JP2018119751A - Heat exchanger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat exchanger which utilizes airflow generated by driving a fan to air-cool an inverter device and a motor.SOLUTION: A fan device 1 includes: a fan 5 connected with a motor 7; an inverter control part 51 which controls operation of the motor 7 through an inverter 8 which can change a speed of the motor 7; a motor control casing 17 in which a motor casing 53 which houses the motor 7 and an inverter casing 54 which houses the inverter 8 and the inverter control part 51 are integrated; a fan casing 18 which houses the fan 5; a holding member 55 which connects the fan casing 18 with the motor control casing 17 to hold the motor control casing 17; and a guide plate 56 which is held by the holding member 55 and guides air flowing from the exterior to the interior of a heat exchanger body so that the air flows along the motor control casing 17.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a heat exchanger, and more particularly to an air-cooled or water-cooled heat exchanger such as a cooling tower or a radiator.

  Conventionally, a heat exchanger such as a cooling tower or a radiator is used in a cooling system for cooling a liquid (for example, cooling water) used in an air conditioner or a plant. Such a heat exchanger includes a heat exchanger main body, an introduction pipe for introducing a liquid into the heat exchanger main body, a drain pipe for discharging the liquid from the heat exchanger main body, and outside air inside the heat exchanger main body. It has a fan device for introduction. The fan device has a motor and a fan connected to the rotation shaft of the motor, and air is introduced into the heat exchanger body by rotating the fan by the motor. The liquid introduced into the heat exchanger body from the introduction pipe is cooled by exchanging heat with the air introduced into the heat exchanger body. The cooled liquid is discharged from the heat exchanger body through the drain pipe. The air introduced into the heat exchanger body and exchanged heat with the liquid is discharged from the heat exchanger body through the fan device.

  2. Description of the Related Art A heat exchanger including a fan device having an inverter device that can change the speed of a fan motor is known. Patent Document 1 discloses a technique for controlling the rotation speed of a fan motor of a cooling tower by an inverter device. The inverter circuit that constitutes the inverter device is usually composed of a switching element and its peripheral circuit, and the inverter device needs to cool the heat generated when switching the main circuit including the switching element. Heat is cooled by a cooling fan or heat sink.

JP-A-5-340690

  As described above, the inverter device is cooled by the cooling fan in order to cool the heat generated when the circuit including the switching element is switched. The cooling tower and the inverter device are often installed outdoors, and when installed in a place receiving direct sunlight, the inverter device may become hot and cause a failure. Further, the inverter device is installed on the control panel together with the control device for controlling the entire cooling tower system so that the inverter device does not break down due to high temperature, and further consumes electric power such as cooling the control panel with a fan.

  The present invention has been made in view of the above-described circumstances, and utilizes the flow of air from the outside to the inside of the heat exchanger main body generated by driving a fan included in a heat exchanger such as a cooling tower or a radiator. By air-cooling the inverter device and the motor, the air-cooling fan for the inverter device and the air-cooling fan for the motor can be deleted, and the inverter device and the motor can be cooled without using extra equipment and power. An object of the present invention is to provide a heat exchanger that can be used.

  In order to achieve the above object, one aspect of the present invention is a heat exchanger including a fan device for introducing air into a heat exchanger main body that performs heat exchange between a liquid and air, The fan device includes a motor, a fan fixed to the rotation shaft of the motor, an inverter that allows the motor to change speed, an inverter control unit that controls the operation of the motor via the inverter, and the motor. A motor casing that integrates the inverter and an inverter casing that houses the inverter and the inverter controller, a fan casing that houses the fan and is connected to the heat exchanger body, and the fan casing A holding member connected to the motor control casing to hold the motor control casing; and provided on the holding member And a guide plate that is arranged on the outer peripheral side of the motor control casing and guides the air flowing from the outside to the inside of the heat exchanger main body along the motor control casing. To do.

In a preferred aspect of the present invention, the inner side surface of the guide plate is configured to have a constant interval with the motor control casing.
In a preferred aspect of the present invention, the guide plate includes a cylindrical guide plate, a guide plate formed of a plurality of arc segments, or a substantially cylindrical guide plate obtained by cutting a part of a cylinder in a radial direction. To do.
In a preferred aspect of the present invention, the inner side surface of the guide plate is configured to have a polygonal shape around the motor control casing.

