JP2018138856A - Cooling and air blowing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cooling and air blowing apparatus having a simple configuration while securing thermal insulation performance thereof.SOLUTION: An air blowing unit 3 of a cooling and air blowing apparatus 1 comprises a first fan 36 for blowing air having passed through an evaporator, and a second fan 37 for blowing air having passed through a condenser. The air blowing unit 3 further comprises a motor 35 having a rotary shaft 35a to which the first fan 36 and the second fan 37 are connected. The air blowing unit 3 has a bracket fixed to the motor 35 and a casing 10, the bracket having a first bracket 33 being one of two halves into which it is divided in the direction intersecting with the axial direction of the motor 35 and a second bracket 34 being the other. The air blowing unit 3 also includes a casing 30 housing the first fan 36 and the second fan 37 and fixed to the bracket. The casing 30 is formed of a foamable resin and has a first casing 31 being one of two halves into which it is divided in a vertical direction DV and a second casing 32 being the other.SELECTED DRAWING: Figure 8

Description

  The disclosure in this specification relates to a cooling fan.

  Patent Document 1 discloses a cooling apparatus in which an evaporator, a condenser, a compressor, a blower, and the like are accommodated in an exterior body. The blower device includes a plurality of fan cases, a plurality of blower fans each composed of a sirocco fan housed in each of these fan cases, a single motor that drives these blower fans, It is configured as a unit using a lower connector, and is assembled so that it can be taken in and out of the heat exchange chamber from the upper surface opening portion of the exterior body with the top plate removed. Further, both ends of the upper connector and the lower connector are attached to the fan case, and the motor is sandwiched between the fan cases in this state.

Japanese Patent Laid-Open No. 5-240459

  In the air blower in the air conditioner of Patent Literature 1, condensation occurs when the air that has passed through the evaporator passes through the inside of the air blower. For this reason, it is necessary to ensure the heat insulation performance of the blower. Moreover, in patent document 1, since the fan case which accommodates one ventilation fan and the fan case which accommodates another ventilation fan are connected and unitized, a number of parts increases and a structure becomes complicated.

  The disclosed object is to provide a cooling fan having a simple configuration while ensuring heat insulation performance.

  A plurality of aspects disclosed in this specification adopt different technical means to achieve each purpose. In addition, the reference numerals in the parentheses described in the claims and in this section are examples showing the correspondence with the specific means described in the embodiments described later as one aspect, and limit the technical scope. is not.

  One of the disclosed cooling blowers has an evaporator (21), a condenser (24), a compressor (23), and a blower (3) in a housing (10), and passed through the evaporator. It is a cooling blower that blows air to the outside by a blower, and the blower blows air that has passed through an evaporator, and a second fan that blows air that has passed through a condenser ( 37), and a motor (35) having a shaft portion (35a) having a first fan connected to one end side and a second fan connected to the other end side, and rotationally driving the first fan and the second fan; A bracket integrally coupled to the motor and fixed to the housing, the first bracket (33) being one of the two divided in the direction intersecting the axial direction of the motor and the first being the other Brackets (33, 34) having two brackets (34) And a first casing that accommodates the first fan and the second fan and is fixed to the bracket, the casing being formed of a foamable resin and divided into two in a direction crossing the axial direction ( 31) and a casing (30) having a second casing (32) which is the other.

  According to this disclosure, since the first casing and the second casing are formed of the foamable resin, they have heat insulation properties. Further, the first fan, the second fan, the motor, and the bracket can be integrally accommodated by the first casing and the second casing that are divided in a direction that intersects the axial direction of the motor. Therefore, the blower can be configured simply. As described above, it is possible to provide a cooling fan having a simple configuration while ensuring heat insulation performance.

It is a front perspective view of the cooling air blower concerning a 1st embodiment. It is a back perspective view of the cooling air blower concerning a 1st embodiment. It is a side view of the cooling air blower concerning a 1st embodiment. It is a rear view of the cooling air blower concerning a 1st embodiment. It is a rear view of the state which removed the back plate of the cooling air blower of a 1st embodiment. It is a perspective view which shows the state which removed the upper surface board of the cooling air blower of 1st Embodiment. It is a perspective view which shows a ventilation unit. It is a disassembled perspective view of a ventilation unit. It is a figure which shows the 1st casing of a ventilation unit. It is a figure which shows the 2nd casing of a ventilation unit. It is sectional drawing which shows fitting with the XI-XI cross section of FIG. 9, and the XI-XI cross section of FIG. It is sectional drawing which shows fitting with the XII-XII cross section of FIG. 9, and the XII-XII cross section of FIG. It is a disassembled perspective view which shows a mode that a fan, a motor, and a bracket are accommodated in a casing.

