JP2020084815A - Centrifugal pump - Google Patents

Abstract

To increase centrifugal force to be added to a fluid by increasing a diameter of an impeller while suppressing the enlargement of a pump housing.SOLUTION: A centrifugal pump 10 includes an impeller 56 that has a blade portion 58, a pump housing 26 that stores the impeller 56, a rotary shaft 36 that rotation-drives the impeller 56, a suction port 46 that is provided in the pump housing 26 and has a suction port 47, a volute forming portion 50 that is provided in the pump housing 26 and forms a volute 51, and a discharge port 53 that is provided in the pump housing 26 and has a discharge port 54. The blade portion 58 has an extension blade portion 59 that projects outward in a diametrical direction from a main plate portion 57 and opposes to a side wall portion 18b of an impeller chamber 44 through a gap. The volute forming portion 50 is disposed so as to oppose to the extension blade portion 59 on a side facing the main plate portion 57 of the impeller 56.SELECTED DRAWING: Figure 3

Description

The technology disclosed herein relates to centrifugal pumps. More specifically, the present invention relates to a centrifugal pump that sucks fluid, pressurizes it, and discharges it.

Conventionally, for example, there is a centrifugal pump described in Patent Document 1. The centrifugal pump has a plurality of blade plates formed radially, and an impeller in which a ring-shaped front plate is formed at the tip of the top of the blade plate, and an impeller having an appropriate clearance with the front plate inside. It has a blade plate storage chamber for storing the plate pieces. A suction chamber communicating with the suction port is formed at the center of the impeller, and the housing has a pump discharge port at a position corresponding to the blade plate piece formation side and the outer peripheral side of the impeller. A circumferential projection is formed at the boundary between the blade plate piece storage chamber and the suction chamber so as to project toward the blade plate piece.

JP, 2009-8062, A

According to the conventional centrifugal pump, the volute provided in the housing and for introducing the fluid on the impeller side is arranged so as to surround the outer peripheral portion of the impeller between the side wall portion of the impeller chamber and the outer peripheral portion of the impeller. In such a volute, it is difficult to increase the centrifugal force applied to the fluid, because the increase in diameter of the impeller is limited. Further, by increasing the diameter of the housing, it is possible to increase the diameter of the impeller and increase the centrifugal force applied to the fluid, but this leads to an increase in the size of the housing.

An object of the technology disclosed in this specification is to increase the diameter of the impeller and increase the centrifugal force applied to the fluid while suppressing the increase in size of the pump housing.

In order to solve the above problems, the technique disclosed in the present specification takes the following means.

A first means is a centrifugal pump that sucks fluid, pressurizes and discharges the fluid, and has an impeller having a plurality of blade portions radially extending on one surface of a disc-shaped main plate portion, and the impeller. A pump housing having an impeller chamber for rotatably accommodating therein, a rotary shaft for rotationally driving the impeller, and a suction port provided in the pump housing and communicating with the impeller chamber on a side of the impeller facing the vane portion. A suction port, a volute forming portion that is provided in the pump housing and forms a volute that introduces fluid on the impeller side, and a discharge port that is provided in the pump housing and that communicates with a downstream end of the volute. A discharge port having, wherein the vane portion has an extending vane portion that projects radially outward from the main plate portion and faces a side wall portion of the impeller chamber with a gap, The volute forming portion is a centrifugal pump arranged so as to face the extending blade portion on the side of the impeller facing the main plate portion.

According to the first means, the volute forming portion of the pump housing is arranged so as to face the extending blade portion of the impeller on the side facing the main plate portion of the impeller. Therefore, it is possible to eliminate the conventional restriction of reducing the diameter of the impeller by the outer peripheral volute. Further, the extending blade portion of the impeller can be extended so as to face the side wall portion of the impeller chamber with a gap therebetween. Therefore, it is possible to increase the diameter of the impeller and increase the centrifugal force applied to the fluid while suppressing the size increase of the pump housing. Also, pump efficiency can be improved by increasing the centrifugal force applied to the fluid.

A second means is the centrifugal pump according to the first means, wherein a side surface of the extending blade portion on a front side in the impeller rotation direction is inclined outward in the impeller radial direction and toward the volute side. It is a pump.

According to the second means, the impeller-side fluid can be easily introduced into the volute by the side surface of the extending blade portion of the impeller on the front side in the impeller rotation direction. Thereby, pump efficiency can be improved.

A third means is the centrifugal pump according to the first means, wherein the impeller has a corner angle between the extending vane portion and the main plate portion on the rear side of the extending vane portion in the impeller rotation direction. The centrifugal pump is provided with a shielding portion that shields the portion.

According to the third means, the blowback of the fluid from the volute side to the impeller side can be suppressed by the impeller shield portion, and the flow of the fluid in the volute can be rectified. Thereby, pump efficiency can be improved.

A fourth means is the centrifugal pump according to the first means, wherein the impeller has a corner between the main body portion of the blade portion and the main plate portion on the rear side of the extending blade portion in the impeller rotation direction. The centrifugal pump is provided with a shielding portion that shields a corner portion.

According to the fourth means, the blowback of the fluid from the volute side to the impeller side can be suppressed by the impeller shield portion, and the flow of the fluid in the volute can be rectified. Thereby, pump efficiency can be improved.

A fifth means is the centrifugal pump according to any one of the first to fourth means, wherein the extending vane portion is provided with a guide portion for guiding the fluid to the volute side. Is.

