JP2008096018A - Outdoor unit of air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To elongate a service life of an electric heater while reducing its cost by improving a layout structure of the electric heater in an outdoor unit of an air conditioner. <P>SOLUTION: A bulging portion 40 is formed on a bottom plate 25 of the outdoor unit. The bulging portion 40 is formed by making a part of the bottom plate 25 bulge upward. The bulging portion 40 has the long ridge shape extending along four sides of a rectangle shape. The electric heater 50 is disposed on the bulging portion 40. As the drainage and the like drops down under the bulging portion 40, the electric heater 50 is prevented from being dipped in the water for a long time. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an installation structure of an electric heater in an outdoor unit of an air conditioner.

  Conventionally, a separate type air conditioner is known. In this type of air conditioner, an outdoor unit installed outdoors and an indoor unit installed indoors are connected to each other by a communication pipe.

  The outdoor unit is provided with a heat exchanger for exchanging heat between the outside air and the refrigerant. During the heating operation, the outdoor unit heat exchanger serves as an evaporator. Therefore, in this heat exchanger, moisture in the outside air condenses to become drain water, or moisture in the outside air becomes frost and adheres to the heat exchanger. The drain water generated by the heat exchanger of the outdoor unit accumulates on the bottom plate of the outdoor unit. For this reason, there is a possibility that drain water accumulated on the bottom plate freezes in winter when the outside air temperature is below freezing. In addition, since the outdoor unit is installed outdoors, snow may enter the outdoor unit and accumulate on the bottom plate in a cold region in winter. If ice blocks grow or snow falls in the outdoor unit, the ice or snow may come into contact with the fan, making it impossible to operate the air conditioner.

For this problem, for example, as disclosed in Patent Document 1, a measure is taken to attach an electric heater to the bottom plate of the outdoor unit. Specifically, the bottom plate of the outdoor unit is heated with an electric heater to prevent the drain water from freezing on the bottom plate and snow from accumulating on the bottom plate.
JP 2004-069220 A

  In the outdoor unit described in Patent Document 1, an electric heater is mounted on a flat bottom plate. And until the water produced | generated by melting snow etc. with an electric heater is discharged | emitted from an outdoor unit, an electric heater will be in the state immersed in water. That is, the electric heater is immersed in water for a long time.

  On the other hand, an electric heater generally has a structure in which a heating element is accommodated in a metal tube, or a structure in which the heating element is covered with resin, rubber, or the like. And if the electric heater of such a structure is exposed to the state wet with water for a long time, it will become easy to advance corrosion of a metal pipe, and deterioration of coating | cover. For this reason, the conventional outdoor unit has a problem that the life of the electric heater cannot be sufficiently secured. In addition, although it is conceivable that the electric heater is made of a material having high corrosion resistance, this increases the manufacturing cost of the electric heater.

  The present invention has been made in view of such a point, and an object thereof is to extend the life of the electric heater while suppressing the cost by improving the arrangement structure of the electric heater in the outdoor unit of the air conditioner. is there.

  The first invention includes a heat exchanger (31), a fan (32), a casing (20) that houses the heat exchanger (31) and the fan (32), and a bottom plate (25) of the casing (20). It is intended for an outdoor unit of an air conditioner installed outdoors with an electric heater (50) for heating. And the bottom plate (25) of the casing (20) is formed with a bulging portion (40) bulging upward and a through hole (28) for draining through the bottom plate (25), The electric heater (50) is installed on the bulging portion (40).

  In the first invention, when the electric heater (50) is energized, the bottom plate (25) of the casing (20) is heated by the generated Joule heat. For this reason, the drain water falling on the bottom plate (25) is kept in a liquid state, and the snow that has entered the casing (20) comes into contact with the bottom plate (25) and melts. In this invention, the electric heater (50) is installed on the bulging part (40). The liquid water existing on the bottom plate (25) collects in a portion lower than the upper surface of the bulging portion (40) and flows out through the through hole (28). For this reason, the electric heater (50) is not immersed in water.

  In a second aspect based on the first aspect, the electric heater (50) extends along the upper surface of the bulging portion (40) and extends over the entire length of the upper surface of the bulging portion (40). A heat transfer section (52) in contact therewith is provided.

  In the second invention, the heat transfer section (52) of the electric heater (50) is in contact with the upper surface of the bulging section (40) over its entire length. For this reason, heat transfer from the heat transfer section (52) of the electric heater (50) to the bottom plate (25) of the casing (20) is reliably performed.

  In a third aspect based on the second aspect, the bulging portion (40) is formed in a bowl shape extending along the heat transfer portion (52) of the electric heater (50).

  In 3rd invention, an electric heater (50) is installed on the bulging part (40) formed in bowl shape. Part of the snow that has entered the casing (20) comes into contact with the upper surfaces of the electric heater (50) and the bulging portion (40) and melts. The water in the liquid state generated at that time immediately flows down from the upper surface of the bulging portion (40).

  In a fourth aspect based on the third aspect, the bulging portion (40) has a mountain shape in cross section.

  In the fourth invention, the bulging portion (40) has a shape with almost no horizontal portion on its upper surface. The water adhering to the upper portion of the electric heater (50) and the bulging portion (40) flows down along the slope constituting the bulging portion (40) without staying in the vicinity of the electric heater (50).

  In a fifth aspect based on the fourth aspect, the heat transfer portion (52) of the electric heater (50) is in contact with one upper end portion of two slopes constituting the bulging portion (40). Is.

