters can be easily and functionally and structurally made, and the design and manufacture of the control device Convenience also has an effect that can be increased.

1 is a conceptual diagram of a clothes processing apparatus according to an embodiment of the present invention.
2A is a side view of a drum and an air circulation passage in a clothes treating apparatus according to an embodiment of the present invention.
2A is a perspective view of a base and parts mounted on the base in the apparatus for treating clothes according to an embodiment of the present invention;
3A is a block diagram illustrating control components of a clothes treating apparatus according to the present invention.
3B is a circuit diagram showing a control circuit of the clothes treating apparatus according to the present invention.
Figure 4A is an exploded perspective view of a control device of the clothes treating apparatus according to the present invention.
4B is a combined view of the control device as shown in FIG. 4A.
5 is an exemplary view showing an example of heat dissipation means of the control device of the clothes treating apparatus according to the present invention.
Figure 6 is an exemplary view showing a configuration on a circuit board according to an embodiment of the control device of the clothing processing apparatus according to the present invention.
7 is an exemplary view showing a position provided according to an embodiment of the control device of the clothing processing apparatus according to the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments disclosed herein will be described in detail with reference to the accompanying drawings, and technical terms used herein are only used to describe specific embodiments, and are intended to limit the spirit of the technology disclosed herein. Note that is not.

In addition, the technical terms used herein should be construed as meanings generally understood by those skilled in the art to which the technology disclosed herein belongs, unless defined otherwise in this specification. It should not be interpreted in a comprehensive sense, or in an overly reduced sense.

Hereinafter, to facilitate the understanding of the embodiments of the present invention, the embodiments are described in [Basic Configuration of Apparel Processing Apparatus], [Circuit Board of Control Apparatus of Apparel Processing Apparatus], [Control Apparatus of Apparel Processing Apparatus], and [Apparel Processing Apparatus]. Explain separately.

[Basic Configuration of Apparel Processing Unit]

First, the basic configuration of the clothes treating apparatus to which the present invention is applied will be described.

EMBODIMENT OF THE INVENTION Hereinafter, the clothing processing apparatus which concerns on this invention is demonstrated in detail with reference to drawings. In the present specification, different embodiments are given the same or similar reference numerals for the same or similar components, and description thereof is replaced with the first description. As used herein, the singular forms "a", "an" and "the" include plural forms unless the context clearly indicates otherwise.

When a component is referred to herein as being "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but other components may be present in between. It should be understood that it may. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that there is no other component in between.

1 is a conceptual diagram of a clothes processing apparatus 1000 according to an embodiment of the present invention.

The cabinet 1010 forms an appearance of the clothes treating apparatus 1000. A plurality of metal plates constituting the front part, the rear part, the left and right side parts, the upper part and the lower part of the clothes processing apparatus 1000 are coupled to each other to form a cabinet 1010. The front opening 1011 is formed in the front portion of the cabinet 1010 so that the object to be processed may be introduced into the drum 1030.

The door 1020 is formed to open and close the front opening 1011. The door 1020 may be rotatably connected to the cabinet 1010 by a hinge 1021. The door 1020 may be formed of a partially transparent material. Therefore, even when the door 1020 is closed, the inside of the drum 1030 may be visually exposed through the transparent material.

The drum 1030 is rotatably installed in the cabinet 1010. The drum 1030 is formed in a cylindrical shape to accommodate the object to be treated. The drum 1030 is disposed so as to lie toward the front and rear direction of the clothes treating apparatus 1000 so as to receive the object to be treated through the front opening 1011. Unevenness may be formed along the circumference of the outer circumferential surface of the drum 1030.

The drum 1030 is formed with openings opened toward the front and the rear of the clothes processing apparatus 1000. The object to be treated may be introduced into the drum 1030 through the front opening. Hot dry air may be supplied into the drum 1030 through the rear opening.

The drum 1030 is rotatably supported by the front supporter 1040, the rear supporter 1050, and the roller 1060. The front supporter 1040 is disposed below the front of the drum 1030, and the rear supporter 1050 is disposed behind the drum 1030.

The roller 1060 may be installed at the front supporter 1040 and the rear supporter 1050, respectively. The roller 1060 is disposed directly below the drum 1030 and contacts the outer circumferential surface of the drum 1030. The roller 1060 is formed to be rotatable, and an elastic member such as rubber is coupled to the outer circumferential surface of the roller 1060. The roller 1060 is rotated in a direction opposite to the rotation direction of the drum 1030.

Heat pump cycle devices 1100 may be installed below the drum 1030. Here, the lower side of the drum 1030 means a lower portion in the space between the outer circumferential surface of the drum 1030 and the inner circumferential surface of the cabinet 1010. The heat pump cycle devices 1100 refer to devices that constitute a cycle to sequentially evaporate-compress-condense-expand the refrigerant. Upon operation of the heat pump cycle apparatuses 1100, the air is hot dried while sequentially exchanging heat with the evaporator 1110 and the condenser 1130.

Inlet duct 1210 and outlet duct 1220 form a flow path for circulating hot dry air formed by heat pump cycle devices 1100 to drum 1030. The inlet duct 1210 is disposed at the rear of the drum 1030, and the air dried by the heat pump cycle devices 1100 is supplied to the drum 1030 through the inlet duct 1210. The outlet duct 1220 is disposed at the front lower side of the drum 1030, and the air that has dried the object to be processed is recovered again through the outlet duct 1220.

A base 1310 is installed below the heat pump cycle devices 1100. The base 1310 refers to a molded body that supports various components of the clothes treating apparatus 1000, including the heat pump cycle apparatuses 1100, from below.

The base cover 1320 is installed between the base 1310 and the drum 1030. The base cover 1320 is formed to cover the heat pump cycle devices 1100 mounted on the base 1310. When the side wall of the base 1310 and the base cover 1320 are combined, an air circulation flow path is formed. Some of the heat pump cycle devices 1100 are installed in the air circulation passage.

The bucket 1410 is disposed on the upper left side or the upper right side of the drum 1030. Here, the upper left or upper right side of the drum 1030 means the upper left or upper right portion in the space between the outer circumferential surface of the drum 1030 and the inner circumferential surface of the cabinet 1010. In FIG. 1, a bucket 1410 is shown disposed on the upper left side of the drum 1030. The water container 1410 collects condensate.

Condensed water is generated when the air that has dried the object to be treated is recovered through the outlet duct 1220 and heat exchanged with the evaporator 1110. More specifically, when the temperature of the air decreases due to heat exchange in the evaporator 1110, the amount of saturated water vapor that the air may contain decreases. Since the air recovered through the outlet duct 1220 contains moisture exceeding the amount of saturated water vapor, condensed water is inevitably generated.

The water pump 1440 (see FIG. 2B) is installed in the clothes processing apparatus 1000. The water pump 1440 raises the condensate to the water tank 1410. The condensate is collected in the bucket 1410.

The bucket cover 1420 may be disposed at one corner of the front portion of the clothes processing apparatus 1000 to correspond to the position of the bucket 1410. The bucket cover 1420 is formed to be gripped by hand and is disposed on the front surface of the clothes processing apparatus 1000. When the bucket cover 1420 is pulled to empty the condensed water collected in the bucket 1410, the bucket 1410 is withdrawn from the bucket supporting frame 1430 together with the bucket cover 1420.

The bucket supporting frame 1430 is formed to support the bucket 1410 in the cabinet 1010. The bucket supporting frame 1430 extends along the insertion or withdrawal direction of the bucket 1410 to guide the insertion or withdrawal of the bucket 1410.

The input / output panel 1500 may be disposed beside the bucket cover 1420. The input / output panel 1500 may include an input unit 1510 for receiving a selection of a clothing processing course from a user, and an output unit 1520 for visually displaying an operating state of the clothing processing apparatus 1000. The input unit 1510 may be formed of a jog dial, but is not limited thereto. The output unit 1520 may be configured to visually display an operating state of the clothes processing apparatus 1000, and the clothes processing apparatus 1000 may include a separate configuration for an acoustic display in addition to the visual display.

