KR100405788B1 - Water pump - Google Patents

Abstract

The present invention relates to a water pump for a cooling device of a vehicle for improving the performance of the pump by minimizing the reverse flow of the cooling water generated from the high pressure side to the negative pressure side in the gap between the impeller and the cylinder block of the water pump,

A rotating shaft is accommodated inside the pump housing, and an impeller having a plurality of blades radially formed on one side of the rotating shaft for applying centrifugal force to the cooling water is prevented. In the water pump is covered with a circular cap formed in the through hole in the center to the outside of the blades,

A cylindrical portion is formed on one side of the cap so that the through hole formed in the center of the cap extends by a predetermined length, and an annular sheet is formed on the surface of the cylinder block so that the cylindrical portion can be accommodated. It is characterized in that for minimizing the amount of cooling water flow back to the gap between the impeller.

Description

Water pump for automobile cooling unit

The present invention relates to a water pump for a cooling device of an automobile, and more particularly, to improve the performance of a pump by minimizing the reverse flow of cooling water generated from the high pressure side to the negative pressure side in the gap between the impeller and the cylinder block of the water pump. The present invention relates to a water pump for a cooling device of an automobile.

In general, the engine is powered by burning fuel, the temperature of the combustion gas to be burned in the cylinder reaches 2000 ℃ or more, but not all of this heat of combustion is converted to power, a considerable amount of heat is the cylinder head and Absorption of the piston or the like causes heat loss and overheating of these parts.

As a result, excessively high temperatures such as cylinders cause deformation of the cylinders or break up the oil film, resulting in poor lubrication, and severe damages to the engine and worsening of combustion, resulting in knocking and premature ignition. The output will be drastically reduced.

Accordingly, the engine is cooled to prevent overheating of the engine. On the contrary, if the engine is cooled too much, heat generated by combustion cannot be converted into power, and the amount of loss due to cooling increases, thereby lowering thermal efficiency and increasing fuel consumption. In addition, a gasoline insufficiency mixer is supplied to the engine to dilute the engine oil by gasoline to promote cylinder wear.

For this reason, a cooling system for cooling the engine to prevent overheating and keeping it at a constant temperature is used in the engine. As shown in FIG. 5, the water jacket 11 surrounding the cylinder and the combustion chamber and the circulation of water to the cylinder are circulated. Water-cooled cooling device 14 including a water pump 20 to be cooled, a radiator 12 for cooling the engine to transfer the heat of the coolant, the temperature of which has risen to the outside air, and a cooling fan 13 to help ventilate the radiator. Is mainly used.

The water-cooled cooling device 14 is provided with a device for changing the flow of the cooling water in accordance with the temperature of the cooling water, called the thermostat 15, and at the beginning of the low temperature of the engine, the cooling water does not flow to the radiator 12 side for heat radiation cooling. By allowing the engine to circulate again through the bypass pipe 16, the temperature of the engine is quickly raised to the normal temperature. When the engine reaches the normal temperature, the thermostat 15 follows the cooling water temperature to prevent the engine from overheating. Since the cooling water is circulated to the radiator 12, the heat is cooled and radiated, and then the engine is circulated to maintain the temperature.

As described above, the water pump 20 for forced circulation of the cooling water is composed of a pump housing 21, an impeller 22, a rotation shaft 23, a bearing 24, a pulley 25, and the like. Is mounted on one side.

In addition, the side of the impeller 22 is formed with a blade 26 for forcibly circulating the cooling water, the impeller 22 formed with the blade 26 is configured to circulate while causing the cooling water to vortex while rotating. . However, in the case of the water pump 20 configured as described above, since the loss due to leakage at the end of the impeller 22 has a lot of negative effects on maximizing the flow rate and improving the efficiency. So, to compensate for this, one side of the impeller 22 configured as described above is provided with a water pump 20 having a circular cap 27 for reducing leakage as shown in FIG.

However, even in the case of the water pump capped on one side of the impeller as described above, the size of the gap between the rotor (impeller) and the stator (cylinder block) is changed, and the negative pressure region in the high pressure region in the gap between the impeller and the cylinder block. As a backflow occurs, there was a problem that can not completely solve the reduction in efficiency.

Accordingly, the present invention has been made to solve the above problems, more specifically, in the gap between the impeller and the cylinder block of the water pump to minimize the back flow of the cooling water generated from the high pressure side to the negative pressure side to improve the performance of the pump It is an object of the present invention to provide a water pump for a cooling device of an automobile.

The present invention as a means for achieving the above object,

A rotating shaft is accommodated inside the pump housing, and an impeller having a plurality of blades radially formed on one side of the rotating shaft for applying centrifugal force to the cooling water is prevented. In the water pump is covered with a circular cap formed in the through hole in the center to the outside of the blades,

A cylindrical portion is formed on one side of the cap so that the through hole formed in the center of the cap extends by a predetermined length, and an annular sheet is formed on the surface of the cylinder block so that the cylindrical portion can be accommodated. It is characterized in that for minimizing the amount of cooling water flow back to the gap between the impeller.

