KR20190080770A - Pump apparatus - Google Patents

Abstract

A pump apparatus comprises a tank in which an insulating fluid to be handled flows and a pump installed in the tank. The pump comprises: an impeller in which a magnet is embedded; a motor stator disposed at a position opposing the magnet; a pump casing configured to store the impeller; and a motor casing configured to store the motor stator. The motor casing is opened for a coil of the motor stator to be immersed in the fluid to be handled.

Description

[0001] PUMP APPARATUS [0002]

The present technology relates to a pump apparatus.

Conventionally, pumped liquid (heat medium) used for cooling or regulating the temperature of an external apparatus such as a semiconductor manufacturing apparatus is circulated by a pump from a tank in which the pumped liquid is stored to a heat exchange section of the external apparatus.

Such a pump is often installed outside the tank (on the side or bottom of the tank), and therefore, the entire apparatus tends to be large in size, especially when it is provided on the side of the tank. Japanese Patent Laying-Open No. 2006-330901 discloses a vertical multi-stage pump in which a motor portion of a pump is provided on an upper portion of a tank.

Further, when a fluorine-based insulating liquid is used as a pumped fluid (heating medium), the pumped fluid itself is expensive, and a semiconductor detector is provided with a gas detector for detecting toxic gases used in the manufacturing process, The gas detector may be erroneously detected. Therefore, there is an example in which a candle motor pump which does not cause leakage of liquid is used as a pump for circulating the pumped liquid.

However, in the candle motor pump, since the heat generation of the motor is cooled by the pumped liquid, the temperature of the motor becomes high when the circulating temperature of the pumped liquid is relatively high. Therefore, circulation of the liquid for forced cooling of the motor from the outside may be required, and air purging may be required, and the entire apparatus tends to be further increased in size.

It is desired to provide a pump device capable of coping with a relatively high-temperature pumped fluid without enlarging the entire device.

The pump device according to one embodiment,

A tank in which insulating pumped liquid is stored,

The pump

And,

The pump includes:

An impeller in which a magnet is embedded,

A motor stator disposed at a position opposite to the magnet,

A pump casing accommodating the impeller,

And a motor casing

Lt; / RTI &

The motor casing is opened so that the windings of the motor stator are immersed in the pumped liquid.

1 is a schematic view showing a configuration of a pump apparatus according to a first embodiment.
Fig. 2 is an enlarged cross-sectional view of the pump of the pump device shown in Fig. 1. Fig.
3 is a plan view of the pump shown in Fig. 2 viewed from the suction side.
4 is a schematic view showing the configuration of the pump apparatus according to the second embodiment.

In the pump device according to the first aspect of the embodiment,

A tank in which insulating pumped liquid is stored,

The pump

And,

The pump includes:

An impeller in which a magnet is embedded,

A motor stator disposed at a position opposite to the magnet,

A pump casing accommodating the impeller,

And a motor casing

Lt; / RTI &

The motor casing is opened so that the windings of the motor stator are immersed in the pumped liquid.

According to this aspect, since the pump is installed in the tank, the entire apparatus can be downsized. Further, since the motor casing is opened and the windings of the motor stator are immersed in the pumped liquid in the tank, the windings can be directly cooled by the pumped liquid, thereby improving the cooling efficiency of the windings. As a result, the temperature rise of the winding can be reduced, so that it is possible to increase the pump capacity and raise the upper limit of the liquid temperature to be handled.

In addition, according to this aspect, the waterproof connector used for a part of the conventional motor casing or the power connection part becomes unnecessary, and the housing can be simplified, and the cost can be reduced. In addition, compared to the conventional example in which the motor is cooled by the air flow, the air purging becomes unnecessary, so that an energy saving effect can be obtained, the apparatus can be downsized, and the number of parts such as cooling fins and manifolds can be reduced And the air flow rate control is not necessary, so that the entire apparatus can be simplified.

