KR101700026B1 - flatness gauge for steel plate - Google Patents

Abstract

A hydraulic pump for high pressure according to an embodiment of the present invention includes: a motor that is mounted on the outside of an oil tank which stores rotational oil and provides rotational power; A housing provided inside the oil tank and receiving a drive shaft of the motor; A low pressure pump mounted on a bottom surface of the housing for sucking operating oil in the oil tank by primary rotation of the driving shaft; A plurality of high-pressure compressors for compressing the operating fluid supplied from the low-pressure pump by a reciprocating piston interlocked with a cam member formed on the driving shaft, the plurality of high- Pump; A low pressure discharge passage formed in the housing and connected to the low pressure pump to discharge the operating fluid compressed by the low pressure pump to the outside; A low-pressure supply passage formed in the housing to allow the low-pressure pump and the plurality of high-pressure pumps to communicate with each other to allow the hydraulic fluid compressed in the low-pressure pump to flow to the high-pressure pump; A high-pressure fluid passage formed inside the plurality of high-pressure pumps to form an inlet and an outlet passage for the working fluid compressed by the piston; And a high-pressure discharge passage formed in the housing, the high-pressure discharge passage being connected to the high-pressure passage so that the high-pressure hydraulic fluid secondary-compressed by the plurality of high-pressure pumps is discharged to the outside.

Description

A flatness gauge for steel plate

The present invention relates to a high-pressure hydraulic pump.

Generally, the hydraulic pump supplies the mechanical energy supplied from the outside to the hydraulic system hydraulic oil

Pressure energy, and it is variously divided into gear type, vane type, rotary piston type, and reciprocating piston type. Various types of pumps for obtaining high-pressure hydraulic oil have been developed.

In Korean Patent No. 10-1196946, a low-pressure pump is provided at the lower end of the housing, a high-pressure pump is disposed along the periphery of the housing, and a low-pressure pump and a high- Pressure hydraulic pump capable of two-stage compression. A high-pressure hydraulic pump is provided at the upper end of the housing to provide a high-pressure hydraulic fluid at a sufficient flow rate by providing a discharge block for collecting and discharging compressed hydraulic fluid from a plurality of high-pressure pipes.

However, the high-pressure hydraulic pump having such a structure has a structure in which the low-pressure pump, the high-pressure pump, and the discharge block are combined with the housing, and tolerance management and leakage prevention are structurally difficult.

Further, when the number of the high-pressure pumps to be mounted is changed according to the required specifications, it is necessary to change the structure of the discharge block according to the arrangement of the high-pressure pump. Therefore, There is a costly problem.

It is an object of the present invention to provide a high-pressure hydraulic pump capable of reducing the number of overall blocks and facilitating tolerance management and leakage prevention and coping with various specifications.

The hydraulic pump for high pressure according to the present embodiment is provided with a motor mounted on the outside of the oil tank where the hydraulic oil is stored, A housing provided inside the oil tank and receiving a drive shaft of the motor; A low pressure pump provided on a lower surface of the housing for sucking operating oil in the oil tank by primary rotation of the driving shaft; A low pressure chamber which is recessed from a lower surface of the housing and accommodates the low pressure pump to provide a compression space for the hydraulic oil; A plurality of high-pressure compressors for compressing the operating fluid supplied from the low-pressure pump by a reciprocating piston interlocked with a cam member formed on the driving shaft, the plurality of high- Pump; A low pressure discharge passage formed in the housing and connected to the low pressure pump so that the operating fluid compressed by the low pressure pump is discharged to the outside through the outer surface of the housing; Pressure chamber and the high-pressure pump so that the low-pressure chamber communicates with the plurality of high-pressure pumps so that the hydraulic fluid compressed by the low-pressure pump can flow into the high-pressure pump; A high-pressure fluid passage formed inside the plurality of high-pressure pumps to form an inlet and an outlet passage for the working fluid compressed by the piston; And a high-pressure discharge passage formed in the housing, the high-pressure discharge passage being connected to the high-pressure passage so that the high-pressure hydraulic fluid secondary-compressed by the plurality of high-pressure pumps is discharged to the outside through the outer surface of the housing, A first high-pressure flow path communicating with an upper end of the low-pressure supply flow path to guide inflow of operating fluid for secondary compression; And a second high-pressure flow path communicating with the high-pressure discharge flow path and guiding the discharge of the secondarily compressed working fluid, wherein the high-pressure discharge flow path is connected to the lower end of the second high-pressure flow path formed in each of the plurality of high- A plurality of connection flow paths extending from below the first high pressure flow path toward the drive shaft; A mixing flow path which is opened at a circumferential surface of the housing and extends to a predetermined depth so as to be connected to each other in a closed loop shape and communicates with all of the plurality of connection flow paths from the inside of the housing; And a discharge passage connecting one side of the mixing passage and an outer side of the housing to guide the discharge of the operating oil.

