JP2015218658A - Pump device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pump device that can effectively cool an inverter device for supplying power to an electric motor for driving a pump while saving space and reducing cost.SOLUTION: A pump device comprises: a pump 310 for pressurizing liquid; a totally-enclosed electric motor 210 for driving the pump 310; and an inverter device 230 for supplying power to the electric motor 210. The inverter device 230 comprises a cooling surface 236 consisting of a plurality of radiating fins 231a. The electric motor 210 comprises a fan cover 216 covering at least a portion of a motor casing 211a and a fan 215. In the fan cover 216, an opening 220 opposed to the cooling surface 236 of the inverter device 230 is formed.

Description

  The present invention relates to a pump device, and more particularly to a pump device capable of effectively cooling an inverter device for driving an electric motor.

  2. Description of the Related Art Conventionally, in order to supply water to a home, a pump device using a cascade pump that supplies water stored in a water receiving tank or well water is often used. The main reason for using the cascade pump is that it has a self-priming property in addition to a compact structure. Such a conventional pump device is equipped with an inverter device, and performs an efficient pump operation according to the load.

  However, due to the nature of the inverter device, considerable heat generation is unavoidable, and if the temperature rises too much, it may cause a failure. In order to prevent the failure of the inverter device due to the temperature rise, it is conceivable to enlarge the radiation fins of the inverter device or upgrade the elements in the inverter device to elements having high heat resistance. However, if the heat dissipating fins are enlarged, the size of the inverter device increases, and the cost increases when the elements are upgraded.

JP 2005-248898 A JP-A-11-210640

  Accordingly, an object of the present invention is to provide a pump device that can effectively cool an inverter device that supplies electric power to an electric motor that drives a pump while realizing space saving and cost reduction.

  One aspect of the present invention includes a pump that boosts a liquid, a fully-closed electric motor that drives the pump, and an inverter device that supplies electric power to the electric motor, and the inverter device includes a plurality of radiating fins. The electric motor has a motor casing in which a rotor and a stator are arranged, a drive shaft to which the rotor is fixed, an outer surface of the motor casing, and the motor A fan fixed to a drive shaft; and a fan cover that covers at least a part of the motor casing and the fan. The fan cover includes a peripheral wall that surrounds the entire periphery of the fan. An opening facing the cooling surface of the inverter device is formed.

In a preferred aspect of the present invention, an annular gap is formed between the fan cover and the motor casing.
In a preferred aspect of the present invention, the cooling surface is parallel to the drive shaft of the electric motor.
In a preferred aspect of the present invention, the apparatus further includes a pressure tank that holds a discharge pressure of the pump, and a unit cover that covers the pump, the electric motor, the inverter device, and the pressure tank.
In a preferred aspect of the present invention, the pressure tank and the electric motor are arranged adjacent to each other and parallel to each other.
In a preferred aspect of the present invention, the cooling surface of the inverter device is disposed facing the outer peripheral surface of the electric motor and the outer peripheral surface of the pressure tank.

  According to the present invention, since the cooling air blown by the fan can be directly applied to the cooling surface of the inverter device, the inverter device whose temperature is likely to rise can be effectively cooled.

  Furthermore, according to the present invention, the heat dissipation area of the inverter device can be reduced, and space saving, weight reduction, and cost reduction can be realized. Since it is no longer necessary to use an expensive element with high heat resistance in the inverter device, it is possible to reduce the cost and improve the product life by improving the temperature environment. Furthermore, since the present invention can effectively reduce the temperature, the clearance provided in the unit cover can be eliminated, and noise can be reduced.

It is a front view which shows the pump apparatus which concerns on one Embodiment. It is a rear view which shows the pump apparatus which concerns on this embodiment. It is the sectional view on the AA line of FIG. It is a figure which shows the schematic diagram of the pump apparatus which concerns on this embodiment. FIG. 5A is a partial cross-sectional view of the electric motor, and FIG. 5B is a view as seen from the direction indicated by the arrow B in FIG. FIG. 6A and FIG. 6B are diagrams showing a part of the inverter device. It is a perspective view which shows a pump apparatus. It is sectional drawing of a slit hole.