The controller 1600 is configured to control the operation of the clothing processing apparatus 1000 based on a user's input applied through the input unit 1510. The controller 1600 may be composed of a printed circuit board and elements mounted on the printed circuit board. When the user inputs a control command such as selecting a clothes processing course through the input unit 1510 or operating the clothes processing apparatus 1000, the controller 1600 controls the operation of the clothes processing apparatus 1000 according to a preset algorithm. do.

The printed circuit board constituting the controller 1600 and the elements mounted on the printed circuit board may be disposed on the upper left side or the upper right side of the drum 1030. In FIG. 1, the printed circuit board is disposed on the upper right side of the drum 1030 opposite to the water tank 1410 on the upper side of the drum 1030. Electrical products such as condensate is collected in the bucket 1410, moisture pumped air flows to the heat pump cycle apparatuses 1100 and ducts 1210, 1220, and 1230, and printed circuit boards and components. Given the vulnerability to water, the printed circuit board and elements are preferably spaced as far as possible from the water bottle 1410 or the heat pump cycle devices 1100.

Hereinafter, the drum 1030 and the air circulation passage will be described.

2A is a side view of the drum 1030 and the air circulation passage. In FIG. 2A, the left side corresponds to the front F of the drum 1030, and the right side corresponds to the rear R of the drum 1030.

In order to dry the clothes and the like (processing object) put into the drum 1030, the air is dried at high temperature and supplied to the drum 1030, and the air from which the clothes are dried is recovered again to remove moisture from the air. shall. In order to repeat this process in a condensation dryer, air must be continuously circulated through the drum 1030. The air is circulated through the drum 1030 and the air circulation passage.

The air circulation passage is formed by an inlet duct 1210, an outlet duct 1220, and a connecting duct 1230 disposed between the inlet duct 1210 and the outlet duct 1220. Each of the inlet duct 1210, the outlet duct 1220, and the connecting duct 1230 may be formed by combining a plurality of members.

The inlet duct 1210, the drum 1030, the outlet duct 1220, and the connection duct 1230 are sequentially connected based on the flow of air, and the connection duct 1230 is connected to the inlet duct 1210 again to waste oil. Form a closed flow path.

Inlet duct 1210 extends from connecting duct 1230 to the rear of rear supporter 1050. The rear surface of the rear supporter 1050 refers to the surface facing the rear of the clothes processing apparatus 1000. Since the drum 1030 and the connecting duct 1230 are disposed to be spaced apart from each other along the vertical direction, the inlet duct 1210 is directed toward the rear of the drum 1030 from the connecting duct 1230 disposed below the drum 1030. It may have a structure extending in the vertical direction.

The inlet duct 1210 is coupled to the rear of the rear supporter 1050. Holes are formed in the rear surface of the rear supporter 1050. Therefore, the hot dry air is supplied from the inlet duct 1210 into the drum 1030 through the hole formed in the rear supporter 1050.

The outlet duct 1220 is disposed below the front supporter 1040. Since the front opening for injecting a treatment object should be formed in front of the drum 1030, the outlet duct 1220 is disposed below the front of the drum 1030.

Outlet duct 1220 extends from front supporter 1040 to connecting duct 1230. Like the inlet duct 1210, the outlet duct 1220 may extend in the vertical direction, but the length of the outlet duct 1220 extending in the vertical direction is shorter than that of the inlet duct 1210. Air dried in the drum 1030 is recovered to the connecting duct 1230 through the outlet duct 1220.

An evaporator 1110 and a condenser 1130 of the heat pump cycle devices 1100 are installed in the connection duct 1230. In addition, a circulation fan 1710 for supplying hot dry air to the inlet duct 1210 is also installed in the connection duct 1230. An evaporator 1110 is disposed upstream of the condenser 1130 based on the flow of air, and a circulation fan 1710 is disposed downstream of the condenser 1130. The circulation fan 1710 generates air in the direction of sucking air from the condenser 1130 and supplying the inlet duct 1210.

Next, the components under the drum 1030 will be described.

2B is a perspective view of the base 1310 and components mounted to the base 1310.

The base 1310 is formed to support the mechanical elements of the garment treatment apparatus 1000, including the heat pump cycle devices 1100. The base 1310 forms a number of mounts 1313 for mounting of the mechanical elements. Mounting portion 1313 refers to an area provided for mounting of mechanical elements. Each mounting portion 1313 may be partitioned from each other by a step of the base 1310. Hereinafter, the components will be described in the counterclockwise direction with respect to the connection duct 1230.

Unlike the drum 1030 disposed at the center of the clothes processing apparatus 1000 in the left and right directions, the air circulation path is eccentrically disposed to the left or the right of the drum 1030. In FIG. 2B, the air circulation flow path is shown disposed on the lower right side of the drum 1030. Eccentric arrangement of the air circulation passage is for efficient drying of the object to be treated and for efficient placement of the parts.

The inlet portion 1311 of the connecting duct 1230 is disposed below the outlet duct 1220 and is connected to the outlet duct 1220. The inlet portion 1311 of the connecting duct 1230 is formed with the outlet duct 1220 to guide the air in an inclined direction. For example, in FIG. 2B the inlet portion 1311 of the connecting duct 1230 narrows down. In particular, the left side surface of the inlet portion 1311 is formed to be inclined to the lower right side. If the air circulation passage is disposed on the lower left side of the drum 1030, the right side of the inlet portion 1311 will be formed to be inclined downward left.

The evaporator 1110, the condenser 1130 and the circulation fan 1710 are sequentially disposed downstream of the inlet portion 1311 based on the flow of air. When the clothes processing apparatus 1000 is viewed from the front, the condenser 1130 is disposed behind the evaporator 1110, and the circulation fan 1710 is disposed behind the condenser 1130. The evaporator 1110, the condenser 1130 and the circulation fan 1710 are mounted to respective mounting portions 1313 provided in the base 1310.

The base cover 1320 may be installed on the evaporator 1110 and the condenser 1130. The base cover 1320 may be composed of a single member or a plurality of members. When the base cover 1320 is formed of a plurality of members, the base cover 1320 may include a front base cover 1321 and a rear base cover 1322.

The base cover 1320 is formed to cover the evaporator 1110 and the condenser 1130. The base cover 1320 may be coupled to a step or sidewall of the base 1310 formed on the left and right sides of the evaporator 1110 and the condenser 1130 to form a part of the connection duct 1230.

The circulation fan 1710 is surrounded by the base 1310 and the base cover 1320. An outlet portion 1312 of the connecting duct 1230 is formed above the circulation fan 1710. The outlet portion 1312 of the connecting duct 1230 is connected with the inlet duct 1210. The hot dry air formed by the heat pump cycle devices 1100 is supplied to the drum 1030 through the inlet duct 1210.

A water pump 1440 is installed at one side of the condenser 1130 (or one side of the circulation fan 1710). The water pump 1440 is formed to transfer the condensed water collected to the mounting portion in which the water pump 1440 is installed.

The base 1310 is formed to drain the condensed water generated during the operation of the heat pump cycle devices 1100 to a mounting portion in which the water pump 1440 is installed. For example, the bottom surface of the mounting portion 1313 may be inclined to allow the condensed water to flow to the mounting portion where the water pump 1440 is installed, or the stepped height of the mounting portion where the water pump 1440 is installed may be partially low.

By the structure of the base 1310, the condensed water collected by the mounting unit 1313 in which the water pump 1440 is installed may be transferred to the water tank 1410 by the water pump 1440. In addition, the condensed water may be transferred by the water pump 1440 and used to clean the evaporator 1110 or the condenser 1130.

One side of the water pump 1440 may be a compressor 1120 and a compressor cooling fan 1720 for cooling the compressor 1120. The compressor 1120 is an element constituting the heat pump cycle devices 1100, but does not need to be installed in the air circulation passage because it does not directly exchange heat with air. Rather, since the compressor 1120 may interfere with the flow of air if the compressor 1120 is installed in the air circulation passage, the compressor 1120 is preferably installed outside the air circulation passage as shown in FIG. 2B.

