KR20140043292A - Cooling device and air conditioner with same - Google Patents

Abstract

A cooling unit for cooling the air in the control box by heat exchange with the refrigerant, a fan for stirring the air in the control box, a temperature detecting means in the control box for detecting the temperature in the control box, and a drive of the compressor for circulating the coolant And a frequency control means for controlling the frequency, and by configuring the cooling device such that the frequency control means lowers the frequency when the temperature detection means in the control box detects a temperature higher than or equal to a predetermined temperature, for example, the cooling unit cannot sufficiently cool the control component. Even in this case, the drive frequency of the compressor can be lowered below a predetermined value so that the control component does not become a temperature higher than the predetermined temperature so as not to damage the control component, thereby ensuring higher reliability.

Description

COOLING DEVICE AND AIR CONDITIONER WITH SAME

TECHNICAL FIELD This invention relates to the cooling apparatus which cools the control component of an air conditioner, and the air conditioner provided with the same.

Background Art Conventionally, in an air conditioner having a compressor, an outdoor heat exchanger, a pressure reducing device, an indoor heat exchanger, and a pipe connected with a refrigerant flowing therein, a control component such as a control board is used to protect, for example, from dust and water. It is housed in a control box. At that time, it is necessary to consider cooling of the control component to ensure that the control component operates stably. When cooling the control component in such a manner, there is a problem that condensation occurs when the control component is too cold. Then, the air conditioner which detects the temperature in a control box and the temperature of a control component, and determines whether to drive or stop a cooling apparatus is proposed (for example, refer patent document 1).

FIG. 6: shows the air conditioner provided with the conventional cooling apparatus of patent document 1. As shown in FIG. As shown in FIG. 6, the air conditioner includes a refrigeration cycle composed of an electrical appliance box 2 containing a heating element 1, a compressor 3, a condenser 4, an expansion valve 5, and an evaporator 6. 7) and a cooling mechanism 8 for cooling the heat generator 1 via the radiator 12 with the low temperature refrigerant in the refrigerating cycle 7. In addition, the air conditioner includes a heating element temperature detection unit 9 that detects the temperature of the heating element 1, an air temperature detection unit 10 that detects the temperature in the electrical appliance box 2, and a heating element detected by the heating element temperature detection unit 9. The temperature is compared with the air temperature in the electrical appliance box detected by the air temperature detection unit 10, and when the heating element temperature reaches the upper limit of the predetermined temperature width region above the air temperature in the electrical appliance box, the cooling mechanism 8 is operated, and The control apparatus 11 which stops the cooling mechanism 8 when it reaches the minimum of the temperature width | variety area | region of this is provided.

(Prior art document)

(Patent Literature)

Patent Document 1: Japanese Patent Laid-Open No. 5-187725

However, in the case of the air conditioner described in Patent Document 1, when the cooling device (cooling mechanism) cannot sufficiently cool the control component (heating element), the temperature of the control component becomes a predetermined temperature or more, which may damage the control component. I have a problem that there is.

An object of this invention is to provide the cooling apparatus which does not damage a control component, even if a cooling apparatus cannot fully cool a control component by solving the said conventional subject.

In order to achieve the above object, the present invention is configured as follows.

According to the first aspect of the present invention, there is provided a cooling unit that is disposed in a control box in a state separated from the control component, and cools the air in the control box by heat exchange with a refrigerant, a fan that stirs the air in the control box; And a temperature detecting means in a control box for detecting a temperature in the control box, and a frequency controlling means for controlling a driving frequency of a compressor circulating the refrigerant, wherein the temperature detecting means in the control box detects a predetermined temperature or more. The frequency control means provides a cooling device for lowering the frequency.

According to the second aspect of the present invention, there is provided a cooling unit which is disposed in a control box in a state separated from the control component, and cools the air in the control box by heat exchange with a refrigerant, a fan that stirs the air in the control box; Temperature detecting means in a control box for detecting a temperature in the control box, and current control means for controlling a current flowing in a compressor circulating the refrigerant, and when the temperature detecting means in the control box detects a predetermined temperature or more, The current control means provides a cooling device for lowering the current value.

According to the cooling device of the present invention, even if the cooling device cannot sufficiently cool the control parts, the cooling device and the air conditioner having high reliability can be protected by preventing the control parts from reaching a temperature higher than a predetermined temperature. Can be realized.

1 is a schematic configuration diagram of a cooling device and an air conditioner using the same according to Embodiment 1 of the present invention;
2 is a schematic configuration diagram showing the inside of a control box shown in FIG. 1;
3 is a perspective view of the cooling unit shown in FIG. 1;
4 is a schematic configuration diagram of a cooling device and an air conditioner using the same according to Embodiment 2 of the present invention;
5 is a schematic configuration diagram of a cooling device and an air conditioner using the same according to Embodiment 3 of the present invention;
6 is a schematic configuration diagram of a conventional cooling device and an air conditioner using the same;
7 is a schematic configuration diagram of a cooling device and an air conditioner according to Embodiment 4 of the present invention;
8 is a schematic configuration diagram of a cooling device and an air conditioner according to Embodiment 5 of the present invention;
9 is a schematic configuration diagram showing an interior of a control box of an air conditioner according to Embodiment 6 of the present invention;
10 is a schematic configuration diagram showing an interior of a control box of a control box of an air conditioner according to a modification of Embodiment 6;
11 is a schematic perspective view and a partially enlarged view of an air conditioner according to Embodiment 6;
12 is a schematic configuration diagram showing an interior of a control box of an air conditioner according to Embodiment 7 of the present invention;
13 is a schematic perspective view of an air conditioner according to a seventh embodiment;
14 (a) is a block diagram of an air conditioner according to Embodiment 8 of the present invention;
14 (b) is a refrigerant flow chart of the air conditioner according to the eighth embodiment;
15 is a schematic diagram of a detached state of a control box according to the eighth embodiment;
16 is a schematic diagram of an installation state of a control box according to the eighth embodiment;
17 (a) is a schematic diagram of a control box according to Embodiment 9 of the present invention;
FIG. 17B is a cross-sectional view taken along line BB ′ of the control box of FIG. 17A. FIG.

The cooling apparatus of 1st invention is arrange | positioned apart from a control component in a control box, The cooling unit which cools the air in the said control box by heat exchange with a refrigerant | coolant, The fan which stirs the air in the said control box, The said Temperature detecting means in a control box for detecting a temperature in the control box, and frequency control means for controlling a driving frequency of a compressor for circulating the refrigerant, wherein the frequency is detected when the temperature detecting means in the control box detects a predetermined temperature or more. The control means is configured to lower the frequency. Thus, for example, even when the cooling unit cannot sufficiently cool the control component, the drive frequency of the compressor can be lowered below a predetermined value, so that the control component is not brought to a temperature higher than or equal to the predetermined temperature so as not to damage the control component, resulting in higher reliability. Can be secured.

In the cooling device of 1st invention, 2nd invention is further provided with the fan rotation speed detection means which detects the rotation speed of the said fan, and when the said fan rotation speed detection means detects below predetermined rotation speed, it controls the said frequency control. The means is to lower the frequency. As a result, even when the rotation speed of the fan decreases for some reason and the control part cannot be sufficiently cooled, the driving frequency of the compressor can be lowered to a predetermined value or less, so that the control part does not become a temperature higher than or equal to a predetermined temperature so as not to damage the control part. Therefore, higher reliability can be ensured.

The cooling apparatus of 3rd invention is arrange | positioned apart from a control component in a control box, The cooling unit which cools the air in the said control box by heat exchange with a refrigerant | coolant, The fan which stirs the air in the said control box, The said Temperature detection means in a control box for detecting a temperature in the control box, and current control means for controlling a current flowing in a compressor circulating the refrigerant, wherein the current is detected when the temperature detection means in the control box detects a predetermined temperature or more. The control means is configured to lower the current value. Thus, for example, even when the cooling unit cannot sufficiently cool the control component, the current value flowing through the compressor can be lowered to prevent the control component from reaching a temperature higher than a predetermined temperature so as not to damage the control component, thereby ensuring higher reliability. Can be.

The fourth invention is the cooling device of the third invention, further comprising fan rotation speed detecting means for detecting the rotation speed of the fan, wherein the current control when the fan rotation speed detection means detects a predetermined rotation speed or less. The means is to lower the current value. As a result, even if the rotation speed of the fan decreases for some reason and the control parts cannot be sufficiently cooled, the current flowing through the compressor can be lowered below a predetermined value so that the control parts are not brought to a temperature higher than or equal to a predetermined temperature so as not to damage the control parts. Therefore, higher reliability can be ensured.

5th invention is a cooling device of the 1st-4th invention WHEREIN: The fan drive control means which controls the drive of the said fan, The said fan drive control means, The temperature detection means in the said control box has the temperature below predetermined value. When the fan is detected, the fan is stopped, and when the fan detects a predetermined temperature or more, the fan is driven. Since cooling of a control component is attained by preventing condensation of a control component by this, since it has high reliability and can be implement | achieved by the temperature detection means of one temperature detection means in a control box, it is inexpensive.