  Embodiments of the present invention will be described below with reference to the drawings. A pump device 201 according to an embodiment of the present invention will be described. FIG. 1 is a front view showing a pump device 201 according to the present embodiment. FIG. 2 is a rear view showing the pump device 201 according to the present embodiment. 3 is a cross-sectional view taken along line AA in FIG. In the present embodiment, the pump device 201 includes a cascade pump as the pump 310. The cascade pump is a pump that is also called a friction pump, and includes an impeller 311 (see FIG. 1) formed as a disk having a large number of grooves on the periphery. Although this type of pump is small, a single impeller can obtain a lift comparable to several stages of centrifugal pumps, and is suitable for the purpose of small-capacity high-lift. Cascade pumps are self-priming and are suitable for pumping water and well water stored in a water receiving tank to supply water to households.

  The impeller 311 is housed in the pump casing 312. A casing cover 313 is attached with bolts to the front surface of the pump casing 312 as viewed from the axial direction of the impeller 311. When the casing cover 313 is removed, the impeller 311 can be accessed and maintenance inspection is easy.

  The pump device 201 includes an electric motor 210 that drives the pump 310. The structure of the electric motor 210 will be described in detail later with reference to FIG. The pump device 201 further includes an inverter device 230 that supplies electric power of a variable frequency to the electric motor 210 so that the pump 310 can control the discharge pressure of the pump 310 by performing variable speed operation. The inverter device 230 is arranged in the vicinity of the electric motor 210. More specifically, the inverter device 230 is disposed adjacent to a fan 215 (see FIGS. 2 and 3) for cooling the electric motor main body 211. A check valve 321 is disposed in the flow path between the pump suction port 326 and the impeller 311.

  FIG. 4 is a diagram illustrating a schematic diagram of the pump device 201 according to the present embodiment. With reference to the schematic diagram of FIG. 4, the arrangement | positioning and effect | action according to the flow of water of each component apparatus of the pump apparatus 201 are demonstrated. Here, the pump device 201 is an automatic water supply device that automatically starts and stops the pump 310 according to the flow rate of water, and automatically changes the operation speed to a variable speed.

  In FIG. 4, water W is accumulated up to level L in the well Well dug from the ground S. The pump device 201 used as a water supply device is installed on the ground S in the vicinity of the well Well.

  The suction pipe 309 is connected to the suction port 326 of the pump 310. The water W is sucked into the impeller 311 of the pump 310 through the check valve 321. The check valve 321 is a check valve that prevents the water W from flowing back into the well Well when the pump 310 is stopped. Since the pump 310 is a cascade pump, even if there is air in the suction pipe 309 at the time of starting, it can be discharged to suck up the water W. However, since the check valve 321 is provided, the pump 310 is started. There is no need to expel air every stop.

  A steam / water separation chamber (not shown) is provided on the downstream side of the impeller 311, a flow switch 324 is disposed on the downstream side of the steam / water separation chamber, and a pressure sensor 323 is disposed in the vicinity thereof. The flow switch 324 and the pressure sensor 323 are disposed in a discharge pipe 325 provided downstream of the steam / water separation chamber. A discharge port 327 of the pump device is provided downstream of the discharge pipe 325. A pressure tank 322 is connected to the discharge pipe 325. An expelling tap 328 (see FIG. 2) is provided above the pressure tank 322. The pressure tank 322 is provided on the discharge side of the pump 310 and on the downstream side of the flow switch 324.