The compressor cooling fan 1720 generates wind toward the compressor 1120 or in the direction of sucking air from the compressor 1120. When the temperature of the compressor 1120 is lowered by the compressor cooling fan 1720, the compression efficiency is improved.

The gas-liquid separator 1140 is installed upstream of the compressor 1120 based on the flow of the refrigerant. The gas-liquid separator 1140 separates the gaseous phase and the liquid phase of the abnormal refrigerant introduced into the compressor 1120 so that only the gas phase flows into the compressor 1120. This is because the liquid phase causes a failure of the compressor 1120 and a decrease in efficiency.

The refrigerant is evaporated (liquid-> gas) while absorbing heat from the evaporator 1110, and the refrigerant is brought into the compressor 1120 at a low temperature and low pressure gas state. When the gas liquid separator 1140 is installed upstream of the compressor 1120, the refrigerant may pass through the gas liquid separator 1140 before entering the compressor 1120. In the compressor 1120, the refrigerant in the gas phase is compressed and flows to the condenser 1130 at a high temperature and high pressure. In the condenser 1130, the refrigerant liquefies while releasing heat. The liquefied high pressure refrigerant is depressurized in an expander (not shown). The low temperature low pressure liquid refrigerant enters the evaporator 1110.

The hot dry air is supplied to the drum 1030 through the inlet duct 1210 to dry the object to be treated. The hot dry air evaporates the moisture of the object to be treated and becomes hot and humid air. The high temperature and high humidity air is recovered through the outlet duct 1220, and receives the heat of the refrigerant through the evaporator 1110 to become low temperature air. As the temperature of the air decreases, the amount of saturated water vapor in the air decreases, and the steam contained in the air condenses. Subsequently, the low temperature dry air receives heat of the refrigerant through the evaporator 1110, and becomes the high temperature dry air and is supplied to the drum 1030 again.

Hereinafter, a control configuration of the clothes treating apparatus according to the present invention will be described with reference to FIG. 3A.

Referring to FIG. 3A, the garment treating apparatus according to the present invention includes an input unit 310, an output unit 320, a communication unit 330, a detection unit 340, an inverter 350, a motor 360, and a converter 370. The control unit 380 may include at least one of the valve unit 391, the pump unit 392, and the auxiliary heater unit 393.

The input unit 310 may receive a control command related to an operation of the clothing processing apparatus from a user. The input unit 310 may be configured as a plurality of buttons or may be configured as a touch screen.

In detail, the input unit 310 may be formed as a control panel that receives a selection of an operation mode of the clothes processing apparatus or receives an input related to execution of the selected driving mode.

The output unit 320 may output information related to the operation of the clothes processing apparatus. The output unit 320 may include at least one display.

The information output by the output unit 320 may include information related to an operating state of the clothes processing apparatus. That is, the output unit 320 may output information related to at least one of the selected driving mode, whether a failure occurs, the driving completion time, and the amount of storage accommodated in the drum.

In one embodiment, the output unit 320 may be a touch screen integrally formed with the input unit 310.

The communication unit 330 may communicate with an external network. The communication unit 330 may receive a control command related to the operation of the clothing processing apparatus from an external network. For example, the communication unit 330 may receive an operation control command of the clothes processing apparatus sent from the external terminal through the external network. In this way, the user can remotely control the clothes processing apparatus.

In addition, the communication unit 330 may transmit information related to the operation result of the clothes processing apparatus to a predetermined server through an external network.

In addition, the communication unit 330 may communicate with other electronic devices to establish an Internet of Things (IOT) environment.

The detector 340 may detect information related to the operation of the clothes processing apparatus.

In detail, the detector 340 may include at least one of a current sensor, a voltage sensor, a vibration sensor, a noise sensor, an ultrasonic sensor, a pressure sensor, an infrared sensor, a visual sensor (camera sensor), and a temperature sensor.

In one example, the current sensor of the sensing unit 340 may detect a current flowing to one point of the control circuit of the clothing processing apparatus.

In another example, the temperature sensor of the sensing unit 340 may detect the temperature in the drum.

As described above, the sensing unit 340 may include at least one of various types of sensors, and the type of sensor included in the clothes treating apparatus is not limited. In addition, the number or installation position of each sensor can also be variously designed according to the purpose.

The inverter 350 includes a plurality of inverter switches, converts the smoothed DC power supply (Vdc) into three-phase AC power supplies (va, vb, vc) of a predetermined frequency by outputting them to a motor. can do.

Referring to FIG. 3A, the clothes treating apparatus according to the present invention may include a plurality of inverters 351, 352, and 353, and each inverter may supply power to the plurality of motors 361, 362, and 363. have.

In FIG. 3A, the clothes treating apparatus includes three inverters 351, 352, and 353, and each inverter supplies power to three motors 361, 362, and 363. It is not limited to this.

In detail, the first inverter 351 may supply power to the first motor 361 that rotates the drum 301, and the second inverter 352 may rotate the second motor 362 that rotates the blower fan 302. ), And the third inverter 353 may supply power to the third motor 363 driving the compressor of the heat pump 303.

The rotating shaft of the first motor 361 and the rotating shaft of the drum 301 are connected by a belt (not shown), and the first motor 361 may transmit the rotating force to the drum 301 through the belt.

The motor 360 may be a BLDC motor capable of speed control based on the speed command value, or may be a constant speed motor that does not perform speed control. In one example, the first motor for rotating the drum, the third motor for driving the compressor may be configured as a BLDC motor, the second motor for rotating the blowing fan may be configured as a constant speed motor.

Inverters 351, 352, and 353 each have a pair of upper arm switches Sa, Sb, Sc, and lower arm switches S'a, S'b, S'c connected in series with each other. The lower arm switches are connected in parallel with each other (Sa & S'a, Sb & S'b, Sc & S'c). Diodes are connected in anti-parallel to each of the switches Sa, S'a, Sb, S'b, Sc and S'c.

That is, the first upper arm switch Sa and the first lower arm switch S'a implement the first phase, and the second upper arm switch Sb and the second lower arm switch S'b implement the second phase. The third upper arm switch Sc and the third lower arm switch S'c may implement the third phase.

In an embodiment, the inverter 350 may include a shunt resistor corresponding to at least one of the first to third phases.

Specifically, the first shunt resistor may be connected to one end of the first lower arm switch S'a of the first pair of switches Sa and S'a, and similarly, to one end of the second lower arm switch S'b. The second shunt resistor may be connected, and a third shunt resistor may be connected to one end of the third lower arm switch S'c. The first to third shunt resistors are not essential components, and only some of the three shunt resistors may be provided as necessary.

In another embodiment, the inverter 350 may be connected to a common shunt resistor commonly connected to the first to third phases.

Meanwhile, the switches in the inverters 351, 352, and 353 perform on / off operations of the switches based on the inverter switching control signal generated by the controller 380. As a result, the three-phase AC power having a predetermined frequency is output to the motor 360.

Inverters 351, 352, and 353 having such a function include an IPM (Intelligent Power Module) in which the switches Sa, S'a, Sb, S'b, Sc, and S'c are formed in one module form. Can be made.

The controller 380 may control the switching operation of the inverters 351, 352, and 353 based on the sensorless method. In detail, the controller 380 may control the switching operation of the inverter 350 using the motor phase current detected by the current sensor of the detector 340.

The controller 380 outputs an inverter switching control signal to the inverters 351, 352, 353 in order to control the switching operation of the inverters 351, 352, 353. Here, the inverter switching control signal is composed of a switching control signal of the pulse width modulation (PWM).

As shown in FIG. 3A, the clothes treating apparatus according to the present invention includes a plurality of inverters. Since the power consumption may increase as the number of inverters increases, the present invention proposes a clothes treating apparatus having a converter 370.

The converter 370 converts commercial AC power into DC power and outputs the DC power. In more detail, the converter 370 may convert the single-phase AC power or the three-phase AC power into DC power to output the same. The internal structure of the converter 370 also varies according to the type of commercial AC power source.

On the other hand, the converter 370 may be made of a diode or the like without a switching element, and may perform rectification without a separate switching operation.