Further, according to this aspect, noise can be reduced because the pump is installed in the tank and immersed in the pumped liquid, and the tank serves as a double housing.

A pump device according to a second embodiment of the present invention is the pump device according to the first aspect,

On the suction side of the pump, a guide for guiding the pumped liquid is disposed so that the pumped liquid passes through the position where the motor casing opens.

According to this aspect, the pumped liquid is guided by the guide so as to pass through the position where the motor casing opens, and even if the temperature of the pumped fluid rises due to the heat generation of the coil in the vicinity of the motor stator coil, The cooling efficiency of the winding by the pumped liquid can be further increased.

A pump apparatus according to a third embodiment of the present invention is the pump apparatus according to the first or second aspect,

The suction port of the pump is disposed at a height higher than the motor stator.

According to this aspect, during the normal operation of the pump, the windings of the motor stator can be immersed in the pumped liquid and maintained in a state of direct cooling.

A pump device according to a fourth aspect of the present invention is the pump device according to the third aspect,

Monitoring the current supplied to the motor stator and performing at least one of stopping supply of current to the motor stator and ringing an alarm when the current supplied to the motor stator becomes smaller than a predetermined threshold value And a control unit.

According to this aspect, when the winding is not immersed in the handling liquid and the winding can not be efficiently cooled by the pumped liquid, the operation of the pump can be continued to prevent the temperature of the winding from excessively increasing.

Hereinafter, specific examples of the embodiments will be described in detail with reference to the accompanying drawings. In addition, in the drawings attached to this specification, dimension ratios such as scale, length and width are appropriately changed and exaggerated from the actual ones for convenience of understanding.

1 is a schematic view showing a configuration of a pump apparatus 1 according to a first embodiment. As shown in Fig. 1, the pump apparatus 1 includes a tank 10 and a pump 20 installed in the tank 10.

In the tank 10, an insulating pumped liquid 11 is stored. As the pumped liquid 11, for example, a fluorine-based insulating liquid (specifically, Fluorinert (registered trademark)) is used.

In the illustrated example, the transfer pipe 14 is inserted into the lower side wall of the tank 10 and the discharge pipe 20c of the pump 20 is connected to the transfer pipe 14 through the joint 15 . A union joint or a ferrule joint is preferably used as the joint 15 in order to facilitate connection and disconnection of the pipe in the tank 10. [ The pumped liquid 11 discharged from the discharge pipe 20c of the pump 20 is sent to an external device (not shown) through the transfer pipe 14.

A return pipe 13 is inserted into the ceiling of the tank 10 and the pumped liquid 11 which has undergone heat exchange through an external device not shown is introduced into the tank 10 through the return pipe 13, And returned to the inside to be stored.

Fig. 2 is an enlarged cross-sectional view of the pump 20 installed in the tank 10. Fig. 2, the pump 20 includes an impeller 21 in which a magnet (permanent magnet) 22 is embedded, a motor stator 23 disposed at a position opposed to the magnet 22, A pump casing 24 for accommodating the motor stator 21, and a motor casing 25 for accommodating the motor stator 23. The liquid-contact portion between the pump casing 24 and the motor casing 25 is made of a material capable of withstanding the pumped liquid 11, for example, a resin such as PPS (polyphenylene sulfide) or PEEK (polyetheretherketone) .

2, the motor stator 23 and the motor casing 25 are disposed on the suction side of the impeller 21, and the motor casing 25 defines the suction port 20a. A bearing assembly 26 for supporting a radial load and a thrust load of the impeller 21 is disposed between the motor casing 25 and the impeller 21.

As shown in Fig. 2, a liquid passage is formed in the center portion of the motor casing 25 and the bearing assembly 26, respectively. These liquid flow paths are connected in series to constitute one liquid flow path extending from the suction port 20a to the liquid inlet of the impeller 21. [ These liquid flow paths are in communication with the liquid inlet of the impeller 21.

The pump 20 according to the present embodiment is a pump mounted with an axial gap type PM motor in which a magnet 22 and a motor stator 23 are disposed along the liquid flow path.

