The present invention relates to an outdoor unit and an air conditioner, the outdoor unit including a heat dissipator.
An outdoor unit disclosed in Patent Literature 1 includes: a housing with an outlet formed on a front panel; a heat exchanger, a compressor, and a blower provided in the housing; a control substrate provided in the housing and controlling the operation of the compressor and the blower; an electric component provided on the control substrate; and a heat dissipator for dissipating heat generated by the electric component. The outdoor unit further includes a partition board that partitions the space in the housing into a blower chamber and a compressor chamber, the blower chamber being a space where the blower is arranged, and the compressor chamber being a space where the compressor is arranged. The heat dissipator includes a base thermally connected to the electric component, and a plurality of fins provided on the base. An air guide is provided on the side of tips of the plurality of fins, and the space surrounded by the base, the plurality of fins, and the air guide forms an air passage. According to the outdoor unit disclosed in Patent Literature 1, even when the heat dissipator is provided near the periphery of a blower fan having a relatively small amount of ventilation, the entire heat dissipator is cooled efficiently by allowing air to flow through the air passage formed in the heat dissipator.
Patent Literature 1: Japanese Patent Application Laid-open No. 2009-299907
However, when a bell mouth is provided around the outlet of the housing of the outdoor unit disclosed in Patent Literature 1, a closed space surrounded by an outer peripheral surface of the bell mouth, an inner surface of the front panel, and the partition board is formed in the housing. The bell mouth is an annular member that projects from an annular wall surface forming the outlet into the housing so as to reduce a pressure loss when the air having passed through the heat exchanger and flowed into an blower chamber is discharged to the outside of the blower chamber through the outlet. In this closed space, the pressure tends to be high because the air flow is more stagnant therein than in the space outside the closed space. Therefore, when leeward end surfaces of the fins lie in the closed space, the air having entered the air passage formed between the adjacent fins from windward end surfaces of the fins flows toward the tips of the fins, that is, ends of the fins on the side opposite to the side of the base, before reaching the leeward end surfaces of the fins. Such a change in the direction of flow of the air having entered the air passage causes a decrease in the velocity of flow of the air at the leeward end surfaces of the fins, so that the cooling capacity of the heat dissipator cannot be sufficiently achieved.
The present invention has been made in view of the above, and an object of the present invention is to provide an outdoor unit in which the cooling capacity of a heat dissipator can be improved even when a bell mouth is provided in a housing.
An outdoor unit according to an aspect of the present invention includes a housing that includes a front panel having an outlet for an airflow, a back panel facing the front panel, a left side panel, a right side panel facing the left side panel, a bottom panel, and a top panel facing the bottom panel. The outdoor unit further includes a control substrate that is provided in the housing and provided with an electric component, an electric component box in which the control substrate is provided, and a heat dissipator that is provided between the top panel and the electric component box and dissipates heat generated by the electric component. A region surrounded by the heat dissipator, the back panel, the front panel, the electric component box, and the top panel is formed on a windward side of the heat dissipator.
The outdoor unit according to the present invention has an effect that the cooling capacity of the heat dissipator can be improved even when the bell mouth is provided in the housing.
An outdoor unit and an air conditioner according to embodiments of the present invention will now be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.
First, an overview of the configuration of an outdoor unit 1-1 according to a first embodiment of the present invention will be described with reference to
The housing 2 includes a front panel 3 that forms a front surface of the housing 2, a back panel 8 that faces the front panel 3 and forms a back surface of the housing 2, a left side panel 4 that forms a side surface on the left side of the housing 2 when the housing 2 is viewed from the front, a right side panel 5 that faces the left side panel 4, a bottom panel 6 that forms a bottom surface of the housing 2, and a top panel 7 that faces the bottom panel 6. Note that the front panel 3 and the left side panel 4 may be formed by one component.
An inlet 4a is formed on the left side panel 4. An inlet 8a is formed on the back panel 8. The inlet 4a and the inlet 8a are for taking air from the outside of the housing 2 into the housing 2.
An outlet 31 of a circular shape is formed on the front panel 3. The outlet 31 is an opening for discharging the air taken into the housing 2 to the outside of the housing 2. The bell mouth 9 is provided on a wall surface 3a having an annular shape and forming the outlet 31. The bell mouth 9 is an annular member projecting from the wall surface 3a into the housing 2.
