KR19980035357A - Integrated pump - Google Patents

Abstract

The present invention relates to an integrated pump in which a water pump and an oil cooler each configured as a single unit are integrated into one.

The integrated pump includes a pulley 31 driven by a belt, a shaft 32 mounted on the pulley 31, a case 33 into which a part of the shaft 32 is inserted, and the shaft ( 32 is mounted to the impeller 44 to circulate the cooling water, and the rotor 45 is mounted to the shaft 32 to circulate the oil.

As a result, the water pump and the oil cooler are integrated, so that the number of parts and the number of assembly processes can be reduced, thereby reducing costs, and freeing space in the engine room in which the water pump and the oil cooler are mounted, and loss of power. There is also an effect to reduce.

Description

Integrated pump

The present invention relates to an integrated pump mounted on a vehicle, and more particularly, to an integrated pump in which a water pump and an oil cooler each configured as a single unit are integrated into one.

A conventional case will be described with reference to FIGS. 1 and 2.

In the related art, a water pump 1 for circulating coolant supplied to an engine and an oil cooler 10 provided in an oil cooler for forcibly circulating oil are each configured separately.

Referring to FIG. 1, a conventional water pump 1 is connected to a pulley 6 driven by a belt, a shaft 2 mounted on the pulley 6, the shaft 2, and a housing 4. It is composed of an impeller (3) that is built in the) to circulate the cooling water.

The shaft 2 penetrates through a hole formed in the housing 4, and a bearing 5 is mounted in the hole to support the shaft 2.

The impeller 5 of the water pump 1 rotates at 1.2 to 1.6 times the engine speed, and the efficiency of the water pump is inversely proportional to the cooling water temperature and proportional to the pressure.

Referring to FIG. 2, a conventional oil cooler 10 is connected to a pulley 11 driven by a belt, a shaft 12 mounted on the pulley 11, the shaft 12, and a housing 14. It is composed of a rotor (13) built in the) to circulate the oil.

The housing 14 includes an outer case 15 and an inner case 16 embedded in the outer case 15, and a passage through which air moves between the outer case 15 and the inner case 16. (17) is formed.

Air is circulated to the passage 17, where the air exchanges heat with the oil to lower the temperature of the oil.

The outer case 15 has an inlet 20 through which air flows in and an outlet 21 through which air flows out.

The inner case 16 is formed with an inlet port 18 through which oil flows in and an outlet port 19 through which oil flows out.

The oil cooler 10 configured as described above heats the oil temperature of 125 to 130 ° C. or higher with air to maintain about 70 to 80 ° C.

However, in the related art, as described above, the oil cooler and the water pump are each composed of a single product, so that a large amount of power is lost because the oil cooler and the water pump have to occupy a lot of internal space, and the oil pump and the water pump must be driven respectively.

Accordingly, the present invention is to overcome the above-mentioned conventional problems, an object of the present invention is to provide an integrated pump in which the water pump and the oil cooler (oil cooler) each composed of a single unit is integrated into one.

As an example of an integrated pump for achieving the object of the present invention, a pulley 31 driven by a belt, a shaft 32 mounted to the pulley 31, and a part of the shaft 32 is internally It is characterized in that it is composed of a case 33 to be inserted, an impeller 44 mounted on the shaft 32 to circulate the cooling water, and a rotor 45 mounted to the shaft 32 to circulate oil.

With this configuration, the water pump and the oil cooler are integrated into one.

1 is a schematic view showing a conventional water pump

2 is a schematic view showing a conventional oil pump

3 is a schematic diagram showing an integrated pump according to the present invention.