As shown in Fig. 2, on the side surface of the pump casing 24, there is provided a discharge pipe 20c having a discharge port 20b. The liquid pressurized by the rotating impeller 21 is discharged from the discharge port 20b through the discharge pipe 20c. The pump 20 according to the present embodiment is a so-called end-saw type pump in which the suction port 20a and the discharge port 20b are perpendicular to each other.

The impeller 21 is made of a non-magnetic material which is easy to slip, hard to wear, and able to withstand the pumped liquid 11. [ For example, as the material of the impeller 21, resins such as PPS (polyphenylene sulfide) and PEEK (polyether ether ketone) or ceramics are suitably used. The pump casing 24 and the motor casing 25 can also be formed of the same material as the impeller 21. [

The impeller 21 is rotatably supported by a single bearing assembly 26. This bearing assembly 26 is a sliding bearing (hydrodynamic bearing) using fluid dynamic pressure. The bearing assembly 26 is composed of a combination of a rotary side bearing 26a and a fixed side bearing 26b that are loosely engaged with each other.

The rotary side bearing 26a is fixed to the impeller 21 and is disposed so as to surround the fluid inlet of the impeller 21. [ The fixed side bearing 26b is fixed to the motor casing 25 and is disposed on the suction side of the rotating side bearing 26a. The rotary side bearing 26a has a cylindrical portion extending in the axial direction of the rotary side bearing 26a and a flange portion projecting outward from the cylindrical portion.

The cylindrical portion of the fixed side bearing 26b has a radial surface for supporting the radial load of the impeller 21. The flange portion has a thrust surface for supporting the thrust load of the impeller 21. [ The radial surface is parallel to the axial center of the impeller (21), and the thrust surface is perpendicular to the axial center of the impeller (21). The rotary side bearing 26a is disposed around the cylindrical portion of the fixed side bearing 26b.

A part of the pumped fluid 11 discharged from the impeller 21 is guided to the bearing assembly 26 through the minute clearance between the impeller 21 and the motor casing 25. [ When the rotary side bearing 26a rotates together with the impeller 21, a dynamic pressure of the fluid is generated between the rotary side bearing 26a and the fixed side bearing 26b, whereby the impeller 21 is rotated by the bearing assembly 26 In a noncontact manner. The tilting of the impeller 21 is limited by the bearing assembly 26 since the fixed side bearing 26b supports the rotary side bearing 26a by the orthogonal radial and thrust surfaces.

The motor stator 23 has a core 23a and a plurality of windings (coils) 23b. The plurality of windings 23b are arranged in an annular shape. The impeller 21 and the motor stator 23 are disposed concentrically with the bearing assembly 26 and the intake port 20a.

A lead wire 23c is connected to the winding 23b of the motor stator 23 via a wiring board 23d. 1, the power connector 12 is mounted on the upper sidewall of the tank 10. The winding 23b of the motor stator 23 is connected to the lead wire 23c, the wiring board 23d, And is electrically connected to the inverter device 3 through the inverter 12. The inverter device 3 is connected to a power source 2 and is also connected to a control device (control section) 4 for controlling the operation of the inverter device 3. [

The inverter device 3 supplies a current to the winding 23b of the motor stator 23 and generates a rotating magnetic field in the motor stator 23. [ This rotating magnetic field acts on the magnet 22 embedded in the impeller 21 to rotationally drive the impeller 21. The torque of the impeller 21 depends on the magnitude of the current supplied to the motor stator 23. As long as the load applied to the impeller 21 is constant, the current supplied to the motor stator 23 is substantially constant.

When the impeller 21 rotates, the pumped liquid 11 stored in the tank 10 is introduced into the liquid inlet of the impeller 21 from the suction port 20a. The pumped liquid 11 is pressurized by the rotation of the impeller 21 and is discharged from the discharge port 20b. While the impeller 21 is conveying the pumped liquid 11, the back surface of the impeller 21 is pressed to the suction side (i.e., toward the suction port 20a) by the pressurized liquid. Since the bearing assembly 26 is disposed on the suction side of the impeller 21, the bearing assembly 26 supports the thrust load of the impeller 21 from the suction side.