1 is a cross-sectional view of a water pump formed by the present invention.

2 is a perspective view of a cap which is an essential part of the present invention.

3 and 4 are graphs showing the experimental results of experimenting the performance and efficiency of the water pump formed by the present invention.

5 is a view showing a cooling device of a typical automobile engine.

6 and 7 show a conventional water pump.

※ Explanation of code for main part of drawing

20: water pump 21: pump housing

22 impeller 23 rotation axis

24: bearing 25: pulley

26: blade 27: cap

40: cylinder block 41: sheet

Hereinafter, the embodiment according to the present invention will be described in detail with the accompanying drawings.

1 is a cross-sectional view of a water pump formed by the present invention, Figure 2 is a perspective view of the cap which is the main part of the present invention, Figures 3 and 4 are the experimental results of experiments on the performance and efficiency of the water pump formed by the present invention The graph shown.

Reference numeral 40 denoted in the drawing indicates a cylinder block, reference numeral 20 denotes a water pump, and some reference numerals related to the water pump 20 are used as they are in the description of the prior art. do.

The pump housing 21 of the water pump 20 is accommodated in the center of the rotary shaft 23 as in the prior art, the impeller 22 is mounted to the inner end of the rotary shaft 23, the rotary shaft ( At the outer end of 23, a pulley 25 is mounted. The bearing 24 is interposed in the outer periphery of the rotating shaft 23 accommodated in the inner surface of the pump housing 21.

In addition, a plurality of blades 26 are radially protruded on the outer surface of the impeller 22, the coolant flows backward by a gap between the cylinder block 40 and the blade 26 on the outer side of the blades 26. A circular cap 27 is formed as in the prior art to prevent it from becoming. And the cylindrical portion 30 is protruded to one side of the cap 27 so that the through hole 28 formed in the center of the cap 27 extends by a predetermined length.

The annular seat 41 is formed on the surface of the cylinder block 40 to accommodate the cylindrical portion 30 of the cap 27 on the side of the cylinder block 40 on which the water pump 20 is mounted. ) Is formed.

That is, the cylindrical portion 30 of the cap 27 is accommodated in the annular sheet 41 so that the outer circumferential edge of the cylindrical portion 30 is in surface contact with the inner circumferential edge of the sheet 41.

Referring to the operation and operation of the water pump 20 configured as described above are as follows.

When the engine is operated, the piston in the cylinder is moved up and down, the driving force is generated by the interaction of the connecting rod and the crank shaft, and at the same time the water pump 20 is rotated.

When the water pump 20 is rotated as described above, the centrifugal force is generated by the impeller 22 and the blade 26, and the coolant is supplied to the water jacket formed in the cylinder block 40 to cool the engine.

In this process, the cylindrical portion 30 formed on one side of the cap 27 is in close contact with the seat 41 of the cylinder block 40, so that the pumped coolant is prevented from flowing back to the impeller 22.

Therefore, the amount of backflow generated from the high pressure side to the negative pressure side in the gap between the cap 27 and the cylinder block 40 surface is minimized, thereby maximizing the performance of the water pump 20.

3 and 4 are graphs of the results of experiments of the performance and efficiency of the water pump formed by the present invention, a comparison between the water pump equipped with a cap with a cylindrical protrusion and the water pump without a cap according to the present invention. This is the result of the experiment.

That is, the water pump according to the present invention in the above-described performance and efficiency experiment graph can be seen that the performance and efficiency is greatly improved since the cap 27 is provided with a cylindrical portion 30 protruding on one side.

In the present invention as described above, the cylindrical portion is protruded to one side of the cap covering one side of the impeller, the sheet is formed on the side of the cylinder block to accommodate the cylindrical portion of the cap, the gap formed between the blade and the cylinder block of the impeller Is minimized, and the pumped coolant is prevented from leaking and flowing back so that the efficiency of the water pump is improved.

Claims (1)

The rotating shaft 23 is accommodated inside the pump housing 21, and on one side of the rotating shaft 23, a plurality of blades 26 for radially applying a centrifugal force to the cooling water are mounted, and an impeller 22 is formed. Water pump with a circular cap 27 with a through hole 28 formed in the center of the blades 26 to prevent the coolant from leaking into the gap between the face and the blades 26 of the impeller 22. To A cylindrical portion 30 is formed on one side of the cap 27 so that the through hole 28 formed in the center of the cap 27 extends by a predetermined length, and the cylinder 30 is accommodated therein. An annular seat 41 is formed on the face of the block 40 to minimize the amount of coolant flowing back into the gap between the face of the cylinder block 40 and the impeller 22 during pump operation. Water pump for chiller.