In the sixth invention, in the cooling devices of the first to fourth inventions, a fan drive control means for controlling the drive of the fan, a frequency detection means for detecting a frequency of a compressor for compressing the refrigerant, or a predetermined frequency is set. And a frequency setting means, wherein the fan drive control means stops the fan when the frequency detecting means detects a frequency lower than or equal to a predetermined frequency or when the frequency setting means outputs a frequency lower than or equal to a predetermined frequency. When the frequency is detected or a predetermined frequency or more is output, the fan is driven. This makes it possible to cool the control part while preventing condensation on the control part, and therefore it is more inexpensive because it can be realized without high temperature detection means.

7th invention is a cooling device of 1st-4th invention WHEREIN: The fan drive control means which controls the drive of the said fan, and the electric current value detection means which detects the electric current value which flows through the compressor which compresses the said refrigerant | coolant, or predetermined electric current value. And a current value setting means for setting, wherein the fan drive control means stops the fan when the current value detecting means detects a predetermined value or less, or when the current value setting means outputs a predetermined value or less. When the above value is detected or a predetermined value or more is output, the fan is driven. This makes it possible to cool the control part while preventing condensation on the control part, and therefore it is more inexpensive because it can be realized without high temperature detection means.

8th invention is a cooling device of 1st-4th invention WHEREIN: The fan drive control means which controls drive of the said fan, and the outside air temperature detection means which detects outside air temperature, The said fan drive control means is the said, When the outside temperature detection means detects a temperature below a predetermined value, the fan is stopped, and when the temperature above a predetermined temperature is detected, the fan is driven. Since cooling of a control component is attained by preventing condensation of a control component by this, since it has high reliability and can be implement | achieved by the temperature detection means of one outdoor temperature detection means, it is inexpensive.

A ninth invention is the cooling device of the first to eighth inventions, wherein the cooling unit includes a fin structure having a plurality of fins, and a refrigerant pipe mounted on a side opposite to the fin of the fin structure. The fin and the groove for mounting the refrigerant pipe are formed in the same direction. Thereby, the fin structure can be produced at low cost by drawing molding or extrusion molding.

10th invention is the cooling apparatus of 9th invention WHEREIN: The said cooling unit is arrange | positioned under the said control component, and arrange | positions the drip tray below the said cooling unit. Thereby, even if dew condensation water generate | occur | produces, for example, it can prevent that a control component gets wet by this condensation water.

The eleventh invention is the cooling device of the ninth invention, wherein the cooling unit includes a separate fin structure having a plurality of fins directly mounted to a control board that is part of the control component, wherein the fin of the separate fin structure Is exposed to the outside of the control box incorporating the cooling unit. Thereby, it can cool effectively by providing a fin structure in the heat generating element installation part which heats especially high heat on a control board.

12th invention is a cooling apparatus of 9th invention WHEREIN: The said fan which stirs the air in the said control box is arrange | positioned so that it may be blown toward the said fin structure of the said cooling unit. As a result, the air cooled by the cooling unit diffuses to the whole of the control box, thereby improving the cooling effect, accelerating the flow of air around the cooling unit, making condensation water less likely to occur on the surface of the cooling unit, and condensation water is generated. Can be effectively prevented.

A thirteenth invention is an air conditioner having said compressor, an outdoor heat exchanger, a decompression device, an indoor heat exchanger, and a pipe through which a refrigerant flows by connecting them, said control component housed in said control box of said air conditioner. As a cooling apparatus which cools, it is an air conditioner using the cooling apparatus of 1st-12th invention. Thereby, the air conditioner which can cool a control component and has high reliability can be realized, while preventing condensation with a cheap structure.

14th invention is a refrigerant | coolant of the said refrigeration unit which cools the air in the said control box in the said cooling apparatus in the air conditioner of 13th invention, The refrigerant | coolant which flows through the piping between the said decompression device and the said indoor heat exchanger. I am doing it. Thereby, condensation prevention and cooling of a control part are attained, suppressing the fall of the cooling capability of an air conditioner.

15th invention is the air conditioner of 13th invention WHEREIN: The refrigerant | coolant of the said cooling unit which cools the air in the said control box in the said cooling apparatus is the said compressor, the said outdoor heat exchanger, the said decompression device, The refrigerant is classified from a part of the refrigeration cycle composed of the indoor heat exchanger. Thereby, condensation prevention and cooling of a control part are attained, suppressing the fall of the cooling capability of an air conditioner.

A sixteenth invention is an outdoor device of an air conditioner having a refrigeration cycle in which the compressor, outdoor heat exchanger, decompression device, and indoor heat exchanger are connected, wherein the outdoor device comprises the compressor, the outdoor heat exchanger, and an outdoor device. A control fan including a blower fan, the control box provided with the control component therein, and the cooling device of the first to eighth inventions for cooling the control component, wherein the number of dew condensation generated in the control box is controlled. The discharge path to the outside of the building is to be provided. According to this configuration, even when used in an environment with a lot of dust, the control parts of the air conditioner are accommodated in the control box, protected, cooled, and the control parts are prevented from getting wet by the condensation water. Even when it occurs, it can be reliably drained.

In a seventeenth aspect of the present invention, in the outdoor device of the air conditioner of the sixteenth aspect, the cooling unit is positioned in the control box spaced downward with respect to the control component or in the control box spaced in the horizontal direction with respect to the control component. To be placed in. Thereby, even if dew condensation water is generated in the control box, the effect according to the sixteenth invention can be sufficiently exhibited, and by using the refrigeration cycle of the air conditioner, there is no need to provide a new cooling device for control box cooling. .

18th invention is the outdoor apparatus of the air conditioner of 17th invention WHEREIN: The said cooling unit is arrange | positioned in the said control box, Comprising: The piping in the control box through which a refrigerant flows, and a some fin, The piping in the said control box It has a pin structure attached to it. Thereby, heat exchange between the air in a control box and the refrigerant | coolant which flows through the piping in a control box is performed efficiently.

19th invention WHEREIN: The outdoor apparatus of the 18th invention air conditioner WHEREIN: The piping in the said control box of the said cooling unit is a part of piping which connects the said decompression device and the said indoor heat exchanger. By effectively using the pipe connecting the decompression device and the indoor heat exchanger, it is unnecessary to provide a new pipe only for cooling the air in the control box.

In the outdoor device of the air conditioner of the 16th invention, in the 20th invention, one end of the discharge path is connected to the drip tray provided in the control box, and the other end of the discharge path is lower than one end of the discharge path. Moreover, it is arrange | positioned at the position higher than the bottom plate of the said outdoor apparatus. As a result, the water accumulated in the drip tray provided in the control box flows through the drainage path, so that even in a serious state in which dust is deposited on the bottom plate of the outdoor device, the flow of the drainage path is not impeded. Can be reached.

In the twenty-first aspect of the present invention, in the outdoor device of the air conditioner of the twentieth aspect, the other end of the discharge path is arranged at a position lower than the upper end of the compressor. Thereby, the short at the filling part near the upper end of a compressor can be prevented.

In the 22nd invention, in the outdoor apparatus of the air conditioner of 16th invention, the said discharge path is comprised by the drain hose. Thereby, the water accumulated in the drip tray provided in the control box can reliably reach the bottom plate of an outdoor apparatus.

A twenty-third aspect of the present invention provides the outdoor device of the air conditioner of the sixteenth invention, wherein the discharge path is located between the bottom surface of the control box and the bottom plate of the outdoor device, and the outdoor device is placed on the air path side and the machine. It is comprised by the groove provided in the longitudinal direction on the partition plate surface partitioned to the actual side. Thereby, the drainage path can be realized with a simpler configuration.

24th invention is an air conditioner provided with the outdoor apparatus of the air conditioner of 16th-23rd invention. As a result, an air conditioner having high reliability can be realized.

A twenty-fifth aspect of the present invention provides the cooling device of the first to eighth inventions, wherein the control box for controlling the operation of the compressor, the outdoor heat exchanger, the outdoor fan, and the air conditioner, and the control component housed in the control box, It is arrange | positioned in the outdoor apparatus of the said air conditioner, and the said control box is equipped with the fin structure which dissipates the heat | fever emitted from the said control component to the exterior of the said control box. As a result, heat generated from the control component can be radiated to the air outside the control box by the fin structure. In addition, the control component having a small heat generation amount but low heat resistance is cooled by air in the control box cooled by heat exchange with the refrigerant in the cooling unit. Therefore, the cooling unit is not enlarged more than necessary and the operating efficiency of the air conditioner is not lowered.

In the twenty-sixth aspect of the present invention, in the cooling device of the twenty-fifth aspect, the control box is made of a material having good thermal conductivity, and the control component of the control box is mounted on the fin structure. According to this structure, it is made of a material with good thermal conductivity and is arrange | positioned so that it may penetrate a control box, The other side mounts the control component with a large heat generation inside the control box, and the other side is outside the control box and the wind is exposed. It has the fin structure arrange | positioned at the position to become, whereby the control component is suppressed from being wet by the dew condensation water which generate | occur | produced on the surface of a cooling unit, and a control component (for example, a heat generating element) which is high in heat quantity and comparatively heat resistance. The heat generated from the heat can be radiated to the air outside the control box by the fin structure. In addition, the control component having a small heat generation amount but low heat resistance is cooled by air in the control box cooled by heat exchange with the refrigerant in the cooling unit. Therefore, the cooling unit is not enlarged more than necessary and the operating efficiency of the air conditioner is not lowered.