In a preferred aspect of the present invention, the guide plate is a polygonal cylindrical guide plate, a guide plate arranged in a substantially polygonal cylindrical shape by contacting a plurality of plate-like segments or spaced apart, or a polygonal cylindrical one. It is characterized by comprising a substantially polygonal cylindrical guide plate having a portion cut in the radial direction.
In a preferred aspect of the present invention, a vertical extension line of the lowest point of the guide plate coincides with a horizontal effective point where the fan generates an air flow.
In a preferred aspect of the present invention, the radially inner side surface of the guide plate is inclined inward in the radial direction at a predetermined angle with respect to the vertical line.
In a preferred aspect of the present invention, the radially outer side surface of the guide plate is inclined radially outward at a predetermined angle with respect to the vertical line.

In a preferred aspect of the present invention, the distance between the radially inner end of the upper surface of the guide plate and the side surface of the motor control casing is a predetermined value.
In a preferred aspect of the present invention, the vertical position of the upper surface of the guide plate is substantially the same as the position of the side surface having the highest temperature in the motor control casing.
In a preferred aspect of the present invention, the vertical position of the lower surface of the guide plate is a position close to the fan and is not in contact with the fan.

The present invention has the following effects.
(1) The inverter device and the motor are air-cooled by using the air flow from the outside to the inside of the heat exchanger main body generated by driving the fan included in the heat exchanger such as a cooling tower or a radiator, thereby the inverter device The air cooling fan for the motor and the air cooling fan for the motor can be eliminated, and the inverter device and the motor can be cooled without using extra equipment and electric power.
(2) A cooling structure having no external fan such as an air cooling fan or a large number of fins can be provided, and the manufacturing cost can be reduced.
(3) Since the inverter device and the motor can be efficiently cooled using the air flow from the outside to the inside of the heat exchanger main body generated by driving the fan included in the heat exchanger, the inverter device and It can cope with the reduction of heat dissipation area due to miniaturization of motor.
(4) The circulation of the airflow can be prevented by the guide plate, and the air blowing efficiency can be improved.

FIG. 1 is a schematic view showing an embodiment of a cooling tower which is a heat exchanger of the present invention. FIG. 2 is a schematic view showing another embodiment of a cooling tower which is a heat exchanger of the present invention. Fig.3 (a) is a schematic diagram which shows one Embodiment of the radiator which is a heat exchanger of this invention, FIG.3 (b) is cooling which meanders the internal space of the frame shown in Fig.3 (a). It is a schematic diagram which shows a pipe | tube. FIG. 4 is a cross-sectional view of the fan device shown in FIGS. FIG. 5 is a plan view of the fan device shown in FIG. 6A and 6B are plan views showing the relationship between the motor control casing and the guide plate. 7A, 7B, and 7C are perspective views showing examples of the shape of the guide plate. 8A, 8B, and 8C are perspective views showing another example of the shape of the guide plate. FIGS. 9 (a) and 9 (b) show the case around the fan device and in the heat exchanger body when the guide plate is not installed (FIG. 9 (a)) and when the guide plate is installed (FIG. 9 (b)). It is a figure which shows the flow (airflow) of air typically. FIG. 10 is a schematic cross-sectional view showing details of the guide plate.

Hereinafter, an embodiment of a heat exchanger according to the present invention will be described with reference to FIGS. 1 to 10. 1 to 10, the same or corresponding components are denoted by the same reference numerals, and redundant description is omitted.
FIG. 1 is a schematic view showing an embodiment of a cooling tower which is a heat exchanger of the present invention. The cooling tower shown in FIG. 1 includes a cooling tower body (heat exchanger body) 3, a filler 2 disposed inside the cooling tower body 3, and a fan device 1 attached to the upper portion of the cooling tower body 3. ing. The detailed configuration of the fan device 1 will be described later. When the fan 5 disposed in the fan casing 18 of the fan device 1 is rotated by the motor 7, air is introduced into the cooling tower body 3 through the louver 15 provided on the side surface of the cooling tower body 3. The air introduced into the cooling tower body 3 is discharged from the cooling tower through the fan device 1.