  The electric motor 210 and the pressure tank 322 are fixed to the pump 310. The pump 310 and the inverter device 230 are mounted on the unit base 332 and fixed with bolts, and are compactly assembled as a whole. The pump device 201 includes a resin unit cover 331 that covers the pump 310, the electric motor 210, the pressure tank 322, and the inverter device 230. The unit cover 331 and the unit base 332 cover the entire components of the pump device 201 almost hermetically. Therefore, the components of the pump device 201 can be protected from wind and rain, and a high soundproofing effect is provided.

  The flow switch 324 detects the discharge flow rate of the pump 310 and transmits the detection result to the control device 234 in the inverter device 230. The pressure sensor 323 detects the discharge-side pressure of the pump 310 and transmits the detection result to the control device 234 in the inverter device 230.

  The pressure tank 322 provided in the discharge pipe 325 has a rubber bladder built in the pressure vessel, and when the discharge pressure of the pump 310 rises, the air outside the bladder is compressed and water is stored in a pressurized state. The In addition, as the pressure in the discharge pipe 325 decreases, the compressed air expands and pushes the stored water to the discharge pipe 325. In this way, even if the pump 310 is stopped, water is supplied from the pressure tank 322 to the discharge pipe 325 for a while.

  The inverter device 230 includes an IPM (Intelligent Power Module) 232 that supplies driving power to a permanent magnet type (PM type) motor 210 as an electric motor, and a control device 234 that controls the IPM 232. The control device 234 includes a motor controller 235. Since the pressure tank 322 is installed on the downstream side of the flow switch 324, the flow switch 324 does not detect the flow rate of the water supplied from the pressure tank 322.

  The motor controller 235 transmits a voltage signal to the IPM 232. The control device 234 includes a pressure controller unit and a speed controller unit (not shown).

  The pressure signal from the pressure sensor 323 is input to the pressure controller unit, and the pressure controller unit sends a speed set value to the speed controller unit. The speed controller unit outputs a control signal corresponding to the difference between the set speed and the actual driving speed to the IPM 232.

  Since the IPM 232 handles electric power for driving the pump 310, the IPM 232 generates considerable heat as the pump 310 is operated. For this reason, it is necessary to take the heat of the IPM 232. The inverter device 230 includes at least a device that handles the driving power of the pump 310 and generates heat. In the present embodiment, the inverter device 230 is configured to include an IPM 232. The reason why the inverter device 230 needs to be cooled by blowing air is that it is not a device that generates a small amount of heat because the inverter device 230 handles signals, but a device that generates a large amount of heat so as to handle electric power.

  With reference to Fig.5 (a) and FIG.5 (b), the electric motor suitable for using for the pump apparatus of this Embodiment is demonstrated. 5A is a partial cross-sectional view of the electric motor 210, and FIG. 5B is a view seen from the direction indicated by the arrow B in FIG. 5A. The electric motor 210 is a permanent magnet type (PM type) electric motor, and is a fully enclosed outer fan type electric motor. The fully-closed motor is a motor of a type in which the entire motor has a sealed structure and does not allow liquid to enter the interior. The fully closed outer fan type electric motor is a fully closed type electric motor in which a cooling fan is provided outside the motor casing.

  The fully closed outer fan type motor 210 includes a motor body 211 having a fully closed structure, a drive shaft 214 connected to the impeller 311 of the pump 310, and a cooling fan 215 attached to the drive shaft 214. Fully enclosed outdoor fans and outdoor electric motors are always installed outdoors and are suitable for environments exposed to direct sunlight, wind and rain, and snow. The electric motor 210 may be a fully enclosed outdoor fan / outdoor motor, or a fully enclosed outdoor fan / indoor motor.

  The electric motor main body 211 has a structure that is hermetically sealed with a motor casing 211a, and the interior of the electric motor main body 211 is isolated from the external environment. A rotor (not shown) that is mounted on the drive shaft 214 and rotates and a stator (not shown) that surrounds it and forms a rotating magnetic field are disposed inside the motor casing 211a having a fully closed structure. The stator is mounted on the inner surface of the motor casing 211a.