Inside the housing 2, the blower 13 is arranged within a region that is obtained by projecting an inner edge of the bell mouth 9 from the front panel 3 of the housing 2 toward the back panel 8 thereof. The blower 13 includes an impeller 13a and a motor 13b that is a power source for the impeller 13a. When the motor 13b of the blower 13 is driven to cause the impeller 13a of the blower 13 to rotate, air is taken into a blower chamber 11 of the housing 2 through the inlets 4a and 8a. The air taken into the blower chamber 11 is discharged to the outside of the housing 2 through the outlet 31. In
The partition board 10 is a member that partitions the space in the housing 2 into the blower chamber 11 and a compressor chamber 12, the blower chamber 11 being a space where the blower 13 is arranged, and the compressor chamber 12 being a space where the compressor 14 is arranged. The blower chamber 11 is the space surrounded by the front panel 3, the left side panel 4, the bottom panel 6, the top panel 7, the back panel 8, and the partition board 10. The compressor chamber 12 is the space surrounded by the front panel 3, the right side panel 5, the bottom panel 6, the electric component box 15, the back panel 8, and the partition board 10. When the outdoor unit 1-1 is viewed from the front, for example, the partition board 10 extends from the bottom panel 6 toward the top panel 7 and comes into contact with a lower surface of the electric component box 15 before reaching the top panel 7.
The compressor chamber 12 is the space surrounded by the partition board 10 and the right side panel 5. The compressor chamber 12 is provided with the compressor 14 for compressing the refrigerant. The compressor 14 is connected to a plurality of pipes (not shown) included in the heat exchanger 22, and the refrigerant compressed by the compressor 14 is sent to the pipes. When air passes through the heat exchanger 22, heat exchange occurs between the refrigerant flowing through the pipes and the heat exchanger 22.
The heat exchanger 22 is provided inside the housing 2 so as to cover the inlets 4a and 8a. The heat exchanger 22 is provided in the blower chamber 11 and faces the inside of each of the back panel 8 and the left side panel 4 of the housing 2. When the outdoor unit 1-1 is viewed from above, for example, the heat exchanger 22 has an L-shape extending from the left side panel 4 toward the back panel 8. The heat exchanger 22 includes a plurality of heat dissipating fins (not shown) arranged apart from one another, and the plurality of pipes (not shown) provided to pass through the plurality of heat dissipating fins and allowing the refrigerant to flow through the pipes.
The electric component box 15 is provided above the compressor chamber 12. The electric component box 15 is provided in a space formed between an upper end of the partition board 10 and the top panel 7. The electric component box 15 is for controlling components of the air conditioner, and is arranged over the blower chamber 11 and the compressor chamber 12.
The electric component box 15 houses the control substrate 16 on which an electric component 17 is provided. The control substrate 16 includes a first substrate surface 16a and a second substrate surface 16b that is on the opposite side of the first substrate surface 16a. The first substrate surface 16a is a substrate surface on the side of the top panel 7. The second substrate surface 16b is a substrate surface on the side of the bottom panel 6. The control substrate 16 is a plate-shaped member with the first substrate surface 16a being parallel to the top panel 7. The electric component 17 is provided on the first substrate surface 16a of the control substrate 16. The electric component 17 is, for example, a semiconductor element, a reactor, or the like forming an inverter circuit that converts direct current power into alternating current power and drives at least one of the compressor 14 and the blower 13. The electric component 17 is not limited to the semiconductor element or the reactor constituting the inverter circuit and may be, for example, a semiconductor element constituting a converter circuit that converts alternating current power supplied from a commercial power source into direct current power and outputs it to an inverter circuit, a resistor for voltage detection, or a smoothing capacitor.
The heat dissipator 18-1 is in contact with the electric component 17. The heat dissipator 18-1 is a component for cooling the electric component 17. The heat dissipator 18-1 may be fixed to the electric component 17, or may be fixed to the control substrate 16 or the electric component box 15 via a fixing member (not shown). In the blower chamber 11, as illustrated in
Note that the heat dissipator 18-1 need only be arranged such that at least a part of the heat dissipator 18-1 lies in a first region R1 between the electric component box 15 and the top panel 7.