  The cooling tower has an introduction pipe 10 extending through the cooling tower body 3, and a liquid (for example, cooling water) is introduced into the cooling tower body 3 through the introduction pipe 10. A discharge port 10 a located above the filler 2 is formed at the end of the introduction pipe 10, and a liquid is discharged from the discharge port 10 a to the filler 2. The liquid discharged into the filler 2 flows down inside the filler 2 and comes into contact with the air introduced into the cooling tower body 3 by the fan device 1. Thereby, heat exchange is performed between the liquid and air, and the liquid is cooled.

  The cooled liquid is collected in a water tank 12 provided in the lower part of the cooling tower body 3, and is discharged from the drain pipe 11 connected to the water tank 12 to the outside of the cooling tower body 3. A temperature sensor 19 for measuring an outlet temperature that is a temperature of a liquid flowing through the drain pipe 11 is attached to the drain pipe 11. The cooling tower shown in FIG. 1 is a water-cooled heat exchanger in which a liquid is directly cooled by air, and is called an open cooling tower.

  FIG. 2 is a schematic view showing another embodiment of a cooling tower which is a heat exchanger of the present invention. The cooling tower shown in FIG. 2 includes a cooling tower body (heat exchanger body) 3, a coil tube 20 disposed inside the cooling tower body 3, and a fan device 1 attached to the upper portion of the cooling tower body 3. ing. A cooling tower introduction pipe 10 shown in FIG. 2 is connected to one end of a coil pipe 20 disposed inside the cooling tower main body 3, and a drain pipe 11 for discharging liquid from the cooling tower main body 3 is connected to the coil pipe 20. Is connected to the other end. Also in the present embodiment, a temperature sensor 19 for measuring the outlet temperature of the liquid is attached to the drain pipe 11. The liquid flows from the introduction pipe 10 into the coil pipe 20 and flows out from the coil pipe 20 to the drain pipe 11. Further, the cooling tower shown in FIG. 2 includes a water spray pipe 22 for spraying water onto the coil pipe 20. The sprinkling pipe 22 extends from the outside of the cooling tower to above the coil pipe 20, and a sprinkling port 22 a for spraying water is formed at the end of the sprinkling pipe 22. The water sprayed from the water spout 22 a of the water spray pipe 22 contacts the surface of the coil pipe 20 to exchange heat with the liquid flowing through the coil pipe 20. Thereby, the liquid flowing through the coil tube 20 is cooled.

  The water sprayed from the water spout 22 a of the water sprinkling pipe 22 is cooled by the air introduced into the cooling tower body 3 by the fan device 1. The water that has flowed down in contact with the coil pipe 20 is collected in the water tank 12 and discharged from the watering drain pipe 25 connected to the water tank 12 to the outside of the cooling tower. The cooling tower shown in FIG. 2 is a water-cooled heat exchanger in which the liquid flowing through the coil tube 20 is cooled by the water sprayed from the sprinkling pipe 22, and is called a hermetic cooling tower.

  Fig.3 (a) is a schematic diagram which shows one Embodiment of the radiator which is a heat exchanger of this invention, FIG.3 (b) is cooling which meanders the internal space of the frame shown in Fig.3 (a). It is a schematic diagram which shows a pipe | tube. The radiator shown in FIG. 3A includes a radiator main body (heat exchanger main body) 32, a frame 33 to which a cooling pipe 30 (see FIG. 3B) through which a liquid flows is attached, and an upper portion of the radiator main body 32. And a fan device 1 attached thereto.

  As shown in FIG. 3B, one end of the cooling pipe 30 installed in the frame 33 is connected to the introduction pipe 10 that introduces liquid into the radiator body 32, and the other end of the cooling pipe 30 is It is connected to the drain pipe 11 that discharges the liquid from the radiator body 32. Also in the present embodiment, a temperature sensor 19 for measuring the outlet temperature of the liquid is attached to the drain pipe 11. The cooling pipe 30 meanders the internal space of the frame 33 so that the straight pipe portion 30a of the cooling pipe 30 extends in the vertical direction. The cooling pipe 30 may meander the internal space of the frame 33 such that the straight pipe portion 30a of the cooling pipe 30 extends in the horizontal direction. The frame 33 is fitted into an opening formed on the side surface of the radiator body 32 and is fixed to the radiator body 32. Although not shown, the frame 33 to which the cooling pipe 30 is attached may be fitted into an opening formed on the upper surface or the lower surface of the radiator main body 32.