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And an input check valve is provided in the first high pressure passage to prevent reverse flow of the hydraulic oil that is secondarily compressed, and the second high pressure passage is formed with an elastic force greater than that of the input check valve, And a check valve is further provided.

The housing has a polygonal cross-sectional structure, and the high-pressure pump is disposed on each surface around the housing.

And a low pressure discharge port connected to the low pressure discharge passage and a high pressure discharge port connected to the high pressure discharge passage are formed on a circumferential surface of the housing.

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And the mixing passage is formed in a closed loop shape having the center of the driving shaft.

And the upper surface of the housing is mounted so as to be shielded by the inner surface of the oil tank.

The following effects can be expected from the high-pressure hydraulic pump according to the embodiment of the present invention.

The high pressure hydraulic pump according to the embodiment of the present invention includes a low pressure pump at the lower end of the housing and a high pressure pump along the periphery thereof. Further, it is possible to realize a flow path through which the hydraulic oil is discharged to the inside of the housing and the high-pressure pump, so that a separate discharge block is not required.

Therefore, the overall assembly work flow is reduced, the material cost is reduced, and the productivity is improved.

In addition, by eliminating the discharge block, the overall flow path length can be reduced, and the efficiency can be improved. In addition, the total number of blocks to be combined is reduced, thereby facilitating overall tolerance management and oil leakage prevention.

Further, since it is not necessary to provide a separate discharge block, it is possible to mount various numbers of high-pressure pumps only by changing the structure of the housing and the flow path of the high-pressure pump, and it is possible to provide various types of high- .

1 is a view showing a structure of a high-pressure hydraulic pump according to an embodiment of the present invention.
2 is a plan view of the pump assembly.
3 is a side view of the pump assembly.
4 is a longitudinal sectional view of the pump assembly.
5 is a cross-sectional view taken along line 5-5 'of FIG.
6 is a cross-sectional view taken along line 6-6 'of FIG.
7 is a cross-sectional view taken along line 7-7 'of FIG.
8 is a diagram showing the flow path structure of the discharge port and the high-pressure pump.
Fig. 9 is a view showing an oil flow state in a low load state. Fig.
Fig. 10 is a view showing an oil flow state under a high load condition. Fig.

Hereinafter, a high-pressure hydraulic pump according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a view showing a structure of a high-pressure hydraulic pump according to an embodiment of the present invention.

Referring to the drawings, a high-pressure hydraulic pump 1 according to an embodiment of the present invention may include a motor 10, an oil tank 20, and a pump assembly 30.

The motor 10 provides power for driving the pump assembly 30. A DC motor for a hydraulic pump, which is generally used, may be used. The motor 10 is mounted on the upper surface of the oil tank 20 so as to be exposed to the outside of the oil tank 20 and the driving shaft 11 of the motor 10 is mounted on the upper surface of the pump assembly 30 As shown in FIG.

The oil tank 20 is formed so as to provide a space for storing oil used as operating oil and accommodating the pump assembly 30. A distribution block 21 may be mounted on the upper surface of the oil tank 20. The distribution block 21 is configured to allow the actuator to be connected so that the hydraulic fluid can be supplied to the actuator. The distribution block 21 is connected to the housing 40 by the high-pressure discharge pipe 22 and the low-pressure discharge pipe 23, and receives the compressed operating fluid.