  The motor casing 211a is formed of a material having rigidity. The motor casing 211a is made of cast iron, for example. Since the motor casing 211a has rigidity, distortion of the stator during operation of the electric motor 210 can be prevented, and noise can be reduced.

  The electric motor 210 includes a fan 215 that blows cooling air to the outer surface of the motor casing 211a. The fan 215 is disposed outside the motor casing 211a, and is fixed to an end of the drive shaft 214 opposite to the end connected to the pump 310. The fan 215 is attached to the outside of the electric motor main body 211 so as to be called an outer fan type. The fan 215 blows off air on the outer surface of the electric motor main body 211 in order to release heat generated in the electric motor main body 211. Thus, since the cooling air does not pass through the inside of the electric motor 210, the fully-closed electric motor 210 is suitable for use in an environment with dusty dirt outdoors.

  A fan cover 216 is attached to the motor casing 211a so as to surround the fan 215. The fan cover 216 guides cooling air toward the electric motor body 211. The fan cover 216 is disposed so as to cover a part of the motor casing 211a and the entire fan 215. The fan cover 216 is formed in a bowl shape, and is disposed so as to cover the fan 215 so that the opening of the fan cover 216 partially overlaps the motor casing 211a. The opening of the fan cover 216 is made slightly larger than the outer diameter of the motor casing 211a and is fixed to the motor casing 211a with screws 222. Since the fan cover 216 is made of resin, the fan cover 216 may be fixed to the motor casing 211a by fitting using the elasticity of the resin. The fan cover 216 may cover the entire motor casing 211a.

  The cooling air is guided to the outer peripheral surface of the electric motor main body 211 through a gap 223 formed between the fan cover 216 and the motor casing 211a. A gap 223 formed between the fan cover 216 and the motor casing 211a is an annular gap (space) formed between the inner peripheral surface of the fan cover 216 and the outer peripheral surface of the motor casing 211a. That is, the wind generated by the fan 215 passes through the space 223 surrounded by the inner peripheral surface of the fan cover 216 and the outer peripheral surface of the motor casing 211a.

  The fan cover 216 includes a peripheral wall 217 that surrounds the entire periphery of the fan 215, and a disk-shaped end wall 218 connected to the peripheral wall 217. The end wall 218 is formed integrally with the peripheral wall 217, and the end wall 218 is perpendicular to the axial direction of the drive shaft 214 of the electric motor 210. An air intake hole 219 is formed in the end wall 218. A plurality of slit holes (openings) 220 are formed in the peripheral wall 217 of the fan cover 216. In order to prevent the user from accidentally touching the fan 215 rotating at high speed, each slit hole 220 is provided with a plurality of grids 221. The grid 221 extends in parallel with the axial direction of the drive shaft 214. For this reason, the mold used when resin molding the fan cover 216 can be divided into two, and a slide mold that slides in the lateral direction is not required. Therefore, it is possible to realize a reduction in mold cost and good moldability.

  The slit hole 220 faces the inverter device 230. Only the slit hole 220 is formed on the peripheral wall 217 of the fan cover 216, and no other opening is formed. In the present embodiment, two slit holes 220 are provided, but the number of slit holes 220 may be one or more as long as the slit hole 220 faces the inverter device 230. If the opening of the slit hole 220 is small, the lattice 221 may be omitted. As the fan 215 rotates, external air is sucked from the air intake hole 219 and is sent to the electric motor main body 211 and the inverter device 230 through the gap 223 and the slit hole 220 between the fan cover 216 and the motor casing 211a.