According to the fifth means, the guide portion of the impeller guides the fluid to the volute side, so that the frictional resistance of the fluid to the side wall portion of the impeller chamber can be reduced. Thereby, pump efficiency can be improved.

6th means is a centrifugal pump of a 5th means, Comprising: The said guide part is a centrifugal pump which has a concave curved surface which curves to the said volute side toward the front-end|tip of the said extension blade part.

According to the sixth means, the flow of the fluid on the impeller side to the volute side can be smoothed by the concave curved surface. Thereby, pump efficiency can be improved.

A seventh means is the centrifugal pump according to any one of the first to sixth means, wherein the discharge port is formed in a hollow hole shape extending tangentially outward from a downstream end of the volute. The discharge port has a circular cross section, the inner diameter of which gradually increases from the volute side toward the downstream side, and the center line inclines in the direction in which the impeller and the volute are aligned from the upstream side toward the downstream side. It is a centrifugal pump having a gradually changing portion.

According to the seventh means, the flow of the fluid flowing from the volute side to the downstream side of the discharge port can be smoothed by the gradually changing portion. Thereby, pump efficiency can be improved.

Eighth means is a centrifugal pump that sucks fluid, pressurizes it, and discharges it. An impeller having a communication hole penetrating the main plate portion in the plate thickness direction on the side of the central portion thereof, a pump housing having an impeller chamber that rotatably accommodates the impeller, a rotary shaft that rotationally drives the impeller, and the pump A suction port that is provided in the housing and has a suction port that communicates with the impeller chamber on a side of the impeller that faces the main plate portion; and a volute that is provided in the pump housing and that forms a volute that introduces fluid on the impeller side. A discharge port provided in the pump housing and having a discharge port communicating with the downstream end of the volute; A guide wall portion that faces the blade portion of the impeller on the side facing the blade portion of the impeller, and the guide wall portion that faces the blade portion of the impeller is provided. Is a centrifugal pump that is arranged to

According to the eighth means, the volute forming portion of the pump housing is arranged so as to face the blade end portion of the blade portion on the side facing the blade portion of the impeller. Therefore, it is possible to eliminate the conventional restriction of reducing the diameter of the impeller by the outer peripheral volute. Further, the blade portion can be extended so that the guide wall portion of the impeller faces the side wall portion of the impeller chamber with a gap. Therefore, it is possible to increase the diameter of the impeller and increase the centrifugal force applied to the fluid while suppressing the size increase of the pump housing. In addition, the pump efficiency can be improved by increasing the centrifugal force applied to the fluid.

A ninth means is the centrifugal pump according to the eighth means, wherein a bearing is interposed between the pump housing and the rotary shaft on a side of the pump housing facing the vane portion of the impeller. , A centrifugal pump.

According to the ninth means, the bearing can be positively cooled by the fluid flowing in the impeller chamber. As a result, deterioration of the bearing due to heat damage can be suppressed.

A tenth means is the centrifugal pump according to the eighth or ninth means, wherein the discharge port is formed in a hollow hole shape extending tangentially outward from a downstream end portion of the volute, and The discharge port has a gradually changing portion having a circular cross section, the inner diameter of which gradually increases from the volute side toward the downstream side, and the center line of which is inclined in the direction in which the impeller and the volute are aligned from the upstream side toward the downstream side. It has a centrifugal pump.

According to the tenth means, the flow of the fluid flowing from the volute side to the downstream side of the discharge port can be smoothed by the gradually changing portion. Thereby, pump efficiency can be improved.

An eleventh means is a centrifugal pump that sucks fluid, pressurizes and discharges the fluid, and has an impeller having a plurality of blade portions radially extending on one surface of a disc-shaped main plate portion, and the impeller. A pump housing having an impeller chamber for rotatably accommodating therein, a rotary shaft for rotationally driving the impeller, and a suction port provided in the pump housing and communicating with the impeller chamber on a side of the impeller facing the vane portion. A suction port, a volute forming portion that is provided in the pump housing and forms a volute that introduces fluid on the impeller side, and a discharge port that is provided in the pump housing and that communicates with a downstream end of the volute. A discharge port having, and having an outer peripheral portion of the impeller, a guide wall portion that faces the side wall portion of the impeller chamber with a gap and guides the fluid to the volute side is provided, The volute forming portion is a centrifugal pump arranged so as to face a blade end portion of the impeller on a side of the impeller facing the blade portion.

According to the eleventh means, the volute forming portion of the pump housing is arranged so as to face the blade end portion of the blade portion on the side facing the blade portion of the impeller. Therefore, it is possible to eliminate the conventional restriction of reducing the diameter of the impeller by the outer peripheral volute. Further, the blade portion can be extended so that the guide wall portion of the impeller faces the side wall portion of the impeller chamber with a gap. Therefore, it is possible to increase the diameter of the impeller and increase the centrifugal force applied to the fluid while suppressing the size increase of the pump housing. Also, pump efficiency can be improved by increasing the centrifugal force applied to the fluid.

A twelfth means is the centrifugal pump according to the eleventh means, wherein the discharge port is arranged in parallel with the suction port.

According to the twelfth means, the pipes for the discharge port and the suction port can be routed in the same direction. As a result, the maneuverability of the pipe for the discharge port and the suction port can be improved.

According to the technique disclosed in the present specification, it is possible to increase the diameter of the impeller and increase the centrifugal force applied to the fluid while suppressing the increase in size of the pump housing.