<Explanation of symbols for main parts of drawing>

1: water pump 2, 12: shaft

3: impeller 4, 14: housing

5: bearing 6, 11: pulley

10: oil cooler 13: rotor

30: integral pump 31; Rotor

32: shaft 33: housing

34: inner housing 35: outer housing

36: sealing partition 37, 39, 42: inlet

38, 40, 43: outlet 41: case

44 impeller 45 rotor

Hereinafter, an embodiment of the present invention will be described in detail with reference to Figure 3, Figure 3 is a schematic diagram showing an integrated pump according to the present invention, the integral pump 30 according to the present invention is a pulley 31 driven by a belt ), A shaft 32 mounted to the pulley 31, a housing 33 into which a portion of the shaft 32 is inserted, and an impeller 44 mounted to the shaft 32 to circulate cooling water. And a rotor 45 mounted on the shaft 32 to circulate oil.

The housing 33 is divided into an inner housing 34 for circulating air by the sealing partition 36 and an outer housing 35 for circulating coolant.

The outer housing 35 is formed with an inlet 37 through which the coolant flows, and an outlet 38 through which the coolant flows out, and an impeller 44 mounted on the shaft 32 to circulate the coolant.

The inner housing 34 has an inlet 39 through which air flows in and an outlet 40 through which air flows out, and has a case 41 for heat-exchanging oil.

The case 41 has an inlet 42 through which oil is introduced and an outlet 43 through which oil is discharged, and a rotor 45 mounted on the shaft 32 to circulate oil is built in the case 41.

The rotor 45 is composed of an inner rotor 46 mounted to the shaft 32 and an outer rotor 47 engaged with the inner rotor 46.

By the above configuration, the integrated pump of the present invention operates as follows.

The shaft 32 rotates by the rotation of the pulley 31, and the impeller 44 and the rotor 45 rotate simultaneously as the shaft 32 rotates. The cooling water flows into the inlet 37 of the outer housing 35 by the rotation of the impeller 44 and then flows out of the outlet 38. The leaked coolant prevents overheating of the engine.

In addition, when the inner rotor 46 attached to the shaft 32 rotates in the rotor 45, the outer rotor 47 engaged with the inner rotor 46 rotates. As a result, the oil is introduced into the inlet 42 formed in the case 41, and the introduced oil is thermally correlated with air flowing outside the case 41, thereby lowering the temperature. In addition, the cooled oil flows out through the outlet 43 and flows into an oil filter (not shown). Here, the air flows into the inlet port 39 formed in the inner housing 34, heat exchanges in the case 41, and then flows out of the outlet port 40.

As described above, the integrated pump according to the present invention integrates the water pump and the oil cooler, thereby reducing the number of parts and the number of assembly processes, thereby reducing the cost, and freeing space in the engine room in which the water pump and the oil cooler are installed. It is possible to reduce the power loss.

What has been described above is only one embodiment for carrying out the integrated pump according to the present invention, and the present invention is not limited to the above-described embodiment, and the scope of the present invention as claimed in the following claims Without departing from the scope of the present invention, those of ordinary skill in the art can make various modifications.

Claims (5)

A pulley 31 driven by a belt, a shaft 32 mounted on the pulley 31, a case 33 into which a part of the shaft 32 is inserted, and a mounting on the shaft 32. And an impeller (44) for circulating coolant and a rotor (45) mounted on the shaft (32) for circulating oil. The method of claim 1, The housing (33) is a one-piece pump, characterized in that divided into an inner housing (34) for circulating the air by the sealing partition (36), and an outer housing (35) for circulating the coolant. The method of claim 1, The outer housing 35 is formed with an inlet 37 through which coolant flows, and an outlet 38 through which coolant flows, and an impeller 44 mounted to the shaft 32 is integrated. The method of claim 1, The inner housing 34 is formed with an inlet 39 through which air is introduced, and an outlet 40 through which air is discharged, and an integrated pump, characterized in that the case 41 is built-in. The method of claim 1, The case 41 has an inlet 42 through which oil is introduced, and an outlet 43 through which oil is discharged, and a rotor 45 mounted on the shaft 32 to circulate oil is embedded therein. Integral pump.