KR100198286B1 - Heat radiation of underwater pump - Google Patents

Abstract

The present invention is a submersible pump, in the structure to cool the heat generated when driving the motor to prevent overheating of the pump to improve the efficiency of the motor, the impact applied to the control panel by means used for the purpose of heat dissipation The present invention relates to a heat dissipation flow path structure of an underwater pump to reduce vibrations of the underwater pump itself.

The heat dissipation flow path structure of the conventional submersible pump has a part of the water introduced into the upper side of the impeller 1 by the rotation of the impeller 1 through the inlet 4 to the open drive shaft 3 without exiting the outlet 8. Since the water flows through the drive shaft 3 to cool the heat generated by the motor 5, the water pressure of the water falling to the motor 5 side through the empty space of the drive shaft 3 is higher than the control panel 6. As a result, the impact directly causes problems to the circuit components of the control panel 6.

In the present invention, in order to solve the problems caused by the heat dissipation passage structure as described above, by configuring the impact relief means to drop the water pressure of the high pressure water passing through the drive shaft, so that the water pressure of the water is not directly transmitted to the control panel By forming a water outlet at the bottom of the drive shaft to be discharged to the outside, to protect the circuit components configured in the control panel, and to reduce the vibration of the submersible pump.

Description

Heat dissipation flow path structure of submersible pump

1 is a cross-sectional view showing a heat radiation flow path structure of a conventional submersible pump.

2 is a cross-sectional view showing a heat dissipation flow path structure of the present invention underwater pub.

* Explanation of symbols for main parts of the drawings

1: impeller 2: diffuser

3: drive shaft 4: inlet

5: motor 6: control panel

7: control power source 8: discharge port

9: outlet 10: pump case

11 check valve 12 rubber stopper

The present invention is a submersible pump, in the structure to cool the heat generated when driving the motor to prevent overheating of the pump to improve the efficiency of the motor, the impact applied to the control panel by means used for the purpose of heat dissipation The present invention relates to a heat dissipation flow path structure of an underwater pump to reduce vibrations of the underwater pump itself.

In general, submersible pumps are designed vertically to minimize the diameter of the excavated part due to the reduction of the excavation cost, and because they are small, they are convenient to use at home, but they realize a small head with a small size. Many heat losses occur.

In the present invention, in the heat dissipation passage structure formed to cool the heat generated by the motor in this way, to reduce the impact applied to the control panel during the heat dissipation action to protect the control panel, in the conventional cooling structure of the water pump The coolant is filled into a hollow drive shaft, and the filled coolant is used as a heat dissipation means to cool the heat of the motor. However, in the cooling structure of the conventional submersible motor, a coolant is inserted into a hollow drive shaft with a stopper and plugged with a stopper. It must be given, making automation difficult in the manufacturing process of the pump.

In addition, since a certain amount of coolant enters the enclosed shaft, if it is continuously heated and the temperature of the coolant is equal to the temperature of the motor, it is difficult to expect a cooling effect more than virtue. The heat dissipation flow path structure of the conventional submersible pump has one or more outlet ports formed at the end of the drive shaft and the motor coupling part as shown in FIG. 1, and both ends of the drive shaft are opened to be introduced at a high speed. While the water is to pass through the drive shaft, the cooling action is to be made, with reference to the accompanying drawings illustrating the configuration and operation as follows.

At least one impeller 1 and a diffuser 2 are formed, and a driving shaft 3 for rotating the impeller 1 is formed inside the formed impeller 1, and the impeller 1 is formed. ) And an inlet 4 through which the water is introduced by the rotation of the impeller 1, a motor 5 for rotating the drive shaft 3, and the motor 5 below the diffuser 2. The control panel 6 is formed at the lower side of the control panel, and the control power supply unit 7 is formed at the lower side of the configured control panel 6. As the drive shaft 3 rotates, the water introduced into the inlet port 4 flows into the impeller 1. In the structure of the submersible pump moved to the side to be discharged to the discharge port (8), the inside of the drive shaft (3) is formed of an empty tube, both ends of the formed drive shaft (3) in an open state The outlet 9 is formed so that water is discharged to the outside at the coupling portion side of the drive shaft 3 and the motor 5. A portion of the water introduced into the impeller 1 through the inlet 4 is introduced into the drive shaft 3 through the coupling portion side of the impeller 1 to pass through the drive shaft 3 to perform a cooling operation. It is done.

Reference numeral 10 denotes a pump case and 11 a check valve.

The heat dissipation flow path structure of the conventional submersible pump having such a structure is that part of the water introduced into the upper side of the impeller 1 by the rotation of the impeller 1 through the inlet port 4 is opened without exiting to the discharge port 8. It enters the drive shaft (3) to pass through the drive shaft (3) to cool the heat generated in the motor (5), a portion of the water discharged to the outlet via the check valve 11 for the cooling action It is formed to open both ends of the drive shaft (3) to be moved to the (5) side.