In this embodiment, as shown in Figs. 1 and 2, the motor casing 25 is opened so that the winding 23b of the motor stator 23 is immersed in the pumped liquid 11. As shown in Fig. Reference numeral 25a denotes an opening of the motor casing 25. As shown in Fig. The motor casing 25 opens to the suction side (upper side in the figure) of the pump 20.

3 is a plan view of the pump 20 viewed from the suction side. 3, reference numeral 25a1 denotes the inner periphery of the opening 25a of the motor casing 25, and reference numeral 25a2 denotes the outer periphery of the opening 25a. The area between the inner periphery 25a1 and the outer periphery 25a2 is the opening 25a. 3, a wiring board 23d for connecting the lead wire 23c extending from the power source connector 12 to each winding 23b is disposed in the opening 25a of the motor casing 25 And a plurality of notches 23e are formed on the outer periphery and the inner periphery of the wiring board 23d, respectively. The plurality of notches 23e are formed spaced apart from each other in the circumferential direction (for example, at regular intervals). The pumped fluid 11 stored in the tank 10 flows into the interior of the motor casing 25 from the opening 25a of the motor casing 25 through the notch 23e of the wiring board 23d, 23b are directly immersed in the pumped liquid 11.

The wiring board 23d is not necessarily required and the wiring board 23d may be omitted and the lead wire 23c extending from the power source connector 12 may be directly connected to each of the windings 23b. In this case, the pumped liquid 11 stored in the tank 10 flows directly into the interior of the motor casing 25 from the opening 25a of the motor casing 25 so that the coil 23b is directly fed to the pumped liquid 11 It is immersed.

When electric current flows through the coil 23b of the motor stator 23 during the operation of the pump 20, heat is generated by the electric resistance of the coil 23b. In the present embodiment, however, the motor casing 25 is opened And the winding 23b of the motor stator 23 is immersed in the pumped liquid 11 of the tank 10 so that the winding 23b can be cooled directly by the pumped liquid 11 and the winding 23b can be efficiently Lt; / RTI > Furthermore, in this embodiment, since the pumped liquid 11 is an electrically insulating liquid, there is no case where the coil 23b is short-circuited by being immersed in the pumped liquid 11. [

As shown in Figs. 1 and 2, the suction port 20a of the pump 20 may be disposed at a height higher than the motor stator 23. Thereby, during the operation of the pump 20, the coil 23b of the motor stator 23 can be immersed in the pumped liquid 11 to maintain the state of direct cooling.

1, the control device 4 for controlling the operation of the inverter device 3 monitors the current supplied from the inverter device 3 to the motor stator 23 and supplies the current to the motor stator 23 When the current becomes smaller than the predetermined threshold value, at least one operation of stopping supply of current to the motor stator 23 and ringing an alarm is executed.

For example, the control device 4 determines whether the pump 20 is operating in an abnormal level of current, that is, in a dry state or in a state in which the liquid is insufficient, based on the change in the current change rate and / . When the pump 20 is immersed in the pumped liquid 11 and the pumped liquid 11 is present in the pump 20, the rate of change of the current and / or the change of the current value is substantially zero.

On the other hand, when the pump 20 is operated (idle) in a dry state or in a state where the liquid is insufficient, the current supplied to the motor stator 23 decreases. The control device 4 compares the change rate of the current and / or the current value with a predetermined threshold value. Here, the predetermined threshold value refers to a generic term of the following values (the number of times of lowering the reference value, the set value, the specified value, the number of times of lowering the allowable value, the amount of deviation, etc.).