  In the radiator configured as shown in FIGS. 3A and 3B, when the fan 5 of the fan device 1 is rotated by the motor 7, the air passes through the gap formed between the meandering cooling pipes 30. Is introduced into the radiator body 32. A cooling fin (not shown) is usually attached to the cooling pipe 30, and the heat of the liquid flowing through the cooling pipe 30 is transmitted to the cooling fin. The liquid flowing through the cooling pipe 30 of the radiator exchanges heat with the air introduced into the radiator main body 32 by the fan device 1 through the cooling pipe 30 and the radiation fins. Thereby, the liquid flowing through the cooling pipe 30 is cooled. The radiators shown in FIGS. 3A and 3B are air-cooled heat exchangers in which the liquid flowing through the cooling pipe 30 is cooled by air.

  FIG. 4 is a cross-sectional view of the fan device 1 shown in FIGS. The fan device 1 shown in FIG. 4 is provided in a heat exchanger such as the cooling tower shown in FIG. 1 or FIG. 2 or the radiator shown in FIG. The fan device 1 includes a fan 5, a motor 7 that rotates the fan 5, an inverter 8 that can change the speed of the motor 7, and an inverter control unit 51 that controls the operation of the motor 7 via the inverter 8. . The fan 5 has a hub 16 at the center and a plurality of blades 14 extending radially from the hub 16. The fan 5 is directly connected to the motor 7 by fixing the hub 16 of the fan 5 to the end of the rotating shaft 6 of the motor 7. Further, the fan device 1 controls the operation signal of the motor 7 (for example, a start signal or a stop signal of the motor 7 or a command value of the rotation speed of the motor 7 based on the measured value of the outlet temperature output from the temperature sensor 19. Etc.) is output to the inverter control unit 51.

  The inverter control unit 51 is arranged on an inverter board 8a on which power elements (for example, switching elements such as IGBT) 50 constituting the inverter 8 are arranged. In one embodiment, the inverter control unit 51 may be arranged away from the inverter 8. The inverter control unit 51 controls the switching operation of the power element 50 of the inverter 8 to control the rotational speed of the motor 7, that is, the rotational speed of the fan 5.

  The temperature sensor 19 is connected to the temperature control unit 52 via the signal cable 45, and the measured value of the outlet temperature output from the temperature sensor 19 is input to the temperature control unit 52 via the signal cable 45. The inverter control unit 51 controls the operation of the motor 7 (that is, the start or stop of the motor 7 or the rotation speed of the motor 7) based on the control signal output from the temperature control unit 52. The temperature control unit 52 stores in advance a start temperature for starting the motor 7, a predetermined target temperature for converging the measured value of the outlet temperature, and a stop temperature for stopping the motor 7. When the measured value of the outlet temperature becomes higher than the starting temperature, the temperature control unit 52 outputs a start signal (control signal) for the motor 7 to the inverter control unit 51, whereby the inverter control unit 51 The motor 7 is started via 8.

  After the motor 7 is started, the temperature control unit 52 outputs to the inverter control unit 51 a command value (control signal) for the rotation speed of the motor 7 for making the measured value of the outlet temperature coincide with the target temperature. The temperature control unit 52 has a calculation device (for example, CPU) (not shown), and the calculation device calculates a command value for the rotational speed of the motor 7 for making the measured value of the outlet temperature coincide with the target temperature. The inverter control unit 51 that has received the command value of the rotation speed of the motor 7 output from the temperature control unit 52 controls the inverter 8 based on the command value, and increases or decreases the rotation speed of the motor 7. Further, when the measured value of the outlet temperature becomes lower than the stop temperature, the temperature control unit 52 outputs a stop signal (control signal) of the motor 7 to the inverter control unit 51, whereby the inverter control unit 51 Then, the motor 7 is stopped via the inverter 8.

  The fan device 1 shown in FIG. 4 has a motor casing 53 in which the motor 7 is accommodated, and an inverter casing 54 in which the inverter 8 and the inverter control unit 51 are accommodated. The inverter casing 54 and the motor casing 53 are integrated as one motor control casing 17. More specifically, the motor control casing 17 is configured by connecting the inverter casing 54 to the motor casing 53. The motor 7 is accommodated in a motor chamber 27 formed inside the motor casing 53, and the inverter 8 and the inverter control unit 51 are accommodated in an inverter chamber 28 formed inside the inverter casing 54.