In the twenty-seventh aspect of the present invention, in the cooling device of the twenty-fifth aspect, the cooling unit is disposed in the control box and includes a pipe in a control box through which a refrigerant flows, a plurality of fins, and is attached to a pipe in the control box. It has a pin structure. Thereby, heat exchange between the air in a control box and the refrigerant | coolant which flows through the piping in a control box is performed efficiently.

28th invention is a cooling apparatus of 27th invention WHEREIN: The piping in the said control box of the said cooling unit is a part of piping which connects a decompression device and an indoor heat exchanger. By effectively using the pipe connecting the decompression device and the indoor heat exchanger, it is unnecessary to provide a new pipe only for cooling the air in the control box.

In the twenty-ninth invention, in the cooling device of the twenty-fifth invention, the cooling device according to the twenty-fifth invention has a drip tray receiving condensation water. Thereby, the component of the air conditioner located under the cooling unit can be prevented from getting wet by the dew condensation water which generate | occur | produced on the surface of a cooling unit.

30th invention is a cooling device of 25th invention WHEREIN: It is made to have the heat insulating material which insulates the internal space of the said control box. As a result, the movement of heat from the outside into the control box is suppressed. As a result, the cooling effect of the control component by a cooling unit improves compared with the case where there is no heat insulating material.

A thirty-first invention is the cooling device of the thirtieth invention, wherein the heat insulator is a vacuum heat insulator. By the vacuum insulator, the movement of heat from the outside into the control box is further suppressed as compared with the insulator. As a result, the cooling effect of the control component by the cooling unit further improves.

32nd invention is an air conditioner provided with the cooling device of 25th-31st invention. As a result, an air conditioner having high reliability can be realized.

A thirty-third invention has the cooling device of the first to eighth inventions, the compressor, the indoor heat exchanger, the decompression device, and the indoor heat exchanger; In the air conditioner provided with a heat pump apparatus, the control box accommodates the control component for controlling the flow rate and pressure of the refrigerant by performing operation control of the compressor and the decompression device of the heat pump apparatus, And a cooling unit accommodating portion for cooling the exhaust from the control box, forming an air passage including the opening, and accommodating the cooling unit in the air passage, and the control box and the cooling unit. Bonding means for joining the unit storage portion, and a control box for fixing the control box to the heat pump device. It is an air conditioner further provided with a fixing means and the cooling unit fixing means which fixes the said cooling unit accommodating part to the said heat pump apparatus. As a result, the control box can be detached while the cooling unit accommodating part is fixed to the heat pump device (ie, the air conditioner).

A thirty-fourth invention is the air conditioner of the thirty-third invention, wherein the cooling unit introduces a refrigerant pipe connecting the decompression device of the heat pump device and the indoor heat exchanger, and the exhaust and the refrigerant of the heat pump device. The heat exchange means which makes heat exchange between them is provided. This makes it possible to utilize cold heat of the evaporation-side refrigerant.

35th invention is an air conditioner of 33rd invention WHEREIN: The said cooling unit accommodating part is provided with the heat insulating material which insulates at least one part of the said air path. As a result, the heat insulation of the refrigerant pipe and the cooling unit accommodating portion is improved, and heat loss of the refrigeration cycle is suppressed.

A thirty-fourth invention is the air conditioner of the thirty-third invention, wherein the cooling unit accommodating portion includes a drain passage connected to the bottom of the air passage. Thereby, discharge of condensation water can be made possible.

37th invention is an air conditioner of 33rd invention WHEREIN: The said fan is made to ventilate the air in the said control box through the said opening part opened to the said control box. Thereby, forced ventilation can be performed by the fan.

In the thirty-eighth invention, in the air conditioner of the thirty-third invention, a heat insulation layer is formed between an inner surface of the cooling unit storage portion and the cooling unit. Thereby, the heat insulation of a refrigerant | coolant piping and a cooling unit accommodating part improves, and the heat loss of a refrigeration cycle can be suppressed.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described, referring drawings. The present invention is not limited by these embodiments.

(Embodiment 1)

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows roughly the structure of the cooling apparatus and air conditioner which concerns on Embodiment 1 of this invention. 2 is a diagram schematically showing an internal configuration of a control box according to the first embodiment. 3 is a perspective view of a cooling unit according to the first embodiment.

As shown in FIG. 1, the air conditioner 20 includes a compressor 22, an outdoor heat exchanger 24, a pressure reducing device 26, an indoor heat exchanger 28, and refrigerant pipes 30 and 32 connecting them. , 34, 36). As the decompression device 26, an expansion valve or a capillary tube which is a capillary tube made of copper can be employed. Moreover, the air conditioner 20 is divided into the outdoor apparatus which accommodates the compressor 22, the outdoor heat exchanger 24, and the decompression device 26, and the indoor apparatus which accommodates the indoor heat exchanger 28. As shown in FIG. .

In the air conditioner 20, the refrigerant passes through the refrigerant pipes 30, 32, 34, and 36, and sequentially from the compressor 22 to the outdoor heat exchanger 24, the pressure reducing device 26, and a control box to be described later. It is comprised so that the refrigeration cycle which returns to the compressor 22 via the cooling unit 44 and the indoor heat exchanger 28 of 42 is implemented.

In the refrigeration cycle, the refrigerant is compressed by the compressor 22 and then flows into the refrigerant pipe 30 toward the outdoor heat exchanger 24 in a gaseous state. Next, the refrigerant is deprived of heat by heat exchange with outdoor air passing through the outdoor heat exchanger 24 to become a liquid state, and flows through the refrigerant pipe 32 toward the decompression device 26. Subsequently, the refrigerant is expanded by the pressure reducing device 26 to lower the pressure, and flows through the refrigerant pipe 34 toward the indoor heat exchanger 28 via the cooling unit 44 of the control box 42 described later. Then, the refrigerant takes heat from the indoor air via the indoor heat exchanger 28 to a gaseous state, and flows through the refrigerant pipe 36 toward the compressor 22.

The air conditioner 20 further includes a control component (including a control board and various electronic components mounted on the control board) 40 for controlling the refrigeration cycle and a control box for protecting the control component 40. Has 42. In addition, the control box 42 is installed in the outdoor device.

In addition, the "control component" used in the present invention refers to components such as electronic components for use in the control of the air conditioner 20, for example, the output of the compressor 22 and the expansion valve as the decompression device 26. The electronic component for controlling the tightening amount is not limited to a control board on which a plurality of electronic components are mounted, and refers to a component that requires cooling in order to partially or entirely generate heat.

The control part 40 is accommodated in the control box 42, and is protected from dust, water, etc., for example. Therefore, the control box 42 is comprised so that it may be sealed so that dust and water may not enter inside. For example, in the control box 42, a hole through which a cable (not shown) extending from the control component 40 to the outside of the control box 42 passes is sealed. In addition, it is preferable that the control box 42 is comprised from the main body which the upper surface opened, and the cover which covers the upper surface of a main body from the surface of maintainability, and it is more preferable to be sealed also between a main body and a cover. In addition, a sponge-like resin material such as an EPT (ethylene propylene rubber) sheet can be used for such sealing.

Since the control component 40 is enclosed and accommodated in the control box 42, cooling is required. Therefore, the cooling unit 44 is installed in the control box 42.

The cooling unit 44 is configured to cool the air in the control box 42 by heat exchange with the refrigerant of the refrigeration cycle, and is mounted on the refrigerant pipe 34 and the refrigerant pipe 34 as shown in FIG. 2. Fin structure 46.

Specifically, as shown in FIG. 1, a portion of the refrigerant pipe 34 passes through the control box 42, and as shown in FIG. 2, a plate-shaped portion is formed in the portion of the refrigerant pipe 34 in the control box 42. The fin structure 46 provided with the some pin 46a is attached. The cooling unit 44 is provided at a position away from the control component 40, and is heat exchanged between the air in the control box 42 and the refrigerant flowing in the refrigerant pipe 34 via the fin structure 46. The air in the control box 42 is cooled. By this cooling unit 44, the control component 40 is cooled via air.

In addition, as for the refrigerant piping which comprises a part of the cooling unit 44, the refrigerant piping 34 which connects the decompression device 26 and the indoor heat exchanger 28 is preferable. By effectively using the refrigerant pipe 34, there is no need to separately provide a pipe through which the refrigerant flows through the control box 42 only for cooling the air in the control box 42.

In addition, since the refrigerant | coolant which became low pressure flows through the refrigerant | coolant piping 34 by the pressure reduction apparatus 26, compared with the other refrigerant | coolant piping 30, 32, 36 shown in FIG. Therefore, the arrangement | positioning of the refrigerant | coolant piping 34 in the control box 42 can suppress a vibration compared with the case where other refrigerant | coolant piping 30, 32, 36 is arrange | positioned. Moreover, as a result, it becomes possible to make the piping arrange | positioned in the control box 42 thin, and also has the secondary advantage that the material to be used can be reduced and cost can be held down. As another reason, since the refrigerant flowing through the refrigerant pipe 34 is originally low pressure, the influence of the pressure loss caused by the length of the control via the control box 42 (by lengthening) is small.

