JP2021080835A - Liquid pump - Google Patents

Abstract

To provide a liquid pump capable of restraining lubrication failure caused by air accumulating in the vicinity of a support shaft.SOLUTION: A water pump 100 rotates an impeller 120, and sends out cooling water with centrifugal force. The water pump 100 includes a support shaft 130 which extends along a rotation center of the impeller 120 and has a distal end exposed at a front end of the impeller 120. A through hole 131 communicating an outer peripheral surface with the distal end is provided in the support shaft 130.SELECTED DRAWING: Figure 1

Description

The present invention relates to a liquid pump.

Patent Document 1 discloses a liquid pump that rotates an impeller and delivers a liquid by centrifugal force. In this liquid pump, a through hole is provided in the impeller, and air collected on the back surface of the impeller is discharged to the front side of the impeller through the through hole.

Jikkenhei 5-47493

By the way, the support shaft that supports the impeller is located at the center of rotation of the rotating impeller. Therefore, when the liquid is sent out by centrifugal force, air tends to collect around the support shaft. If air collects around the support shaft, liquid lubrication may not be performed properly.

Hereinafter, means for solving the above problems and their actions and effects will be described.
The liquid pump for solving the above problems is a liquid pump that rotates an impeller and sends out liquid by centrifugal force, and extends along the rotation center of the impeller and the tip is exposed at the front end of the impeller. The support shaft is provided with a communication hole for communicating the outer peripheral surface of the support shaft and the tip of the support shaft.

As the impeller rotates, the liquid is sent out by centrifugal force so as to move away from the center of rotation of the impeller. Therefore, a negative pressure is generated by the flow of the liquid near the center of the front end of the impeller where the tip of the support shaft is exposed. In the above configuration, the support shaft is provided with a communication hole that communicates with the tip. The communication hole also communicates with the outer peripheral surface of the support shaft. Therefore, due to the action of the negative pressure generated by the rotation of the impeller, a flow is generated in the communication hole from the outer peripheral surface side of the support shaft toward the tip end side of the support shaft. According to the above configuration, the air accumulated around the support shaft can be sucked out through the communication hole and discharged from the tip of the support shaft by utilizing the flow in the communication hole generated in this way. As a result, poor lubrication due to the accumulation of air around the support shaft can be suppressed.

Sectional drawing of the water pump of 1st Embodiment. An enlarged cross-sectional view of the portion surrounded by the alternate long and short dash line in FIG. Sectional drawing of the water pump of 2nd Embodiment. An enlarged cross-sectional view of the portion surrounded by the alternate long and short dash line in FIG.

(First Embodiment)
The water pump 100, which is the first embodiment of the liquid pump, will be described with reference to FIGS. 1 and 2.

As shown in FIG. 1, the water pump 100 is attached to the cylinder block 10 of the internal combustion engine via a sealing material 30 to form a pump chamber 20 that forms a part of a circulation path of cooling water of the internal combustion engine.

The water pump 100 includes an impeller 120, and the impeller 120 is housed in the pump chamber 20. A support shaft 130 is rotatably attached to the housing 110 of the water pump 100 via a ball bearing 140. The impeller 120 is fixed to the tip of the support shaft 130.

A mechanical seal 150 is attached to a portion of the support shaft 130 located between the impeller 120 and the ball bearing 140. In addition, in FIG. 1 and FIG. 2, the detailed structure of the mechanical seal is omitted and is shown as a single cross section. The mechanical seal 150 seals the gap between the housing 110 and the support shaft 130 while rotatably supporting the support shaft 130, and the cooling water in the pump chamber 20 enters the ball bearing 140 side in the housing 110. To prevent.

A pulley around which an endless belt that transmits the rotation of the output shaft of the internal combustion engine is wound is fixed to the rear end of the support shaft 130. Therefore, the rotation of the output shaft is transmitted to the support shaft 130 via the endless belt as the output shaft of the internal combustion engine rotates. Then, as the support shaft 130 rotates, the impeller 120 fixed to the tip of the support shaft 130 rotates.

In the water pump 100, the rotation of the impeller 120 in this way causes the cooling water in the pump chamber 20 to swirl and is sent out by centrifugal force so as to be separated from the rotation center of the impeller 120.

As a result, as shown by the white arrows in FIG. 2, in the pump chamber 20, the cooling water is sucked from the front end side of the impeller 120, and the cooling water flows toward the outside of the impeller 120, and the cooling water flows to the water pump. It is sent out from 100.