(First embodiment)
The cooling air blower of 1st Embodiment is demonstrated with reference to FIGS. In each figure, the vertical direction VD, the width direction WD, and the depth direction DD of the cooling fan 1 are illustrated. The vertical direction VD is a direction substantially coincident with the vertical direction when the cooling blower 1 is installed on the floor or the ground. The width direction WD and the depth direction DD are directions perpendicular to the vertical direction VD. The width direction WD and the depth direction DD are directions perpendicular to each other.

  The cooling air blower 1 is a so-called spot cooler that provides local cooling by blowing cooling air to a person, an object, or the like to be cooled. The cooling air blower 1 is used in a state where it is placed on the floor surface or ground of the place where it is used. The cooling air blower 1 can be easily moved by the user using the wheel unit 70. The cooling air blower 1 is a spot cooler that can provide cooling at a user's desired location. As shown in FIG. 2, the cooling blower 1 includes a plurality of refrigeration cycle functional components for providing a refrigeration cycle, a blower unit 3 that blows air cooled by the refrigeration cycle as cooling air, and a plurality of refrigeration cycles. And a housing 10 for housing the functional parts and the blower unit 3.

  The housing 10 is a substantially rectangular parallelepiped box that is long in the vertical direction VD, for example. As shown in FIGS. 1 to 5, the housing 10 includes two side plates 12 and 13 having exterior surfaces parallel to the vertical direction VD and the depth direction DD, and an exterior surface parallel to the vertical direction VD and the width direction WD. And a back plate 14 having. The side plate 12 and the side plate 13 are a pair of metal plate members facing each other in the width direction WD. The side plate 12 has a bent portion 12a bent inward at the upper end. Similar to the side plate 12, the side plate 13 has a bent portion 13 a that is bent inward at the upper end. The bent portions 12a and 13a are each bent at a substantially right angle with respect to the exterior surface. The housing | casing 10 has the suction part 16 in the surface on the opposite side in the backplate 14 and the depth direction DD. The suction portion 16 is a portion that passes when external air is sucked into the housing 10. The suction part 16 is provided by a filter that captures foreign matters such as dust and dirt. The upper surface of the housing 10 is covered with an upper surface plate 11. The lower surface of the housing 10 is covered with a base portion 15.

  The upper surface plate 11 is formed of, for example, a metal plate member. The top plate 11 is provided with two openings through which air sucked into the housing 10 is blown out. One of the two openings is a first opening through which air that has passed through the evaporator 21 is blown out. For example, a duct 40 is connected to the first opening. Therefore, the air that has passed through the first opening passes through the inside of the duct 40 and is blown out to the outside. The duct 40 is configured, for example, in a bellows shape, and its blowing direction can be freely changed. The duct 40 may have a swing mechanism that can automatically and periodically change the blowing direction. A plurality of first openings and ducts may be provided. The other of the two openings is the second opening 11b through which the air that has passed through the condenser 24 is blown out. The 2nd opening part 11b is a discharge port for releasing the waste heat which generate | occur | produced in the refrigerating cycle unit to the exterior.

  The refrigeration cycle unit has a plurality of refrigeration cycle functional parts. The plurality of refrigeration cycle functional components are, for example, an evaporator 21, a condenser 24, a compressor 23, an accumulator 22, a capillary tube, and the like. The plurality of refrigeration cycle functional components are connected in an annular shape by piping, so that the refrigerant can circulate.

  The evaporator 21 is provided adjacent to the suction portion 16 in the depth direction DD, and is disposed so that air immediately after passing through the suction portion 16 can pass therethrough. The air that has passed through the upper portion of the suction portion 16 passes through the evaporator 21. The condenser 24 is arranged side by side with the evaporator 21 in the vertical direction VD. The condenser 24 is provided below the evaporator 21. The condenser 24 and the evaporator 21 are provided side by side in the vertical direction VD in a direction in which the thickness direction coincides with the depth direction DD. The condenser 24 and the evaporator 21 are accommodated in the housing 10 adjacent to the suction part 16. Air sucked from the lower portion of the suction portion 16 passes through the condenser 24. The compressor 23 is fixed to the base portion 15. The accumulator 22 is provided fixed to the compressor 23.