  In the present embodiment, the temperature control unit 52 is also accommodated in the inverter casing 54. More specifically, the temperature control unit 52 is built in the inverter control unit 51. In this case, the function of the arithmetic unit provided in the temperature control unit 52 for calculating the control signal for the operation of the motor 7 and the inverter control unit 51 for controlling the operation of the motor 7 based on the control signal are provided. The inverter control unit 51 (or the temperature control unit 52) may have a common calculation device (for example, a CPU) having the function of the calculation device. The common arithmetic unit calculates a control signal for the operation of the motor 7 based on the measured value of the outlet temperature output from the temperature sensor 19, and controls the operation of the motor 7 based on the control signal via the inverter 8. Run. When the operation of the motor 7 is controlled by a common arithmetic device, the manufacturing cost of the fan device 1 (that is, the manufacturing cost of the heat exchanger) can be reduced.

  In the present embodiment, the motor casing 53 and the inverter casing 54 have a cylindrical container shape. Further, a shaft seal 70 that seals a gap between the rotating shaft 6 and the motor casing 53 is disposed in a shaft penetrating portion where the rotating shaft 6 of the motor 7 passes through the motor casing 53.

  As shown in FIG. 4, the fan 5 and the motor control casing 17 in which the motor casing 53 and the inverter casing 54 are integrated are arranged in the vertical direction. More specifically, the inverter casing 54 is connected to the motor casing 53 so that the fan 5, the motor casing 53, and the inverter casing 54 are arranged in the vertical direction. Thereby, the motor 7, the inverter 8, the inverter control part 51, and the temperature control part 52 are unitized. Further, the motor casing 53 is connected to the inverter casing 54 so that the motor casing 53 is positioned between the inverter casing 54 and the fan 5. In the present embodiment, the inverter casing 54 is located above the motor casing 53, and the fan 5 is located below the motor casing 53.

  A power cable hole 54a is formed in the side wall 54b of the inverter casing 54, and the power cable 42 for supplying power from the power source (not shown) to the inverter 8 extends through the power cable hole 54a. Further, the signal cable 45 extending from the temperature sensor 19 to the temperature control unit 52 passes through the power cable hole 54a. A bottom wall through hole 54d is formed in the bottom wall 54c of the inverter casing 54, and an upper wall through hole 53b communicating with the bottom wall through hole 54d of the inverter casing 54 is formed in the upper wall 53a of the motor casing 53. Yes. In the present embodiment, the diameter of the bottom wall through hole 54 d of the inverter casing 54 is the same as the diameter of the upper wall through hole 53 b of the motor casing 53. A motor cable 46 for supplying electric power from the inverter 8 to the motor 7 extends through the bottom wall through hole 54d and the upper wall through hole 53b.

  The motor 7 may be an induction motor, but the motor 7 is a PM motor (Permanent Magnet Motor) having a rotor in which a permanent magnet is arranged and a stator arranged to face the rotor. preferable. In particular, as shown in FIG. 4, the motor 7 is preferably an IPM motor (Interior Permanent Magnet Motor) in which a permanent magnet 41 is disposed inside a rotor 43. Since the PM motor (in particular, the IPM motor) has high efficiency, the motor 7 can be downsized.

  The rotor 43 is fixed to the rotating shaft 6, and the stator 44 is fixed to the inner surface of the motor casing 53. The motor 7 shown in FIG. 4 is a radial gap type motor in which a stator 44 is disposed on the radially outer side of the rotor 43. Although not shown, the motor 7 may be an axial gap type motor in which a stator and a rotor are arranged along the axial direction. The rotating shaft 6 of the motor 7 is rotatably supported by two bearings 35 and 36 disposed in the motor casing 53 so as to be separated from each other in the vertical direction. The upper bearing 35 is attached to the upper surface of the motor chamber 27, and the lower bearing 36 is attached to the lower surface of the motor chamber 27.

  As shown in FIG. 4, the fan device 1 houses the fan 5 and is connected to the heat exchanger main body (the cooling tower main body 3 or the radiator main body 32), the fan casing 18, and the motor control casing 17. Are connected to each other to hold the motor control casing 17, and a guide plate 56 is provided on the holding member 55 and arranged on the outer peripheral side of the motor control casing 17. The guide plate 56 has a function of guiding air flowing from the outside to the inside of the heat exchanger main body (the cooling tower main body 3 or the radiator main body 32) so as to flow along the motor control casing 17. As shown in FIG. 4, the guide plate 56 has an inverted triangular cross-sectional shape.