3 is a plan view schematically showing the centrifugal pump according to the first embodiment. FIG. FIG. 2 is a sectional view taken along the line II-II of FIG. 1. It is sectional drawing which shows a pump part typically. It is a perspective view which shows the blade|wing part of an impeller. FIG. 6 is a perspective view showing a blade portion of an impeller according to the second embodiment. It is the side view which looked at the impeller blade part from the impeller radial direction outside. FIG. 6 is a perspective view showing a shield plate portion of the impeller according to the third embodiment. FIG. 9 is a perspective view showing a shield plate portion of the impeller according to the fourth embodiment. FIG. 10 is a perspective view showing a shield plate portion of the impeller according to the fifth embodiment. It is the side view which looked at the guide plate part of the impeller concerning Embodiment 6 from the impeller radial direction outside. FIG. 11 is a sectional view taken along the line XI-XI of FIG. 10. It is the side view which looked at the guide plate part of the impeller concerning Embodiment 7 from the impeller radial direction outside. It is sectional drawing which shows the discharge port concerning Embodiment 8. It is the figure which looked at the discharge port from the exit side. It is sectional drawing which shows the pump part concerning Embodiment 9 typically. It is sectional drawing which shows the pump part concerning Embodiment 10 typically.

Hereinafter, embodiments will be described with reference to the drawings.

[Embodiment 1]
In the present embodiment, a centrifugal pump used as a purge pump mounted on a vehicle such as an automobile is exemplified. The purge pump is a centrifugal pump that supplements the purge amount of purge gas from the canister to the intake passage of the internal combustion engine (engine). 1 is a plan view schematically showing a centrifugal pump, and FIG. 2 is a sectional view taken along the line II-II of FIG. Note that the orientation of the centrifugal pump is determined as shown by the arrow in FIGS. 1 and 2, but the orientation of the centrifugal pump is not specified.

(Outline of centrifugal pump)
As shown in FIG. 2, the centrifugal pump 10 includes a pump unit 12 and a motor unit 14 which are arranged in the axial direction (vertical direction). The housing 16 of the centrifugal pump 10 includes a pump cover 18, a pump body 20, and a motor case 22. The pump cover 18 is formed in the shape of a short cylinder whose upper surface is closed. The motor case 22 is formed in a bottomed cylindrical shape. The pump cover 18 and the motor case 22 are fastened together by a plurality of screws or the like.

The pump body 20 is formed in an annular plate shape. The outer peripheral end 20 a of the pump body 20 is sandwiched between the pump cover 18 and the motor case 22. The pump body 20 vertically divides an internal space formed by the pump cover 18 and the motor case 22. An O-ring 24 is interposed between the pump cover 18 and the motor case 22 to seal them. The O-ring 24 also seals between the pump body 20 and the motor case 22. A hollow cylindrical boss portion 20b extending downward is concentrically formed in the central portion of the pump body 20.

The pump cover 18 and the pump body 20 form a pump housing 26. A motor housing 28 is configured by the motor case 22 and the pump body 20. The pump cover 18, the pump body 20, and the motor case 22 are each made of metal.

(Motor part 14)
The motor unit 14 is a brushless motor. A stator 30, a rotor 32, a control circuit 34 and the like are housed in the motor case 22. The stator 30 is formed in a cylindrical shape, and is concentrically and fixedly arranged in the motor case 22. The stator 30 includes a stator core, a stator coil and the like.

The rotor 32 is concentrically and rotatably arranged in the hollow portion of the stator 30. The rotor 32 includes a rotating shaft 36 and a permanent magnet 38. A plurality of permanent magnets 38 are arranged so as to have a plurality of magnetic poles in the circumferential direction with respect to the rotating shaft 36. One end (upper end) of the rotary shaft 36 projects upward from the permanent magnet 38. The upper end of the rotary shaft 36 is the end on the output side and is inserted into the boss portion 20b of the pump body 20. The rotating shaft 36 is rotatably supported by the boss portion 20b via a pair of upper and lower bearings 40. The bearing 40 is a ball bearing.

The control circuit 34 is arranged at the lower end of the motor case 22. Further, the motor case 22 has an electric connector portion (not shown). An external power supply connector is connected to the electrical connector portion. The rotor 32 is rotationally driven by the supply of electric power from the external power supply to the control circuit 34.

(Pump part 12)
FIG. 3 is a sectional view schematically showing the pump portion. As shown in FIG. 3, a substantially circular impeller chamber 44 is concentrically formed inside the pump housing 26. The pump cover 18 has an annular plate-shaped upper wall portion 18a and a side wall portion 18b extending downward from the outer peripheral portion of the upper wall portion 18a. A hollow cylindrical suction port 46 protruding upward is formed at the center of the upper wall portion 18a. A suction port 47 is formed in the suction port 46 to communicate the inside and outside of the impeller chamber 44. An arc wall portion 18c having a quarter arc shape in cross section is formed at an inner corner portion between the upper wall portion 18a and the side wall portion 18b.

In the pump body 20, an annular plate-shaped portion extending radially outward from the upper end of the boss portion 20b is referred to as a main wall portion 20c. Between the outer peripheral end 20a and the main wall 20c, a stepped wall 20d is formed in a concentric manner in the shape of an annular plate that is one step lower. A short cylindrical upper cylinder wall portion 20e is formed between the outer peripheral portion of the main wall portion 20c and the inner peripheral portion of the step wall portion 20d. A lower cylindrical wall portion 20f having a short cylindrical shape is formed between the inner peripheral portion of the outer peripheral end portion 20a and the outer peripheral portion of the step wall portion 20d. Inner corners of the step wall portion 20d and the upper cylinder wall portion 20e are formed in an arcuate cross section. The lower cylindrical wall portion 20f is fitted in the side wall portion 18b of the pump cover 18 with almost no space. The side wall portion 18b of the pump cover 18, the stepped wall portion 20d of the pump body 20, and the upper cylindrical wall portion 20e constitute a volute forming portion 50 that forms a substantially annular groove-shaped volute 51.