  The tank 60 is a storage unit that stores water generated by condensation in the evaporator 21. The tank 60 is made of, for example, resin. The tank 60 is formed in a box shape. The tank 60 is placed on the base portion 15 and accommodated in the cooling air blower 1. The tank 60 is accommodated in an accommodation space defined by the partition portion 17 and the base portion 15. The tank 60 has a gripping portion 62 for the user to grip. The tank 60 can be easily taken out of the storage space or stored in the storage space by the user. The tank 60 is taken out of the storage space from the tank take-out opening 19. The tank 60 is accommodated in the accommodating space from the tank outlet opening 19. The tank take-out opening 19 is formed by the front end of the base 15 and the partition 17 in the depth direction DD. Here, the near side is the near side when the suction part 16 is viewed from the front in the cooling blower 1.

  The base portion 15 is formed of, for example, a metal plate member. A plurality of wheel portions 70 are attached to the lower surface of the base portion 15. The wheel unit 70 is a member that the user moves by pushing or pulling the cooling air blower 1, and is a so-called caster. A compressor 23 is attached to the base portion 15. A tank 60 is placed on the base portion 15. The base portion 15 is provided with a tank receiving portion that receives the tank 60. The tank receiving part is a plate-like metal member that extends in the depth direction DD in a state where it is installed in the base part 15, for example. The tank receiving portion is installed on the base portion in a state where one end portion is in contact with the base portion and the other end portion is lifted by the spring member so as to be separated from the base portion 15. The tank receiving portion rotates downward with one end portion as an axis by the load of the tank 60. The tank receiving portion rotates so that the other end portion is positioned further downward as the load of the tank 60 increases. The elastic modulus of the spring member is adjusted so that the tank receiving portion turns on the switch device by the load of the tank 60 when a predetermined amount of water is stored in the tank 60. When the switch of the switch device is turned on, the electric circuit for informing the notification unit is energized. The notification unit performs notification using visual information such as lamp lighting or auditory information such as a buzzer.

  As shown in FIG. 8, the blower unit 3 includes two fans for blowing air by rotational driving, a motor 35 for rotationally driving the two fans, a casing 30 for housing the two fans, a motor 35 and the casing 30. There is a bracket for fixing to the housing. The blower unit 3 is provided adjacent to the top plate 11. The blower unit 3 is a blower for sucking air from the suction part 16 and blowing it out. One of the two fans is a first fan 36 that blows air passing through the evaporator 21. The blower unit 3 blows air cooled by passing through the evaporator 21 as cooling air. The other of the two fans is a second fan 37 that blows air passing through the condenser 24. The first fan 36 and the second fan 37 are provided by, for example, a centrifugal multiblade fan. Alternatively, it may be provided by an axial fan, a diagonal fan, or the like. The first fan 36 and the second fan 37 are provided in the casing 30 so that their axial directions are substantially aligned with the depth direction DD and are aligned in the depth direction DD, for example. The first fan 36 is provided closer to the suction portion 16 than the second fan 37 in the depth direction DD. The second fan 37 is provided closer to the back plate 14 than the first fan 36 in the depth direction DD.

  The motor 35 includes a rotating shaft 35a, a rotor that holds the rotating shaft 35a, and a cylindrical motor case 35b that houses the rotor. The motor case 35b has a flange portion 35c projecting radially outward on the outer peripheral surface. The motor 35 is a double-axis motor capable of transmitting rotational motion to the outside from both ends of the rotary shaft 35a. The motor 35 has a first fan 36 attached to one end side of the rotating shaft 35a and a second fan 37 attached to the other end side. The rotating shaft 35a corresponds to a shaft portion in the claims. The motor 35 is provided in the housing 10 so that the axial direction of the rotation shaft 35a substantially coincides with the depth direction DD.

  As shown in FIG. 7, the casing 30 includes a first fan housing portion 30 a, a second fan housing portion 30 c, and a connection portion 30 b that connects the first fan housing portion 30 a and the second fan housing portion 30 c. . The first fan 36 is accommodated in the first fan accommodating portion 30a. A second fan 37 is accommodated in the second fan accommodating portion 30c. The connecting portion 30b is formed to extend in the depth direction DD so as to connect between the first fan accommodating portion 30a and the second fan accommodating portion 30c.