  FIG. 5 is a plan view of the fan device 1 shown in FIG. As shown in FIG. 5, a cylindrical guide plate 56 is installed so as to surround the motor control casing 17. The holding member 55 that holds the motor control casing 17 by connecting the fan casing 18 and the motor control casing 17 includes two long holding members 55a that are stretched over the cylindrical fan casing 18, and a long length. The two short holding members 55b spanned between the two holding members 55a and four holding members 55c connecting the motor control casing 17 to the holding members 55a and 55b. Yes. The guide plate 56 is held by four holding members 55c.

6A and 6B are plan views showing the relationship between the motor control casing 17 and the guide plate 56. FIG.
In the example shown in FIG. 6A, the inner side surface 56 a of the guide plate 56 is configured to have a constant interval with the motor control casing 17. In the illustrated example, the guide plate 56 is formed in a cylindrical shape, and the inner side surface 56 a is spaced apart from the motor control casing 17.
In the example shown in FIG. 6B, the inner side surface 56 a of the guide plate 56 is configured to have a polygonal shape around the motor control casing 17. In the illustrated example, the guide plate 56 is formed in an octagonal cylinder shape, and the inner side surface 56 a has an octagonal shape around the motor control casing 17.
In this way, the inner side surface 56a of the guide plate 56 is configured to have a certain distance from the motor control casing 17, so that air flowing from the outside to the inside of the entire periphery of the motor control casing is transferred to the motor control casing 17. It can guide so that it may flow along, and can cool an inverter device and a motor efficiently.

FIGS. 7A, 7 </ b> B, and 7 </ b> C are perspective views illustrating examples of the shape of the guide plate 56.
In the example shown in FIG. 7A, the guide plate 56 is a cylindrical guide plate.
In the example shown in FIG. 7B, the guide plate 56 is composed of a plurality (four in the illustrated example) of arc segments S1, S2, S3, S4, and the arc segments S1 to S4 are substantially cylindrical. To form a single guide plate 56.
In the example shown in FIG. 7C, the guide plate 56 is formed of a substantially cylindrical guide plate obtained by cutting a part of a cylinder in the radial direction.
Each of the guide plates 56 shown in FIGS. 7A, 7B, and 7C has an inverted triangular cross-sectional shape and is configured such that the inner side surface 56a has a certain distance from the motor control casing 17. Has been.
In this way, by configuring the guide plate in a cylindrical shape, it is possible to guide the air flowing from the outside toward the inside evenly around the motor control casing so as to flow along the motor control casing 17. The apparatus and the motor can be efficiently cooled.
Moreover, what is necessary is just to select suitably the guide plate 56 shown to Fig.7 (a), (b), (c) based on the manufacturing cost of a guide plate or the assembly cost at the time of connecting a guide plate to a fan casing. .

FIGS. 8A, 8 </ b> B, and 8 </ b> C are perspective views showing another shape example of the guide plate 56.
In the example shown in FIG. 8A, the guide plate 56 is a polygonal cylindrical guide plate.
In the example shown in FIG. 8B, the guide plate 56 is composed of a plurality (8 in the illustrated example) of plate-like segments S1, S2, S3, S4, S5, S6, S7, and S8. The segments S1 to S8 are arranged in a substantially polygonal cylinder to form one guide plate 56.
In the example shown in FIG. 8C, the guide plate 56 is formed of a substantially polygonal cylindrical guide plate obtained by cutting a part of a polygonal cylinder in the radial direction.
The guide plates 56 shown in FIGS. 8A, 8 </ b> B, and 8 </ b> C all have an inverted triangular cross-sectional shape, and the inner side surface 56 a has a polygonal shape around the motor control casing 17. It is configured.
Thus, by configuring the guide plate in a polygonal cylinder shape, it is possible to manufacture the guide with an inexpensive flat plate, and guide the air flowing from the outside to the inside around the motor control casing along the motor control casing. The inverter device and the motor can be efficiently cooled.
Further, based on the manufacturing cost of the guide plate or the assembly cost when connecting the guide plate to the fan casing, any one of the guide plates 56 shown in FIGS. 8A, 8B, and 8C may be selected as appropriate. .