  In a sixth aspect based on the fourth aspect, the heat transfer section (52) of the electric heater (50) is formed on the through hole (28) side of two slopes constituting the bulge section (40). It is in contact with the upper end of the direction facing.

  In the fifth and sixth inventions, the heat transfer section (52) of the electric heater (50) is in contact with the inclined surface constituting the bulging section (40). For this reason, compared with the case where the electric heater (50) contacts the top part of the bulging part (40), the electric heater (50) is supported in a stable state by the bulging part (40). Moreover, in these invention, the heat-transfer part (52) of an electric heater (50) contacts the upper end part of the slope which comprises a bulging part (40). For this reason, almost all of the water adhering to the upper portions of the electric heater (50) and the bulging portion (40) flows down along the slope of the bulging portion (40).

  In the sixth aspect of the invention, the heat transfer portion (52) of the electric heater (50) is in contact with the slope of the bulging portion (40) toward the through hole (28). For this reason, the water that has flowed down from the vicinity of the electric heater (50) along the slope of the bulging portion (40) is quickly discharged through the through hole (28).

  The seventh invention includes a heat exchanger (31), a fan (32), a casing (20) that houses the heat exchanger (31) and the fan (32), and a bottom plate (25) of the casing (20). An outdoor unit of an air conditioner that is installed outdoors with an electric heater (50) for heating And the said electric heater (50) is arrange | positioned so that the lower surface of the bottom plate (25) of the said casing (20) may be contact | connected.

  In the seventh invention, when the electric heater (50) is energized, the bottom plate (25) of the casing (20) is heated by the generated Joule heat. For this reason, the drain water falling on the bottom plate (25) is kept in a liquid state, and the snow that has entered the casing (20) comes into contact with the bottom plate (25) and melts. In the present invention, the electric heater (50) is disposed so as to contact the lower surface of the bottom plate (25) of the casing (20). That is, the electric heater (50) is installed outside the casing (20). On the other hand, in the casing (20), liquid water is collected on the bottom plate (25). Therefore, the electric heater (50) in contact with the lower surface of the bottom plate (25) does not come into contact with water on the bottom plate (25).

  In an eighth aspect based on the seventh aspect, a recess (41) for embedding the electric heater (50) is formed on the lower surface of the bottom plate (25).

  In the eighth invention, the electric heater (50) is embedded in the recess (41) formed in the lower surface of the bottom plate (25) of the casing (20). That is, the electric heater (50) is installed in a state where there is no portion that protrudes from the lower surface of the casing (20) or only a portion thereof protrudes from the lower surface of the casing (20).

  In a ninth aspect based on the seventh aspect, the electric heater (50) extends along the lower surface of the bottom plate (25) and is in contact with the lower surface of the bottom plate (25) over the entire length. (52).

  In 9th invention, the heat-transfer part (52) of an electric heater (50) contact | connects the lower surface of the part which forms a recessed part (41) among bottom plates (25) over the full length. For this reason, heat transfer from the heat transfer section (52) of the electric heater (50) to the bottom plate (25) of the casing (20) is reliably performed.

  In a tenth aspect based on the ninth aspect, both end portions of the electric heater (50) are formed so as to extend through the bottom plate (25) upward.

  In the tenth invention, both end portions of the electric heater (50) extend through the bottom plate (25) of the casing (20) into the casing (20).

  The eleventh invention comprises a heat exchanger (31), a fan (32), a casing (20) that houses the heat exchanger (31) and the fan (32), and a bottom plate (25) of the casing (20). An outdoor unit of an air conditioner that is installed outdoors with an electric heater (50) for heating A concave groove (43) for fitting the electric heater (50) is formed on the upper surface of the bottom plate (25) of the casing (20), and the bottom plate (25) And a through hole (28) communicating with the concave groove (43) is formed. In the concave groove (43), the bottom and the electric heater (50) fitted in the concave groove (43) are formed. A gap (44) is formed between the two.

  In the eleventh invention, when the electric heater (50) is energized, the bottom plate (25) of the casing (20) is heated by the generated Joule heat. For this reason, the drain water falling on the bottom plate (25) is kept in a liquid state, and the snow that has entered the casing (20) comes into contact with the bottom plate (25) and melts. In this invention, the liquid water accumulated on the bottom plate (25) of the casing (20) also enters the gap (44) formed between the bottom of the concave groove (43) and the electric heater (50). To do. The water that has entered the gap (44) is quickly discharged to the outside of the casing (20) through the through hole (28).

  In a twelfth aspect based on the first aspect, the concave groove (43) is formed so as to gradually become deeper as it approaches the through hole (28).

  In the twelfth invention, the concave groove (43) is deeper as it is closer to the through hole (28). Water flowing into the gap (44) between the bottom of the groove (43) and the electric heater (50) flows to the through hole (28) through the bottom of the inclined groove (43) and penetrates. It is discharged through the hole (28).

  In a thirteenth aspect based on the eleventh aspect, the electric heater (50) extends along the concave groove (43) and contacts the bottom plate (25) over the entire length (52). Is provided.

  In the thirteenth aspect, the heat transfer section (52) of the electric heater (50) is in contact with the portion of the bottom plate (25) where the concave groove (43) is formed over its entire length. For this reason, heat transfer from the heat transfer section (52) of the electric heater (50) to the bottom plate (25) of the casing (20) is reliably performed.