As shown in FIG. 3, for example, the fin structure 46 of the cooling unit 44 includes a plurality of plate-shaped fins 46a and a main body portion 46b on which the fins 46a are mounted. It is provided and is integrally formed with metals, such as aluminum. The plurality of plate-shaped pins 46a are arranged on one surface of the main body portion 46b of the fin structure 46 at equal intervals in parallel with each other. Moreover, the fin structure 46 is equipped with the some groove 46c which engages with the part of the refrigerant pipe 34 shape | molded in an S-shape on the surface on the opposite side to the surface in which the fin 46a was provided.

As shown in FIG. 3, the plurality of grooves 46c of the fin structure 46 are formed to extend in the same direction as the parallel direction (extension direction) of the plurality of fins 46a, respectively, and with the refrigerant pipe 34. The heat exchange of the fin 46a of the is made efficient. The fin structure 46 having such a structure can be produced by drawing or extrusion molding, and can be produced at a lower cost than other production methods (for example, cutting).

In addition, if possible, as shown in FIG. 2, the cooling unit 44 is preferably separated from the control component 40 and disposed below the control component 40. This is to reliably prevent the control component from being wetted by condensation water generated on the surface of the cooling unit 44 (specifically, the surface of the fin structure 46 and the surface of the refrigerant pipe 34).

It is preferable to provide the dish-shaped drip tray 48 which receives the condensation water below the cooling unit 44 in preparation for the case where the condensation water generated on the surface of the cooling unit 44 drips. Thereby, the component of the air conditioner 20 located below the cooling unit 44 can be prevented from getting wet by dew condensation water. As shown in FIG. 2, the drain pipe 49 for discharging the condensation water in the drip tray 48 to the outside of the control box 42 may be connected to the bottom of the drip tray 48.

In addition, the cooling apparatus of this Embodiment 1 is provided with some means for cooling the other control components 40 (other parts of the control board) in addition to the cooling unit 44.

As shown in FIG. 2, the fin structure 52, which is separate from the fin structure 46 of the cooling unit 44, provides relatively high heat to the control component 40, in particular the control substrate which is part of the control component 40. It is attached directly to the part which emits | releases (for example, a heat generating element installation part). The fin structure 52 is configured to exchange heat between the control component 40 and the outside air of the control box 42.

Specifically, similarly to the fin structure 46 of the cooling unit 44, the fin structure 52 is made of aluminum etc., for example, and is provided with the some fin 52a. The pin 52a of the fin structure 52 is configured to be exposed to the outside of the control box 42. In addition, the fin 52a is provided so as to be located under the wind of a fan (not shown) for discharging the air around the outdoor heat exchanger 24 to the outside of the outdoor device. By passing through this fin structure 52, the control component 40 is cooled by the fan (not shown) of an outdoor apparatus.

In addition, a fan 54 for forcibly stirring the air of the control box 42 is provided in the control box 42. When the fan 54 stops driving, for example, even if a low-temperature refrigerant flows in the refrigerant pipe 34 by the compressor 22 being driven, the fan 54 is controlled by the control component 40 by the cooling unit 44. Has little cooling effect. On the other hand, when the fan 54 is driven, the air in the control box 42 is stirred, so that the temperature distribution in the control box 42 is made uniform, and the cooling efficiency of the control component 40 can be increased. Therefore, when the control component 40 is to be cooled, the fan 54 is driven. The drive of the fan 54 is controlled by the fan drive control device 56 (fan drive control means) mounted to the control component 40.

The fan 54 can also suppress generation of condensation water on the surface of the cooling unit 44 by forcibly stirring the air in the control box 42. Specifically, since the air around the cooling unit 44 is moved by the fan 54, condensation water is less likely to occur on the surface of the cooling unit 44 than in the case where the fan 54 is not present. It is also difficult to grow significantly even if condensation occurs.

In addition, as shown in FIG. 2, the fan 54 is preferably arranged to blow toward the fin structure 46 of the cooling unit 44. As the fan 54 blows toward the fin structure 46, the air cooled by the cooling unit 44 diffuses into the entire control box 42. In addition, the flow of air around the cooling unit 44 is faster, and condensation water is less likely to occur on the surface of the cooling unit 44.

In addition, in order to suppress the movement of heat from the outside to the inside of the control box 42, the inner space of the control box 42 is preferably insulated by a heat insulating material (not shown). The heat insulating material is provided in the outer surface of the control box 42, for example. By this heat insulating material, the cooling effect with respect to the control component 40 by the cooling unit 44 improves compared with the case where there is no heat insulating material. Moreover, although it is preferable from a viewpoint of the effective use of the space in the control box 42, the heat insulating material may be provided in the outer surface of the control box 42, but you may provide it in the inner surface of the control box 42.

Moreover, as a heat insulating material, foam type heat insulating materials, such as fiber type heat insulating materials, such as glass fiber, and foamed synthetic rubber, vacuum heat insulating materials, etc. are mentioned. It is preferable to use a vacuum insulator having higher heat insulating performance. As a vacuum heat insulating material, what is achieved by packing a glass fiber with a laminated film, for example, and depressurizing the internal pressure is mentioned.

In the control box 42, as shown in FIG. 1, the fan drive control apparatus 56 and the temperature detection part 60 in the control box which detects the temperature in the control box 42 are provided. The fan drive control device 56 and the control box internal temperature detection unit 60 are provided as the control component 40.

After the compressor 22 starts to operate, when the temperature in the control box 42 is equal to or lower than the predetermined temperature T1, the fan drive control device 56 does not drive the fan 54 and does not cool the control component 40. . And when the temperature in the control box 42 becomes T1 or more and the temperature detection part 60 in the control box detects this, the fan drive control apparatus 56 drives the fan 54 to cool the control component 40, The control part 40 is prevented from being damaged due to being above a certain temperature. In addition, when the temperature in the control box 42 becomes a temperature T2 lower than T1 provided separately from T1 or becomes a temperature of T2 or less and the temperature detection unit 60 in the control box detects this, the fan drive control device 56 The fan 54 is stopped.

When the temperature in the control box 42 is T1 or less, the fan 54 is not driven once, but after the T1 is over, the fan 54 is driven, and when the temperature becomes lower than T2 which is lower than T1. By stopping the fan 54, the control component 40 can be cooled more than necessary to prevent condensation from occurring on the control substrate (control component) 40, and reliability can be ensured. Providing two different temperatures T1 and T2 as temperature thresholds for determining the driving and stopping of the fan 54 is that if the temperature in the control box 43 repeats a slight change when T2 is the same temperature as T1 This is to prevent this because the fan 54 frequently repeats driving and stopping, and the possibility of failure of the fan 54 increases.

In addition, if the fan 54 is not driven when the temperature in the control box 42 is several degrees or more, that is, if the control component 40 is not cooled, the control component 40 will be damaged, and the control box 42 When the temperature inside the) is below a few degrees, the temperature of the T1 and T2 should be determined in advance as to whether the control component 40 causes condensation when the fan 54 is driven to cool the control component 40. Temperature setting is possible. In such a configuration, by providing one temperature detection means (that is, by providing one temperature detection unit 60 in the control box), the control component 40 is cooled while preventing condensation, thereby preventing damage to the control component 40. It becomes possible to prevent. Therefore, it is cheap enough compared with the case where the drive of the fan 54 is controlled using a some temperature detection means.

As mentioned above, although this invention was described based on embodiment mentioned above, this invention is not limited to embodiment mentioned above.

For example, in the above-described embodiment, the air conditioner 20, that is, the refrigerant flows sequentially through the compressor 22, the outdoor heat exchanger 24, the pressure reducing device 26, and the indoor heat exchanger 28, namely, Although the air conditioner 20 which performs cooling operation was demonstrated, this invention is not limited to this. An air conditioner in which the refrigerant flows sequentially through the compressor 22, the indoor heat exchanger 28, the pressure reducing device 26, and the outdoor heat exchanger 24, that is, an air conditioner for performing a heating operation, a cooling operation, and a heating operation. The present invention is also applicable to an air conditioner that can be switched to perform the operation.

In the above-described embodiment, the cooling unit 44 is configured to cool the air in the control box 42 by using all of the refrigerant flowing in the refrigerant pipe 34, but the present invention is not limited thereto. A part of the coolant flowing in any of the coolant pipes 30, 32, 34, 36 may be used for cooling the air in the control box 42.

For example, branched from the portion of the refrigerant pipe 34 near the downstream side of the pressure reducing device 26, passing through the control box 42, and the refrigerant pipe near the upstream side of the indoor heat exchanger 28 ( The piping to bypass which reaches the part of 34) may be provided, the fin structure may be attached to this bypass piping, and the cooling unit 44 may be comprised. In this case, compared with the above-mentioned embodiment, although the cooling ability with respect to the control component 40 falls, the cooling ability of the air conditioner 20 improves.

(Embodiment 2)

4 is a diagram schematically showing a configuration of an air conditioner according to Embodiment 2 of the present invention. In FIG. 4, (66) is described only about the part different from Embodiment 1 below by the outdoor air temperature detection part (outdoor air temperature detection means) which detects outside air temperature.