The drive shaft 3 formed as described above is a hollow tube inside, so that some water comes down to the place where the motor 5 is located on the drive shaft 3.

At this time, the water flowing down at a high flow rate cools the heat generated by the motor 5 while passing through the motor 5 portion, and is immediately discharged to the outside through the outlet 9 formed at the end of the drive shaft 3. do.

As described above, the cooling operation is continued at a different flow rate while the pump is driven, and part of the water introduced into the impeller 1 is introduced into the drive shaft 3.

Here, the hole on the impeller 1 side of the drive shaft (3) into which water is introduced can be adjusted to an appropriate size to configure the device with almost no power loss, and the drive shaft (3) is made of a material having high thermal conductivity. By doing so, a higher cooling effect can be expected.

As such, the cooling of the motor and the pump is performed by the water passing through the drive shaft at a different flow rate, and thus an excellent cooling effect can be expected.

However, since the water pressure of water dropped to the motor 5 side through the empty space of the drive shaft 3 directly affects the upper side of the control panel 6, as shown in the drawing, the impact on the control panel 6 due to the impact. Problems occur with the circuit components.

Therefore, in order to solve the problems caused by the heat dissipation passage structure as described above, in the present invention, the impact relief means is configured to reduce the water pressure of the high pressure water passing through the drive shaft, so that the water pressure of the water is directly transmitted to the control panel. In order to protect the circuit components of the control panel by the water pressure transmitted directly to the control panel, and to reduce the vibration of the submersible pump.

The heat dissipation flow path structure of the present invention submersible pump for achieving the above object is the same as in the prior art by the same reference numerals to explain the configuration and operation as follows.

FIG. 2 is a cross-sectional view showing the heat dissipation flow path structure of the submersible pump according to the present invention. Referring to FIG. 2, the drive shaft 3 and the motor are formed through an inner side of the drive shaft 3 formed of a pipe in an empty state. The outlet 9 is formed on the coupling part side of the coupling part 5 so that a part of the water flowing into the impeller 1 through the inlet port 4 is driven through the coupling part side of the impeller 1. 3) In the heat dissipation flow path structure of the submersible pump characterized in that the cooling flow is performed while passing through the drive shaft (3), the end is connected to the drive shaft (3) to the upper side of the control panel (6) In order to form a blockage, to form at least one discharge port (3a) in the portion of the space in which the extended drive shaft 3 and the outlet (9) abut, to relieve the water pressure of water falling from the upper side of the drive shaft (3) Rubber stopper as a shock absorbing means ( 12) is formed.

The heat dissipation flow path structure of the submersible pump of the present invention formed as described above relieves the water pressure of the water falling from the upper side through the inside of the drive shaft 3 so that the water pressure of the water falling on the control panel 6 does not directly affect the control panel 6. In this case, when the pumping operation of the submersible pump starts, water is introduced through the inlet port 4, and the introduced water is moved upwardly of the impeller 1 through the plurality of impellers 1 to discharge through the outlet port 8. It is discharged to the outside.

At this time, a part of the water discharged through the discharge port 8 flows into the inside of the drive shaft 3 and flows inside the drive shaft 3 formed of a pipe, thereby depriving the heat of the motor 5.

Thereafter, the water flowing inward of the drive shaft 3 falls to the lower end of the drive shaft 3 as described above, and loses power while hitting the rubber stopper 12 formed at the lower end of the drive shaft 3, and the water pressure is weakened. The drive shaft 3 is discharged to the outlet 9 through a plurality of discharge ports 3a formed in parallel with the control panel 6, and is discharged completely to the outside of the pump through the outlet 9.

That is, as water falls on the rubber stopper 12, which is an impact mitigating means, the water pressure is weakened, and the weakened water is dropped to the part in contact with the control panel 6 through the discharge port 3a parallel to the control panel 6, This will reduce the impact on the control panel (6).

As described above, by reducing the water pressure of the control panel, it is possible to protect the circuit components of the control panel, and also to reduce the vibration of the submersible pump, thereby improving the user's reliability of the apparatus.

Claims (2)

The inlet port 4 is formed by forming an outlet port 9 so that water is discharged to the outside through the inside of the drive shaft 3 formed as a tube having an empty inside, so that water is discharged to the outside of the coupling part side of the drive shaft 3 and the motor 5. In the heat dissipation flow path structure of the submersible pump characterized in that the cooling action is performed while a part of the water introduced into the impeller 1 passes through the drive shaft 3, the drive shaft 3 is connected to the control panel 6. A heat dissipation flow path structure of the submersible pump, characterized in that the end is closed by connecting to the upper side, and at least one discharge port 3a is formed in a part of the space where the extended drive shaft 3 and the outlet port 9 contact. . The heat dissipation flow path structure of a submersible pump according to claim 1, characterized in that a shock absorbing means is formed at a blocked end to relieve the water pressure of the water delivered through the drive shaft (3).