  In the said 1st invention, the electric heater (50) is installed on the bulging part (40) formed in the baseplate (25). For this reason, the liquid water existing around the electric heater (50) and its surroundings quickly flows downward from the bulging portion (40), and the electric heater (50) remains in the water for a long time. It will never be immersed.

  Moreover, in the said 7th invention, the electric heater (50) is installed in the lower surface of the bottom plate (25) of a casing (20). That is, the electric heater (50) is attached at a position where it does not come into contact with water accumulated on the bottom plate (25). For this reason, the electric heater (50) is not immersed in water.

  In the eleventh aspect of the invention, the electric heater (50) is fitted in the concave groove (43) formed in the upper surface of the casing (20), and the gap between the bottom of the concave groove (43) and the electric heater (50) Water will invade (44), but this water is quickly discharged from the groove (43) through the through hole (28). For this reason, the electric heater (50) is not in a state of being immersed in water for a long time.

  Thus, according to the present invention, it is possible to avoid a situation in which the electric heater (50) continues to be immersed in water for a long time. For this reason, corrosion and deterioration of the electric heater (50) can be suppressed without taking measures such as making the material of the electric heater (50) highly corrosion resistant. Therefore, according to the present invention, the life of the electric heater (50) can be extended while suppressing the cost of the electric heater (50).

  According to the second, ninth, and thirteenth inventions, the heat transfer section (52) of the electric heater (50) is brought into contact with the bottom plate (25) of the casing (20) over the entire length thereof. Therefore, heat transfer from the heat transfer section (52) to the bottom plate (25) can be reliably performed, and the power consumption of the electric heater (50) can be minimized.

  In the said 3rd invention, the bulging part (40) by which an electric heater (50) is installed on it is formed in bowl shape (namely, elongate shape). For this reason, the amount of water remaining on the bulging portion (40) can be reduced, and the progress of corrosion and deterioration of the electric heater (50) can be surely delayed.

  In the fourth aspect of the invention, since the cross-sectional shape of the bulging portion (40) is mountain-shaped, there is almost no horizontal portion on the upper surface of the bulging portion (40). Therefore, according to the present invention, the amount of water remaining on the bulging portion (40) can be minimized, and the progress of corrosion and deterioration of the electric heater (50) can be more reliably delayed. .

  In the fifth and sixth inventions, the electric heater (50) is in contact with the inclined surface constituting the bulging portion (40). For this reason, the electric heater (50) can be stably installed on the bulging portion (40), and the reliability of the outdoor unit (10) can be improved. In particular, in the sixth aspect of the invention, since the electric heater (50) is in contact with the slope of the bulging portion (40) facing the through hole (28), the electric heater (50) flows down from the vicinity of the electric heater (50). Water can be reliably drained from the through hole (28), and the amount of water remaining in the vicinity of the electric heater (50) can be reduced more reliably.

  In the eighth aspect of the invention, the electric heater (50) is embedded in the recess (41) formed in the lower surface of the bottom plate (25) of the casing (20). The electric heater (50) does not jump out from the lower surface of the casing (20) at all, or only a part of the electric heater (50) protrudes from the lower surface of the casing (20). For this reason, when installing the outdoor unit (10) or the like, it is possible to avoid a situation where the electric heater (50) hits something and breaks it, and the reliability of the outdoor unit (10) can be ensured.

  In the tenth invention, the heat transfer section (52) of the electric heater (50) is installed outside the casing (20), while both ends of the electric heater (50) are the bottom plate (25) of the casing (20). And extends into the casing (20). For this reason, the wiring for supplying electric power to the electric heater (50) can be stored in the casing (20), and the possibility of troubles such as disconnection of the wiring can be reduced.

  In the twelfth aspect of the invention, the bottom of the concave groove (43) is inclined toward the through hole (28). For this reason, water that has entered the gap (44) formed between the bottom of the concave groove (43) and the electric heater (50) flows in the direction of the through hole (28) and passes through the through hole (28). Then it is discharged from the gap (44). Therefore, according to the present invention, water can be more reliably discharged from the gap (44) in the groove (43), and corrosion and deterioration of the electric heater (50) can be more reliably suppressed.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1 of the Invention
A first embodiment of the present invention will be described.

  As shown in FIG. 1, the outdoor unit (10) of this embodiment is provided with a rectangular parallelepiped casing (20). On the front surface of the casing (20), a blowing grill (21) is attached at a position slightly to the left. This outdoor unit (10) is installed outdoors and constitutes a separate type air conditioner together with an indoor unit installed indoors.

  As shown in FIGS. 2 and 3, components such as a heat exchanger (31), a fan (32), and a compressor (33) are accommodated in the casing (20) of the outdoor unit (10). . The heat exchanger (31) is formed in a thick plate shape bent in an L shape, and is placed on the bottom plate (25) of the casing (20) in a posture along the back and left sides of the casing (20). Has been. The fan (32) is disposed on the front side of the heat exchanger (31). The compressor (33) is disposed on the right side in the casing (20), and is placed on the bottom plate (25) of the casing (20).

  As shown in FIGS. 4, 5, and 6, the bottom plate (25) of the casing (20) is a metal member formed on the tray. The bottom plate (25) includes a rectangular plate-shaped main body (26) and an edge (27) extending upward from the peripheral edge of the main body (26). Note that the right back side in FIG. 4 and the upper side in FIG. 5A are the back side of the casing (20), respectively. On the bottom plate (25), the heat exchanger (31) is disposed along the edge (27) on the back side and the left side.