  The IPM 232 will be described with reference to FIGS. 6 (a) and 6 (b). Portions of the inverter device 230 other than the heat dissipating fin base 231 and the IPM 232 are represented by imaginary lines (two-dot chain lines). The IPM (element) 232 is embedded in the resin mold 233. As shown in FIG. 6B, the resin mold 233 in which the IPM element 232 is embedded is attached to the radiating fin base 231. As shown in FIG. 6A, a large number of radiation fins 231 a are formed integrally with the radiation fin base 231 on the surface of the radiation fin base 231 opposite to the IPM element 232. In the present embodiment, the radiating fin base 231 and the radiating fin 231a are formed of aluminum which is a material having high thermal conductivity. However, it is not limited to aluminum, but may be copper, for example.

  The plurality of heat radiating fins 231 a constitute a cooling surface 236 for cooling the inverter device 230. The air sent from the slit hole 220 contacts the cooling surface 236 and takes the heat of the inverter device 230 through the radiation fins 231a. Since the cooling surface 236 is composed of a plurality of heat dissipating fins 213a, the area in contact with the air increases dramatically.

  FIG. 7 is a perspective view showing the pump device 201. In FIG. 7, the unit cover 331 is omitted. The fan 215 is attached to the drive shaft 214 of the electric motor 210 and rotates integrally with the drive shaft 214. Therefore, the fan 215 can generate an airflow in accordance with the rotation speed of the electric motor 210, that is, the load. The slit hole 220 formed in the fan cover 216 faces the cooling surface 236 of the inverter device 230, and the cooling surface 236 is located on the radially outer side of the fan 215. The airflow generated by the fan 215 directly hits the cooling surface 236 of the inverter device 230 through the slit hole 220.

  When the electric motor 210 is operated, the fan 215 (see FIG. 5) attached to the end of the drive shaft 214 opposite to the pump 310 (on the opposite pump side) rotates. The fan 215 sucks ambient air from the air intake hole 219 of the fan cover 216. Most of the air sucked from the air intake hole 219 flows on the outer peripheral surface of the electric motor main body 211 through the annular gap 223 and cools the electric motor main body 211. Part of the air sucked from the air intake hole 219 is discharged from the slit hole 220 and sent to the cooling surface 236 of the inverter device 230. The air comes into contact with the plurality of radiating fins 213a constituting the cooling surface 236 and takes away the heat generated in the inverter device 230, whereby the cooling effect of the inverter device 230 can be obtained.

  Since the slit hole 220 faces the cooling surface 236 of the inverter device 230, the air discharged from the slit hole 220 does not contact the electric motor body 211 and directly contacts the radiation fins 213 a at a low temperature. Therefore, heat exchange between the air and the inverter device 230 is promoted, and the inverter device 230 can be efficiently cooled.

  The pressure tank 322 and the electric motor 210 are arranged adjacent to each other and arranged in parallel to each other. The pressure tank 322 is located above the electric motor 210. The pressure tank 322 and the electric motor 210 are placed horizontally, and the drive shaft 214 of the electric motor 210 extends horizontally. On the other hand, the inverter device 230 is placed vertically. The plurality of heat radiating fins 213 a extend in the vertical direction and constitute a vertical cooling surface 236. The cooling surface 236 is disposed facing the electric motor 210 and the pressure tank 322. The cooling surface 236 of the inverter device 230 is parallel to the drive shaft 214 of the electric motor 210.

  The longitudinal direction of the radiation fin 213a is perpendicular to the longitudinal direction of the drive shaft 214 of the electric motor 210, and the slit hole 220 faces obliquely upward toward the radiation fin 213a. As shown in FIG. 7, the air sent from the slit hole 220 is in contact with the heat dissipating fins 231a constituting the cooling surface 236, and further forms a rising airflow that flows along the longitudinal direction of the heat dissipating fins 231a. Since the slit hole 220 faces obliquely upward toward the radiation fin 213a, an upward airflow that flows along the longitudinal direction of the radiation fin 231a is likely to be generated, and the inverter device 230 is efficiently cooled by the upward airflow.