A hollow cylindrical discharge port 53 is formed on the left side of the rear portion of the pump cover 18 (see FIG. 1). The discharge port 53 projects tangentially outward, that is, counterclockwise outward from the outer peripheral portion of the pump cover 18 in a plan view (see FIG. 1 ). A discharge port 54 is formed in the discharge port 53. The upstream end of the discharge port 54 communicates with the downstream end of the volute 51. The upstream opening of the discharge port 54 is formed so as to overlap the volute 51 in the axial direction of the impeller chamber 44.

An impeller 56 is rotatably housed in the impeller chamber 44. The impeller 56 has a disc-shaped main plate portion 57 and a plurality of blade portions 58 formed on the upper surface, which is one surface of the main plate portion 57, at a predetermined interval in the circumferential direction. The main plate portion 57 faces the upper surface of the main wall portion 20c of the pump body 20 with a slight gap. The main plate portion 57 has the same or substantially the same outer diameter as the outer diameter of the main wall portion 20c of the pump body 20. A shaft hole 57a is formed at the center of the main plate portion 57. The shaft hole 57a is integrally rotatably fitted to the tip (upper end) of the rotary shaft 36 of the rotor 32. Therefore, the impeller 56 is rotated integrally with the rotation of the rotor 32. The impeller 56 is rotated counterclockwise in a plan view. The impeller 56 is made of resin.

The plurality of blades 58 are formed on the upper surface of the main plate 57 in the shape of a strip plate extending upright and radially (see FIG. 4 ). The vane portion 58 has an extending vane portion 59 that projects radially outward from the main plate portion 57. The lower end surface 59a (see FIG. 4) of the extending blade portion 59 is formed so as to be flush with the lower surface of the main plate portion 57.

The extending blade portion 59 faces the volute forming portion 50. That is, the volute forming portion 50 is arranged so as to face the extending blade portion 59 on the side facing the main plate portion 57 of the pump housing 26, that is, on the lower side. Further, the outer end portion of the extending blade portion 59 faces the side wall portion 18b of the pump cover 18 corresponding to the side wall portion of the impeller chamber 44 with a slight gap. The upper portion of the extending blade portion 59 is rounded so as to follow the arc wall portion 18c of the pump cover 18. A portion of the blade portion 58 within the range of the outer diameter of the main plate portion 57 is referred to as a main body portion 58a.

(Operation of centrifugal pump 10)
When the motor unit 14 is driven by the supply of electric power from the external power supply, the impeller 56 is rotated together with the rotor 32, so that the purge gas as a fluid is sucked into the impeller chamber 44 from the suction port 47. The purge gas is sent into the volute 51 by the arc wall portion 18c of the pump cover 18 while flowing radially outward by the rotation of the impeller 56. The purge gas is discharged while being swirled in the volute 51 while being pressurized while flowing to the downstream side. In this way, the purge gas is pumped by the centrifugal pump 10. The flow of purge gas is shown by an arrow in FIG.

(Advantages of this embodiment)
According to the present embodiment, the volute forming portion 50 of the pump housing 26 is arranged so as to face the extended blade portion 59 of the impeller 56 on the side (lower side) of the impeller 56 that faces the main plate portion 57. Therefore, it is possible to eliminate the conventional restriction of reducing the diameter of the impeller 56 due to the outer peripheral volute. Further, the extending blade portion 59 of the impeller 56 can be extended so as to face the side wall portion 18b of the impeller chamber 44 with a gap. Therefore, it is possible to increase the diameter of the impeller 56 and increase the centrifugal force applied to the purge gas while suppressing the increase in size of the pump housing 26. In addition, pump efficiency can be improved by increasing the centrifugal force applied to the purge gas. As a result, it is possible to reduce the rotational torque of the impeller 56 and reduce the power consumption of the motor unit 14.

The pump efficiency can also be improved by rectifying the flow by generating a vortex flow due to the swirling of the purge gas in the volute 51.

[Embodiment 2]
Since the present embodiment is a modification of the impeller 56 (see FIG. 4) of the first embodiment, only the changed part will be described, and duplicate description will be omitted. FIG. 5 is a perspective view showing a blade portion of the impeller, and FIG. 6 is a side view of the blade portion of the impeller seen from the outer side in the impeller radial direction. As shown in FIGS. 5 and 6, in the extending blade portion 59 of the blade portion 58 of the impeller 56, the side surface 59b on the front side in the impeller rotation direction inclines downward toward the impeller radial direction diagonally outward and the volute 51 side. Is formed in a curved shape. Further, in the present embodiment, the lower end surface 59a of the extended blade portion 59 is formed so as to be flush with the upper surface of the main plate portion 57.

According to the present embodiment, the side surface 59b of the extending blade portion 59 of the impeller 56 on the front side in the impeller rotation direction can facilitate introduction of the purge gas on the impeller 56 side into the volute 51. Thereby, pump efficiency can be improved.