  A bulging portion (40) is formed in the main body (26) of the bottom plate (25). The bulging part (40) is formed by bulging a part of the main body part (26) upward. The shape of the bulging portion (40) is a long and narrow bowl extending along four rectangular sides along the longitudinal direction of the bottom plate (25). The bulging portion (40) has a trapezoidal cross-sectional shape and a flat upper surface.

  An electric heater (50) is placed on the bulging portion (40). The electric heater (50) is a sheath heater configured by housing a heating element in an outer cylinder (51) made of a metal circular tube. The electric heater (50) includes a C-shaped heat transfer portion (52) extending along the extending direction of the bulge portion (40), and a rising extending upward from each end of the heat transfer portion (52). Part (53).

  The electric heater (50) is installed in a state in which the divided part of the heat transfer part (52) formed in a C-shape is positioned approximately at the center of the long side part of the bulging part (40). Further, the heat transfer section (52) of the electric heater (50) is in contact with the upper surface of the bulging section (40) over the entire length thereof. Although not shown, a lead wire for power feeding is connected to the tip of each rising portion (53) of the electric heater (50). Although not shown in the figure, a belt-like metal band is attached to the heat transfer section (52) of the electric heater (50) so as to cross it. The electric heater (50) is fixed to the bottom plate (25) by fastening screws inserted into both ends of the metal band to the bottom plate (25).

  Two drain holes (28) are formed in the main body (26) of the bottom plate (25). One of these two drain holes (28) is disposed on the inner side surrounded by the bulging portion (40), and the other is disposed on the outer side of the bulging portion (40). It penetrates the main body (26). As shown in FIG. 4 and FIG. 5 (A), these two drain holes (28) are formed slightly to the left of the center in the left-right direction when the bottom plate (25) is viewed from the front. Moreover, the drain hole (28) arrange | positioned on the outer side of the bulging part (40) is formed near the back surface of the bottom plate (25) rather than the bulging part (40).

  Here, in a state where the air conditioner performs heating operation in winter, the heat exchanger (31) of the outdoor unit (10) functions as an evaporator. For this reason, in the heat exchanger (31) of the outdoor unit (10), water vapor in the air condenses to become drain water, and this drain water flows down onto the bottom plate (25). Moreover, in the state in which the refrigerant | coolant evaporation temperature in a heat exchanger (31) is less than 0 degreeC, the water vapor | steam in air adheres to a heat exchanger (31) as frost. When the defrost operation is performed to melt the frost attached to the heat exchanger (31), the melted frost flows as drain water and flows down onto the bottom plate (25). Further, snow may fall into the casing (20) during snowfall.

  Therefore, in the severe winter season when the outside air temperature is below freezing point, the electric heater (50) is energized in the outdoor unit (10) of the present embodiment. When the electric heater (50) is energized, Joule heat is generated and the bottom plate (25) of the casing (20) is warmed. For this reason, the drain water that has flowed down from the heat exchanger (31) to the bottom plate (25) is kept in a liquid state without solidifying and flows out of the casing (20) through the drain hole (28). go. In addition, the snow that has fallen into the casing (20) melts by touching the bottom plate (25) and flows out of the casing (20) through the drain hole (28) in the same way as drain water. go.

  At that time, snow that has entered the casing (20) may adhere to the electric heater (50) and melt, and in such a case, the electric heater (50) gets wet with water. On the other hand, the electric heater (50) of the present embodiment is disposed on the bulging portion (40) that is one step higher than the surroundings. For this reason, the liquid water existing near the upper surface of the electric heater (50) and the bulging portion (40) flows down along the slope of the bulging portion (40), and from around the electric heater (50). Immediately eliminated.

-Effect of Embodiment 1-
As described above, in the outdoor unit (10) of the present embodiment, water is quickly removed from the electric heater (50) and its surroundings, so that the electric heater (50) continues to be immersed in water for a long time. There is no. Here, since the outer cylinder (51) of the electric heater (50) is made of metal, corrosion tends to proceed at a portion of the electric heater (50) that is in contact with the metal bottom plate (25). On the other hand, according to the present embodiment, it is possible to prevent the contact portion between the electric heater (50) and the bottom plate (25) from getting wet for a long time. Therefore, according to the present embodiment, the corrosion of the electric heater (50) can be suppressed without taking measures such as making the material of the electric heater (50) highly corrosion-resistant. The life of the electric heater (50) can be extended while keeping costs down.

  Moreover, in the outdoor unit (10) of this embodiment, the heat-transfer part (52) which occupies most electric heaters (50) is contacting the upper surface of the bulging part (40) over the full length. For this reason, the Joule heat generated in the electric heater (50) can be reliably transmitted to the bottom plate (25), and the power consumption of the electric heater (50) can be minimized.

  Moreover, in the outdoor unit (10) of this embodiment, since the bulging part (40) of the bottom plate (25) is formed in a bowl shape, the area of the upper surface of the bulging part (40) can be minimized. . That is, since the upper surface of the bulging portion (40) is a flat surface, there is a possibility that some water may remain, but according to the present embodiment, the area of the portion where water may remain is minimized. By suppressing the amount of water, the amount of water present around the electric heater (50) can be minimized. Therefore, according to the present embodiment, the progress of corrosion of the electric heater (50) can be more reliably delayed.