If necessary, the distribution block 21 may be omitted, and the actuator may be directly connected to the discharge pipes 22 and 23. [

2 is a plan view of the pump assembly. 3 is a side view of the pump assembly.

As shown in the figure, the pump assembly 30 includes a low-pressure pump 50 for primarily compressing the oil to be sucked into low pressure, a high-pressure pump 50 for secondarily compressing the oil supplied from the low- (60), and a housing (40) on which these pumps are mounted.

The housing 40 accommodates the driving shaft 11 of the motor 10 and may be configured to mount the low pressure pump 50 and the high pressure pump 60, respectively. The low pressure pump 50 is mounted on the lower surface of the housing 40 and four high pressure pumps 60 may be mounted on each side of the housing 40 along the circumference thereof. The number of the high-pressure pumps 60 mounted on the housing 40 may be adjusted as needed.

The housing 40 is formed in a hexahedron shape having a rectangular cross section. However, depending on the number of the high-pressure pumps 60 mounted on the housing 40, (40) may be configured in various polygonal shapes, and the sizes thereof may be variously provided.

A high pressure discharge port 434 and a low pressure discharge port 412 are formed on one side of the outer surface of the housing 40 to discharge the working fluid compressed by the high pressure pump 60 and the low pressure pump 50 . The high-pressure discharge port 434 and the low-pressure discharge port 412 are provided so as to be open on the same surface of the outer surface of the housing 40, and can be directly discharged through the housing 40, Lt; / RTI >

The driving shaft 11 extends downward through the center of the housing 40 and is rotatably supported by the upper bearing 112 and inside the housing 40. The high-pressure pump 60 and the low-pressure pump 50 can be driven by the rotation of the drive shaft 11. [

The high-pressure pump 60 is assembled to each surface of the housing 40 by a coupling member 62, and may be arranged radially with the driving shaft 11 as a center. The low pressure pump 50 is mounted on the lower surface of the housing 40 and a suction port 511 for sucking the hydraulic oil inside the oil tank 20 is disposed outside the low pressure pump 50 .

4 is a longitudinal sectional view of the pump assembly. 4 is a cross-sectional view cut in various directions, not in one direction, to facilitate explanation of the flow path inside the housing.

As shown in the figure, the housing 40 is vertically opened at the center so that the driving shaft 11 of the motor 10 can be inserted and penetrated. The upper surface of the housing 40 is in close contact with the upper surface of the oil tank 20 and the lower pressure pump 50 is mounted on the lower surface of the housing 40. A plurality of high-pressure pumps 60 may be disposed on the side surface of the housing 40.

That is, the housing 40 is mounted with the driving shaft 11, the low-pressure pump 50 and the high-pressure pump 60 in one block, and the high-pressure pump 60 And the low-pressure pump 50 can be driven at the same time.

The driving shaft 11 is formed with a cam portion 111 formed to be eccentric with the rotation axis of the driving shaft 11 at a position corresponding to the high-pressure pump 60. A cam bearing is mounted on the cam portion, and an end portion of the piston 63 of the high-pressure pump 60 can maintain contact with the cam bearing 114. The piston 63 is reciprocated by the cam portion 111 or the cam bearing 114 by pushing the piston 63 by the rotation of the drive shaft 11 and by the reciprocation of the piston 63 So that the hydraulic oil can be compressed.

An upper bearing 112 and a lower bearing 113 for supporting the driving shaft 11 are provided in the housing 40 so that the driving shaft 11 rotates inside the housing 40 So that it can be mounted as much as possible.

The low-pressure pump 50 is provided at the lower end of the housing 40 and has a structure similar to a general vane pump. The low-pressure pump 50 may be driven by a drive shaft 11 extending from the motor 10, and may be a gear pump instead of a vane pump.

The low pressure pump 50 may be formed in an outer shape by a cover block 51 and may include a vane assembly 53 provided inside the housing 40, a partition member 52, And a low-pressure passage provided in the low-pressure passage.