Further, when the impeller 56 is resin-molded, it is possible to deal with it by simply changing the mold without changing the existing process. Therefore, it is possible to suppress the influence on the productivity.

[Third Embodiment]
Since the present embodiment is a modification of the impeller 56 (see FIG. 4) of the first embodiment, only the changed part will be described, and duplicate description will be omitted. FIG. 7 is a perspective view showing the shield plate portion of the impeller. As shown in FIG. 7, the impeller 56 is provided with a shielding plate portion 61 that shields a corner portion between the extending blade portion 59 and the main plate portion 57 on the rear side of the extending blade portion 59 in the impeller rotation direction. Has been. The shield plate portion 61 is formed in a substantially triangular plate shape in a plan view. The shield plate portion 61 corresponds to the “shield portion” in this specification.

According to the present embodiment, the blowback of the purge gas from the volute 51 side to the impeller 56 side can be suppressed by the shielding plate portion 61 of the impeller 56, and the flow of the purge gas in the volute 51 can be rectified. Thereby, pump efficiency can be improved.

Further, since the shielding plate portion 61 also functions as a reinforcing rib, the strength of the extended blade portion 59 of the blade portion 58 can be improved. This is effective in suppressing the occurrence of defects in the extending blade portion 59.

[Embodiment 4]
Since the present embodiment is a modification of the third embodiment (see FIG. 7), only the changed part will be described, and duplicated description will be omitted. FIG. 8 is a perspective view showing the shield plate portion of the impeller. As shown in FIG. 8, the shielding plate portion (denoted by reference numeral 62) of the present embodiment is formed in a substantially trapezoidal shape having a straight outer end edge 62a on the radially outer end side of the impeller 56 in a plan view. ing. The shielding plate portion 62 corresponds to the “shielding portion” in this specification.

According to this embodiment, the shielding area of the shielding plate portion 62 of the impeller 56 can be increased as compared with the third embodiment (see FIG. 7).

[Fifth Embodiment]
Since the present embodiment is a modification of the impeller 56 (see FIG. 4) of the first embodiment, only the changed part will be described, and duplicate description will be omitted. FIG. 9 is a perspective view showing the shield plate portion of the impeller. As shown in FIG. 9, the impeller 56 has a shielding plate portion 63 that shields a corner portion between the main body portion 58a of the blade portion 58 and the main plate portion 57 on the rear side of the extending blade portion 59 in the impeller rotation direction. Is provided. The shield plate portion 63 is formed in a substantially triangular plate shape when viewed from the outside in the radial direction of the impeller. The shielding plate portion 63 corresponds to the "shielding portion" in this specification.

According to this embodiment, the blowing back of the purge gas from the volute 51 side to the impeller 56 side can be suppressed by the shielding plate portion 63 of the impeller 56, and the flow of the purge gas in the volute 51 can be rectified. Thereby, pump efficiency can be improved.

Further, since the shielding plate portion 61 also functions as a reinforcing rib, the strength of the main body portion 58a of the blade portion 58 can be improved.

[Sixth Embodiment]
Since the present embodiment is a modification of the impeller 56 (see FIG. 3) of the first embodiment, only the changed part will be described, and duplicate description will be omitted. 10 is a side view of the guide plate portion of the impeller as seen from the outer side in the radial direction of the impeller, and FIG. 11 is a sectional view taken along the line XI-XI of FIG. As shown in FIG. 11, the extending blade portion 59 of the blade portion 58 of the impeller 56 is provided with a guide plate portion 65 that guides the purge gas to the volute 51 side. The guide plate portion 65 is formed in an arc-shaped cross section along the outer shape of the outer end portion of the extending blade portion 59. The guide plate portion 65 has a concave curved surface 65 a that curves toward the volute 51 side toward the tip of the extending blade portion 59. The guide plate portion 65 is formed in an annular shape that is continuous with the extended blade portions 59 of all the blade portions 58 of the impeller 56 (see FIG. 10). The guide plate portion 65 corresponds to the “guide portion” in this specification.

According to the present embodiment, the guide plate portion 65 of the impeller 56 guides the purge gas to the volute 51 side, so that the friction resistance of the purge gas to the side wall portion 18b of the impeller chamber 44 can be reduced. Thereby, pump efficiency can be improved.

Further, the imbalance of the impeller 56 can be adjusted by performing additional processing such as cutting on the outer side surface of the guide plate portion 65. Thereby, the vibration due to the imbalance of the impeller 56 can be reduced.

Further, the guide plate portion 65 has a concave curved surface 65a that curves toward the volute 51 side toward the tip of the extending blade portion 59. Therefore, the flow of the purge gas on the impeller 56 side to the volute 51 side can be smoothed by the concave curved surface 65a. Thereby, pump efficiency can be improved.

[Embodiment 7]
Since the present embodiment is a modification of the impeller 56 (see FIGS. 10 and 11) of the sixth embodiment, only the changed parts will be described, and redundant description will be omitted. FIG. 12 is a side view of the guide plate portion of the impeller as viewed from the outside in the radial direction of the impeller. As shown in FIG. 12, the guide plate portion (denoted by reference numeral 66) of the present embodiment is the front side of the guide plate portion 65 (see FIG. 10) of the impeller 56 of the sixth embodiment from the blade portion 58 in the impeller rotation direction (see FIG. In FIG. 12, it is formed to the right side) with a predetermined length. Therefore, the opening 67 is formed between the guide plate portion 66 and the blade portion 58 on the front side in the impeller rotation direction. The guide plate portion 66 corresponds to the “guide portion” in this specification.