-Modification 1 of Embodiment 1-
In the present embodiment, as shown in FIG. 7, the bulging portion (40) may be formed by bulging the entire rectangular region of the main body (26) of the bottom plate (25) in a plateau shape. . In the case of this modification, the heat transfer part (52) of the electric heater (50) extends along the periphery of the bulging part (40).

-Modification 2 of Embodiment 1
In the present embodiment, as shown in FIG. 8, the bulging portion (40) may be formed so that the cross-sectional shape thereof is a mountain shape.

  The bulging part (40) of this modification is comprised by the outer side slope part (61) located in the outer peripheral side, and the inner side slope part (62) located in the inner peripheral side. That is, the bulging portion (40) has a shape with almost no horizontal surface at the top.

  In the bulging portion (40), the slope on the back side of the bottom plate (25) is gentler than the slope on the front side of the bottom plate (25). As described above, the bulging portion (40) has a long and narrow shape extending along four rectangular sides along the longitudinal direction of the bottom plate (25). That is, in this bulging portion (40), one long side portion (63, 64) along the longitudinal direction of the bottom plate (25) is formed on the front side and the back side of the bottom plate (25).

  Specifically, in the front side long side part (63) located on the front side of the bottom plate (25), the slope of the inner slope part (62) is gentler than the slope of the outer slope part (61). On the other hand, in the back side long side part (64) located on the back side of the bottom plate (25), the slope of the outer slope part (61) is gentler than the slope of the inner slope part (62). Thus, in the bulging part (40), the slope of the slope part on the back side of the bottom plate (25) (that is, the slope part facing the drain hole (28) side) among the long side parts (63, 64). Has become moderate. Moreover, although not shown in figure, in a pair of short side part along the transversal direction of a baseplate (25) among bulging parts (40), the inclination of an outer slope part (61) is compared with the inclination of an inner slope part in each. It has become moderate.

  In this modification, the heat transfer part (52) of the electric heater (50) has an upper end with a gentler inclination between the outer slope part (61) and the inner slope part (62) constituting the bulge part (40). Is in contact with the department. That is, the heat transfer part (52) of the electric heater (50) is connected to the upper end part of the inner slope part (62) and the bulge part (40) at the front long side part (63) of the bulge part (40). The back side long side part (64) is in contact with the upper end part of the outer slope part (61). As described above, the electric heater (50) of the present modified example has the long side portions (63, 64) of the inclined portion on the back side of the bottom plate (25) (that is, the inclined portion facing the drain hole (28) side). ).

  In this modification, since the cross-sectional shape of the bulging portion (40) is mountain-shaped, there is almost no horizontal portion on the upper surface of the bulging portion (40). In particular, in this modification, the electric heater (50) is brought into contact with the upper end portion of the slope portions (61, 62) constituting the bulging portion (40). Therefore, according to this modification, the amount of water remaining on the bulging portion (40) can be minimized, and the progress of corrosion and deterioration of the electric heater (50) can be more reliably delayed. it can.

  Moreover, in this modification, an electric heater (50) contacts the slope part (61, 62) which comprises a bulging part (40). For this reason, compared with the case where the electric heater (50) contacts the top part of the bulging part (40), the electric heater (50) is supported in a stable state by the bulging part (40). Therefore, according to this modification, the electric heater (50) can be stably installed on the bulging portion (40), and the reliability of the outdoor unit (10) can be improved.

  Moreover, in this modification, the electric heater (50) is made to contact the slope part (61, 62) of the bulging part (40) toward the drain hole (28) side. For this reason, the water which flowed down from the vicinity of the electric heater (50) can be surely drained from the drain hole (28), and the amount of water staying in the vicinity of the electric heater (50) can be further reliably reduced.

  In this modification, the cross-sectional shape of the bulging portion (40) is a mountain shape, but the cross-sectional shape of the bulging portion (40) is not limited to the mountain shape, and for example, the cross-section of the bulging portion (40) The shape may be a semicircular arc. Also in this case, there is almost no horizontal surface at the top of the bulging portion (40), and the amount of water remaining on the bulging portion (40) can be minimized.

-Modification 3 of Embodiment 1-
In the present embodiment, the heat transfer section (52) of the electric heater (50) does not necessarily have to be in contact with the upper surface of the bulging section (40) over the entire length thereof. That is, for example, a part of the heat transfer section (52) may be separated from the upper surface of the bulge section (40).

<< Embodiment 2 of the Invention >>
A second embodiment of the present invention will be described. In the present embodiment, in the outdoor unit (10) of the first embodiment, the structure of the bottom plate (25) of the casing (20) and the arrangement of the electric heater (50) are changed. Here, about the outdoor unit (10) of this embodiment, a different point from the said Embodiment 1 is demonstrated.

  As shown in FIGS. 9, 10, and 11, a recess (41) that is recessed upward is formed on the lower surface of the main body (26) of the bottom plate (25). The shape of the recess (41) is a long and narrow groove extending along four rectangular sides along the longitudinal direction of the bottom plate (25). Moreover, the cross-sectional shape of this recessed part (41) is the shape and magnitude | size which the heat-transfer part (52) of an electric heater (50) completely embeds. Specifically, the cross section of the recess (41) is formed in a semicircular arc shape having a radius of curvature equal to or greater than the diameter of the heat transfer section (52) of the electric heater (50). The depth of the recess (41) is also equal to or greater than the diameter of the heat transfer section (52).