When the outside temperature is above the predetermined temperature T3, when the outside temperature detecting unit 66 detects this, the fan drive control device 56 drives the fan 54 to cool the control component 40, so that the control component 40 It is kept above a certain temperature to prevent damage. And when the outside air temperature is below the predetermined temperature T4 lower than the temperature T3, the fan drive control device 56 does not drive the fan 54 and does not cool the control part 40, but cools the control part 40 more than necessary. To prevent condensation. In the case where the fan 54 is being driven, even when the outside air temperature is changed from a state of T4 or higher to a temperature of T4 or lower, the fan 54 is stopped to cool the control component 40 more than necessary to condensation. Prevent from occurring

The two different temperatures T3 and T4 are provided as temperature thresholds for determining the driving and stopping of the fan 54 in order to prevent the fan 54 from repeatedly failing the driving and stopping frequently.

In addition, when the fan 54 is not driven when the outside temperature is a few degrees or more, that is, when the control component 40 is not cooled, the control component 40 is damaged, and when the outside temperature is several degrees or less, When the fan 54 is driven to cool the control component 40, condensation will occur in the control component 40, and the temperature conditions of T3 and T4 can be set by determining the temperature condition in advance. In such a structure, even if there is only one temperature detection means, it is possible to cool the control component 40 while preventing condensation and to prevent damage to the control component 40, so that the fan 54 can be operated using a plurality of temperature detection means. It is cheap enough compared with the case of controlling the drive of).

(Embodiment 3)

5 is a diagram schematically showing a configuration of an air conditioner according to Embodiment 3 of the present invention. In Fig. 5, reference numeral 62 denotes a frequency detector (frequency detection means) for detecting the frequency of the compressor 22, and 64 denotes a current value detector (current value detection means) for detecting a current value flowing through the compressor. 40). Hereinafter, only the part different from Embodiment 1, 2 is described.

When the frequency detector 62 detects a frequency equal to or greater than a predetermined frequency f1, the fan drive control device 56 drives the fan 54 to cool the control component 40, so that the control component 40 is equal to or higher than a predetermined temperature. To prevent damage. And when the frequency detection part 62 detects the frequency below predetermined frequency f2, the fan drive control apparatus 56 will not drive the fan 54, but will not cool the control component 40, and the control component 40 Cool more than necessary to prevent condensation.

Predetermined the frequency of the compressor which needs to cool the control component 40 by driving the fan 54, and the frequency which needs to stop the fan 54 and prevent condensation of the control component 40 in advance, and predetermined frequency. f1 and f2 can be set. In such a configuration, it is possible to cool the control component 40 to prevent damage to the control component 40 while preventing dew condensation even without the temperature detection means, so that the drive of the fan 54 is driven using the temperature detection means. Cheapness is sufficient compared with the case of control.

In addition, when the current value detection unit 64 detects the predetermined current value I1 or more, the fan drive control device 56 drives the fan 54 to cool the control component 40, so that the control component 40 has a constant temperature. It is abnormal and prevents damage. And when the current value detection part 64 detects below the predetermined electric current value I2 lower than the electric current value I1, the fan drive control apparatus 56 will not drive the fan 54, but will not cool the control component 40, and the control component 40 ) Is cooled more than necessary to prevent condensation.

The current value required to cool the control component 40 by driving the fan 54 and the current value required to stop the fan 54 to prevent condensation of the control component 40 are determined in advance so that the predetermined current value I1, I2 can be set. In such a configuration, it is possible to cool the control component 40 to prevent damage to the control component 40 while preventing dew condensation even without the temperature detection means, so that the drive of the fan 54 is driven using the temperature detection means. Cheapness is sufficient compared with the case of control.

As the threshold values for controlling the driving and stopping of the fan 54 by using the frequency or the current value, two values of the frequency f1, f2 and the current values I1 and I2 are provided, respectively. This is to prevent frequent failures.

As described above, even if the frequency detector 62 or the current value detector 64 is not provided to detect the frequency or the current value, for example, the compressor 22 is provided from the frequency controller or the current controller provided in the control component. When the drive frequency or the current value is transmitted to the compressor 22 as a control signal, the drive of the fan 54 may be controlled based on the control value.

In addition, when the compressor 22 which has been driven is stopped, a certain time is required to cool the control component and there is no fear of condensation of the control component. A method of cooling the control component by driving 54) can also be considered.

In the above embodiment, in order to control the driving and the stop of the fan 54, a method of controlling by using either the frequency detector 62 or the current value detector 64 has been described. It is okay. Further, the driving of the fan 54 is controlled by combining one or both of the frequency detector 62 and the current value detector 64 with any one of the temperature detector 60 and the outside temperature detector 66 in the control box. It is also possible. Also in this case, only one temperature detecting means is sufficient, and inexpensive enough is sufficient compared with the case where the drive of the fan 54 is controlled by using a plurality of temperature detecting means.

(Fourth Embodiment)

7 is a diagram schematically showing a configuration of an air conditioner according to a fourth embodiment of the present invention. Hereinafter, only the part different from embodiment mentioned above is described.

As shown in FIG. 7, the control component 40 includes a fan drive control device 56 (fan drive control means), a temperature detection unit 60 in the control box for detecting the temperature in the control box 42, and a compressor ( A frequency control device (frequency control means) 68 for controlling the frequency of 22 and a current control device (current control means) 70 for controlling the current flowing through the compressor 22 are provided.

When the temperature in the control box 42 is equal to or higher than the predetermined temperature T5, the temperature detection unit 60 in the control box detects this, and the frequency control device 68 lowers the frequency of the compressor 22 to a predetermined value or lower. . Thereby, for example, even when the fan 54 lowers or stops for some reason, and the cooling device which consists of the fan 54 and the cooling unit 44 cannot fully cool the control component 40, for example. By lowering the drive frequency of the compressor 22, the amount of heat generated by the control component 40 can be reduced, and the temperature thereof can be lowered so as not to damage the control component 40. This operation is performed even when the fan drive control device 56 functions as normal and the fan 54 is driving. That is, when the cooling of the control component 40 by the fan 54 becomes impossible for some reason, or when the cooling degree is bad even if cooling is possible, the frequency control apparatus 68 sets the frequency of the compressor 22 predetermined. By lowering the value to or below, the amount of heat generated by the control component 40 is suppressed to prevent the damage. And when the temperature detection part 60 in a control box detects below another predetermined temperature T6 lower than predetermined temperature T5, the frequency control apparatus 68 raises the frequency of the compressor 22 to predetermined value, or it is original. Drive up to the frequency.

As a temperature threshold for changing the frequency of the compressor 22, two different temperatures T5 and T6 are provided, when T5 and T6 are the same temperature, the temperature in the control box 42 repeats a slight temperature change. In this case, the operation of lowering the frequency and the height of the operation are repeated frequently, so that the operation of the air conditioner 20 is repeatedly changed frequently in a short time, but this is to be avoided.

Moreover, as another means of suppressing the temperature rise of the control component 40, when the temperature in the control box 42 becomes more than predetermined temperature T7, the temperature detection part 60 in a control box detects this, and the current control apparatus ( 70 lowers the current flowing through the compressor 22 to a predetermined value or less. Thereby, for example, even when the fan 54 lowers or stops for some reason, and the cooling device which consists of the fan 54 and the cooling unit 44 cannot fully cool the control component 40, for example. By lowering the current flowing through the compressor 22, the amount of heat generated by the control component 40 can be reduced, and the temperature thereof can be lowered so as not to damage the control component 40. And when the temperature detection part 60 in a control box detects below another predetermined temperature T8 lower than predetermined temperature T7, the electric current control apparatus 70 raises the electric current which flows through the compressor 22 to a predetermined value, or it is original. Operate by raising the current to.

As temperature thresholds for changing the current flowing in the compressor 22, two different temperatures T7 and T8 are provided, where T7 and T8 are at the same temperature, the temperature in the control box 42 causes a slight temperature change. If repeated, the operation | movement which lowers and raises the electric current which flows through the compressor 22 will repeat frequently, and the operation | movement of the air conditioner 20 will repeat repeatedly changing frequently in a short time, but in order to avoid this.

According to the present embodiment, even if the cooling device cannot sufficiently cool the control component 40, for example, the fan 54 is lowered or stopped for some reason, the drive frequency of the compressor 22 is lowered or Alternatively, by lowering the current flowing through the compressor 22, the temperature of the control component 40 can be lowered so as not to damage the control component 40. Therefore, even when the cooling device cannot fully cool the control component, it is possible to prevent the control component from being damaged. Moreover, by applying the structure of Embodiment 1 to 3 mentioned above to this embodiment, the number of the temperature detection means for driving the fan 54 can be reduced, and a cheap cooling apparatus can be provided.

As mentioned above, although this invention was described based on embodiment mentioned above, this invention is not limited to embodiment mentioned above. For example, although the cooling unit 44 is disposed in the control box 42, as shown in FIG. 2, under the control component 40, the air in the control box 42 by the fan 54 is forced. If condensation water, such as dripping on the surface of the cooling unit 44 by stirring, does not generate | occur | produce, the cooling unit 44 can be arrange | positioned above the control component 40. FIG. In this case, it is preferable to arrange the drip tray 48 between the cooling unit 44 and the control component 40.