According to the present embodiment, the impeller 56 can be made lighter than the sixth embodiment (see FIGS. 10 and 11).

[Embodiment 8]
In this embodiment, since the discharge port 53 (see FIGS. 1 and 3) of the first embodiment is modified, only the modified part will be described, and duplicate description will be omitted. FIG. 13 is a sectional view showing the discharge port, and FIG. 14 is a view similarly seen from the outlet side. As shown in FIG. 13, the discharge port (denoted by reference numeral 70) of the present embodiment is formed in the shape of a hollow hole extending tangentially outward from the downstream end of the volute 51. The discharge port 70 has a circular cross section, the inner diameter thereof gradually increases from the volute 51 side toward the downstream side, and the center line 70L is inclined downward from the upstream side toward the downstream side, which is the direction in which the impeller 56 and the volute 51 are aligned. It has a gradually changing portion 72 (see FIG. 14).

According to the present embodiment, the flow of the purge gas flowing from the volute 51 side of the discharge port 70 to the downstream side can be smoothed by the gradual change portion 72 (see the arrow in FIG. 13 ). Thereby, pump efficiency can be improved.

To supplement this point, the flow of the purge gas flowing from the volute 51 side to the downstream side of the discharge port 70 flows so as to spread downward in the direction in which the impeller 56 and the volute 51 are arranged. Therefore, when the discharge port has a constant opening area, the flow of the purge gas is likely to be obstructed. On the other hand, according to the present embodiment, since the discharge port 70 has the gradually changing portion 72, the flow of the purge gas flowing from the volute 51 side to the downstream side of the discharge port 70 can be smoothed by the gradually changing portion 72. ..

[Embodiment 9]
Since the present embodiment is a modification of the impeller 56 (see FIG. 3) of the first embodiment, only the changed part will be described, and duplicate description will be omitted. FIG. 15 is a cross-sectional view schematically showing the pump part. As shown in FIG. 15, the impeller (denoted by reference numeral 74) includes a disk-shaped main plate portion 75 and a plurality of sheets formed on the lower surface, which is one surface of the main plate portion 75, at a predetermined interval in the circumferential direction. And a blade portion 76. The main plate portion 75 has an outer diameter slightly smaller than the inner diameter of the side wall portion 18b of the pump cover 18. A shaft hole 75a is formed in the center of the main plate portion 75. Similar to the first embodiment, the shaft hole 75a is integrally and rotatably fitted to the tip (upper end) of the rotary shaft 36 of the rotor 32.

The plurality of blade portions 76 are formed on the lower surface of the main plate portion 75 in the shape of a strip plate that extends downward and radially. A communication hole 77 that penetrates the main plate portion 75 in the plate thickness direction is formed at the center side of the main plate portion 75, that is, at a portion near the shaft hole 75a. The communication hole 77 is arranged between the blade portions 76 adjacent to each other in the circumferential direction.

A guide wall portion 78 that guides the purge gas toward the volute 51 is provided on the outer peripheral portion of the impeller 74. The guide wall portion 78 is formed in a short cylindrical shape extending downward from the outer end portion of the main plate portion 75. The guide wall portion 78 is connected to the outer end portions of the plurality of blade portions 76. The outer peripheral surface of the guide wall portion 78 is arranged so as to face the inner peripheral surface of the side wall portion 18b of the pump cover 18 of the pump cover 18, which is the inner peripheral surface of the impeller chamber 44, with a slight gap therebetween. On the inner peripheral side of the guide wall portion 78, a guide surface 78a having a concave curved surface whose inner diameter gradually increases from the upper side to the lower side is formed. Of the blade portion 76, a portion within the range of the minimum inner diameter of the guide surface 78a is referred to as a main body portion 76a, and a portion outside the range of the minimum inner diameter of the guide surface 78a is referred to as a blade end portion 76b.

The blade end portion 76b of the blade portion 76 faces the volute forming portion 50. That is, the volute forming portion 50 is arranged so as to face the blade end portion 76b of the blade portion 76 on the side facing the blade portion 76 of the impeller 74, that is, on the lower side.

In the present embodiment, as the impeller 74 is rotated, the purge gas, which is a gas, is sucked into the impeller chamber 44 from the suction port 47, and then the blade portions 76 that are circumferentially adjacent to each other via the communication hole 77 of the impeller 74. Flows in between. The purge gas is sent into the volute 51 by the guide wall portion 78 while flowing radially outward by the rotation of the impeller 74. The purge gas is discharged while being swirled in the volute 51 while being pressurized while flowing to the downstream side. In this way, the purge gas is pumped by the centrifugal pump 10.

According to the present embodiment, the volute forming portion 50 of the pump housing 26 is arranged so as to face the blade end portion 76b of the blade portion 76 on the side facing the blade portion 76 (lower side) of the impeller 74. Therefore, it is possible to eliminate the conventional restriction of reducing the diameter of the impeller 74 due to the outer peripheral volute. Further, the blade portion 76 can be extended so that the guide wall portion 78 of the impeller 74 faces the side wall portion 18b of the impeller chamber 44 with a gap. Therefore, it is possible to increase the diameter of the impeller 74 and increase the centrifugal force applied to the purge gas while suppressing the increase in size of the pump housing 26. In addition, pump efficiency can be improved by increasing the centrifugal force applied to the purge gas. As a result, it is possible to reduce the rotational torque of the impeller 74 and reduce the power consumption of the motor unit 14.