  For example, a plurality of connection portions 30b are provided. For example, one connection portion 30 b is provided in the first casing 31 and two connection portions 30 b are provided in the second casing 32. The connection part 30b provided in the 1st casing 31 has a dimension smaller than a 1st fan accommodating part and a 2nd fan accommodating part in the width direction WD, for example. The connection portion 30b provided in the first casing 31 is provided at the upper portion in the vertical direction at the approximate center in the width direction WD of the first casing 31. The connection portion 30 b provided in the first casing 31 is fitted with a notch portion formed at the center in the width direction WD at the upper end of the first bracket 33. Two connection portions 30b provided in the second casing 32 are provided one by one on the one end side and the other end side in the width direction WD of the second casing 32. A motor 35 is disposed between the first fan housing portion 30a and the second fan housing portion 30c. The three connection portions 30 b are formed at positions that do not interfere with the motor 35.

  The casing 30 includes a first suction port 300a that sucks air into the first fan housing portion 30a and a second suction port 300c that sucks air into the second fan housing portion 30c. The first suction port 300 a is an opening formed on the front surface of the casing 30 in the depth direction DD. The first suction port 300 a is provided adjacent to the evaporator 21, and can suck the air that has passed through the evaporator 21. The casing 30 has a ridge 30d formed around the first suction port 300a so as to protrude from the surface on which the first suction port 300a is formed. The protrusion 30d is provided so that the end thereof is closer to the evaporator 21 than the surface on which the first suction port 300a is formed. The ridge portion 30d is a frame that suppresses the air that has passed through the evaporator 21 from flowing to the second suction port 300c.

  The second suction port 300c is an opening formed on the surface of the second fan housing portion 30c on the side close to the first fan housing portion 30a in the depth direction DD. In other words, both the first fan housing portion 30a and the second fan housing portion 30c suck in so that air is directed from the near side to the far side in the depth direction DD. The second suction port sucks in air that has passed through the condenser 24.

  The casing 30 includes a first air outlet 310 that blows out air blown by the first fan 36 and a second air outlet 311 that blows out air blown by the second fan 37. The first air outlet 310 communicates with the first opening of the upper surface plate 11. The second air outlet 311 communicates with the second opening 11 b of the upper surface plate 11.

  The casing 30 has a structure divided into two in the vertical direction. The first casing 31 is an upper part of the casing 30 which is divided into two. The second casing 32 is a lower part of the casing 30 which is divided into two. The casing 30 is integrated by fitting the first casing 31 and the second casing 32 with each other. The casing 30 is substantially equally divided in the vertical direction and is divided into a first casing 31 and a second casing 32. The first casing 31 and the second casing 32 face each other so as to sandwich the motor 35 from the direction intersecting the axial direction. The first casing 31 and the second casing 32 are one side and the other side where the casing 30 is divided into two in the direction intersecting the axial direction of the motor 35. The casing 30 is formed of a foamable resin that is a synthetic resin that is foam-molded so that bubbles are dispersed therein. For this reason, the casing 30 has a configuration in which the occurrence of condensation is relatively suppressed by the heat insulating property of the foamable resin. Moreover, the casing 30 is comprised comparatively lightweight by being formed with a foamable resin.

  The first casing 31 has a first air outlet 310 through which air blown by the first fan 36 blows out. The first air outlet 310 is formed in a part of the first casing 31 that constitutes the first fan accommodating portion 30a. The 1st blower outlet 310 is an opening formed in the surface of the upper part of the 1st casing 31, so that air blows off upwards from the inside of the casing 30, for example. The first air outlet 310 communicates with the first opening of the upper surface plate 11. The air blown out from the first air outlet 310 passes through the first opening and is blown out from the duct 40 to a person or object to be cooled. The first casing 31 has a second outlet 311 through which the air blown by the second fan 37 blows out. The second air outlet 311 is formed in a part of the first casing 31 that constitutes the second fan accommodating portion 30c. The second blower outlet 311 is an opening formed on the upper surface of the first casing 31 so that air blows upward from the inside of the casing 30, for example, similarly to the first blower outlet 310. The second air outlet 311 communicates with the second opening 11 b of the upper surface plate 11. The air blown out from the second outlet 311 passes through the second opening 11b and is blown out of the housing 10.