FIGS. 9A and 9B show the surroundings of the fan device 1 and the inside of the heat exchanger when the guide plate is not installed (FIG. 9A) and when the guide plate is installed (FIG. 9B). It is a figure which shows typically the flow (airflow) of air.
The heat exchanger performs heat exchange with air by forcibly ventilating the resistor (heat exchange part). Due to the pressure loss when passing through the resistor (heat exchange part), the inside of the heat exchanger body becomes negative pressure. Since no airflow is generated in the portion without the blades 14, the portion without the blades 14 flows from the outside to the inside of the heat exchanger body. Where there is a wing 14, the airflow generally flows outward at a velocity proportional to the radius. Since the velocity of the airflow is expressed as a vector having a magnitude and a direction, in FIGS. 9A and 9B, the length of the airflow indicates the magnitude of the airflow velocity, and the direction of the arrow indicates the airflow velocity. Indicates the direction.

  The vertical extension line of the lowest point Lp of the guide plate 56 coincides with the effective point Ep in the horizontal direction where the blades 14 generate airflow. That is, the lowermost point Lp of the guide plate 56 is configured to be on the vertical extension line of the end of the blade 14 on the rotating shaft side. Since the lowest point Lp of the guide plate 56 is located at the end of the blade 14 on the rotating shaft side, the air flow toward the inner side of the heat exchanger main body and the air flow toward the outer side do not collide with each other. All of the flow toward the inside of the main body can be made to flow along the motor control casing 17. The air flow gathers around the motor control casing 17 to increase the flow velocity, and the cooling amount of the motor control casing 17 can be increased.

  FIG. 10 is a schematic cross-sectional view showing details of the guide plate 56. As shown in FIG. 10, a horizontal effective point Ep where the blade 14 generates an air current is positioned on the vertical line VL of the lowest point Lp of the guide plate 56. The radially inner side surface 56a of the guide plate 56 is inclined inward in the radial direction at a predetermined angle θ1 with respect to the vertical line VL. Since the inner side surface 56a of the guide plate 56 is inclined inward in the radial direction with respect to the vertical line VL, the flow on the inner side in the radial direction of the guide plate 56 becomes an enlarged flow as indicated by an arrow. If the angle of expansion is low, the airflow does not collect around the motor control casing 17, and if it is too high, resistance is caused by rapid expansion. For this reason, the angle θ1 is preferably an angle of about 15 degrees, which is an upper limit value in which air resistance does not occur in the duct design in the case of an enlarged flow. As described above, by setting the angle θ1 to about 15 degrees, resistance to the airflow is not caused, and thus the generated airflow can be effectively used for cooling the motor control casing 17.

  As shown in FIG. 10, the outer side surface 56b in the radial direction of the guide plate 56 is inclined radially outward at a predetermined angle θ2 with respect to the vertical line VL. The angle θ2 is preferably in the range of more than 0 degree and within 15 degrees. The angle is determined as appropriate based on the air flow around the motor side and the fan capacity required for the heat exchanger (cooling tower or radiator). In this way, by setting the angle θ2 in the range of more than 0 degree and within 15 degrees, the flow on the discharge side of the fan is pushed outward to prevent the circulation of the airflow. As a result, it is possible to prevent the warmed air after heat exchange from flowing around the motor and to improve the fan efficiency.

  A distance D (see FIG. 4) between the radially inner end of the upper surface of the guide plate 56 and the side surface of the motor control casing 17 is a predetermined value. The narrower the distance D, the faster the flow velocity, but if it is too narrow, it becomes a noise source, and the flow rate decreases due to the increase in airflow resistance. The optimum distance is determined from tests based on the air velocity (heat transfer coefficient) and flow rate. In this way, by setting the distance D between the radial inner end of the upper surface of the guide plate 56 and the side surface of the motor control casing 17 to be the optimum distance, the air speed and flow rate can be set to the optimum speed and flow rate. And the amount of exhaust heat can be maximized.

The position of the upper surface of the guide plate 56 in the vertical direction is substantially the same as the position of the side surface having the highest temperature in the motor control casing 17. In the embodiment shown in FIG. 4, the vertical position of the upper surface of the guide plate 56 is substantially the same as that of the inverter control unit 51. Thereby, efficient cooling can be performed by increasing the air velocity around the inverter control unit that requires cooling.
The position of the upper surface of the guide plate 56 in the vertical direction may be the same as the position of the power element 50. The temperature of the side surface of the motor control casing 17 is measured by a test, and the position is the position of the side surface having the highest temperature. That's fine.
Further, the vertical position of the lower surface of the guide plate 56 is a position close to the fan and is not in contact with the fan. That is, by positioning the lower end of the guide plate 56 in the vicinity of the blade 14, the flow of the generated airflow in two directions is more accurately divided into two, thereby preventing warm air after heat exchange from flowing around the motor. In addition, the fan efficiency can be improved.