The pump efficiency can also be improved by rectifying the flow by generating a vortex flow due to the swirling of the purge gas in the volute 51.

Further, a bearing 40 is interposed between the pump housing 26 and the rotary shaft 36 on the side (lower side) of the pump housing 26 that faces the blade portion 76 of the impeller 74. Therefore, the bearing 40 can be positively cooled by the purge gas flowing through the impeller chamber 44. As a result, deterioration of the bearing 40 due to heat damage can be suppressed.

Further, the ejection port 70 of the eighth embodiment (see FIGS. 13 and 14) can also be applied to the present embodiment.

[Embodiment 10]
Since the present embodiment is a modification of the pump unit 12 (see FIG. 3) of the first embodiment, only the modified part will be described, and duplicate description will be omitted. FIG. 16 is a sectional view schematically showing the pump section. As shown in FIG. 16, in the present embodiment, the impeller 74 (see FIG. 3) of the first embodiment is changed to an impeller (reference numeral 74A is attached). The impeller 74A has the same configuration as that of the impeller 74 except that the communication hole 77 of the impeller 74 (see FIG. 15) of the ninth embodiment is not formed, and therefore, the same reference numerals are given to the same portions and overlapping description will be omitted. ..

The impeller 74A is arranged in the impeller chamber 44 in a state of being turned upside down. Therefore, the impeller 74A has a plurality of blade portions 76 on the lower surface which is one surface of the main plate portion 75. The outer peripheral surface of the guide wall portion 78 faces the inner peripheral surface of the side wall portion 18b of the pump cover 18, which is the inner peripheral surface of the impeller chamber 44, with a slight gap therebetween, as in the ninth embodiment (see FIG. 15). It is arranged to. The tip end (upper end) of the rotary shaft 36 is integrally rotatably fitted in the shaft hole 75a of the impeller 74A.

In the pump body 20, instead of omitting the upper cylindrical wall portion 20e and the stepped wall portion 20d of the first embodiment (see FIG. 3), the main wall portion 20c has a larger diameter and the lower cylindrical wall portion 20f moves upward. It is extended and the upper end of the lower cylindrical wall 20f is connected to the outer periphery of the main wall 20c.

An annular volute forming portion (denoted by reference numeral 80) is formed on the outer peripheral portion of the upper wall portion 18a of the pump cover 18. The volute forming portion 80 is formed in a semi-circular shape in cross section having an opening on the lower surface. The volute forming unit 80 forms a volute 81 for introducing the purge gas on the impeller 74A side. That is, the volute forming portion 80 is arranged so as to face the blade end portion 76b of the blade portion 76 on the side facing the blade portion 76 of the impeller 74, that is, on the upper side.

On the upper surface side of the volute forming portion 80, a hollow cylindrical discharge port (denoted by reference numeral 83) is vertically formed. The discharge port 83 is arranged in parallel with the suction port 46. A discharge port 84 is formed in the discharge port 83. The upstream end of the discharge port 84 communicates with the downstream end of the volute 81. The upstream opening of the discharge port 84 is formed so as to overlap the volute 81 in the radial direction of the impeller chamber 44.

In the present embodiment, as the impeller 74A is rotated, the purge gas, which is a gas, is sucked into the impeller chamber 44 from the suction port 47. The purge gas is sent into the volute 81 by the guide wall portion 78 while flowing radially outward by the rotation of the impeller 74A. The purge gas is discharged while being swirled in the volute 81 while being pressurized while flowing to the downstream side. In this way, the purge gas is pumped by the centrifugal pump 10.

According to the present embodiment, the volute forming portion 80 of the pump housing 26 is arranged so as to face the outer end portion of the impeller 74 on the side (upper side) of the impeller 74 that faces the blade portions 76. Therefore, it is possible to eliminate the conventional restriction of reducing the diameter of the impeller 74A due to the outer peripheral volute. Further, the blade portion 76 can be extended so that the guide plate portion 65 of the impeller 74A faces the side wall portion 18b of the impeller chamber 44 with a gap. Therefore, it is possible to increase the diameter of the impeller 74A and increase the centrifugal force applied to the purge gas while suppressing the increase in size of the pump housing 26. In addition, pump efficiency can be improved by increasing the centrifugal force applied to the purge gas. As a result, it is possible to reduce the rotational torque of the impeller 74A and reduce the power consumption of the motor unit 14.

The pump efficiency can also be improved by rectifying the flow by generating a vortex flow due to the swirling of the purge gas in the volute 51.

Further, the discharge port 83 is arranged in parallel with the suction port 46. Therefore, the pipes for the discharge port 83 and the suction port 46 can be routed in the same direction. As a result, the maneuverability of the piping for the discharge port 83 and the suction port 46 can be improved.

[Other Embodiments]
The technology disclosed in this specification is not limited to the above-described embodiment, and can be implemented in various other forms. For example, the centrifugal pump 10 may be applied to a pump used for pressure-feeding a gas such as air other than the purge gas, or a fluid such as a liquid. The brushless motor of the motor unit 14 may be replaced with a brush motor. Alternatively, the centrifugal pump may be configured only by the pump unit 12, and the rotating shaft 36 may be driven by an external drive source. Further, the shape and arrangement of the impeller blades may be changed as desired.