  As shown in FIG. 9, the first casing 31 has a first fitting portion 315 that fits with the second casing 32 at a portion constituting the second fan accommodating portion 30 c of the casing 30. The 1st fitting part 315 is formed in the wall part facing in the depth direction DD the wall part in which the part of 2nd inlet 300c in the part which comprises the 2nd fan accommodating part 30c was formed. In the first fitting portion 315, a plurality of convex portions 315a and a plurality of concave portions 315b are alternately arranged in two rows. That is, in the first fitting portion 315, two rows in which the convex portions 315a and the concave portions 315b are alternately arranged in the width direction are formed adjacent to each other in the thickness direction of the wall portion. The arrangement of the convex portions 315a and the concave portions 315b in one row is alternated with the arrangement of the convex portions 315a and the concave portions 315b in the other row. The convex portion 315a corresponds to the first convex portion in the claims, and the concave portion 315b corresponds to the first concave portion in the claims.

  The second casing 32 is an integrally molded product with the second bracket 34. For example, the second casing 32 is integrally formed with the metal second bracket 34 by insert molding. As shown in FIG. 10, the second casing 32 includes a second fitting portion 325 that fits with the first fitting portion 315 of the first casing 31 at a portion constituting the second fan accommodating portion 30 c of the casing 30. Have. In the second fitting portion 325, a plurality of convex portions 325 a and a plurality of concave portions 325 b are arranged in two rows alternately like the first fitting portion 315. In other words, in the second fitting portion 325, the rows of the convex portions 325a and the concave portions 325b alternately arranged in the width direction WD form part of the second suction port 300c in the portion constituting the second fan accommodating portion 30c. Two rows are formed adjacent to the thickness direction of the wall portion facing the wall portion in the depth direction DD. The arrangement of the convex portions 325a and the concave portions 325b in one row is alternated with the arrangement of the convex portions 325a and the concave portions 325b in the other row. Furthermore, the convex part 325a of the 2nd fitting part 325 is provided so that the recessed part 315b by the side of the 1st fitting part 315 may be fitted. The concave portion 325b of the second fitting portion 325 is provided so as to be fitted to the convex portion 315a on the first fitting portion 315 side.

  That is, as shown in FIG. 11, the fitting portion between the first fitting portion 315 and the second fitting portion 325 has a concave portion 315b and a second fitting portion inside the second fan housing portion 30c. The convex part 325a of the fitting part 325 is fitted, and the convex part 315a of the first fitting part 315 and the concave part 325b of the second fitting part are fitted outside the first fan housing part 30a. . Furthermore, as shown in FIG. 12, the fitting portion between the first fitting portion 315 and the second fitting portion 325 is formed on the inner side of the second fan housing portion 30c with the convex portion 315a of the first fitting portion 315 and the second fitting portion 325. 2 is engaged with the recess 325b of the fitting portion 325, and is adjacent to the recess 325b in the depth direction DD, and on the outside of the second fan housing portion 30c, the recess 315b of the first fitting portion 315 and the protrusion of the second fitting portion 325 The part 325a is fitted. The convex portion 325a corresponds to the second convex portion in the claims, and the concave portion 325b corresponds to the second concave portion in the claims.

  Due to the fitting of the first fitting portion 315 and the second fitting portion 325, the wall portion of the second fan housing portion 30c facing the wall portion in which the second suction port 300c is formed in the depth direction DD is blown. It is possible to effectively suppress leakage of air. For example, compared with the case of the convex part which continued over the whole width direction WD, and the case of the fitting by a continuous recessed part, the fitting with the 1st fitting part 315 and the 2nd fitting part 325 is a convex part and a recessed part. Since these are arranged alternately, the size of the gap due to distortion or the like is easily suppressed.

  The bracket is fixed to the flange portion 35 c of the motor 35. The bracket is fixed to the casing 30. The bracket is fixed to the housing 10. The bracket is a member for fixing the motor 35 to the housing 10 and the casing 30. The bracket includes a first bracket 33 that is an upper part divided into two in the vertical direction and a second bracket 34 that is a lower part divided into two in the vertical direction. The first bracket 33 and the second bracket 34 are made of, for example, a metal plate material.

