KR200373781Y1 - Hydraulic pump for rock splitter - Google Patents

Abstract

The present invention relates to a hydraulic piston pump for use in a hydraulic rock crusher.

An object of the present invention is to provide a hydraulic piston pump for use in a hydraulic rock crusher that facilitates maintenance of a cylinder and lowers the maintenance cost of the cylinder by providing a cylinder block inside the main body.

The hydraulic pump 200 for a rock crusher of the present invention has three low pressure cylinder blocks 13 and three high pressure cylinders on the same pitch circle from the center of the main body 12 in parallel with the rotational central axis G as its main axis. The upper block 14 is fitted, and three low pressure cylinder bores 103 are formed in the three low pressure cylinder blocks 13, and the low pressure cylinder bores 103 described above are included in the three high pressure cylinder upper blocks 14. Three high-pressure cylinder bores 104 are installed on the same pitch circle as that, and the high-pressure cylinder lower block 16 is fitted inside each of the high-pressure cylinder upper blocks 14, and the high-pressure cylinder housing 17 is a high-pressure cylinder. Surrounding the lower block 16, it characterized in that the high-pressure cylinder upper block 14 is supported.

According to the present invention, there is provided a hydraulic pump for a rock crusher, which facilitates maintenance of the cylinder and at the same time has a low maintenance cost and improves the reliability of the product.

Description

Hydraulic pump for rock splitter

The present invention relates to a hydraulic piston pump for use in a hydraulic rock crusher. More specifically, the piston is reciprocated by the rotation of the cylinder block in conjunction with the rotation of the rotary shaft, and the hydraulic oil sucked from the low pressure first suction port and the high pressure second suction port by the reciprocating motion of the piston is operated at low pressure. The present invention relates to an improvement of a hydraulic piston pump for a hydraulic rock crusher, which is configured to be separately delivered to the first delivery port and the second high pressure delivery port.

1 is a longitudinal sectional view showing an example of a swash plate piston pump generally used for a rock crusher. There is no cylinder block assembled separately in the apparatus main body 61, and a plurality of cylinder bores 65 and 66 are arranged on the same pitch circle from the center of the main body 61 in parallel with the main axis of rotation G thereof. And the pistons 59 and 60 reciprocate in the above-described cylinder bores 65 and 66, accompanied by the rotation of the rotation transmission shaft 100 provided coaxially with the rotation center axis G. It is designed to suck and discharge air.

In such a swash plate type piston pump, one end of each piston 59, 60 is reciprocated by the piston 59, 60 by revolving while being in contact with the swash plate 53 in contact with the inclined rotation shaft 54. However, at this time, in the volume enlargement process according to the rotation of the inclined rotary shaft 54 in contact with the swash plate 53, one of the pistons 59, 60 by the low pressure side spring 57 and the high pressure side spring 58 The end of is raised along the pressing ring 101 to enlarge the volume of each cylinder bore (65, 66), in the compression stroke one end of each piston (59, 60) by the pressing ring 101 The volume of the cylinder bores 65 and 66 is reduced by pressing in the opposite direction to the expansion stroke.

As described above, each of the pistons 59, 60 performs a stroke movement in the suction direction during the half rotation during idle, and in the delivery direction during the remaining half rotation, and the plurality of cylinder bores 65, 66 during the suction. The oil is sucked in by the suction valves 62 and 63 provided at the lower part of the valve. When oil is discharged, the low pressure side check valve 70 and the high pressure side check valve 68 shown in Figs. By discharging, a continuous pump action can be obtained.

The hydraulic piston pump used in the conventional hydraulic rock crusher, since a plurality of cylinder bores (65, 66) is formed in the main body 61 without the cylinder block, it is very difficult to repair due to wear and damage of the cylinder bore, There was a problem that the cost for the repair of the cylinder bore was very high.

The present invention is invented to effectively solve the above problems of the prior art.

The present invention is devised to solve the above problems, the object of the present invention is to install a cylinder block inside the main body, to facilitate the maintenance of the cylinder, and at the same time the hydraulic maintenance to lower the maintenance cost of the cylinder It is to provide a hydraulic piston pump used for rock crushers.

1 is a longitudinal sectional view showing the configuration of a conventional hydraulic pump for rock crushers

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a cross-sectional view taken along line B-B of FIG.

Figure 4 is a longitudinal sectional view showing the configuration of the hydraulic pump for rock crusher of the present invention

5 is a cross-sectional view showing a main body of the present invention

6 is a top view of FIG. 5

7 is a cross-sectional view taken along line B-B of FIG.

8 is a cross-sectional view taken along line C-C of FIG.

<Explanation of symbols for main parts of drawing>

4: swash plate 6: inclined rotary shaft

7: low pressure piston 8: high pressure piston

12 body 13 low pressure cylinder block

14 high pressure cylinder upper block 15 high pressure delivery valve

16: high pressure cylinder lower block 18: low pressure delivery valve

100: rotation transmission shaft 102: pressing plate

103: low pressure cylinder bore 104: high pressure cylinder bore

200: Hydraulic piston pump for hydraulic rock crusher

The configuration of the present invention will be described with reference to FIGS. 4, 5, 6, 7, and 8. FIG. 4 is a longitudinal sectional view showing the configuration of the hydraulic pump for rock crusher of the present invention, in which three low pressures are formed on the same pitch circle from the center of the main body 12 shown in FIG. The cylinder block 13 and three high pressure cylinder upper blocks 14 are fitted, and three low pressure cylinder bores 103 are formed in the three low pressure cylinder blocks 13, and three high pressure cylinder upper blocks 14 are provided. Three high-pressure cylinder bores 104 are installed in the same pitch circle as the low-pressure cylinder bore 103 described above, and the high-pressure cylinder lower block 16 is fitted inside each of the high-pressure cylinder upper blocks 14. The high pressure cylinder housing 17 surrounds the high pressure cylinder lower block 16 and supports the high pressure cylinder upper block 14.