  The embodiment described above is described for the purpose of enabling the person having ordinary knowledge in the technical field to which the present invention belongs to implement the present invention. Various modifications of the above embodiment can be naturally made by those skilled in the art, and the technical idea of the present invention can be applied to other embodiments. Therefore, the present invention should not be limited to the described embodiments, but should be the widest scope according to the technical idea defined by the claims.

DESCRIPTION OF SYMBOLS 1 Fan apparatus 2 Filler 3 Cooling tower main body 5 Fan 6 Rotating shaft 7 Motor 8 Inverter 10 Introducing pipe 11 Drain pipe 12 Water tank 14 Wing 15 Louver 16 Hub 17 Motor control casing 18 Fan casing 19 Temperature sensor 20 Coil pipe 22 Sprinkling pipe 25 Sprinkling drain pipe 27 Motor room 28 Inverter room 30 Cooling pipe 32 Radiator body 33 Frame 35 Upper bearing 36 Lower bearing 41 Permanent magnet 42 Power cable 43 Rotor 44 Stator 45 Signal cable 46 Motor cable 50 Power element 51 Inverter controller 52 Temperature Control unit 53 Motor casing 54 Inverter casing 55, 55a, 55b, 55c Holding member 56 Guide plate 70 Shaft seal Lp Bottom point Ep Effective point θ1, θ2 Angle VL Vertical line D Distance

Claims (11)

A heat exchanger provided with a fan device for introducing air into a heat exchanger body that exchanges heat between liquid and air,
The fan device is
A motor,
A fan fixed to the rotating shaft of the motor;
An inverter capable of shifting the motor;
An inverter control unit for controlling the operation of the motor via the inverter;
A motor control casing that integrates the motor casing that houses the motor, and the inverter casing that houses the inverter and the inverter control unit;
A fan casing that houses the fan and is connected to the heat exchanger body;
A holding member that holds the motor control casing by connecting the fan casing and the motor control casing;
A guide plate provided on the holding member and disposed on the outer peripheral side of the motor control casing, for guiding air flowing from the outside to the inside of the heat exchanger main body along the motor control casing. A heat exchanger characterized by that.   The heat exchanger according to claim 1, wherein an inner side surface of the guide plate is configured to have a certain distance from the motor control casing.   3. The heat according to claim 2, wherein the guide plate comprises a cylindrical guide plate, a guide plate formed of a plurality of arc segments, or a substantially cylindrical guide plate obtained by cutting a part of the cylinder in a radial direction. Exchanger.   The heat exchanger according to claim 1, wherein an inner side surface of the guide plate is formed in a polygonal shape around the motor control casing.   The guide plate is a polygonal cylindrical guide plate, a guide plate arranged in a substantially polygonal cylindrical shape with a plurality of plate-shaped segments in contact with each other, or a part of the polygonal cylindrical portion cut out in the radial direction. The heat exchanger according to claim 4, comprising a substantially polygonal cylindrical guide plate.   6. The vertical extension line of the lowest point of the guide plate coincides with a horizontal effective point at which the fan generates an airflow. 6. Heat exchanger.   The heat exchanger according to any one of claims 1 to 6, wherein an inner side surface in the radial direction of the guide plate is inclined inward in the radial direction at a predetermined angle with respect to a vertical line.   The heat exchanger according to claim 7, wherein an outer side surface in the radial direction of the guide plate is inclined radially outward at a predetermined angle with respect to a vertical line.   The heat exchanger according to any one of claims 1 to 8, wherein a distance between a radially inner end of the upper surface of the guide plate and a side surface of the motor control casing is a predetermined value.   The heat exchanger according to any one of claims 1 to 9, wherein the position of the upper surface of the guide plate in the vertical direction is substantially the same as the position of the side surface having the highest temperature in the motor control casing. .   11. The heat exchanger according to claim 1, wherein a position of the lower surface of the guide plate in a vertical direction is a position close to the fan and is not in contact with the fan. .

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