(Embodiment 5)

8 is a diagram schematically showing a configuration of an air conditioner according to a fifth embodiment of the present invention. In FIG. 8, 72 is a fan rotation speed detection part (fan rotation speed detection means) which detects the rotation speed of the fan 54. As shown in FIG. Hereinafter, only the part different from embodiment mentioned above is described.

When the fan rotation speed detection unit 72 detects a predetermined rotation speed or less, the frequency control device 68 that controls the drive frequency of the compressor sets the frequency to a predetermined value or less. Therefore, even if the rotation speed of the fan 54 becomes small for some reason, or the control component 40 cannot be cooled sufficiently, such as the rotation of the fan 54 stops, the drive frequency of the compressor 22 is changed. By lowering it, it is possible to protect the temperature of the control component 40 so that it does not become above predetermined temperature, and high reliability can be ensured. In addition, when the rotation speed of the fan 54 reaches a predetermined or more rotation speed different from the above, the value of the frequency is raised or returned to the original frequency.

In addition, when the fan rotation speed detection unit 72 detects a predetermined rotation speed or less, the current control device 70 that controls the current flowing through the compressor 22 may set the current to a predetermined value or less. This reduces the current flowing through the compressor 22 even when the rotation speed of the fan 54 becomes small due to some reason, or when the control component 40 cannot be sufficiently cooled, such as when the fan 54 stops. It is possible to protect the temperature of the control component 40 so that the temperature does not become more than a predetermined value, thereby ensuring higher reliability. In addition, when the rotation speed of the fan 54 reaches a predetermined or more rotation speed different from the above, the current value is increased or returned to the original current value. In addition, by applying the configuration of Embodiments 1 to 3 described above to the present embodiment, the number of the temperature detecting means for driving the fan 54 can be reduced, and a cheap cooling device can be provided.

(Embodiment 6)

The schematic block diagram which shows the inside of the control box with which the air conditioner which concerns on Embodiment 6 of this invention is equipped is shown in FIG. Hereinafter, only the part different from embodiment mentioned above is described.

As shown in FIG. 9, the cooling unit 44 is separated from the control board 80 and is disposed below the control board 80. This is to prevent the control board 80 from getting wet due to the condensation water generated on the surface of the cooling unit 44 (specifically, the surface of the fin structure 46 and the surface of the refrigerant pipe 34). In addition, as in the schematic configuration of the control box according to the modification of the sixth embodiment shown in FIG. 10, the cooling unit 44 is separated from the control board 80 and is horizontal to the control board 80. You may arrange | position in a direction.

In preparation of the case where the dew condensation water which generate | occur | produced on the surface of the cooling unit 44 is dripped, the dish-shaped drip tray 48 which receives condensation water is provided below the cooling unit 44. As shown in FIG. Thereby, the component of the air conditioner 20 located below the cooling unit 44 can be prevented from getting wet by dew condensation water. As shown in FIG. 9 (or FIG. 10), the bottom of the drip tray 48 is equipped with the drain pipe 49 for discharging the condensation water accumulate | stored in the outside to the control box 42. As shown in FIG. One end of the discharge path 93 shown in FIG. 11 is connected to the drain pipe 49, and the discharge path 93 extends downward along the partition plate 90 to the bottom plate 94 of the outdoor device. Induced.

When the drain path 93a uses the drain hose 93a (refer to the enlarged view of the portion A in FIG. 11A), the other end is opened downward, and the opening is upward from the bottom plate 94 of the outdoor device. Is placed in a position away from.

In addition, when the discharge path 93 is the groove 93b provided in the longitudinal direction on the surface of the partition plate 90 (refer to the enlarged view of the A portion in FIG. 11B), the groove restricts the flow of water in the vertical direction. In addition, scattering from the inside of the groove 93b to the outside due to the surface tension of the water can be prevented. At the end of the groove 93b, the depth of the groove 93b is gradually made shallower at a position higher than the bottom plate 94 of the outdoor device, and finally configured to be flush with the partition plate 90. Thereby, even in a severe state such as dust depositing on the bottom plate 94 of the outdoor device, the discharge path 93 can reach the bottom plate 94 of the outdoor device without impeding the flow of water. Moreover, the other end of the discharge path 93 is arrange | positioned in the position lower than the upper end of the compressor 22, and is comprised so that the short in the filling part of the upper end vicinity of the compressor 22 may be prevented.

In order to suppress the movement of heat from the outside into the inside of the control box 42, the inner space of the control box 42 is preferably insulated by the heat insulator 82. The heat insulating material 82 is provided in the outer surface of the control box 42, for example as shown in FIG. By this heat insulating material 82, the cooling effect with respect to the control board 80 by the cooling unit 44 improves compared with the case where there is no heat insulating material 82. FIG. In addition, although the heat insulating material 82 is preferable to be provided in the outer surface of the control box 42 from a viewpoint of the space effective use in the control box 42, you may provide in the inner surface of the control box 42. As shown in FIG. Moreover, as a heat insulating material 82, foam type heat insulating materials, such as a fiber-based heat insulating material, such as glass fiber, foamed synthetic rubber, a vacuum heat insulating material, etc. are mentioned.

According to this embodiment, the position or control board in the control box 42 below the control board 80 in the state in which the cooling unit 44 which cools the air in the control box 42 is separated from the control board 80. It is arranged at a position in the control box 42 in the horizontal direction with respect to 80. Thereby, the control board 80 is prevented from getting wet by the dew condensation water which generate | occur | produced on the surface of the cooling unit 44, and the air conditioner 20 which has high reliability can be realized.

As mentioned above, although this invention was described based on embodiment mentioned above, this invention is not limited to embodiment mentioned above.

For example, in the above-described embodiment, the fan 54 is disposed in the control box 42 for forcibly stirring the air in the control box 42, but the control board 80 by the cooling unit 44 is provided. Fan cooling may be omitted as long as cooling to the

(Seventh Embodiment)

The schematic block diagram which shows the inside of the control box with which the air conditioner which concerns on Embodiment 7 of this invention is equipped is shown in FIG. Hereinafter, only the part different from embodiment mentioned above is described.

As shown in FIG. 12, since the control board 80 is accommodated in the control box 42, cooling is required. The control component mounted on the control board 80 and generating heat directly acts directly on the output of the compressor 22, and is relatively excellent in heat resistance, for example, in a semiconductor element 86 such as a power transistor, a diode bridge, or the like. There exists a component, such as the electrolytic capacitor 88, for which the reliability may fall remarkably by this.

In a state where control parts having different heat generation and heat resistance are arranged in close proximity, the air temperature in the control box 42 is cooled below a limit temperature at which the reliability of the low heat resistance control part, for example, the electrolytic capacitor 88 is lowered. Needs to be. On the other hand, while a control component having excellent heat resistance, for example, a semiconductor element 86 such as a power transistor or a diode bridge, has a large amount of heat generation, a control component having a low heat resistance, for example, an electrolytic capacitor 88 It is not necessary to lower it to the limit temperature at which reliability decreases.

That is, an electrolytic capacitor, which is relatively excellent in heat resistance, for example, may have a significant decrease in reliability due to a rise in temperature, for example, a semiconductor element 86 (first component) such as a power transistor or a diode bridge. It is preferable to cool components (second components) such as (88) by another method.

Therefore, while the cooling unit 44 is provided in the control box 42, it is made of the material with good thermal conductivity, and is arrange | positioned so that it may penetrate the control box, and the other one is inside the control box 42, and the calorific value In addition to mounting this large control component, one side is also provided with the fin structure 52 (2nd fin structure) arrange | positioned outside the control box and in the position which a wind is exposed. Specifically, the fin structure 52 is made of aluminum, for example, similarly to the fin structure 46 (first fin structure) of the cooling unit 44, and is provided with the some fin 52a. . The pin 52a of the fin structure 52 is configured to be exposed to the outside of the control box 42.

In addition, as shown in FIG. 13, the fin 52a is provided so that it may be located under the wind of the fan 96 for discharging the air around the outdoor heat exchanger 24 to the exterior of an outdoor apparatus. By passing through such a fin structure 52, the control component, such as the semiconductor element 86 with a large heat generation amount mounted on the control board 80, is cooled by the fan 96 of an outdoor device.

According to this embodiment, the position or control board in the control box 42 below the control board 80 in the state in which the cooling unit 44 which cools the air in the control box 42 is separated from the control board 80. It is arranged at a position in the control box 42 in the horizontal direction with respect to 80. Thereby, the control board 80 is prevented from getting wet by the dew condensation water which generate | occur | produced on the surface of the cooling unit 44, and the air conditioner 20 which has high reliability can be realized.

(Embodiment 8)

The structure of the air conditioner concerning Embodiment 8 of this invention is shown to FIG. 14 (a). The air conditioner 101 which concerns on Embodiment 8 of this invention is comprised from the outdoor device 156, the indoor device 154, and the refrigerant piping which connects them. In the outdoor device 156, a compressor 102, a control valve 106 (decompression device), and an outdoor heat exchanger 104 are disposed. The air conditioner 101 further includes a first pipe 166 connecting the refrigerant discharge port of the compressor 102 and the outdoor heat exchanger 104, and a second pipe connecting the outdoor heat exchanger 104 and the control valve ( 164, a third pipe 162 reaching the indoor heat exchanger 108 from the control valve 106, and a fourth pipe 160 connecting the indoor heat exchanger 108 and the compressor 102. .