  The bottom plate (25) has two drain holes (28) and two insertion holes (42). One of the two drain holes (28) is disposed on the inner side surrounded by the recess (41), and the other is disposed on the outer side of the recess (41). ). The two insertion holes (42) are formed at positions overlapping the recesses (41), and each penetrates the main body (26) of the bottom plate (25). Specifically, the two insertion holes (42) are arranged in a portion extending along one long side of the recess (41) extending along the four sides of the rectangle. Further, one of the two insertion holes (42) is opened slightly to the right of the center of the long side, and the other is opened slightly to the left of the center of the long side. The interval between the two insertion holes (42) is a length corresponding to the interval between the rising portions (53) of the electric heater (50).

  The electric heater (50) is fitted into the recess (41) from below the bottom plate (25). That is, the electric heater (50) is attached to the outside of the casing (20) of the outdoor unit (10). In this state, the entire heat transfer portion (52) of the electric heater (50) is embedded in the recess (41), and the bottom surface (that is, the bottom plate (25) of the recess (41) extends over its entire length. The lower surface of The rising portion (53) of the electric heater (50) extends to the internal space of the casing (20) through the insertion hole (42).

  As shown in FIG. 12, the electric heater (50) is fixed to the bottom plate (25) by a support plate (45) and screws (46). The support plate (45) is a rectangular plate-shaped piece. One support plate (45) is installed at the center of each short side of the recess (41) extending along the four sides of the rectangle. Each support plate (45) is arranged so as to cross the recess (41), and each support plate (45) is fixed to the main body (26) of the bottom plate (25) by two screws (46). The support plate (45) supports the heat transfer section (52) of the electric heater (50) from below and presses the heat transfer section (52) against the bottom plate (25).

  In the outdoor unit (10) of the present embodiment, when the electric heater (50) is energized, Joule heat generated in the electric heater (50) is transmitted to the bottom plate (25) and the bottom plate (25) is warmed. The drain water that has flowed down from the heat exchanger (31) during the heating operation and the liquid water that is generated by melting the snow that has entered the casing (20) are not frozen on the bottom plate (25). It flows out of the casing (20) through the hole (28). On the other hand, the electric heater (50) of the present embodiment is installed on the lower surface side of the bottom plate (25). For this reason, the electric heater (50) is kept almost dry.

-Effect of Embodiment 2-
In this embodiment, since the electric heater (50) is disposed on the lower surface side of the bottom plate (25) of the casing (20), the electric heater (50) is wetted by liquid water existing on the bottom plate (25). Can be surely prevented. Therefore, according to this embodiment, corrosion of the electric heater (50) can be suppressed, and the life of the electric heater (50) can be extended.

  Moreover, in this embodiment, the heat-transfer part (52) of the electric heater (50) is completely buried in the recessed part (41) formed in the lower surface of the bottom plate (25) of the casing (20). That is, the heat transfer section (52) of the electric heater (50) is entirely in the recess (41), and does not protrude at all from the lower surface of the casing (20). Therefore, according to the present embodiment, it is possible to avoid a situation in which the electric heater (50) is struck by anything and damaged when the outdoor unit (10) is installed, and the reliability of the outdoor unit (10) is ensured. Can do.

  Moreover, in this embodiment, while the heat-transfer part (52) of an electric heater (50) is installed in the outer side of a casing (20), both ends of an electric heater (50) are bottom plates (25) of a casing (20). And extends into the casing (20). For this reason, the wiring for supplying electric power to the electric heater (50) can be stored in the casing (20), and the possibility of troubles such as disconnection of the wiring can be reduced.

-Modification of Embodiment 2-
In the present embodiment, the heat transfer section (52) of the electric heater (50) does not necessarily need to be in contact with the bottom surface of the recess (41) (that is, the bottom surface of the bottom plate (25)) over the entire length. That is, for example, a part of the heat transfer section (52) may be separated from the bottom surface of the recess (41).

<< Embodiment 3 of the Invention >>
Embodiment 3 of the present invention will be described. In the present embodiment, in the outdoor unit (10) of the first embodiment, the structure of the bottom plate (25) of the casing (20) and the arrangement of the electric heater (50) are changed. Here, about the outdoor unit (10) of this embodiment, a different point from the said Embodiment 1 is demonstrated.

  As shown in FIGS. 13, 14, and 15, a concave groove (43) that is recessed downward is formed on the upper surface of the main body (26) of the bottom plate (25). The concave groove (43) has long sides extending along four rectangular sides along the longitudinal direction of the bottom plate (25). The width of the opening of the concave groove (43) is narrower than the diameter of the heat transfer section (52) of the electric heater (50). Moreover, the depth of the concave groove (43) is longer than the height of the portion of the heat transfer section (52) of the electric heater (50) that enters the concave groove (43). Furthermore, the depth of the concave groove (43) is substantially constant over its entire length.

  The bottom plate (25) has only one drain hole (28) that is a through hole. The drain hole (28) is formed in a portion overlapping the concave groove (43), and penetrates the main body (26) of the bottom plate (25). Specifically, the drain hole (28) opens at the center of one long side of the concave groove (43) extending along the four sides of the rectangle. That is, the drain hole (28) opens at a position where the groove (43) is divided in the middle.