Next, a configuration of the heat dissipator 18-1 will be described with reference to
A lower surface 19a of the base 19 is in contact with the plurality of electric components 17. The plurality of fins 21 is provided on an upper surface 19b of the base 19. Each of the plurality of fins 21 is a plate-shaped member extending in the direction toward the top panel 7 of the housing 2 from the upper surface 19b of the base 19. The plurality of fins 21 is arranged apart from one another in the Z axis direction. Each of the plurality of fins 21 includes a heat dissipating surface 21a. The heat dissipating surface 21a is a surface facing the adjacent one of the fins 21. The heat dissipating surface 21a has a rectangular shape, for example. Note that the shape of the fin 21 is not limited to the rectangle as long as the fin 21 can dissipate the heat, which is transferred from the base 19 to the fin 21, to the air. The heat dissipating surface 21a is parallel to the front panel 3.
An air passage 23 through which air passes is formed in a gap between the heat dissipating surfaces 21a of the fins 21 adjacent to each other.
As illustrated in
Next, the flow of air in the heat dissipator 18-1 will be described. When the blower 13 rotates, the airflow AF is generated in the housing 2, and the air outside the housing 2 is taken into the blower chamber 11 of the housing 2 through the inlets 4a and 8a. The air taken into a second region R2 in the housing 2 through the inlet 8a flows into the air passages 23 of the heat dissipator 18-1 from the side of the windward end surface 21c of the fins 21. The second region R2 is a space within the first region R1 described above, is surrounded by the heat dissipator 18-1, the right side panel 5, the electric component box 15, the top panel 7, the front panel 3, and the back panel 8, and is also a region on the windward side of the heat dissipator 18-1. The air having flowed into the air passages 23 of the heat dissipator 18-1 in such a manner exchanges heat with the fins 21, flows out to the side of the leeward end surface 21d of the fins 21 thereafter, and is discharged to the outside of the housing 2 through the outlet 31 illustrated in
According to the outdoor unit 1-1 of the first embodiment, the second region R2 surrounded by the heat dissipator 18-1, the right side panel 5, the back panel 8, the front panel 3, the electric component box 15, and the top panel 7 is formed on the windward side of the heat dissipator 18-1, so that there is no structure in the second region R2. Accordingly, even when the pressure in the closed space described above is high, the outdoor unit 1-1 according to the first embodiment can effectively use the air flowing in the second region R2 and reduce or prevent a reduction in the amount of heat exchange in the heat dissipator 18-1 without being affected by the pressure in the closed space. Therefore, the cooling capacity of the heat dissipator 18-1 can be improved as compared to the case where the plurality of fins is arranged in the Z axis direction with a part of each of the plurality of fins lying in the aforementioned closed space, as in the heat dissipator disclosed in Patent Literature 1.
Moreover, according to the outdoor unit 1-1 of the first embodiment, the cooling efficiency of the heat dissipator 18-1 is improved so that the electric component 17 provided on the control substrate 16 is efficiently cooled. The efficient cooling of the electric component 17 can extend the life of the control substrate 16 and the electric component 17. The outdoor unit 1-1 according to the first embodiment can also extend the life of another component not in contact with the heat dissipator 18-1. For example, in a case where the other component is an electrolytic capacitor, the electrolytic capacitor is a component that is easily affected by the ambient temperature because it contains an electrolyte solution.
Being affected by the ambient temperature, the life of the electrolytic capacitor is roughly doubled when the ambient temperature drops by 10° C. The efficient cooling of the electric component 17 can prevent or reduce an increase in the ambient temperature as well. Preventing or reducing the increase in the ambient temperature can prevent or reduce the influence of heat on the other component not in contact with the heat dissipator 18-1, and can significantly extend the life thereof.
When the electric component 17 is downsized, the heat dissipation area of the electric component 17 is reduced, and the heat dissipation efficiency thereof is decreased. According to the outdoor unit 1-1 of the first embodiment, the electric component 17 is in contact with the heat dissipator 18-1 whose cooling efficiency is improved, and thus the decrease in the heat dissipation efficiency of the electric component 17 itself can be compensated for. As a result, the downsizing can be achieved while reducing heat generation of the reactor and the semiconductor element provided as the electric components 17, for example.