The low pressure piston 7 slides up and down inside the low pressure cylinder bore 23, and is accompanied by the rotation of the rotation transmission shaft 100 provided coaxially with the rotation center axis G. The high pressure piston 8 reciprocates in the cylinder bore 23, and the high pressure piston 8 reciprocates in the high pressure cylinder bore 24 to suck and deliver hydraulic oil. Reciprocating motion of the pistons 7 and 8 is performed by revolving while the end is in contact with the swash plate 4 in contact with the inclined rotary shaft 6, and the rotation of the inclined rotary shaft 6 in contact with the swash plate 4 is performed. In the volume expansion process, one end of each of the pistons 7 and 8 is raised along the pressing plate 102 by the low pressure side spring 10 and the high pressure side spring 11, so that the low pressure cylinder bore 23 and the high pressure cylinder bore. (24) to enlarge the volume, in the compression stroke one end of each piston (7, 8) The additional pressing plate 102 is pressed in the opposite direction to the volume expansion stroke to reduce the volume of each cylinder bore 23 and 24, and each piston 7 and 8 is in the suction direction during the half revolution during idle, During the half rotation, the stroke movement is performed in the feeding direction.

During suction, oil is sucked by the low pressure suction valve 21 and the high pressure suction valve 22 installed under the plurality of cylinder bores 23 and 24, and when the oil is discharged, the low pressure discharge valve 18 and the high pressure discharge are carried out. By installing the valve 15 to discharge oil, it has a continuous pump action.

5 is a cross-sectional view showing a main body of the present invention, Figure 6 shows a top view of FIG. The three low pressure cylinder block bores 23 are arranged in the main body 12 between three high pressure cylinder block bores 24 on the same pitch circle.

FIG. 7 is a sectional view taken along the line BB of FIG. 5. The three high pressure cylinder block bores 24 are interconnected through the high pressure side connection flow path 25, and the high pressure oil generated by the three high pressure cylinder block bores 24 by the stroke movement in the delivery direction of the piston. Is sent out through the high-pressure delivery valve 15.

8 is a cross-sectional view of the CC of FIG. 5, wherein the three low pressure cylinder block bores 23 are connected to each other via the low pressure side connection flow path 26, and the three low pressures are applied by a stroke movement in the delivery direction of the piston. The low pressure oil generated in the bore 23 for the cylinder block is discharged through the low pressure delivery valve 18.

As described above, according to the hydraulic piston pump for a hydraulic rock crusher according to the present invention, the maintenance of the cylinder is easy, the maintenance cost of the cylinder is low, and the reliability of the product is improved.

Claims (1)

On the same pitch circle from the center of the main body 12, three low pressure cylinder blocks 13 and three high pressure cylinder upper blocks 14 are fitted in parallel with the main axis of rotation G thereof, and three low pressure cylinders. Three low pressure cylinder bores 103 are formed in the block 13, and three high pressure cylinder bores 104 are formed on the same pitch circle as the low pressure cylinder bores 103 described above in the three high pressure cylinder upper blocks 14. Is installed, the high pressure cylinder lower block 16 is fitted inside each of the high pressure cylinder upper blocks 14, and the high pressure cylinder housing 17 surrounds the high pressure cylinder lower block 16, (14), the low pressure piston (7) slides up and down inside the low pressure cylinder bore (23), accompanied by the rotation of the rotation transmission shaft 100 provided coaxially with the rotation center axis (G). Thus, the low pressure piston 7 is in the low pressure cylinder bore 23 The high pressure piston 8 reciprocates in the high pressure cylinder bore 24 to reciprocate and suck and discharge hydraulic oil. One end of each of the pistons 7 and 8 has an inclined rotary shaft 6. The reciprocating motion of the pistons 7 and 8 is performed by revolving while contacting the swash plate 4 in contact with the swash plate 4. In the volume expansion process according to the rotation of the inclined rotary shaft 6 in contact with the swash plate 4, the low pressure side spring ( 10) and one end of each piston (7, 8) is raised along the pressing plate (102) by the high pressure side spring (11) to reduce the volume in the low pressure cylinder bore (23) and the high pressure cylinder bore (24). In the compression stroke, one end of each piston (7, 8) is pressed by the pressing plate (102) in the opposite direction to the volume expansion stroke to reduce the volume of each cylinder bore (23, 24), each piston (7, 8) is in the suction direction during the half turn during idle, the other half turn The inner side performs stroke movement in the dispensing direction, and during suction, oil is sucked by the low pressure suction valve 21 and the high pressure suction valve 22 installed under the plurality of cylinder bores 23 and 24, and when the oil is discharged. Is a hydraulic piston pump (200) for a hydraulic rock crusher, characterized by having a continuous pumping action by installing a low pressure delivery valve (18) and a high pressure delivery valve (15) to deliver the oil.