By the way, the support shaft 130 that supports the impeller 120 is located at the center of rotation of the rotating impeller 120. Therefore, when the cooling water is sent out by centrifugal force, air tends to collect around the support shaft 130. In the case of the water pump 100, air is particularly likely to collect in the portion of the support shaft 130 between the impeller 120 located in the pump chamber 20 and exposed to the cooling water and the mechanical seal 150.

Therefore, as shown in FIG. 2, in the water pump 100, a communication hole 131 is provided in the support shaft 130 in order to discharge the air accumulated in this portion. The communication hole 131 communicates the tip of the support shaft 130 with the outer peripheral surface. The communication hole 131 is opened in a portion of the outer peripheral surface of the support shaft 130 between the impeller 120 and the mechanical seal 150, that is, a portion where air easily collects. A through hole 121 is provided at the front end of the impeller 120 to expose the tip of the support shaft 130 to the pump chamber 20. Therefore, the communication hole 131 communicates with the vicinity of the center of the front end of the impeller 120 in the pump chamber 20 through the through hole 121.

The operation of the water pump 100 of the first embodiment will be described.
As described above, as the impeller 120 rotates, the cooling water is sent out by centrifugal force so as to be separated from the rotation center of the impeller 120. Therefore, a negative pressure is generated by the flow of the liquid near the center of the front end of the impeller 120 where the tip of the support shaft 130 is exposed. In the water pump 100, a communication hole 131 provided in the support shaft 130 connects a portion where air is likely to accumulate and a portion where negative pressure is generated. Therefore, due to the action of the negative pressure generated by the rotation of the impeller 120, a flow from the outer peripheral surface side of the support shaft 130 toward the tip end side of the support shaft 130 flows into the communication hole 131 as shown by an arrow in FIG. Occurs. Therefore, in the water pump 100, the air accumulated around the support shaft 130 can be sucked out through the communication hole 131 and discharged from the tip of the support shaft 130 by utilizing the flow in the communication hole 131 thus generated.

The effect of the water pump 100 of the first embodiment will be described.
(1) Since the air accumulated around the support shaft 130 can be discharged to the pump chamber 20 by utilizing the negative pressure generated in the pump chamber 20, the sliding portion of the mechanical seal 150 and the support shaft 130 becomes air. It is possible to suppress being driven in an exposed state. That is, it is possible to suppress poor lubrication due to the accumulation of air around the support shaft 130.

(2) The negative pressure generated by the cooling water flowing outward due to centrifugal force is largest near the center of the front end of the impeller 120 and becomes smaller as the distance from the center of the front end of the impeller 120 increases. In the water pump 100, since the communication hole 131 communicates with the vicinity of the center of the front end of the impeller 120 having the largest negative pressure, air can be effectively discharged.

(Second Embodiment)
Next, the water pump 200, which is the second embodiment of the liquid pump, will be described with reference to FIGS. 3 and 4. The water pump 100 of the first embodiment was an engine-driven pump driven by transmitting the rotation of the output shaft of the internal combustion engine, whereas the water pump 200 of the second embodiment is an electric pump driven by electromagnetic force. Pump.

As shown in FIG. 3, the water pump 200 is also attached to the cylinder block 10 of the internal combustion engine to form the pump chamber 20.
The water pump 200 includes an impeller unit 220 in which an impeller 221 and a rotor 222 are integrated. The housing 210 of the water pump 200 is configured by combining the first housing 211 and the second housing 212. The first housing 211 is provided with a rotor accommodating hole 211a, which is a recess for accommodating the rotor 222 of the impeller unit 220. In the impeller unit 220, the rotor 222 is housed in the rotor accommodating hole 211a, while the impeller 221 is exposed to the outside of the first housing 211. The impeller 221 exposed from the first housing 211 is housed in the pump chamber 20.

A support shaft 230 that supports the impeller unit 220 is fixed to the center of the rotor accommodating hole 211a via a fixing member 232. A cylindrical bush 223 is fixed to the center of the impeller unit 220. The impeller unit 220 is fitted in the first housing 211 so that the support shaft 230 passes through the bush 223. The impeller unit 220 rotates with respect to the support shaft 230 by sliding the support shaft 230 and the bush 223. That is, in the water pump 200, the impeller unit 220 rotates around the support shaft 230 fixed to the housing 210. Further, the tip of the support shaft 230 is exposed from the front end of the impeller 221. A tubular retaining member 233 provided with a flange for preventing the impeller unit 220 from coming off the support shaft 230 is fixed to the tip of the support shaft 230.

The rotor 222 of the impeller unit 220 has a structure in which a permanent magnet 222a is wrapped with laminated electromagnetic steel sheets. A stator 240 composed of a core on which electrical steel sheets are laminated and a coil wound around the core is disposed in a portion of the first housing 211 located outside the rotor 222. In the water pump 200, the rotor 222 and the stator 240 constitute a motor for rotating the impeller 221.