The deflector plate 20a is provided in a space between an end surface 211 of the fins 21 and the top panel 7. The deflector plate 20a may be fixed to the end surface 211 of the fins 21, or may be fixed to the inner surface of the top panel 7. The deflector plate 20a includes a flat surface portion 20a1 of a plate shape facing and parallel to the end surface 211 of the fins 21, and an inclined portion 20a2 provided at an end of the flat surface portion 20a1 on the windward side. The end of the flat surface portion 20a1 on the windward side coincides with an end of the flat surface portion 20a1 on the side of the second region R2. The flat surface portion 20a1 and the inclined portion 20a2 may be integrally manufactured using an insulating resin, a metal material, or the like, or may be individually manufactured and joined.
The inclined portion 20a2 functions as a first guide piece that guides the airflow AF generated in the second region R2 to the windward end surface 21c of the fins 21. The inclined portion 20a2 is a surface that is inclined at a certain angle toward the top panel 7 with respect to the Y axis direction. The certain angle is an arbitrary angle from 1° to 89°, for example. A tip of the inclined portion 20a2 may be in contact with the inner surface of the top panel 7, or may be provided at a position slightly away from the inner surface of the top panel 7.
The deflector plate 20b is provided in a space between the lower surface 19a of the base 19 and an upper surface of the electric component box 15. The deflector plate 20b may be fixed to a lower surface 19a of the base 19 or may be fixed to the upper surface of the electric component box 15. The deflector plate 20b includes a flat surface portion 20b1 of a plate shape facing and parallel to the lower surface 19a of the base 19, and the inclined portion 20b2 provided at an end of the flat surface portion 20b1 on the windward side. The end of the flat surface portion 20b1 on the windward side coincides with an end of the flat surface portion 20b1 on the side of the second region R2. The flat surface portion 20b1 and an inclined portion 20b2 may be integrally manufactured using an insulating resin, a metal material, or the like, or may be individually manufactured and joined.
The inclined portion 20b2 functions as a second guide piece that guides the airflow AF generated in the second region R2 to the windward end surface 21c of the fins 21. The inclined portion 20b2 is a surface that is inclined at a certain angle toward the electric component box 15 with respect to the Y axis direction. The certain angle is an arbitrary angle from 1° to 89°, for example. A tip of the inclined portion 20b2 may be in contact with the upper surface of the electric component box 15, or may be provided at a position slightly away from the upper surface of the electric component box 15.
According to the heat dissipator 18-2 illustrated in
Note that the heat dissipator 18-2 illustrated in
Third Embodiment.
The deflector plate 20c is provided in a space between the fins 21 and the back panel 8. The deflector plate 20c may be fixed to the fin 21, or may be fixed to the inner surface of the back panel 8. The deflector plate 20c includes a flat surface portion 20c1 of a plate shape facing and parallel to the heat dissipating surfaces 21a of the fins 21, and an inclined portion 20c2 provided at an end of the flat surface portion 20c1 on the windward side. The end of the flat surface portion 20c1 on the windward side coincides with an end of the flat surface portion 20c1 on the side of the second region R2. The flat surface portion 20c1 and the inclined portion 20c2 may be integrally manufactured using an insulating resin, a metal material, or the like, or may be individually manufactured and joined.
The inclined portion 20c2 functions as a third guide piece that guides the airflow AF generated in the second region R2 to the windward end surface 21c of the fins 21. The inclined portion 20c2 is a surface that is inclined at a certain angle toward the back panel 8 with respect to the Y axis direction. The certain angle is an arbitrary angle from 1° to 89°, for example. A tip of the inclined portion 20c2 may be in contact with the inner surface of the back panel 8, or may be provided at a position slightly away from the inner surface of the back panel 8.
The deflector plate 20d is provided in a space between the fins 21 and the front panel 3. The deflector plate 20d may be fixed to the fin 21, or may be fixed to the inner surface of the front panel 3. The deflector plate 20d includes a flat surface portion 20d1 of a plate shape facing and parallel to the heat dissipating surfaces 21a of the fins 21, and an inclined portion 20d2 provided at an end of the flat surface portion 20d1 on the windward side. The end of the flat surface portion 20d1 on the windward side coincides with an end of the flat surface portion 20d1 on the side of the second region R2. The flat surface portion 20d1 and the inclined portion 20d2 may be integrally manufactured using an insulating resin, a metal material, or the like, or may be individually manufactured and joined.
The inclined portion 20d2 functions as a fourth guide piece that guides the airflow AF generated in the second region R2 to the windward end surface 21c of the fins 21. The inclined portion 20d2 is a surface that is inclined at a certain angle toward the front panel 3 with respect to the Y axis direction. The certain angle is an arbitrary angle from 1° to 89°, for example. A tip of the inclined portion 20d2 may be in contact with the inner surface of the front panel 3, or may be provided at a position slightly away from the inner surface of the front panel 3.