10 Centrifugal Pump 18 Pump Cover 18a Upper Wall 18b Side Wall 20 Pump Body 26 Pump Housing 36 Rotating Shaft 40 Bearing 44 Impeller Chamber 46 Suction Port 47 Suction Port 50 Volute Forming Port 51 Volute 53 Discharge Port 54 Discharge Port 56 Impeller 57 Main Plate Section 58 vane portion 58a main body portion 59 extended vane portion 59a lower end surface 59b side surface 61 shielding plate portion (shielding portion)
62 Shield Plate (Shield)
63 Shield plate part (shield part)
65 Guide plate (guide)
65a concave curved surface 66 guide plate portion (guide portion)
70 Discharge Port 72 Gradual Change Unit 74 Impeller 74A Impeller 75 Main Plate 76 Main Blade 76a Main Body 76b Blade End 77 Communication Hole 78 Guide Wall 80 Volute Forming Section 81 Volute 83 Discharge Port 84 Discharge Port

Claims (12)

A centrifugal pump that inhales fluid, pressurizes it, and discharges it,
An impeller having a plurality of blade portions extending radially on one surface of a disc-shaped main plate portion,
A pump housing having an impeller chamber that rotatably houses the impeller;
A rotating shaft for driving the impeller to rotate,
A suction port provided in the pump housing and having a suction port communicating with the impeller chamber on a side of the impeller facing the vane portion;
A volute forming part provided in the pump housing and forming a volute for introducing the fluid on the impeller side;
A discharge port provided in the pump housing and having a discharge port communicating with the downstream end of the volute;
Is equipped with
The vane portion has an extending vane portion that projects radially outward from the main plate portion and faces the side wall portion of the impeller chamber via a gap,
The centrifugal pump, wherein the volute forming portion is arranged so as to face the extending blade portion on a side of the impeller facing the main plate portion. The centrifugal pump according to claim 1,
The centrifugal pump in which the side surface of the extending blade portion on the front side in the impeller rotation direction is inclined obliquely outward in the impeller radial direction and toward the volute side. The centrifugal pump according to claim 1,
The centrifugal pump, wherein the impeller is provided with a shielding portion that shields a corner portion between the extending blade portion and the main plate portion, on the rear side of the extending blade portion in the impeller rotation direction. The centrifugal pump according to claim 1,
The centrifugal pump, wherein the impeller is provided with a shield portion that shields a corner portion between the main body portion of the blade portion and the main plate portion, on the rear side of the extending blade portion in the impeller rotation direction. The centrifugal pump according to any one of claims 1 to 4,
The centrifugal pump in which the extension vane part is provided with a guide part for guiding the fluid to the volute side. The centrifugal pump according to claim 5, wherein
The centrifugal pump, wherein the guide portion has a concave curved surface that curves toward the volute side toward the tip of the extending blade portion. The centrifugal pump according to any one of claims 1 to 6,
The discharge port is formed in the shape of a hollow hole extending tangentially outward from the downstream end of the volute,
The discharge port has a circular cross section, the inner diameter of which gradually increases from the volute side to the downstream side, and the center line inclines in the direction in which the impeller and the volute are arranged from the upstream side to the downstream side. Having a centrifugal pump. A centrifugal pump that inhales fluid, pressurizes it, and discharges it,
An impeller having a plurality of blade portions extending radially on one surface of the disc-shaped main plate portion and having a communication hole penetrating the main plate portion in the plate thickness direction on the central portion side of the main plate portion,
A pump housing having an impeller chamber that rotatably houses the impeller;
A rotating shaft for driving the impeller to rotate,
A suction port provided in the pump housing and having a suction port communicating with the impeller chamber on a side of the impeller facing the main plate portion;
A volute forming part provided in the pump housing and forming a volute for introducing the fluid on the impeller side;
A discharge port provided in the pump housing and having a discharge port communicating with the downstream end of the volute;
Is equipped with
The outer peripheral portion of the impeller is provided with a guide wall portion that faces the side wall portion of the impeller chamber with a gap and guides the fluid to the volute side,
The centrifugal pump, wherein the volute forming portion is arranged so as to face a blade end portion of the impeller on a side facing the vane portion. The centrifugal pump according to claim 8, wherein
A centrifugal pump in which a bearing is interposed between the pump housing and the rotating shaft on a side of the pump housing facing the vane portion of the impeller. The centrifugal pump according to claim 8 or 9, wherein
The discharge port is formed in the shape of a hollow hole extending tangentially outward from the downstream end of the volute,
The discharge port has a circular cross section, the inner diameter of which gradually increases from the volute side to the downstream side, and the center line inclines in the direction in which the impeller and the volute are arranged from the upstream side to the downstream side. Having a centrifugal pump. A centrifugal pump that inhales fluid, pressurizes it, and discharges it,
An impeller having a plurality of blade portions extending radially on one surface of a disc-shaped main plate portion,
A pump housing having an impeller chamber that rotatably houses the impeller;
A rotating shaft for driving the impeller to rotate,
A suction port provided in the pump housing and having a suction port communicating with the impeller chamber on a side of the impeller facing the vane portion;
A volute forming part provided in the pump housing and forming a volute for introducing the fluid on the impeller side;
A discharge port provided in the pump housing and having a discharge port communicating with the downstream end of the volute;
Is equipped with
The outer peripheral portion of the impeller is provided with a guide wall portion that faces the side wall portion of the impeller chamber with a gap and guides the fluid to the volute side,
The centrifugal pump, wherein the volute forming portion is arranged so as to face a blade end portion of the impeller on a side facing the vane portion. The centrifugal pump according to claim 11,
The centrifugal pump, wherein the discharge port is arranged in parallel with the suction port.

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