The indoor unit 154 includes an indoor heat exchanger 108, a blowing fan (not shown), and a louver (not shown) for controlling the blowing direction.

The control box 110 and the cooling unit accommodating part 112 according to the present invention are disposed on the third pipe 162, and the third pipe 162 is a cooling unit accommodated in the cooling unit accommodating part 112. It penetrates 114 to reach the indoor heat exchanger 108.

Fig. 14B is a schematic diagram showing the flow of the refrigerant during the cooling operation of the air conditioner shown in Fig. 14A. The refrigerant discharged from the discharge port of the compressor 102 reaches the outdoor heat exchanger 104 via the first pipe 166. The refrigerant condensed by heat exchange with outdoor air having a lower temperature than the refrigerant in the outdoor heat exchanger 104 reaches the control valve 106 via the second pipe 164. The refrigerant, which has been depressurized at the control valve 106, and whose temperature has been lowered is introduced into the cooling unit 114 via the third pipe 162, and together with the cooling unit 114, cooling of the temperature increased air in the control box 110. Is provided. Thereafter, the refrigerant reaches the indoor heat exchanger 108, and is evaporated by heat exchange with indoor air that is hotter than the refrigerant, and returns to the inlet of the compressor 102 via the fourth pipe 160.

15 is a schematic separation diagram of the control box 110 and the cooling unit storage unit 112 according to the eighth embodiment. The control box 110 is a resin box, and a necessary part is a metal plate, and the electromagnetic shield is given. Inside the control box 110, a control component 120 made of a print base (control board) forming a control device and an electronic component accompanied by heat generation is fixed. In addition, each of the compressor 102, the fan, the louver, and the regulating valve 106 and the control device inside the switch 110 are electrically connected to and controlled by the control device. In addition, two openings 122 are opened on the bottom surface of the control box 110, and these openings 122 are used as openings for the intake and exhaust of the control box 110. A fan 124 is provided in one opening of each of the openings 122, and it is possible to forcibly exhaust the air inside the control box 110.

Moreover, the control box 110 is provided with the control box fixing means 126 which connects and fixes with the side plate which forms the ventilation path of the outdoor apparatus 156. As shown in FIG. Although the fan which concerns on this embodiment was made for exhaust, intake may be sufficient. In addition, about the installation number of the opening part 122 of the control box 110 which concerns on this embodiment, two or more may not be sufficient, and one structure and a structure may be provided with the fan for intake and exhaust air in a part.

In this embodiment, the control box 110 is bonded to the cooling unit storage part 112 via the bonding means 125. In order to improve the adhesiveness of the control box 110 and the cooling unit storage part 112, the bonding means 125 is comprised by rubber packing and screw fixing. However, the bonding means 125 may have a fitting structure provided in both the control box 110 and the cooling unit storage part 112.

The cooling unit storage part 112 in this embodiment is joined to the control box 110 by the bonding means 125. In addition, the cooling unit accommodating part 112 has a shape of a bowl shape in which the upper surface is largely opened so as to cover the entire opening 122 provided in the control box 110, and has a folding part for pressing the bonding means 125. It is molded by. In addition, the third pipe 162 is introduced into the cooling unit storage unit 112 so as to penetrate the side surface, and the cooling unit 114 joined to the third pipe 162 is accommodated therein. . Moreover, the drainage path 118 which consists of a drain port and a drain pipe is provided in the lowest part of the bottom surface of the cooling unit 114. FIG. Although the cooling unit 114 which concerns on this invention adopts the form which sandwiches the 3rd piping 162 by the heat sink made from aluminum and the base made from aluminum, it is not limited to this, For example, cooling It may be a form of only a copper tube meandering inside the unit storage unit 112.

In addition, the cooling unit accommodating part 112 is fixed by the cooling unit fixing means 128 to the air flow path formation board of the outdoor apparatus which is a part of the heat pump apparatus 103. As shown in FIG. The cooling unit fixing means 128 is comprised in the form of inserting the folding part of the metal plate bent in L shape in the shape of the hook shape formed in the air passage forming plate. In addition, although the cooling unit storage part 112 is being fixed to this metal plate through the heat insulating material which is not shown in figure, the heat insulating means 116 is comprised from these heat insulating materials and a metal plate, for example.

By the above structure, the air in the control box 110 is exhausted in the cooling unit accommodating part 112 which the cooling unit 114 accommodated through the opening part 122 by the fan 124. The air cooled by the cooling unit 114 convections and diffuses into another inside of the control box 110 from another opening 122 provided in the control box 110 by the differential pressure, so that the control component 120 is cooled. In addition, even if condensation forms on the cooling unit 114 and drops it, the condensation water is drained from the drainage path 118, so that the condensation water is prevented from entering the control box 110. Moreover, even if humidity rises inside the cooling unit storage part 112, water vapor will disperse | distribute to the exterior of a system through the drainage path 118 by steam partial pressure, and there exists an effect which reduces internal condensation.

In addition, in this embodiment, although the high temperature piping of the compressor and the condensation side is arrange | positioned under the heat insulation means 116, the heat between the cooling unit accommodating part 112 and these high temperature piping etc. by the heat insulation means 116 is carried out. Movement is blocked. Therefore, the heat loss of a high temperature piping and the density fall by the temperature rise of the refrigerant | coolant inside the 3rd piping 62 which are evaporation side piping can be prevented.

FIG. 16: is a schematic diagram of the state which fixed the control box 110 to the heat pump apparatus 103 with the cooling unit storage part 112 in this embodiment. As described above, the control box 110 and the cooling unit accommodating portion 112 each independently include the control box fixing means 126 and the cooling unit fixing means 128, as shown in FIGS. 15 and 16. Regardless of the third pipe 162 which is difficult to move, the control box 110 can be easily separated.

(Embodiment 9)

The structure of the control box with which the air conditioner which concerns on Embodiment 9 of this invention is demonstrated. Hereinafter, only the part different from embodiment mentioned above is described.

FIG. 17 (a) is a schematic diagram when the opening 122 of the control box 110 is provided on the side surface of the control box 110, and FIG. 17 (b) shows the BB 'in FIG. 17 (a). It is sectional drawing which shows the control box 110, the cooling unit accommodating part 112, and its inside in cross section.

In this embodiment, the minute protrusion 190 is shape | molded as the heat insulation layer forming means toward the bottom part of the cooling unit 114 from the cooling unit accommodation part 112. As shown in FIG. The protrusion 190 forms an air layer (ie, a heat insulation layer) between the cooling unit 114 and the cooling unit storage unit 112. Thereby, the heat exchange area of the cooling unit 114 and air can be increased, and the loss of cooling heat from the cooling unit 114 to the cooling unit accommodating part 112 can be prevented. The heat insulation layer forming means is not limited to the protrusion 190 integrally formed with the cooling unit storage portion 112, and a heat insulating material may be used.

Moreover, by combining suitably any embodiment of the said various embodiment, the effect which each has can be acquired.

According to the present invention, even when the cooling device cannot sufficiently cool the control part, the control part can be protected by not allowing the control part to reach a predetermined temperature or more, thereby realizing a cooling device and an air conditioner with high reliability. Therefore, as long as it cools the air in a control box using a refrigerant | coolant, it is applicable not only to an air conditioner but also to handling refrigerant | coolants, such as a refrigerator, for example.

Although this invention fully described with reference to an accompanying drawing with reference to an accompanying drawing, various deformation | transformation and correction are clear for those skilled in the art. Such modifications and variations are obviously to be understood as included within the scope of the present invention as defined by the appended claims.

The disclosure of the specification, drawings, and claims of Japanese Patent Application No. 2011-144025 (filed date: June 29, 2011), Japanese Patent Application No. 2011-149811 (filed date: July 6, 2011) The contents of the disclosure of the specification, the drawings, and the claims, the contents of the specification, the drawings, and the claims of the Japanese Patent Application No. 2011-149812 (filed date: July 6, 2011), and the Japanese Patent Application The specification of the specification of 2011-239984 (application date: November 1, 2011), the disclosure content of a claim, and the specification of Japanese Patent Application No. 2011-239985 (application date: November 1, 2011), The drawings and the disclosure of the claims are incorporated herein by reference in their entirety.