Further, an LC circuit including an inductor 250 and a capacitor and a control board 260 are housed between the first housing 211 and the second housing 212 in the housing 210.

In the water pump 200, the rotor 222 is rotated by the electromagnetic force generated by controlling the energization of the stator 240 to the coil, and the impeller 221 is rotated. In the water pump 200, the rotation of the impeller 221 in this way causes the cooling water in the pump chamber 20 to rotate, and is sent out by centrifugal force so as to be separated from the rotation center of the impeller 221.

As a result, as shown by the white arrows in FIG. 4, in the pump chamber 20, the cooling water is sucked from the front end side of the impeller 221 and the cooling water flows toward the outside of the impeller 221, and the cooling water is a water pump. It is sent out from 200.

The pump chamber 20 and the rotor accommodating hole 211a communicate with each other, and the rotor accommodating hole 211a is filled with cooling water. Therefore, the sliding portion between the support shaft 230 and the bush 223 is lubricated by the cooling water.

By the way, the support shaft 230 that supports the impeller unit 220 is located at the center of rotation of the rotating impeller unit 220. Therefore, when the cooling water is sent out by centrifugal force, air tends to collect around the support shaft 230. In the case of the water pump 200, if air collects in the support shaft 230, the bush 223, and the sliding portion, lubrication will not be performed well.

Therefore, as shown in FIG. 4, in the water pump 200, a communication hole 231 is provided in the support shaft 230 in order to discharge air. The communication hole 231 communicates the tip of the support shaft 230 with the outer peripheral surface. The communication holes 231 are opened at a plurality of locations on the outer peripheral surface of the support shaft 230 that slides with the bush 223. The tip of the support shaft 230 is exposed in the pump chamber 20 from the front end of the impeller 221. Therefore, the communication hole 231 communicates with the vicinity of the center of the front end of the impeller 221 in the pump chamber 20.

The operation of the water pump 200 of the second embodiment will be described.
As described above, as the impeller 221 rotates, the cooling water is sent out by centrifugal force so as to be separated from the rotation center of the impeller 221. Therefore, a negative pressure is generated near the center of the front end of the impeller 221 where the tip of the support shaft 230 is exposed. In the water pump 200, the communication hole 231 provided in the support shaft 230 connects the sliding portion of the support shaft 230 where air is collected and the portion where negative pressure is generated. Therefore, due to the action of the negative pressure generated by the rotation of the impeller 221, a flow toward the tip end side of the support shaft 230 is generated in the sliding portion and the communication hole 231 as shown by an arrow in FIG. Therefore, in the water pump 200, the air accumulated around the support shaft 230 can be sucked out through the communication hole 231 and discharged from the tip of the support shaft 230 by utilizing the flow generated in this way.

The effect of the water pump 200 of the second embodiment will be described.
(1) Since the air accumulated around the support shaft 230 can be discharged to the pump chamber 20 by utilizing the negative pressure generated in the pump chamber 20, air is discharged to the sliding portion between the bush 223 and the support shaft 230. Accumulation can be suppressed. That is, it is possible to suppress poor lubrication due to the accumulation of air around the support shaft 230.

(2) The negative pressure generated by the cooling water flowing outward due to centrifugal force is largest near the center of the front end of the impeller 221 and decreases as the distance from the center of the front end of the impeller 221 increases. In the water pump 200, since the communication hole 231 communicates with the vicinity of the center of the front end of the impeller 221 having the largest negative pressure, air can be effectively discharged.

Each of the above embodiments can be modified and implemented as follows.
-In each of the above embodiments, an example in which the liquid pump is embodied as a water pump that circulates the cooling water of the internal combustion engine is shown, but the same configuration can be applied not only to the water pump. For example, a similar configuration may be applied to an oil pump that circulates lubricating oil.

-The number and positions of openings communicating with the outer peripheral surface of the support shaft in the communication holes can be changed as appropriate.

100 ... Water pump 110 ... Housing 120 ... Impeller 130 ... Support shaft 131 ... Communication hole 200 ... Water pump 210 ... Housing 220 ... Impeller unit 221 ... Impeller 222 ... Rotor 223 ... Bush 230 ... Support shaft 231 ... Communication hole

Claims (1)

A liquid pump that rotates an impeller and sends out liquid by centrifugal force.
A support shaft extending along the center of rotation of the impeller and having an exposed tip at the front end of the impeller.
A liquid pump in which the support shaft is provided with a communication hole for communicating the outer peripheral surface of the support shaft and the tip thereof.

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