  The electric heater (50) is installed on the bottom plate (25) such that the heat transfer section (52) covers the opening of the concave groove (43). The heat transfer section (52) is in contact with the upper surface of the groove (43) (that is, the upper surface of the bottom plate (25)) over the entire length thereof. Further, the electric heater (50) has a posture in which a divided portion of the heat transfer section (52) formed in a C-shape is positioned on the long side where the drain hole (28) is formed in the concave groove (43). It is installed at.

  As described above, the width of the opening of the concave groove (43) is narrower than the diameter of the heat transfer section (52). For this reason, as shown in FIG. 15, the heat-transfer part (52) of an electric heater (50) contact | abuts to the edge part of the inner peripheral side of a ditch | groove (43), and the edge part of an outer peripheral side. Further, the concave groove (43) is deeper than the height of the portion of the heat transfer section (52) of the electric heater (50) that enters the concave groove (43). For this reason, as shown in FIG. 15, a gap (44) is formed between the bottom of the groove (43) and the heat transfer section (52) of the electric heater (50). Hereinafter, this gap is referred to as a bottom gap (44). The bottom gap (44) formed in the concave groove (43) communicates with the drain hole (28).

  In the outdoor unit (10) of the present embodiment, when the electric heater (50) is energized, Joule heat generated in the electric heater (50) is transmitted to the bottom plate (25) and the bottom plate (25) is warmed. The drain water that has flowed down from the heat exchanger (31) during the heating operation and the liquid water that is generated by melting the snow that has entered the casing (20) are not frozen on the bottom plate (25). It flows out of the casing (20) through the hole (28). At that time, the liquid water present on the bottom plate (25). It also flows into the bottom gap (44) formed in the concave groove (43). The bottom gap (44) communicates with the drain hole (28). Therefore, the water that has entered the bottom gap (44) flows out of the casing (20) through the drain hole (28).

-Effect of Embodiment 3-
In this embodiment, the heat transfer part (52) of the electric heater (50) is arranged so as to close the opening of the groove (43) formed in the bottom plate (25), and the heat transfer part (52) and the groove A bottom gap (44) is formed between the bottom of (43) and the bottom gap (44) communicates with the drain hole (28). For this reason, the liquid water flowing into the bottom gap (44) can be quickly discharged from the drain hole (28), and the electric heater (50) is prevented from getting wet for a long time. it can. Therefore, according to this embodiment, corrosion of the electric heater (50) can be suppressed, and the life of the electric heater (50) can be extended.

  Moreover, in this embodiment, the width | variety of the opening part of a ditch | groove (43) is narrower than the diameter of the heat-transfer part (52) of an electric heater (50), and this heat-transfer part (52) is a ditch | groove ( 43) abuts on both the inner and outer edges. Here, when the tubular heat transfer section (52) is placed on the flat surface of the bottom plate (25), only the lower end of the heat transfer section (52) (that is, only one location) contacts the bottom plate (25). . On the other hand, in this embodiment, the heat transfer section (52) contacts the bottom plate (25) at both the inner peripheral edge and the outer peripheral edge (that is, two locations) of the groove (43). Therefore, according to the present embodiment, the contact area between the heat transfer section (52) of the electric heater (50) and the bottom plate (25) can be increased. As a result, the Joule heat generated in the electric heater (50) can be more reliably transmitted to the bottom plate (25), and the power consumption of the electric heater (50) can be kept low.

-Modification 1 of Embodiment 3
In the third embodiment, the depth of the groove (43) may be gradually changed.

  As shown in FIG. 16, in the bottom plate (25) of this modification, two drain holes (28) are formed at overlapping positions. Specifically, in the bottom plate (25), one drain hole (28) is opened in the long side portion (65) which is a portion extending along the long side of the bottom plate (25) in the concave groove (43). is doing. In each long side part (65), the drain hole (28) is formed near the center of the extending direction of the long side part (65).

  The long side part (65) of the concave groove (43) gradually becomes deeper as the depth approaches the drain hole (28). That is, in FIG. 16, the portion of the long side portion (65) located on the right side of the drain hole (28) gradually becomes deeper from the right side to the left side, while the long side portion (65) has a drain hole. The part located on the left side of (28) is gradually deeper from the left side to the right side.

  Thus, in this modification, the bottom part of the ditch | groove (43) inclines toward the drain hole (28). For this reason, the water that has entered the bottom gap (44) formed between the bottom of the concave groove (43) and the electric heater (50) flows in the direction of the drain hole (28), and the drain hole (28 ) Through the bottom gap (44). Therefore, according to this modification, water can be more reliably discharged from the bottom gap (44) in the concave groove (43), and corrosion and deterioration of the electric heater (50) can be more reliably suppressed.

  In this modification, the depth of the portion of the concave groove (43) along the short direction of the bottom plate (25) may be changed. For example, with respect to the portion of the concave groove (43) along the short direction of the bottom plate (25), the portion on the back side of the bottom plate (25) is directed toward the back surface of the bottom plate (25) rather than the central portion in the extending direction. It is good also as a shape which makes it the shape which becomes deeper gradually, and makes the part of the front side of a baseplate (25) gradually deeper toward the front of a baseplate (25) rather than the center part of the expansion | extension direction.

-Modification 2 of Embodiment 3
In the present embodiment, the heat transfer section (52) of the electric heater (50) does not necessarily need to be in contact with the upper surface of the concave groove (43) (that is, the upper surface of the bottom plate (25)) over the entire length thereof. That is, for example, a part of the heat transfer section (52) may be separated from the upper surface of the groove (43).