For example, in the case of single phase AC power, four diodes may be used in the form of a bridge, and in the case of three phase AC power, six diodes may be used in the form of a bridge.

On the other hand, the converter 370, for example, may be used a half-bridge converter is connected to two switching elements and four diodes, in the case of a three-phase AC power supply, six switching elements and six diodes may be used. .

When the converter 370 includes a switching element, the boosting operation, the power factor improvement, and the DC power conversion may be performed by the switching operation of the switching element.

The valve 391 may be disposed at one point of the flow path installed in the clothes treating apparatus to intermittently flow the flow. The pump unit 392 may provide a driving force for supplying gas or liquid to the flow path.

In addition, the auxiliary heater 393 may be installed separately from the heat pump to supply heat to the drum. The auxiliary heater unit 393 may heat air introduced into the drum.

The controller 380 may control the components included in the clothes processing apparatus.

First, the controller 380 may generate at least one of a power command value, a current command value, a voltage command value, and a speed command value corresponding to the motor 360 to control the rotation of the motor 360.

In detail, the controller 380 may calculate the power or the load of the motor 360 based on the output of the detector 340. In detail, the controller 380 may calculate the rotational speed of the motor by using the phase current value detected by the current sensor of the detector 340.

In addition, the controller 380 may generate a power command value corresponding to the motor, and calculate a difference between the generated power command value and the calculated power. In addition, the controller 380 may generate the speed command value of the motor based on the difference between the power command value and the calculated power.

 In addition, the controller 380 may calculate a difference between the speed command value of the motor and the calculated rotation speed of the motor. In this case, the controller 380 may generate a current command value applied to the motor based on the difference between the speed command value and the calculated rotation speed.

In an example, the controller 380 may generate at least one of a q-axis current command value and a d-axis current command value.

The controller 380 may convert the phase current of the stationary coordinate system or the phase current of the rotational coordinate system based on the phase current detected by the current sensor. The controller 380 may generate a voltage command value applied to the motor by using the converted phase current and the current command value.

By performing such a process, the controller 380 generates an inverter switching control signal according to the PWM method.

The controller 380 may adjust the duty ratio of the switch included in the inverter by using the inverter switching control signal.

In addition, the controller 380 may control at least one of a drum, a blowing fan, and a heat pump based on a control command input by the input unit 310.

In one example, the controller 380 may control the rotation pattern of the drum based on a user input applied to the input unit 310.

In another example, the controller 380 may control the rotational speed or the operation time of the blowing fan based on a user input applied to the input unit 310.

In another example, the controller 380 may control the output of the heat pump to adjust the temperature in the drum based on a user input applied to the input unit 310.

In the following Figure 3b is described a control circuit of the clothes processing apparatus according to the present invention.

The control circuit included in the clothes treating apparatus according to the present invention includes a converter 370, a dc end voltage detector B, a smoothing capacitor Vdc, a plurality of shunt resistors, a plurality of inverters 351, 352, 353, and a plurality of It may further include a diode (D, BD), the reactor (L) and the like.

The reactor L is disposed between the commercial AC power supply Vin and the converter 370 to perform power factor correction or step-up operation. In addition, the reactor L may perform a function of limiting harmonic currents due to the high speed switching of the converter 370.

The converter 370 converts the commercial AC power Vin passed through the reactor L into a DC power source and outputs the DC power. In the drawing, a commercial AC power source Vin is illustrated as a single phase AC power source, but may be a three phase AC power source.

The smoothing capacitor Vdc smoothes the input power and stores it. In the drawing, one device is illustrated as a smoothing capacitor Vdc, but a plurality of devices are provided, and device stability may be ensured. On the other hand, both ends of the smoothing capacitor (Vdc), because the DC power is stored, it may be referred to as a dc terminal or a dc link terminal.

The controller 380 may detect the input current is input from the commercial AC power supply 405 using the shunt resistor installed in the converter 370.

In addition, the controller 380 may detect the phase current of the motor by using the shunt resistor Rin installed in the inverter 350.

[Circuit Board of Control Device of Apparel Processing Apparatus]

Hereinafter, a description will be given of an embodiment of a circuit board of a control device of a clothes processing device in which a control device of a clothes processing device is implemented, and a portion overlapping with the above description is omitted as much as possible, and a specific embodiment of the circuit board will be described below. .

The circuit board (hereinafter, referred to as a circuit board) of the control device of the clothes processing apparatus disclosed herein is a circuit board on which the control device of the clothes processing apparatus as shown in FIG. 3B is implemented. The controller 1600 as described above may be a substrate implemented as a module.

The circuit board is a printed circuit board that removes an unnecessary copper foil according to a circuit diagram of a substrate covered with a copper foil (copper foil) covered with an insulator plate, wherein at least one circuit element is mounted on the substrate to form a module. : PCB).

That is, the circuit board may be a substrate on which a converter is formed of copper foil printed on the circuit board, and the one or more circuit elements are disposed to form a circuit.

Here, the copper foil may be a conductor of a copper (Cu) material, and may be a converter of the circuit board.

As shown in FIGS. 4A and 4B, the circuit board 1610 includes a plurality of heat generating elements 20 and an integrated heat dissipation means 30 disposed on one side of the plurality of circuit elements 10.

The circuit board 1610 as shown in FIG. 4A is a circuit board 1610 in which the control device 1600 of the clothes treating apparatus is implemented as a single module. The circuit board 1610 is shown in FIG. 4B in a combination as shown in FIG. 4A. It may be in the form as shown.

Here, the control device 1600 is a control module for controlling a plurality of motors 360 for driving the clothes processing apparatus 1000, the converter 370 for converting the AC power input from the external power source to the DC power source. And receiving the DC power from the converter 370, converting the DC power into driving power for driving the plurality of motors 360 driving the clothes processing apparatus 1000, and outputting the converted driving power to each of the plurality of motors 360. It may include a plurality of inverters 350.

The control device 1600 also generates a control signal for controlling the operation of the converter 370 and the inverter 350, the control unit 380 for transmitting to each of the converter 370 and the inverter 350. It may further include.

The plurality of heat generating elements 20 in the circuit board 1610 may be disposed on one side of the circuit board 1610 among the plurality of circuit elements 10 that perform a function for driving control of the clothes treating apparatus. It is a heating element.

The plurality of circuit elements 10 may be circuit elements constituting a module to be configured of the circuit board 1610.

For example, it may mean all circuit elements such as resistors, inductors, capacitors, diodes, transistors, switching elements, and integrated circuits (ICs).

That is, the circuit board 1610 may form a module by arranging the plurality of circuit elements 10 on the circuit board 1610 to form a circuit.

In this case, the copper foil printed on the circuit board 1610 may be a converter of the plurality of circuit elements 10 disposed on the circuit board 1610.

The plurality of circuit elements 10 may be disposed on a predetermined position on the circuit board 1610.

The plurality of circuit elements 10 may be circuit elements of the control apparatus 1000 that performs drive control of the clothes treating apparatus, and may be a plurality of circuit elements configuring the control apparatus 1000.

That is, the plurality of circuit elements 10 may be a plurality of types of circuit elements included in the control device 1000.

The plurality of circuit elements 10 may be circuit elements included in the converter 350 and the inverter 370 included in the control device 1600.

The plurality of circuit elements 10 may be distributed on the circuit board 1610.

The plurality of heat generating elements 20 are elements disposed on one side of the plurality of circuit elements 10 that perform a function for driving control of the clothes treating apparatus, and generate heat among the plurality of circuit elements 10. It may be a device made.

The plurality of heat generating elements 20 may be an element having heat resistance less than a predetermined standard among the plurality of circuit elements 10 that perform a function for driving control of the clothes treating apparatus.

The plurality of heating elements 20 may also be an element that generates heat above a predetermined heating reference among the plurality of circuit elements 10 that perform a function for driving control of the clothes treating apparatus.

The constant heating reference may be a reference for heat generated when a current is applied to the device.

According to this, a device in which heat generated when a current is applied among the plurality of circuit elements 10 corresponding to the predetermined heat generation criterion is concentrated on the one side, and the element corresponding to the predetermined heat generation criterion is the The parts may be distributed in portions except one side.