  The first bracket 33 is fixed to the upper portion of the flange portion 35 c of the motor 35 and is integrally coupled to the motor 35. The first bracket 33 is fixed to the flange portion 35c by a fastener such as a screw. The first bracket 33 has a plate-like portion 330 that extends parallel to the width direction WD and the vertical direction VD. The first bracket 33 has an upper end bent portion 33 a that is bent with respect to the plate portion 330 at the upper end of the plate portion 330. The upper end bent portion 33 a is bent at a substantially right angle with respect to the plate-like portion 330. Therefore, the upper end bent portion 33a is a plate-like portion that extends parallel to the width direction WD and the depth direction DD. As shown in FIG. 6, the upper end bent portion 33 a is fixed to the bent portions 12 a and 13 a of the two side plates 12 and 13 at the end in the width direction WD. The upper end bent portion 33a is fixed in a state where it is placed on the upper surfaces of the bent portions 12a and 13a. The upper end bent portion 33a is fixed to the bent portions 12a and 13a by a fastener such as a screw, for example. The upper end bent portion 33a is fixed at the center of the side plates 12 and 13 in the depth direction DD. Accordingly, the first bracket 33 bridges the center of the pair of side plates 12 and 13 in the depth direction DD. The upper end bent portion 33a corresponds to the upper fixed portion in the claims.

  The first bracket 33 has side end bent portions 33 b that are bent with respect to the plate-like portion 330 at both ends in the width direction WD of the plate-like portion 330. The side end bent portion 33 b is bent at a substantially right angle with respect to the plate-like portion 330. Therefore, the side end bent portion 33b is a plate-like portion extending in parallel to the depth direction DD and the vertical direction VD. The side end bent portion 33b is fixed to the inner surfaces of the two side plates 12, 13 as shown in FIG. The side end bent portion 33b is fixed by a fastener such as a screw. In FIG. 6, only the side end bent portion 33b on the side plate 13 side is shown in a transparent manner. The side end bent portion 33b corresponds to the side surface fixing portion in the claims.

  The first bracket 33 has a lower end bent portion 33 c that is bent with respect to the plate portion 330 at the lower end of the plate portion 330. The lower end bent portion 33 c is bent at a substantially right angle with respect to the plate-like portion 330. Therefore, the lower end bent portion 33c is a plate-like portion extending in parallel with the width direction WD and the depth direction DD. The lower end bent portion 33c is fixed to the second bracket 34 by a fastener such as a screw.

  The second bracket 34 is fixed to the lower portion of the flange portion 35 c of the motor 35 and is integrally coupled to the motor 35. The second bracket 34 is fixed to the flange portion 35c by a fastener such as a screw. The second bracket 34 has a plate-like portion 340 that extends parallel to the width direction WD and the vertical direction VD. The second bracket 34 has an upper end bent portion 34 a that is bent with respect to the plate-like portion 340 at the upper end of the plate-like portion 340. The upper end bent portion 34a is bent at a substantially right angle with respect to the plate-like portion 340. Therefore, the upper end bent portion 34a is a plate-like portion extending in parallel with the width direction WD and the depth direction DD. The upper end bent portion 34 a is fixed to the lower end bent portion 33 c in a state where the upper surface thereof is in contact with the lower surface of the lower end bent portion 33 c of the first bracket 33. The second bracket 34 is integrally formed with the second casing 32 and is fixed to the second casing 32.

  The blower unit 3 is assembled by the following processes, for example. That is, as shown in FIG. 13, the first casing 31, the integrally molded product of the second bracket 34 and the second casing 32, and two fans 36 and 37 are attached to both ends of the rotating shaft 35 a and the flange portion 35 c is attached. A motor 35 to which the first bracket 33 is fixed is prepared. Next, the upper end bent portion 34 a of the second bracket 34 and the lower end bent portion 33 c of the first bracket 33 are fixed. Next, the first casing 31 is fitted and attached to the second casing 32 in a state where the lower portion of the motor 35 is accommodated. As described above, the blower unit 3 can be assembled. The assembled blower unit 3 is attached to the housing 10 by fixing the first bracket 33 to the bent portions 12 a and 13 a and the inner surfaces of the side plates 12 and 13.