  The wall surface 220a of the slit hole 220 is inclined with respect to a direction perpendicular to the axial direction of the drive shaft 214 so that air flowing in the axial direction of the drive shaft 214 is efficiently sent to the cooling surface 236 of the inverter device 230. . FIG. 8 is a cross-sectional view of the slit hole 220. The air flowing in the axial direction of the drive shaft 214 collides with the wall surface 220a of the slit hole 220, the flow direction changes by 90 degrees, and is sent to the cooling surface 236 of the inverter device 230. Thus, since the wall surface 220a is inclined, the direction of the air flowing in the axial direction of the drive shaft 214 can be changed smoothly. As an example, the inclination angle of the wall surface 220 a is 45 degrees with respect to the direction perpendicular to the axial direction of the drive shaft 214.

  The airflow that has passed through the radiation fins 231 a is changed in the traveling direction by the unit cover 331, and contacts the pressure tank 322 and the pump 310. As described above, the water pumped from the pump 310 is stored in the pressure tank 322, and the surface temperature of the pressure tank 322 is low. Similarly, during operation of the pump 310, water is present inside the pump 310 and the surface temperature of the pump 310 is low. The airflow whose temperature has risen due to the removal of heat from the inverter device 230 is cooled by contacting the pressure tank 322 and the pump 310. In order to further enhance the cooling effect, the pump casing 312 may be provided with fins. The cooled airflow contacts the electric motor 210 and cools the electric motor 210. Thus, the air discharged from the slit hole 220 circulates through the cooling surface 236 of the inverter device 230, the pressure tank 322, the pump 310, and the electric motor 210 in this order. That is, a circulating air flow as shown in FIG. 7 is formed in the internal space of the unit cover 331.

  The surface of the pump 310 is so low that condensation occurs when water is flowing. The pump 310 is configured to automatically stop when the discharge flow rate of the pump 310 decreases. While the pump is stopped, the inverter device 230 hardly generates heat. That is, when the inverter device 230 needs to be cooled, water is flowing through the pump 310, and when the pump 310 is stopped and no water is flowing, it is convenient because the inverter device 230 does not generate heat.

  According to the present embodiment, when the fan 215 rotates, air is sucked into the fan cover 216 through the air intake hole 219, and a part of the sucked air passes through the slit hole 220 to the cooling surface 236 of the inverter device 230. Sent to the inverter device 230 for cooling. Therefore, expansion of the heat dissipation area of the inverter device 230 can be suppressed, and space saving, weight reduction, and cost reduction can be realized. Further, since the inverter device 230 can be cooled effectively, there is no need to use an expensive element with high heat resistance for the inverter device 230. Therefore, the product life can be improved by reducing the cost and improving the temperature environment.

  The electric motor main body 211 can be cooled using ambient air sucked from the air intake hole 219 of the fan cover 216. Most of the air sucked from the air intake hole 219 passes through the annular gap 223 on the opposite side of the air intake hole 216 and flows on the outer peripheral surface of the electric motor main body 211 to cool the electric motor main body 211. The warmed air hits the pump 310 and is cooled by the pump 310. The air that directly hits the pump 310 becomes an upward flow and contacts the pressure tank 322 (first air flow). Part of the air sucked from the air intake hole 219 is discharged from the slit hole 220 and sent to the inverter device 230. Further, the air flows on the cooling surface 236 of the inverter device 230 and comes into contact with the pressure tank 322 (second air flow). Both the first air flow and the second air flow are cooled by the pressure tank 322. Therefore, the cooling effect of air can be enhanced by combining these two air flows.

  The fan cover 216 may be extended in the axial direction so that the entire outer peripheral surface of the electric motor main body 211 is covered with the fan cover 216. By comprising in this way, while being able to make air strike the pump 310 more effectively, the sound insulation property of the electric motor main body 211 can be improved.