That is, the circuit board 1610 includes a plurality of the plurality of circuit elements 10 distributed on the circuit board 1610 in which heat resistance is less than a predetermined criterion or heat is generated above the predetermined heating standard. The heating element 20 may be concentrated on the one side.

Here, the centrally arranged means that the plurality of heat generating elements 20 of the plurality of circuit elements 10 are dispersed and disposed in a portion corresponding to the one side.

The plurality of heat generating elements 20 may have heat generation less than or equal to a predetermined standard of heat resistance among circuit elements included in the converter 350 and the inverter 370 included in the control device 1600. It may be a device made.

For example, a diode, a transistor, a switching device, or a semiconductor device including the same among the circuit elements included in the converter 350 or the inverter 370 may be weak in heat resistance or generate a large amount of heat when a current is applied. Can be.

The plurality of heat generating elements 20 may include at least one of a rectifier element, a diode, a switching element, and an inverter module included in the inverter 350 included in the converter 370.

That is, at least one of a rectifying element, a diode, a switching element, and an inverter module included in the inverter 350 may be disposed on the one side of the circuit board 1610.

The side surface at which the plurality of heat generating elements 20 are disposed may be an end portion of the circuit board 1610.

The one side may be an end portion of the side surface close to the rear surface of the clothes processing apparatus 1000.

The one side may be a left end of the circuit board 1610 adjacent to the rear surface of the clothes processing apparatus 1000.

That is, the plurality of heat generating elements 20 may be concentrated at the left end of the circuit board 1610.

As such, the plurality of heat generating elements 20 may be disposed on the one side of the circuit board 1610 so that the heat generation of the control device 1600 may be concentrated on the one side.

The plurality of heat generating elements 20 disposed on the one side may be heat radiated through the heat radiating means 30 formed integrally.

That is, heat generated in the plurality of heat generating elements 20 in the circuit board 1610 may be radiated in a batch through the heat radiating means 30.

In the circuit board 1610, the heat dissipation means 30 is an integrated heat dissipation means, which is disposed on the side of the heat dissipation element so as to be adjacent to the plurality of heat dissipation elements 20 to dissipate heat generated by the plurality of heat dissipation elements 20. do.

The heat dissipation means 30 may be made of a metal material having high thermal conductivity, and may be a heat sink that absorbs heat from a circuit element including a semiconductor element and dissipates it to the outside.

As shown in FIG. 5, the heat dissipation means 30 may include a plurality of heat dissipation plates 30 ′ having a structure for dissipating heat to the outside.

Here, the plurality of heat sinks may be a plurality of heat radiation fins formed in a plate shape.

The heat dissipation means 30, the plurality of heat dissipation plate is formed integrally, one may be disposed on the one side.

The heat dissipation means 30 has a structure that dissipates heat to the outside, and may dissipate heat absorbed from the plurality of heat generating elements 20 to the outside.

The heat dissipation means 30 may be disposed on the side surface on which the plurality of heat generating elements 20 are disposed, and absorb heat generated by the plurality of heat generating elements 20 to dissipate to the outside.

The heat dissipation means 30 may be disposed on the one side such that a bottom surface thereof is spaced apart from the surface of the one side by a predetermined distance.

The heat dissipation means 30 may be fixedly coupled to the circuit board 1610 with a lower surface spaced apart from the surface of the one side by a predetermined distance.

That is, the heat dissipation means 30 may be disposed on the one side in a floating form on the circuit board 1610 and fixedly coupled to the circuit board 1610.

In this case, the heat dissipation means 30 may be disposed on the side surface through fixing means (not shown) fixed to the circuit board 1610.

The heat dissipation means 30 may be disposed on an upper surface of at least one heat generating element of the plurality of heat generating elements 20.

The heat dissipation means 30 may be disposed on the one or more heat generating elements so as to overlap one or more heat generating elements disposed on the one side in the one side on which the plurality of heat generating elements 20 are disposed.

The heat dissipation means 30 may be formed in an area including an area in which the plurality of heat generating elements 20 are disposed, in the one side in which the plurality of heat generating elements 20 are disposed.

That is, the heat dissipation means 30 may be formed as an area including the one side surface on which the plurality of heat generating elements 20 are disposed.

The heat dissipation means 30 may be formed in the form of an up and down direction that crosses the opposite side from the tenon of the circuit board 1610.

That is, the heat dissipation means 30 may be formed in the longitudinal direction of the circuit board 1610 and disposed on the one side surface.

The heat dissipation means 30 may be formed in the form of a direction crossing the book.

That is, the heat dissipation means 30 may be formed in the form of a direction coinciding with an end portion of the circuit board 1610 which is a direction crossing the tenon.

The heat dissipation means 30 is preferably formed in a direction coinciding with the end portion, and may be disposed on the left side of the circuit board 1610.

As described above, in the circuit board 1610 in which the control device 1600 is implemented, the plurality of heat generating elements 20 are disposed on one side of the circuit board 1610, and the plurality of heat generating elements 20 are disposed. By disposing the integrated heat dissipation means 30 at a predetermined position, heat generation and heat dissipation may be concentrated at one side of the circuit board 1610.

[Control device of clothing processing device]

Hereinafter, a description will be given of an embodiment of a control apparatus of a clothes processing apparatus, but a portion overlapping with the above description is omitted as much as possible, and a specific embodiment of the clothes processing apparatus control apparatus will be described below.

The control device (hereinafter, referred to as a control device) of the clothes treating apparatus disclosed herein is a control device of the clothes treating apparatus as shown in FIG. 3A, and the controller 1600 as described above in the basic configuration of the clothes treating apparatus. Can be.

The control device 1600 may be formed as a module on one circuit board.

Here, the circuit board may be the circuit board 1610 described above.

That is, the controller 1600 may be provided with a circuit configuration on the circuit board 1610 described above, and may be formed as one module.

A detailed circuit configuration of the control device 1600 formed as one module on the circuit board 1610 may be as shown in FIG. 3B.

As illustrated in FIG. 4A or 4B, the control device 1600 may include a circuit board 1610 of the plurality of circuit elements 10 that performs a function for driving control of the clothes processing apparatus 1000. Integrated heat dissipation means 30 disposed on one side of the plurality of heat generating elements 20 disposed on one side and adjacent to the plurality of heat generating elements 20 to radiate heat generated by the plurality of heat generating elements 20. It includes.

As shown in FIG. 4A or 4B, a specific circuit element of the control device 1600 provided in the circuit board 1610 may be as shown in FIG. 6.

In the control device 1600, the plurality of circuit elements 10 may be distributed and disposed on the circuit board 1610.

In the control apparatus 1600, the plurality of circuit elements 10 may be circuit elements included in the converter 370 and the inverter 350 included in the control apparatus 1600.

The plurality of circuit elements 10 may further include a power supply unit 300 to which power for driving the clothes processing apparatus 1000 is input from the outside, and a controller 380 for controlling the clothes processing apparatus 1000. Can be.

In the control device 1600, the plurality of heat generating elements 20 may be concentrated on one side of the circuit board 1610.

In the control device 1600, the plurality of heat generating elements 20 may generate heat above a predetermined heat generation reference among the plurality of circuit elements 10, or the heat resistance among the plurality of circuit elements 10 may be determined based on a predetermined standard. It may be less than device.

The plurality of heat generating elements 20 may be heat generated above the heat generation reference among the elements included in the converter 370 and the inverter 350, or may be elements having the heat resistance less than the predetermined reference.

The plurality of heat generating elements 20 may include one of the rectifying means 371, the diode 373D, the switching element 373I, and the inverter module 353 included in the inverter 350. It may contain the above.

That is, at least one of the rectifying means 371, the diode 373D and the switching element 373I among the elements included in the converter 370, and the inverter module 353 among the elements included in the inverter 350. Is disposed on the one side, and the converter element 370 'of the converter 370 except for the element disposed on the one side and the inverter element 370' of the inverter 350 are located at a portion except the one side. Can be arranged.

Here, the inverter module 353 may be an inverter module for supplying driving power to a motor for driving the compressor of the heat pump included in the clothes treating apparatus 1000.