  Next, the effect which the cooling air blower 1 of 1st Embodiment brings is demonstrated. The cooling air blower 1 according to the first embodiment includes an evaporator 21, a condenser 24, a compressor 23, and a blower unit 3 in a housing 10, and air that has passed through the evaporator 21 is sent to the outside by the blower unit 3. Blow. The blower unit 3 includes a first fan 36 that blows air that has passed through the evaporator 21, and a second fan 37 that blows air that has passed through the condenser 24. The blower unit 3 includes a rotating shaft 35 a having a first fan 36 connected to one end side and a second fan 37 connected to the other end side, and a motor 35 that rotationally drives the first fan 36 and the second fan 37. Is provided. The blower unit 3 is a bracket that is integrally coupled to the motor 35 and fixed to the housing 10, and is a first bracket 33 that is one of the two divided in a direction intersecting the axial direction of the motor 35. And a bracket having a second bracket 34 which is the other. The blower unit 3 includes a casing 30 that houses the first fan 36 and the second fan 37 and is fixed to the bracket. The casing 30 is formed of a foamable resin, and includes a first casing 31 that is one of two divided in a direction intersecting the axial direction of the motor 35 and a second casing 32 that is the other.

  According to this, the first fan 36, the second fan 37, the motor 35, and the bracket are integrally accommodated by the first casing 31 and the second casing 32 that are divided in the direction intersecting the axial direction of the motor 35. be able to. Thereby, the air blower of a simple structure can be provided. Moreover, since the casing 30 is formed of foamable resin, the heat insulation of the blower can be ensured. As described above, it is possible to provide the cooling fan 1 having a simple configuration while ensuring the heat insulating performance.

  The housing 10 includes a pair of side plates 12 and 13 that face each other in the width direction WD. The first bracket 33 is a member that bridges the center of the pair of side plates 12 and 13 to the center in the depth direction DD, and is fixed to the upper end of each of the pair of side plates 12 and 13 in a state where it is fixed. It has a portion 33a. According to this, the blower unit 3 can be fixed by being suspended from the upper end of the side plate 12 by the upper end bent portion 33 a of the first bracket 33. Therefore, the blower unit 3 can be more stably fixed to the housing 10.

  The first bracket 33 has side end bent portions 33 b that are fixed to the inner surfaces of the side plates 12 and 13. According to this, since the 1st bracket can be fixed also in the side of a side board, fan unit 3 can be fixed to case 10 more stably.

  The second bracket 34 is integrally formed with the second casing 32. According to this, since the 2nd bracket 34 and the 2nd casing 32 can be provided as an integral molded article, the assembly man-hour of the ventilation unit 3 can be reduced.

  The motor 35 has a rotor that holds the rotating shaft 35a and a cylindrical motor case that houses the rotor, and the motor case has a flange portion 35c that protrudes radially outward on the outer peripheral surface. The first bracket 33 and the second bracket 34 are respectively fixed to the flange portion 35c in a state where the motor 35 is sandwiched from above and below and are integrally coupled to the motor 35.

  According to this, when the motor 35 is assembled to the first bracket 33 and the second bracket 34, the motor 35 can be assembled in the vertical direction VD. Therefore, in the assembly of the blower unit 3, the first casing 31, the second casing 32, the first bracket 33, the second bracket 34, and the motor 35 can be assembled in the same assembly direction. Thereby, the ventilation unit 3 can be assembled more easily.

  The casing 30 includes a first fan accommodating portion 30 a that accommodates the first fan 36 and a second fan accommodating portion 30 c that accommodates the second fan 37. The 1st casing 31 has the 1st fitting part 315 which is a part which fits with the 2nd casing 32 in the 2nd fan accommodating part 30c, and the 2nd casing 32 is the 1st fitting in the 2nd fan accommodating part 30c. It has the 2nd fitting part 325 fitted to the joint part 315. FIG. The first fitting portion 315 has a plurality of convex portions 315a and a plurality of concave portions 315b arranged alternately in two rows. The second fitting portion 325 has a plurality of convex portions 325a and a plurality of concave portions 325b arranged in two rows alternately. The convex portion 315a is fitted with the concave portion 325b, and the concave portion 315b is fitted with the convex portion 325a.

  According to this, since the first casing 31 and the second casing 32 can be alternately fitted by the convex portions and the concave portions, the blown air is prevented from leaking from the fitting portion to the outside of the casing 30. can do. For example, even when distortion occurs in the fitted portion, it is possible to suppress an increase in the gap between the first fitting portion and the second fitting portion due to the distortion.

(Other embodiments)
The disclosure of this specification is not limited to the illustrated embodiments. The disclosure encompasses the illustrated embodiments and variations by those skilled in the art based thereon. For example, the disclosure is not limited to the combination of components and elements shown in the embodiments, and various modifications can be made. The disclosure can be implemented in various combinations. The disclosure may have additional parts that can be added to the embodiments. The disclosure includes those in which the components and elements of the embodiment are omitted. The disclosure encompasses parts, element replacements, or combinations between one embodiment and another. The technical scope disclosed is not limited to the description of the embodiments. Some technical scope disclosed is indicated by the description of the claims, and should be understood to include all modifications within the meaning and scope equivalent to the description of the claims. .