  Returning to FIG. 2, the arrangement of the electric motor 210 and the inverter device 230 will be described. On the unit base 332, the inverter device 230 is disposed in the vicinity of the electric motor 210, particularly in the vicinity of the fan 215, more specifically, in the vicinity of the fan cover 216 surrounding the fan 215. The cooling surface 236 of the inverter device 230 is adjacent to the plurality of slit holes 220 formed in the peripheral wall 217 of the fan cover 216.

  The slit hole 220 as an opening for sending the flow of cooling air generated by the fan 215 to the cooling surface 236 of the inverter device 230 is an example, and the shape and number of the openings are the amount of air necessary for cooling the inverter device 230. If it can send, it will not be specifically limited. For example, the opening may be a single hole or a notch.

  The unit cover 331 covers the entire components of the pump device 201 such as the pump 310, the electric motor 210, the inverter device 230, and the pressure tank 322, and the air circulation to the outside is slight. Accordingly, since a large amount of external fresh air does not flow into the inside, the pump device 201 can be operated well even in a dusty environment. Furthermore, noise leaking from the unit cover 331 to the outside can be reduced as much as possible.

  When the flow switch 324 detects the lower limit value of the water discharge flow rate, the control device 234 stops the electric motor 210 and thus the pump 310. Immediately before stopping the electric motor 210, the discharge pressure of the pump 310 is increased by temporarily increasing the operation speed of the pump 310 so that sufficient water is stored in the pressure tank 322. The pump 310 may be stopped due to a decrease in the water discharge flow rate based on the lower limit value of the rotational speed of the pump 310, regardless of the flow switch 323.

  After that, when water is used, water is supplied from the pressure tank 322 for a while, but when the water in the pressure tank 322 decreases and the pressure in the discharge pipe 325 decreases further, the pressure sensor 323 detects this. Then, the control device 234 starts the electric motor 210.

  The pump device of the present invention is not limited to the embodiment described above, and is not limited to the illustrated examples, and various modifications can be made without departing from the scope of the present invention. Needless to say.

201 pump device 210 motor 211 motor body 211a motor casing 214 drive shaft 215 fan 216 fan cover 217 peripheral wall 218 end wall 219 air intake hole 220 slit hole 220a wall surface 221 lattice 222 screw 230 inverter device 231 radiating fin base 231a radiating fin 232 IPM
233 Resin mold 234 Controller 235 Motor controller 236 Cooling surface 309 Suction pipe 310 Pump 311 Impeller 312 Pump casing 313 Casing cover 321 Check valve 322 Pressure tank 323 Pressure sensor 324 Flow switch 325 Discharge pipe 326 Suction port 327 Discharge port 328 Plug 331 Unit cover 332 Unit base

Claims (6)

A pump for boosting the liquid;
A fully-closed electric motor for driving the pump;
An inverter device for supplying electric power to the electric motor,
The inverter device has a cooling surface composed of a plurality of heat radiation fins,
The motor is
A motor casing in which a rotor and a stator are arranged;
A drive shaft to which the rotor is fixed;
A fan disposed outside the motor casing and fixed to the drive shaft;
A fan cover covering at least a part of the motor casing and the fan;
The said fan cover has a surrounding wall surrounding the perimeter of the said fan, The opening facing the said cooling surface of the said inverter apparatus is formed in the said surrounding wall.   The pump device according to claim 1, wherein an annular gap is formed between the fan cover and the motor casing.   The pump device according to claim 1, wherein the cooling surface is parallel to the drive shaft of the electric motor. A pressure tank for holding the discharge pressure of the pump;
The pump device according to any one of claims 1 to 3, further comprising a unit cover that covers the pump, the electric motor, the inverter device, and the pressure tank.   The pump apparatus according to claim 4, wherein the pressure tank and the electric motor are adjacent to each other and arranged in parallel to each other.   6. The pump device according to claim 4, wherein the cooling surface of the inverter device is arranged facing an outer peripheral surface of the electric motor and an outer peripheral surface of the pressure tank.

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