As described above, the control device 1600 includes the rectifying means 371, the diode 373D, the switching element 373I, and the inverter module 353 disposed at one side thereof, and the rectifying means 371 and the diode 373D. ), The heat dissipation means 30 is disposed on the one side on which the switching element 373I and the inverter module 353 are disposed, so that the rectifying means 371, the diode 373D, the switching element 373I, and the inverter module are disposed. Heat generation and heat radiation of the 353 may be concentrated in one aspect.

In this way, the control device 1600 provided on the circuit board 1610 is disposed on one side of the heat dissipation means 30, and the heat radiated by the heat dissipation means 30 is opposite to the one side. It may further include a heat dissipation fan 40 for blowing to.

The heat dissipation fan 40 may be disposed on the same axis as the side surface on which the plurality of heat generating elements 20 and the heat dissipation means 30 are disposed.

The heat dissipation fan 40 may be a box-type heat dissipation fan that blows wind in a direction in which the fan is directed through the rotation of the fan.

The heat dissipation fan 40 may be disposed on one side of the heat dissipation fan to blow heat radiated between the plurality of heat dissipation plates forming the heat dissipation means 30 in a direction opposite to the one side.

The heat dissipation fan 40 is preferably formed at the same height as the heat dissipation means 30, and may blow heat radiated from the heat dissipation means 30 at the same height as the heat dissipation means 30.

As such, heat radiated from the heat radiating means 30 may be blown through the heat radiating fan 40, and heat radiating and cooling of the heat radiating means 30 may be performed.

That is, heat generated by the plurality of heat generating elements 20 is radiated through the heat radiating means 30, and heat radiated by the radiating means 30 may be blown through the radiating fan 40. do.

The heat dissipation fan 40 may be disposed at a position corresponding to an upper direction of the control device 1600 to blow heat radiated from the heat dissipation means 30 toward the lower direction of the control device 1600. .

That is, the heat dissipation fan 40 is disposed above the circuit board 1610 of the left side of the circuit board 1610 on which the heat dissipation means 30 is disposed, and is radiated by the heat dissipation means 30. Heat may be blown in a vertical direction of the heat dissipation means 30, that is, in a lower left direction of the circuit board 1610.

In this way, the control device 1600 includes the heat dissipation fan 40 on the upper left side of the circuit board 1610, thereby dissipating heat radiated from the heat dissipation means 30 to the lower left of the circuit board 1610. And the plurality of heat generating elements 20 are concentrated on one side to increase heat dissipation and cooling effect of the distribution controller 1600 in which heat dissipation is concentrated through the heat dissipation means 30. Can be.

The control device 1600 may be attached to the upper portion of the clothes processing apparatus 1000 in a form perpendicular to the bottom of the clothes processing apparatus 1000.

For example, as shown in FIG. 1 or FIG. 7, the heat dissipation means 30 is attached to an upper portion of the inside of the clothes processing apparatus 1000 so as to be perpendicular to a bottom surface of the clothes processing apparatus 1000. ), That is, the heat dissipation direction may be directed toward the bottom surface of the clothes treating apparatus 1000.

The control device 1600 may be attached to an upper portion of the clothes processing apparatus 1000 and may be provided at a position higher than a central portion of the drum 1030 included in the clothes processing apparatus 1000.

That is, the control device 1600 may be provided at a position higher than the height center of the clothes processing apparatus 1000.

The control device 1600 may be provided on the upper right side of the inside of the clothes processing apparatus 1000, as shown in FIG. 1 or 7.

As such, the control device 1600 is attached to the upper side of the side of the inside of the clothes processing apparatus 1000 so that the heat dissipation direction of the heat dissipation means 30 is directed toward the bottom of the clothes processing apparatus 1000. Heat radiated from the 30 may be radiated to the lower direction of the clothes treating apparatus 1000.

This is because heat is radiated from the heat dissipation means 30 toward the lower direction of the clothes processing apparatus 1000 in which an empty space is formed in the inside of the clothes processing apparatus 1000, that is, the air flow may be actively radiated. In such a structure, the circulation of heat radiated from the heat radiating means 30 may be efficiently performed to increase the cooling effect on the heat radiating means 30.

As illustrated in FIG. 7, the control device 1600 may be provided on the upper side of the rear side of the right side of the clothes processing apparatus 1000.

On the upper right side of the rear of the garment processing apparatus 1000 adjacent to the rear right side of the right side where the control apparatus 1600 is provided, exhaust means 1620 for blowing air in the garment processing apparatus 1000 to the outside is provided. It may be provided.

The exhaust means 1620 provided at the upper right side of the rear surface may blow air into the clothes processing apparatus 1000 from the upper right side of the rear of the clothes processing apparatus 1000 to the outside through an exhaust port or an exhaust fan. .

That is, the control device 1600 may be provided at an upper portion of the rear side of the right side adjacent to the upper right side of the rear surface provided with the exhaust means 1620, and may be adjacent to the exhaust means 1620.

The control device 1600 may be provided at a position within a predetermined interval from the exhaust means 1620.

The control device 1600 may be provided at the same height as the exhaust means 1620 at a position within a predetermined distance from the exhaust means 1620.

That is, the control device 1600 is provided at the same height at a position within a predetermined interval with the exhaust means 1620 on the rear right side of the garment processing apparatus 1000 so as to be adjacent to the exhaust means 1620. Can be.

As such, the control device 1600 is provided at the upper rear side of the right side such that the control device 1600 is adjacent to the exhaust fan 1620, so that the heat generated from the heat dissipation means 30 is transferred to the clothes processing apparatus 1000 through the exhaust means 1620. Can be exhausted to the outside.

That is, the control device 1600 is provided at the upper rear side of the right side to be adjacent to the exhaust means 1620, whereby the heat dissipation means 30 is subjected to the exhaust influence by the exhaust means 1620, and thus the heat dissipation. Cooling to the means 30 may be effected.

As described above, the control apparatus 1600 includes the blower fan 40 blowing the heat dissipation means 30 in a vertical direction of the heat dissipation means 30, and the exhaust means 1620 is the heat dissipation means. The heat dissipation means 30 is blown in the horizontal direction of the 30, so that the heat dissipation and cooling of the heat dissipation means 30 can be effectively performed in the vertical and horizontal directions.

[Clothing processing device]

Hereinafter, an embodiment of the clothes treating apparatus will be described, but a portion overlapping with the above description will be omitted as much as possible, and a specific embodiment of the clothes treating apparatus will be described.

The clothes treating apparatus disclosed herein is a clothes treating apparatus as shown in FIG. 3A, which may be as described in the basic configuration of the clothes treating apparatus.

As shown in FIG. 3A, the clothes treating apparatus 1000 may include a drum 301 for receiving a drying object to perform a drying operation, and a blowing fan for promoting the flow of air inside the clothes treating apparatus 1000. 302, a plurality of heat pumps 303 for removing moisture in the air drawn from the drum 301 and exchanging heat, driving the drum 301, the blowing fan 302, and the heat pump 303, respectively. A control provided on the motor 360 and the circuit board 1610 as shown in FIG. 4A or 4B to control the driving of the plurality of motors 360 to control the operation of the clothes processing apparatus 1000. Device 1600.

In the clothing processing apparatus 1000, the control device 1600 is a control module having a circuit configuration as shown in FIG. 3B, and converts AC power input from an external power source into DC power as shown in FIG. A plurality of inverters receiving the DC power from the converter 370 and the converter 370, converting the DC power into driving power for driving the plurality of motors 360, and outputting the converted power to each of the plurality of motors 360 ( An integrated heat dissipation device including a heat dissipation device (350) and a position adjacent to the plurality of heat generating elements (20) included in the converter (370) and the inverter (350) and dissipating heat generated by the plurality of heat generating elements (20). Means 30.

The plurality of heat generating elements 20 and the heat dissipation means 30 may be disposed on one side of the circuit board 1610, and the one side may be a left end of the circuit board 1610.