More specifically, since the power of the pump 20 is reduced when the pump 20 is operated in a dry state or in a state where the liquid is insufficient, the current supplied from the inverter device 3 to the motor stator 23 is reduced do. That is, when no liquid is present in the pump 20, the load applied to the impeller 21 is minimized, so that the current supplied to the motor stator 23 is minimized. Thus, the control device 4 monitors the current supplied to the motor stator 23 and calculates the rate of change of the current per predetermined period. In one embodiment, the control device 4 may calculate the rate of change of the current per a predetermined period (for example, one month).

The control device 4 then determines whether the pump 20 is operating in an abnormal level of current, that is, in a dry state or in a state in which the liquid is insufficient, based on the current supplied to the motor stator 23. The abnormal level of the current can be defined, for example, as follows. That is, a value such as an average value obtained from the current value when the pump 20 is operating normally is set as a reference value in advance. Then, the rate of change of the supplied current is calculated using this reference value. When the value of the rate of change becomes negative by a predetermined number of times, the control device 4 determines the abnormal level of the current. In one embodiment, when the change rate of the current becomes smaller than the predetermined set value, the control device 4 may determine the abnormal level of the current.

In another embodiment, the control device 4 measures the current value at a predetermined time after starting the operation of the pump 20, and determines whether the deviation of the measured value of the current from the past measured value of the current is When it becomes smaller than the predetermined value, the control device 4 may determine the abnormality level of the current. In this case, the change of the current is calculated instead of the rate of change of the current. The change in current is the value of the deviation. In another embodiment, the controller 4 may determine the abnormal level of the electric current on the basis of the number of times or the number of times the value of the deviation is less than the predetermined allowable value. These specified values and allowable values may be the same value or different values.

The control device 4 transmits a control signal to the inverter device 3 and supplies the current to the motor stator 23 when the change rate of the current and / or the change in the current value exceeds a predetermined threshold value Stop. The motor stator 23 can be prevented from being directly immersed in the pumped liquid 11, that is, the coil 23b of the motor stator 23 can not be directly cooled by the pumped liquid 11. [ It is possible to prevent the temperature from excessively rising due to the heat generation of the winding 23b.

Further, in addition to or in place of stopping the current supply to the motor stator 23, when the rate of change of the current and / or the change of the current value is decreased by exceeding the predetermined threshold value, You can ring and ask the manager for payment response.

According to the present embodiment as described above, since the pump 20 is installed in the tank 10, the entire apparatus can be downsized. Since the motor casing 25 is opened and the winding 23b of the motor stator 23 is immersed in the pumped liquid 11 in the tank 10, the winding 23b is directly cooled by the pumped liquid 11 So that the cooling efficiency of the winding 23b is improved. This makes it possible to reduce the temperature rise of the winding 23b, thereby increasing the pump capacity and raising the upper limit of the treating liquid temperature.

Further, according to the present embodiment, it is possible to simplify the housing, such as eliminating the need for a waterproof connector used for a part of the conventional motor casing or the power connection portion, thereby reducing the cost. In addition, compared to the conventional example in which the motor is cooled by the air flow, the air purging becomes unnecessary, so that an energy saving effect can be obtained, the apparatus can be downsized, and the number of parts such as cooling fins and manifolds can be reduced And the air flow rate control is not necessary, so that the entire apparatus can be simplified.

According to the present embodiment, noise can be reduced because the pump 20 is installed in the tank 10 and immersed in the pumped liquid 11, and the tank 10 serves as a double housing.

According to the present embodiment, the suction port 20a of the pump 20 is disposed at a height higher than that of the motor stator 23. Therefore, during the normal operation of the pump 20, 23b can be immersed in the pumped liquid 11 to maintain the state of direct cooling.