20: air conditioner 22: compressor
24: outdoor heat exchanger 26: pressure reducing device
28: indoor heat exchanger 40: control parts
42: control box 44: cooling unit
54: fan 56: fan drive control device
60: temperature detector in the control box 62: frequency detector
64: current value detection unit 66: outdoor temperature detection unit
68: frequency control device 70: current control device
72: fan rotation speed detection unit 80: control board
82: heat insulating material 90: partition plate
93: discharge path 94: the bottom plate of the outdoor device
86 semiconductor device 88 electrolytic capacitor
96: fan 101: air conditioner
102: compressor 104: outdoor heat exchanger
106: control valve 108: room heat exchanger
110: control box 112: cooling unit storage
114: cooling unit 116: heat insulation means
118: drainage path 120: control parts
122: opening 124: fan
125 bonding means 126 control box fixing means
128: cooling unit fixing means 154: indoor equipment
156: outdoor device 160: fourth piping
162: third pipe 164: second pipe
166: first pipe 190: protrusion (heat insulation layer forming means)

Claims (38)

A cooling unit disposed in the control box in a state away from the control component and cooling the air in the control box by heat exchange with the refrigerant;
A fan for stirring air in the control box,
Temperature detection means in a control box for detecting a temperature in the control box;
And frequency control means for controlling a driving frequency of the compressor circulating the refrigerant,
When the temperature detecting means in the control box detects a predetermined temperature or more, the frequency control means lowers the frequency.
Cooling device.
The method according to claim 1,
Further provided with fan rotation speed detecting means for detecting the rotational speed of the fan,
And the frequency control means lowers the frequency when the fan rotation speed detection means detects a predetermined rotation speed or less.
A cooling unit disposed in the control box in a state away from the control component and cooling the air in the control box by heat exchange with the refrigerant;
A fan for stirring air in the control box,
Temperature detection means in a control box for detecting a temperature in the control box;
And current control means for controlling a current flowing in the compressor circulating the refrigerant,
When the temperature detection means in the control box detects a predetermined temperature or more, the current control means lowers the current value.
Cooling device.
The method of claim 3, wherein
Further provided with fan rotation speed detecting means for detecting the rotational speed of the fan,
And the current control means lowers the current value when the fan rotation speed detection means detects a predetermined rotation speed or less.
5. The method according to any one of claims 1 to 4,
Has fan drive control means for controlling the drive of the fan,
And the fan drive control means stops the fan when the temperature detection means in the control box detects a temperature below a predetermined value, and drives the fan when a predetermined temperature or more is detected.
5. The method according to any one of claims 1 to 4,
Fan drive control means for controlling the drive of the fan;
A frequency detecting means for detecting a frequency of the compressor or a frequency setting means for setting a predetermined frequency,
The fan drive control means stops the fan when the frequency detecting means detects a predetermined frequency or less, or when the frequency setting means outputs a predetermined frequency or less, and detects a predetermined or higher frequency or a predetermined or higher frequency. Cooling device for driving the fan when outputting.
5. The method according to any one of claims 1 to 4,
Fan drive control means for controlling the drive of the fan;
A current value detecting means for detecting a current value flowing in the compressor, or a current value setting means for setting a predetermined current value,
The fan drive control means stops the fan when the current value detecting means detects a predetermined value or less, or when the current value setting means outputs a predetermined value or less, and detects a predetermined value or a predetermined value or more. Cooling device for driving the fan when outputting.
5. The method according to any one of claims 1 to 4,
Fan drive control means for controlling the drive of the fan;
Having the outside temperature detecting means for detecting the outside temperature,
And the fan drive control means stops the fan when the outside air temperature detecting means detects a temperature below a predetermined temperature, and drives the fan when the fan temperature is detected.
9. The method according to any one of claims 1 to 8,
The cooling unit includes a fin structure having a plurality of fins and a refrigerant pipe mounted on a side opposite to the fin of the fin structure, wherein the fin and the groove for mounting the refrigerant pipe are formed in the same direction. .
The method of claim 9,
And the cooling unit is disposed under the control part, and arranges a drip tray below the cooling unit.
The method of claim 9,
The cooling unit has a separate fin structure having a plurality of fins mounted directly to a control board that is part of the control component, wherein the fins of the separate fin structure are exposed to the outside of the control box incorporating the cooling unit. Cooling system.
The method of claim 9,
The fan which stirs the air in the said control box is arrange | positioned so that it may blow toward the said fin structure of the said cooling unit.
An air conditioner having the compressor, an outdoor heat exchanger, a pressure reducing device, an indoor heat exchanger, and a pipe through which a refrigerant flows by connecting them,
As a cooling apparatus which cools the said control component accommodated in the said control box of the said air conditioner, Using the cooling apparatus in any one of Claims 1-12.
Air conditioner.
14. The method of claim 13,
The air conditioner of the said cooling unit which cools the air in the said control box in the said cooling apparatus is a refrigerant | coolant which flows through the piping between the said decompression device and the said indoor heat exchanger.
14. The method of claim 13,
The refrigerant of the cooling unit that cools the air in the control box in the cooling device is classified from a part of a refrigeration cycle comprising the compressor, the outdoor heat exchanger, the decompression device, and the indoor heat exchanger. Air conditioner that is a refrigerant.
An outdoor unit of an air conditioner having a refrigeration cycle in which the compressor, an outdoor heat exchanger, a pressure reducing device, and an indoor heat exchanger are connected,
The outdoor device includes the compressor, the outdoor heat exchanger, an outdoor blower fan, the control box provided with the control part therein, and the cooling device according to any one of claims 1 to 8. Equipped with a cooling device,
A discharge path for discharging condensation water generated in the control box to the outside of the control box is provided.
Outdoor unit of air conditioner.
17. The method of claim 16,
And the cooling unit is disposed at a position in the control box spaced downward relative to the control component or at a position in the control box spaced horizontally relative to the control component.
The method of claim 17,
The cooling unit,
A pipe in the control box disposed in the control box and in which a refrigerant flows;
An outdoor unit of an air conditioner having a plurality of fins and having a fin structure mounted to a pipe in the control box.
19. The method of claim 18,
The outdoor unit of the air conditioner of which the piping in the said control box of the said cooling unit is a part of piping which connects the said decompression device and the said indoor heat exchanger.
17. The method of claim 16,
One end of the discharge path is connected to a drip tray provided in the control box, and the other end of the discharge path is lower than one end of the discharge path and is disposed at a position higher than the bottom plate of the outdoor device. Outdoor equipment.
21. The method of claim 20,
The other end of the discharge path, the outdoor device of the air conditioner is disposed at a position lower than the upper end of the compressor.
17. The method of claim 16,
And the discharge path is an outdoor unit of an air conditioner configured by a drain hose.
17. The method of claim 16,
The discharge path is located between the lower side of the control box and the bottom plate of the outdoor device, and is constituted by grooves installed in a vertical direction on the plane of the partition plate that divides the outdoor device into the air path side and the machine room side. Outdoor unit of air conditioner.
The air conditioner provided with the outdoor device of any one of Claims 16-23.
9. The method according to any one of claims 1 to 8,
The control box for controlling the operation of the compressor, the outdoor heat exchanger, the outdoor fan, and the air conditioner, and the control component accommodated in the control box are disposed in the outdoor device of the air conditioner,
The control box is provided with the fin structure which radiates the heat | fever emitted from the said control component to the exterior of the said control box.
26. The method of claim 25,
And the control box is made of a material having good thermal conductivity, and the fin structure is mounted with the control component of the control box.
26. The method of claim 25,
The cooling unit,
A pipe in the control box disposed in the control box and in which a refrigerant flows;
Cooling apparatus having a plurality of fins and having a fin structure mounted to the piping in the control box.
28. The method of claim 27,
The piping in the said control box of the said cooling unit is a cooling apparatus which is a part of piping which connects a decompression device and an indoor heat exchanger.
26. The method of claim 25,
A cooling device having a drip tray receiving condensation water under the cooling unit.
26. The method of claim 25,
Cooling apparatus having a heat insulating material to insulate the inner space of the control box.
31. The method of claim 30,
Cooling device wherein the insulation is a vacuum insulation.
An air conditioner provided with the cooling device according to any one of claims 25 to 31.
The said cooling apparatus of any one of Claims 1-8,
In the air conditioner provided with the said compressor, the indoor heat exchanger, the decompression device, and the indoor heat exchanger, the heat pump apparatus which has these piping which connects these, flows a refrigerant | coolant, and circulates a refrigerant | coolant, and comprises a refrigeration cycle,
The control box accommodates the control part for controlling the flow rate and pressure of the refrigerant by performing operation control of the compressor and the decompression device of the heat pump device, and has an opening for an intake and exhaust, and the cooling unit has the control box. Cooling the exhaust from
A cooling unit accommodating portion for forming the air passage including the opening and accommodating the cooling unit in the air passage;
Joining means for joining the control box and the cooling unit storage portion;
Control box fixing means for fixing the control box to the heat pump apparatus;
Further comprising cooling unit fixing means for fixing the cooling unit accommodating portion to the heat pump device
Air conditioner.
34. The method of claim 33,
The cooling unit includes air having heat exchange means for introducing a refrigerant pipe connecting the decompression device of the heat pump device to the indoor heat exchanger to perform heat exchange between the exhaust and the refrigerant of the heat pump device. Harmonizer.
34. The method of claim 33,
And the cooling unit accommodating portion includes a heat insulating material for insulating at least a portion of the air passage.
34. The method of claim 33,
And the cooling unit accommodating portion has a drain passage connected to the bottom of the air passage.
34. The method of claim 33,
The fan is an air conditioner that ventilates the air in the control box through the opening opening in the control box.
34. The method of claim 33,
The air conditioner in which the heat insulation layer is formed between the inner surface of the said cooling unit accommodating part, and the said cooling unit.

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