That is, the plurality of heat generating elements 20 and the heat dissipation means 30 included in the control device 1600 may be concentrated at the left end of the circuit board 1610 in the clothes processing apparatus 1000. have.

As described above, the garment processing apparatus 1000 may include the control apparatus 1600 formed as a module on one circuit board 1610.

Here, the circuit board 1610 may be the circuit board 1610 described above, and the control device 1600 may be the control device 1600 described above.

That is, the clothing processing apparatus 1000 may include the control apparatus 1600 formed as one module on the circuit board 1610 described above.

In the clothing processing apparatus 1000, the control device 1600 may be arranged by distributing a plurality of circuit elements 10 on the circuit board 1610.

The plurality of circuit elements 10 may be circuit elements included in the converter 370 and the inverter 350 included in the control device 1600.

The plurality of circuit elements 10 may further include a power supply unit 300 to which power for driving the clothes processing apparatus 1000 is input from the outside, and a controller 380 for controlling the clothes processing apparatus 1000. Can be.

The plurality of heating elements 20 may be an element that generates heat above a predetermined heating reference among the elements included in the converter 370 and the inverter 350 among the plurality of circuit elements 10.

The plurality of heat generating elements 20 may also be elements having heat resistance less than a predetermined standard included in the converter 370 and the inverter 350.

The plurality of heat generating elements 20 may be disposed to be concentrated on the one side of the circuit board 1610.

The plurality of heat generating elements 20 may include one of the rectifying means 371, the diode 373D, the switching element 373I, and the inverter module 353 included in the inverter 350. It may contain the above.

That is, at least one of the rectifying means 371, the diode 373D and the switching element 373I among the elements included in the converter 370, and the inverter module 353 among the elements included in the inverter 350. Is disposed on the one side, and the converter element 370 'of the converter 370 except for the element disposed on the one side and the inverter element 370' of the inverter 350 are located at a portion except the one side. Can be arranged.

Here, the inverter module 353 may include an IPM (inverter 353) which supplies driving power to a motor 363 that drives the compressor of the heat pump 303 among the plurality of motors 360. Intelligent Power Module).

As described above, the garment processing apparatus 1000 includes the rectifying means 371, the diode 373D, the switching element 373I, and the inverter module 353 in the circuit board 1610 on which the control apparatus 1600 is formed. The heat dissipation means 30 is disposed on the one side, and the heat dissipation means 30 is disposed on the one side of the rectifying means 371, the diode 373D, the switching element 373I, and the inverter module 353. The heat generation and heat dissipation of the 371, the diode 373D, the switching element 373I, and the inverter module 353 may be concentrated in one aspect.

In the clothes treating apparatus 1000, the heat dissipation means 30 is an integrated heat dissipation means, which is disposed on the side surface so as to be adjacent to the plurality of heat generating elements 20, and generates heat generated by the plurality of heat generating elements 20. Heat dissipation

As shown in FIG. 5, the heat dissipation means 30 may include a plurality of heat dissipation plates 30 ′ having a structure for dissipating heat to the outside, or may have a plate shape.

The heat dissipation means 30 may be disposed on the side surface on which the plurality of heat generating elements 20 are disposed, and absorb heat generated by the plurality of heat generating elements 20 to dissipate to the outside.

The heat dissipation means 30 may be disposed on the one side such that a bottom surface thereof is spaced apart from the surface of the one side by a predetermined distance.

The heat dissipation means 30 may be disposed on an upper surface of at least one heat generating element of the plurality of heat generating elements 20.

The heat dissipation means 30 may be formed in an area including an area in which the plurality of heat generating elements 20 are disposed, in the one side in which the plurality of heat generating elements 20 are disposed.

The heat dissipation means 30 may be formed in a longitudinal direction of the circuit board 1610.

That is, the heat dissipation means 30 may be formed in a vertical direction crossing the opposite side from the tenon of the circuit board 1610 and disposed on the one side.

The heat dissipation means 30 may be formed in the form of a direction coinciding with an end portion of the circuit board 1610 which is a direction crossing the tenon.

That is, the heat dissipation means 30 may be formed in the form of a direction intersecting the tenon and disposed on the one side surface.

The clothes treating apparatus 1000 as described above is disposed on one side of the heat dissipation means 30, and includes a heat dissipation fan 40 for blowing heat radiated from the heat dissipation means 30 in a direction opposite to the one side. It may further include.

The heat dissipation fan 40 may be disposed on the same axis as the side surface on which the plurality of heat generating elements 20 and the heat dissipation means 30 are disposed.

The heat dissipation fan 40 may be disposed on one side of the heat dissipation fan to blow heat radiated between the plurality of heat dissipation plates forming the heat dissipation means 30 in a direction opposite to the one side.

The heat dissipation fan 40 is preferably formed at the same height as the heat dissipation means 30, and may blow heat radiated from the heat dissipation means 30 at the same height as the heat dissipation means 30.

As such, heat radiated from the heat radiating means 30 may be blown through the heat radiating fan 40, and heat radiating and cooling of the heat radiating means 30 may be performed.

That is, heat generated by the plurality of heat generating elements 20 is radiated through the heat radiating means 30, and heat radiated by the radiating means 30 may be blown through the radiating fan 40. do.

The heat dissipation fan 40 may be disposed at a position corresponding to an upper direction of the control device 1600 to blow heat radiated from the heat dissipation means 30 toward the lower direction of the clothes treating apparatus 1000. have.

That is, the heat dissipation fan 40 is disposed above the circuit board 1610 of the left side of the circuit board 1610 on which the heat dissipation means 30 is disposed, and is radiated by the heat dissipation means 30. Heat may be blown in a vertical direction of the heat dissipation means 30, that is, in a lower left direction of the circuit board 1610.

In this way, the control device 1600 includes the heat dissipation fan 40 on the upper left side of the circuit board 1610, thereby dissipating heat radiated from the heat dissipation means 30 to the lower left of the circuit board 1610. The heat dissipation and cooling effect of the control apparatus 1600 to increase the heat dissipation through the heat dissipation means 30 is concentrated by the plurality of heat generating elements 20. Can be.

The control device 1600 may be attached to the upper portion of the clothes processing apparatus 1000 in a form perpendicular to the bottom of the clothes processing apparatus 1000.

For example, as shown in FIG. 1 or FIG. 7, the heat dissipation means 30 is attached to an upper portion of the inside of the clothes processing apparatus 1000 so as to be perpendicular to a bottom surface of the clothes processing apparatus 1000. ), That is, the heat dissipation direction may be directed toward the bottom surface of the clothes treating apparatus 1000.

The control device 1600 may be attached to an upper portion of the clothes processing apparatus 1000 and may be provided at a position higher than a central portion of the drum 1030 included in the clothes processing apparatus 1000.

As illustrated in FIG. 7, the control device 1600 may be provided on the upper side of the rear side of the right side of the clothes processing apparatus 1000.

On the upper right side of the rear of the garment processing apparatus 1000 adjacent to the rear right side of the right side where the control apparatus 1600 is provided, exhaust means 1620 for blowing air in the garment processing apparatus 1000 to the outside is provided. It may be provided.

The exhaust means 1620 provided at the upper right side of the rear surface may blow air into the clothes processing apparatus 1000 from the upper right side of the rear of the clothes processing apparatus 1000 to the outside through an exhaust port or an exhaust fan. .

That is, the control device 1600 may be provided at an upper portion of the rear side of the right side adjacent to the upper right side of the rear surface provided with the exhaust means 1620, and may be adjacent to the exhaust means 1620.

The control device 1600 may be provided at a position within a predetermined interval from the exhaust means 1620.

The control device 1600 may be provided at the same height as the exhaust means 1620 at a position within a predetermined distance from the exhaust means 1620.

As such, the control device 1600 is provided at the upper rear side of the right side such that the control device 1600 is adjacent to the exhaust fan 1620, so that the heat generated from the heat dissipation means 30 is transferred to the clothes processing apparatus 1000 through the exhaust means 1620. Can be exhausted to the outside.

That is, the control device 1600 is provided at the upper rear side of the right side to be adjacent to the exhaust means 1620, whereby the heat dissipation means 30 is subjected to the exhaust influence by the exhaust means 1620, and thus the heat dissipation. Cooling to the means 30 may be effected.