According to the present embodiment, when the control device 4 monitors the current supplied to the motor stator 23 and the current supplied to the motor stator 23 becomes smaller than the predetermined threshold value, The winding 23b is not immersed in the pumped liquid 11 and the winding 23b is efficiently pumped by the pumped liquid 11 because at least one operation of stopping supply of current to the coil 23 and sounding of the alarm is executed, It is possible to prevent the temperature of the winding 23b from excessively increasing due to the continuous operation of the pump 20. [

Although the first embodiment has been described in detail above, the present technology is not limited to the above-described embodiments, and various modifications can be applied to the above-described embodiments. Hereinafter, an example of the modification will be described with reference to the drawings. In the drawings used in the following description and the following description, the same reference numerals as those used for the corresponding parts in the above-described embodiments are used for the parts that can be configured similarly to the above-described embodiments, The description will be omitted.

Fig. 4 is a schematic view showing a configuration of the pump apparatus 1 'according to the second embodiment.

In the second embodiment, a guide 29 for guiding the pumped liquid 11 is disposed on the suction side of the pump 20 so that the pumped liquid 11 passes through the position where the motor casing 25 opens. In the illustrated example, the guide 29 has a flat plate shape and is spaced upward from the suction port 20a and arranged so as to face both the suction port 20a and the opening 25a of the motor casing 25. [

When the operation of the pump 20 is started, the pumped liquid 11 in the tank 10 passes through the gap between the motor casing 25 and the guide 29 to the position where the motor casing 25 opens, (20a).

According to this embodiment, even if the temperature of the pumped liquid 11 rises due to the heat of the coil 23b in the vicinity of the coil 23b of the motor stator 23, the pumped liquid 11 whose temperature rises does not stay Therefore, the cooling efficiency of the winding 23b by the pumped liquid 11 can be further increased.

In the above embodiment, the pump 20 is arranged vertically in the tank 10 (the inlet 20a is upward), but the present invention is not limited thereto. Depending on the shape of the tank 10, May be disposed horizontally in the tank 10 (the suction port 20a is set in the lateral direction).

Further, in the above-described embodiment, the controller 4 calculates the rate of change of the current supplied to the motor stator 23. When it is determined that the current is smaller than the predetermined threshold value and is in the cooperative operation state, The operation of at least one of stopping the current supply to the stator 23 and ringing the alarm is configured to be performed, but the present invention is not limited thereto.

For example, the control device 4 monitors the measurement value of a flow sensor (not shown) provided on the transfer pipe 14 or the like, and when it is judged that the flow rate is smaller than the predetermined threshold value and is in the open operation state, And stopping supply of current to the stator 23 and ringing an alarm.

For example, the control device 4 monitors the measured value of the water level sensor (not shown) provided in the tank 10, and judges whether the water level in the tank 10 reaches a predetermined threshold value Height position) of the motor stator 23 and is judged to be in the idle operating state, it may be configured to perform at least one of the operation stop of the current supply to the motor stator 23 and the alarm sounding.

Even when the winding 23b is not immersed in the pumped liquid 11 and the winding 23b is not efficiently cooled by the pumped liquid 11, the operation of the pump 20 is continued to the winding 23b can be prevented from excessively increasing.

Although the embodiment of the present invention has been described above by way of example, the scope of the present invention is not limited to this embodiment, and it is needless to say that various changes and modifications may be appropriately made within the scope of the claims .

Claims (4)

A tank in which insulating pumped liquid is stored,
The pump
And,
The pump includes:
An impeller in which a magnet is embedded,
A motor stator disposed at a position opposite to the magnet,
A pump casing accommodating the impeller,
And a motor casing
Lt; / RTI &
Wherein the motor casing has an opening in which the windings of the motor stator are immersed in the pumped liquid
And the pump device. The pump according to claim 1, wherein a guide for guiding the pumped liquid is disposed on a suction side of the pump so that the pumped liquid passes through a position at which the motor casing opens
And the pump device. The pump according to claim 1 or 2, wherein the suction port of the pump is disposed at a height higher than the motor stator
And the pump device. The motor stator according to claim 3, further comprising: a current monitoring unit for monitoring a current supplied to the motor stator, and when the current supplied to the motor stator becomes smaller than a predetermined threshold value, And a control unit for executing one operation
And the pump device.

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