  In the above-described embodiment, the second bracket 34 is integrally formed with the second casing 32. Instead, the second bracket 34 and the second casing 32 may be formed as separate parts and fixed by a fixing tool such as a screw.

  In the above-described embodiment, the first bracket 33 is fixed to the housing 10. However, the second bracket 34 may be fixed to the housing 10.

  In the above-described embodiment, the cooling blower 1 is configured so that the user can easily move the wheel unit 70 to a desired place. Instead of this, the cooling air blower may be a so-called stationary device that does not have the wheel portion 70.

    DESCRIPTION OF SYMBOLS 10 Housing | casing, 12, 13 Side plate, 21 Evaporator, 23 Compressor, 24 Condenser, 3 Blower unit (blower device), 30 Casing, 30a 1st fan accommodating part, 30c 2nd fan accommodating part, 31 1st Casing, 315 first fitting portion, 315a convex portion (first convex portion), 315b concave portion (first concave portion), 32 second casing, 325 second fitting portion, 325a convex portion (second convex portion), 325b Recessed portion (second recessed portion), 33, 34 bracket, 33 first bracket, 33a upper end bent portion (upper fixing portion), 33b side end bent portion (side fixing portion), 34 second bracket, 35 motor, 35a rotating shaft ( Shaft portion), 35b motor case, 35c flange portion, 36 first fan, 37 second fan.

Claims (6)

The housing (10) has an evaporator (21), a condenser (24), a compressor (23), and a blower (3), and the air that has passed through the evaporator is blown to the outside by the blower. A cooling air blower,
The blower is
A first fan (36) for blowing air that has passed through the evaporator;
A second fan (37) for blowing air that has passed through the condenser;
A motor (35) having a shaft portion (35a) connected to one end side of the first fan and connected to the other end side of the first fan, and rotating the first fan and the second fan; ,
A first bracket (33) which is integrally coupled to the motor and is fixed to the housing, and is divided into two in a direction intersecting the axial direction of the motor; A bracket (33, 34) having a second bracket (34);
A casing that houses the first fan and the second fan and is fixed to the bracket, and is a first one that is formed of a foamable resin and divided into two in a direction intersecting the axial direction. A cooling air blower provided with a casing (30) which has a casing (31) and the 2nd casing (32) which is the other. The housing has a pair of side plates (12, 13) facing in the width direction,
The first bracket is
In the pair of side plates, a member that bridges the center in the depth direction that is perpendicular to the width direction and perpendicular to the vertical direction,
The cooling air blower according to claim 1, further comprising an upper fixing portion (33a) fixed in a state of being placed on the upper ends of the pair of side plates. The housing has a pair of side plates (12, 13) facing in the width direction,
The cooling fan according to claim 1 or 2, wherein the first bracket has a side surface fixing portion (33b) fixed to the inner surface of the side surface plate.   The cooling blower according to any one of claims 1 to 3, wherein the second bracket is formed integrally with the second casing. The motor has a rotor that holds a shaft portion, and a cylindrical motor case (35b) that houses the rotor,
The motor case has a flange portion (35c) projecting radially outward on the outer peripheral surface,
The said 1st bracket and the 2nd bracket are each fixed to the said flange part in the state which pinched | interposed the said motor from the upper direction and the downward direction, and are integrally couple | bonded with the said motor. The cooling air blower described in 1. The casing includes a first fan accommodating portion (30a) that accommodates the first fan, and a second fan accommodating portion (30c) that accommodates the second fan,
The first casing has a first fitting portion (315) that is a portion fitted to the second casing in the second fan housing portion,
The second casing has a second fitting portion (325) that fits with the first fitting portion in the second fan housing portion,
The first fitting portion has a plurality of first convex portions (315a) and a plurality of first concave portions (315b) arranged in two rows alternately,
The second fitting portion has a plurality of second convex portions (325a) arranged alternately in two rows, and a plurality of second concave portions (325b),
The cooling air blower according to any one of claims 1 to 5, wherein the first convex portion is fitted to the second concave portion, and the first concave portion is fitted to the second convex portion.