As described above, the clothes treating apparatus 1000 includes the blowing fan 40 blowing the heat radiating means 30 in a vertical direction of the heat radiating means 30, and the exhaust means 1620 radiating the heat. The heat dissipation means 30 is blown in the horizontal direction of the means 30, so that the heat dissipation and cooling of the control device 1600 may be effectively performed in the vertical and horizontal directions.

Embodiments of the circuit board of the control apparatus of the clothes processing apparatus, the control apparatus of the clothes processing apparatus, and the clothes processing apparatus as described above may be performed separately and separately, or may be implemented in a combination of two or more. May be

Embodiments of the circuit board of the control apparatus of the clothes processing apparatus, the control apparatus of the clothes processing apparatus, and the clothes processing apparatus as described above may be implemented as a part or a combination of configurations or steps included in each embodiment, or a combination of the embodiments. It can be implemented as.

As described above, embodiments of the circuit board of the control apparatus of the clothes processing apparatus, the control apparatus of the clothes processing apparatus, and the clothes processing apparatus include a circuit structure of a control apparatus, a control module, a control means, and a control circuit that controls the clothes processing apparatus; It can be applied to the internal structure of the clothes processing apparatus.

As described above, embodiments of the circuit board of the control apparatus of the clothes processing apparatus, the control apparatus of the clothes processing apparatus, and the clothes processing apparatus include a circuit including a converter and a plurality of inverters to control the clothes processing apparatus. It can be usefully applied to the heat dissipation structure of the substrate, the heat dissipation structure of the control device of the clothes processing apparatus and the heat dissipation structure of the clothing processing apparatus.

Embodiments of the circuit board of the control apparatus of the clothes processing apparatus, the control apparatus of the clothes processing apparatus, and the clothes processing apparatus as described above may be applied to all circuit structures and structures of the control apparatus to which the technical spirit of the above technology can be applied. have.

Although specific embodiments of the present invention have been described so far, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited to the above-described embodiments, which can be modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, all equivalent or equivalent modifications thereof will fall within the scope of the present invention.

[Circuit Board Configuration of Control Device of Apparel Processing Equipment]
10: circuit element 20: heating element
30: heat dissipation means 40: heat dissipation fan
1600: controller (control unit) 1610: circuit board
1620: exhaust means
[Control Configuration of Apparel Processing Unit]
301: drum 302: blowing fan
303: heat pump 310: input unit
320: output unit 330: communication unit
340: detection unit
350 (351 to 353): inverter (first to third inverter)
360 361 to 363: motor (first to third motor)
370: converter 371: rectification means 372: DC link capacitor
380: control unit 391: valve unit
392: pump section 393: auxiliary heater section
1600: control unit (control unit)
[Basic Configuration of Apparel Processing Unit]
1000: clothing processing unit 1010: cabinet (cabinet)
1011: front opening 1020: door
1021: hinge 1030: drum {or tub}
1040: front supporter
1050: rear supporter
1060: roller
1100: heat pump cycle devices
1110: evaporator 1120: compressor
1130: condenser 1140: gas-liquid separator
1210: inlet duct 1220: outlet duct
1230 connection duct
1310: base
1311: Inlet part of the connecting duct 1312: Outlet part of the connecting duct
1313: mounting portion 1320: base cover
1321: front base cover 1322: rear base cover
1410: bucket 1420: bucket cover
1430: bucket support frame
1440: water pump 1500: input and output panel
1510: input unit 1520: output unit
1600: control unit (control unit) 1710: circulation fan
1720: compressor cooling fan 1800: motor
1810: pulley 1820: blower fan

Claims (20)

In the circuit board in which the control device of the clothing processing apparatus is implemented
A plurality of heat generating elements disposed on one side of the circuit board among a plurality of circuit elements which perform a function for driving control of the clothes treating apparatus; And
And integrated heat dissipation means disposed on the side of the heat dissipation element so as to be adjacent to the plurality of heat dissipation elements, and configured to dissipate heat generated by the plurality of heat dissipation elements. The method of claim 1,
The plurality of heat generating elements,
A circuit board, wherein the device generates heat above a predetermined heat generation standard. The method of claim 1,
The one side,
A circuit board, characterized in that the end of the circuit board. The method of claim 1,
The heat dissipation means,
A circuit board, characterized in that disposed on the upper surface of the at least one heating element of the plurality of heating elements The method of claim 1,
The heat dissipation means,
Circuit board, characterized in that formed in the form of the vertical direction across the opposite side from the tenon of the circuit board. In the control apparatus of the clothes processing apparatus provided on a circuit board,
A plurality of heat generating elements disposed on one side of the circuit board among a plurality of circuit elements which perform a function for driving control of the clothes treating apparatus; And
And integrated heat dissipation means disposed on the side surface to be adjacent to the plurality of heat generating elements to dissipate heat generated by the plurality of heat generating elements. The method of claim 6,
The plurality of circuit elements,
And a circuit element included in the converter and the inverter included in the control device. The method of claim 7, wherein
The plurality of heat generating elements,
And at least one of a rectifier element, a diode, a switching element, and an inverter module included in the inverter. The method of claim 7, wherein
And a heat dissipation fan disposed on one side of the heat dissipation means and configured to blow heat radiated from the heat dissipation means in a direction opposite to the one side. The method of claim 9,
The heat dissipation fan,
The control apparatus of the clothes processing apparatus arrange | positioned at the position corresponding to the upper direction of the said control apparatus, and blows the heat radiated | emitted by the said heat radiating means to the lower direction of the said control apparatus. The method of claim 7, wherein
The control apparatus of the clothes processing apparatus, characterized in that attached to the upper portion of the clothes processing apparatus in a form perpendicular to the bottom of the clothes processing apparatus. The method of claim 7, wherein
The control apparatus of the clothes processing apparatus, characterized in that provided at a position higher than the center of the drum included in the clothes processing apparatus. The method of claim 7, wherein
The control apparatus of the clothes processing apparatus, characterized in that provided on the upper rear side of the right side of the clothes processing apparatus. The method of claim 7, wherein
The control apparatus of the clothes processing apparatus, characterized in that provided in a position within a predetermined interval with the exhaust means included in the clothes processing apparatus. In the clothes processing apparatus,
A drum for receiving a drying object to perform a drying operation;
A blowing fan for promoting the flow of air inside the clothes treating apparatus;
A heat pump which removes moisture from the air drawn from the drum and exchanges heat;
A plurality of motors driving each of the drum, the blowing fan, and the heat pump; And
And a control device provided on a circuit board to control driving of the plurality of motors to control an operation of the clothes treating apparatus.
The control device,
A converter for converting AC power input from an external power source into DC power;
A plurality of inverters receiving the DC power from the converter, converting the DC power into driving power for driving the plurality of motors, and outputting the converted power to each of the plurality of motors; And
And integrated heat dissipation means provided at a position adjacent to the plurality of heat generating elements included in the converter and the inverter to dissipate heat generated by the plurality of heat generating elements.
The plurality of heat generating elements and the heat dissipation means,
Apparel processing apparatus, characterized in that disposed on one side of the circuit board. The method of claim 15,
The plurality of heat generating elements,
Clothing processing apparatus comprising at least one of a rectifying element, a diode, a switching element and an inverter module included in the inverter included in the converter. The method of claim 15,
The control device,
And a heat dissipation fan disposed on one side of the heat dissipation means and configured to blow heat radiated from the heat dissipation means in a direction opposite to the one side. The method of claim 17,
The heat dissipation fan,
It is disposed at a position corresponding to the upper direction of the control device, clothes processing apparatus characterized in that for blowing the heat radiated by the heat radiating means to the lower direction of the control device. The method of claim 15,
The control device,
Clothing processing apparatus, characterized in that provided on the upper right side rear side of the clothes processing apparatus. The method of claim 15,
The control device,
Clothing processing apparatus characterized in that it is provided at a position within a predetermined interval with the exhaust means included in the clothes processing apparatus.

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