<< Other Embodiments >>
In each of the above embodiments, a sheath heater is used as the electric heater (50). However, the electric heater (50) is not limited to the sheath heater. For example, a silicon heater configured by covering a heating element with silicon rubber may be used as the electric heater (50) of each of the above embodiments.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for an outdoor unit of an air conditioner including an electric heater for heating a bottom plate of a casing.

It is a front view of an outdoor unit. It is a front view of the outdoor unit which abbreviate | omitted a part of casing. It is a top view of the outdoor unit which abbreviate | omitted a part of casing. It is a perspective view which shows the bottom plate and electric heater of Embodiment 1 seen from diagonally upward. (A) is a top view which shows the baseplate and electric heater of Embodiment 1, (B) is a front view which shows the baseplate and electric heater of Embodiment 1. FIG. It is sectional drawing which shows the AA cross section in FIG. It is the perspective view which shows the baseplate and electric heater of the modification 1 of Embodiment 1 seen from diagonally upward. FIG. 7 is a view corresponding to FIG. 6 illustrating a bottom plate and an electric heater according to Modification 2 of Embodiment 1. It is a perspective view which shows the bottom plate and electric heater of Embodiment 2 seen from diagonally downward. (A) is a front view which shows the baseplate and electric heater of Embodiment 2, (B) is a bottom view which shows the baseplate and electric heater of Embodiment 1. FIG. It is sectional drawing which shows the BB cross section in FIG. It is sectional drawing which shows CC cross section in FIG. It is a perspective view which shows the baseplate and electric heater of Embodiment 3 seen from diagonally upward. (A) is a top view which shows the baseplate and electric heater of Embodiment 3, (B) is a front view which shows the baseplate and electric heater of Embodiment 3. FIG. It is sectional drawing which shows the DD cross section in FIG. (A) is a top view which shows the baseplate and electric heater of the modification of Embodiment 3, (B) is a front view which shows the baseplate and electric heater of the modification of Embodiment 3.

Explanation of symbols

20 casing
25 Bottom plate
28 Drain hole (through hole)
31 Heat exchanger
32 fans
40 bulge
41 recess
43 groove
50 Electric heater
52 Heat transfer section

Claims (13)

A heat exchanger (31), a fan (32), a casing (20) that houses the heat exchanger (31) and the fan (32), and electricity for heating the bottom plate (25) of the casing (20) An outdoor unit of an air conditioner installed outdoors with a heater (50),
The bottom plate (25) of the casing (20) is formed with a bulging portion (40) that bulges upward, and a through hole (28) for draining through the bottom plate (25),
The outdoor unit of an air conditioner, wherein the electric heater (50) is installed on the bulging portion (40). In claim 1,
The electric heater (50) includes a heat transfer portion (52) extending along the upper surface of the bulging portion (40) and in contact with the upper surface of the bulging portion (40) over the entire length. A featured outdoor unit for air conditioners. In claim 2,
The outdoor unit of an air conditioner, wherein the bulging part (40) is formed in a bowl shape extending along the heat transfer part (52) of the electric heater (50). In claim 3,
The bulging portion (40) is an outdoor unit of an air conditioner characterized in that its cross-sectional shape is a mountain shape. In claim 4,
The outdoor unit of an air conditioner, wherein the heat transfer section (52) of the electric heater (50) is in contact with one upper end portion of two slopes constituting the bulging section (40). In claim 4,
The heat transfer section (52) of the electric heater (50) is in contact with the upper end of the two inclined surfaces constituting the bulging section (40) facing the through hole (28). Air conditioner outdoor unit. A heat exchanger (31), a fan (32), a casing (20) that houses the heat exchanger (31) and the fan (32), and electricity for heating the bottom plate (25) of the casing (20) An outdoor unit of an air conditioner installed outdoors with a heater (50),
The outdoor unit of an air conditioner, wherein the electric heater (50) is disposed so as to be in contact with a lower surface of a bottom plate (25) of the casing (20). In claim 7,
An outdoor unit for an air conditioner, wherein a recess (41) for embedding the electric heater (50) is formed on the lower surface of the bottom plate (25). In claim 7,
The air heater characterized in that the electric heater (50) includes a heat transfer section (52) extending along the lower surface of the bottom plate (25) and in contact with the lower surface of the bottom plate (25) over the entire length. The outdoor unit of the machine. In claim 9,
Both ends of the electric heater (50) are formed so as to extend upward through the bottom plate (25), respectively. A heat exchanger (31), a fan (32), a casing (20) that houses the heat exchanger (31) and the fan (32), and electricity for heating the bottom plate (25) of the casing (20) An outdoor unit of an air conditioner installed outdoors with a heater (50),
On the top surface of the bottom plate (25) of the casing (20), a concave groove (43) for fitting the electric heater (50) is formed,
The bottom plate (25) is formed with a through hole (28) that penetrates the bottom plate (25) and communicates with the concave groove (43).
The outdoor unit of an air conditioner, wherein a gap (44) is formed between the bottom of the concave groove (43) and the electric heater (50) fitted in the concave groove (43). In claim 11,
The outdoor unit of an air conditioner, wherein the concave groove (43) is formed so as to gradually become deeper as it approaches the through hole (28). In claim 11,
The electric heater (50) includes a heat transfer section (52) extending along the concave groove (43) and in contact with the bottom plate (25) over the entire length. unit.

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