According to the heat dissipator 18-3 illustrated in
Note that the heat dissipator 18-3 illustrated in
The deflector plate 20e extends from the electric component box 15 toward the inner surface of the right side panel 5, and also extends from the front panel 3 illustrated in
In the outdoor unit 1-4, the air taken in from the inlet 5a is taken into the second region R2 in the housing 2 without passing through the heat exchanger 22 illustrated in
When the first electric component 17a is a semiconductor element formed by a wide bandgap semiconductor, the wide bandgap semiconductor has higher heat resistance performance and higher switching speed than a silicon semiconductor. Therefore, the reactor, the motor, and the like can be downsized by operating the first electric component 17a at a high frequency. However, the heat generated by the wide bandgap semiconductor may have a higher value than the heat generated by the silicon semiconductor depending on the frequency, so that the first electric component 17a needs to be sufficiently cooled.
Also, when the reactor is downsized, the reactor can be provided on the control substrate 16. When the reactor is thus provided on the control substrate 16, it is necessary to reduce the influence of the heat generated by the reactor on a component existing around the reactor, and to prevent solder used for connecting a reactor terminal to the control substrate 16 from melting due to the heat generated by the reactor. Therefore, when the reactor is provided on the control substrate 16, it is necessary to sufficiently cool the reactor and to prevent or reduce an increase in the temperature of the reactor as compared to a case where the reactor is installed in a place other than the control substrate 16.
According to the heat dissipator 18-5 illustrated in
Also, in a case where an electrolytic capacitor is provided as a component not in contact with the heat dissipator 18-5, as described above, the life of the electrolytic capacitor is roughly doubled when the ambient temperature drops by 10° C. Even when such a component easily affected by the ambient temperature is used, the heat dissipator 18-5 illustrated in
Moreover, because the plurality of electric components 17 is arranged apart from one another in the Z axis direction as illustrated in
Moreover, the plurality of electric components 17 is arranged in the Z axis direction so that, as compared to a case where the plurality of electric components 17 is arranged in the Y axis direction, the heat generated by the first electric component 17a is less easily transferred to the second electric component 17b with a lower allowable temperature than the first electric component 17a even when the first electric component 17a has the highest amount of heat generated, and that it is possible to prevent the second electric component 17b from getting hot and failing.
Moreover, when the first electric component 17a, the second electric component 17b, and the third electric component 17c are arranged in the order of the first electric component 17a, the second electric component 17b, and the third electric component 17c from the windward side to the leeward side, the heat generated by the first electric component 17a and the second electric component 17b causes the temperature of a specific one of the plurality of fins 21 to be higher than the temperature of the rest of the fins 21. Therefore, the heat generated by the third electric component 17c on the leeward side is less easily absorbed by the fin. On the other hand, when the first electric component 17a, the second electric component 17b, and the third electric component 17c are arranged in the Z axis direction as illustrated in
Note that the heat dissipator 18-5 illustrated in
Moreover, the outdoor units 1-1 to 1-5 of the first to fifth embodiments can each be used as an outdoor unit of a device other than the air conditioner such as a heat pump water heater.
Furthermore, in the first embodiment, the outdoor unit 1-1 when viewed from the front is provided with the blower chamber 11 on the left side and the compressor chamber 12 on the right side, but the outdoor unit 1-1 may be provided with the compressor chamber 12 on the left side and the blower chamber 11 on the right side. In this case, the second region R2 described above is a region surrounded by the heat dissipator 18-1, the left side panel 4, the back panel 8, the front panel 3, the electric component box 15, and the top panel 7. The similar applies to the outdoor units 1-2 to 1-5 according to the second to fifth embodiments. Moreover, when the compressor chamber 12 is provided on the left side and the blower chamber 11 is provided on the right side, the inlet 5a illustrated in
The configuration illustrated in the above embodiment merely illustrates an example of the content of the present invention, and can thus be combined with another known technique or partially omitted and/or modified without departing from the scope of the present invention.
This application is a U.S. national stage application of International Application No. PCT/JP2018/032002 filed on Aug. 29, 2018, the contents of which are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2018/032002 | 8/29/2018 | WO | 00 |