In detail, the lower surface of the housing 40 is opened and a low pressure chamber 41 is formed inside the opening. The low pressure chamber 41 may be shielded by the mounting of the cover block 51 and the drive shaft 11, the vane assembly 53 and the partition member 52 may be accommodated therein.

The driving shaft 11 is disposed to pass through the center of the partition member 52 and the vane assembly 53 and the lower end of the driving shaft 11 can be supported by the cover block 51. [ The vane assembly 53 is mounted to be pierced by the driving shaft 11 and is configured to be rotated together with the driving shaft 11 when the driving shaft 11 rotates. The partition member 52 divides the upper region of the vane assembly 53 to form a closed space in which the hydraulic oil introduced into the low pressure chamber 41 can be compressed.

The cover block 51 is provided with a suction port 511 through which the hydraulic oil in the oil tank 20 flows and a suction passage 513 through which the suctioned hydraulic oil flows into the low pressure chamber 41, . The suction port 511 is formed to be open to the side of the cover block 51, and an accessory such as a separate filter may be attached if necessary.

The suction passage 513 extends from the suction port 511 to the inside of the housing 40 provided with the vane assembly 53 to guide the oil sucked into the low pressure chamber 41.

The low-pressure chamber 41 is formed with a low-pressure passage formed of a plurality of passages through which the hydraulic fluid compressed in the low-pressure chamber 41 is moved.

In more detail, a low-pressure discharge passage 411 communicating with the low-pressure discharge port 412 is formed at one side of the low-pressure chamber 41. The low pressure discharge passage 411 extends from one side of the low pressure chamber 41 to the low pressure discharge port 412 on one side of the housing 40.

Accordingly, the working oil sucked through the suction port 511 and then sucked into the low pressure chamber 41 through the suction passage 513 and then compressed is discharged through the low pressure discharge port 411 to the low pressure discharge port 412, . ≪ / RTI >

A low-pressure supply passage 413 for supplying operating oil primarily compressed in the low-pressure chamber 41 to the high-pressure pump 60 is formed on the other side of the low-pressure chamber 41. The low pressure supply passage 413 may extend from one side of the low pressure chamber 41 to an outer side surface of the housing 40 to which the high pressure pump 60 is mounted.

At this time, the low-pressure supply passage 413 may be extended from the lower side to the upper side of the high-pressure pump 60 in a radial manner about the drive shaft 11. And may be extended to communicate with the first high-pressure flow path (66) formed in the high-pressure pump (60) by opening to the outer surface of the housing (40).

Accordingly, the hydraulic fluid primarily compressed by the low-pressure pump 50 is supplied to the high-pressure pump 60 through the low-pressure supply passage 413, is secondarily compressed, and can be discharged in a high-pressure state.

The high pressure pump 60 mounted to the housing 40 is disposed on the side of the housing 40 corresponding to the cam portion 111 and is capable of compressing the hydraulic oil compressed by the low pressure pump 50 .

The high pressure pump 60 includes a plug body 61 mounted on an outer surface of the housing 40 and a tubular body 61 housed in the plug body 61 so as to be reciprocatable, A piston 63 contacting the piston 63 and a piston spring 64 providing an elastic force to the piston 63 and a piston plug 65 supporting the piston spring 64.

The plug body 61 may include an exposed portion 611 and an inserting portion 612. The exposed portion 611 forms a portion exposed to the outside of the housing when the plug body 61 is mounted, and the inserting portion 612 includes a plug receiving portion (not shown) formed to penetrate toward the center of the housing 40 42, respectively. The plug body 61 can be fixedly mounted on the housing 40 by the joining member 62 which is separately engaged.

The plug body 61 is formed with a body receiving portion 613 in which the piston 63 and the piston spring 64 are received. The body accommodating portion 613 is formed to penetrate the plug body 61. The piston plug 65 is mounted on the opened outer side surface and the piston 63 is accommodated in the opened inner side surface. A piston spring 64 is disposed between the piston plug 65 and the piston 63 to elastically support the piston 63.

The piston plug 65 can be inserted and coupled to the inside of the plug body 61 by screwing on the outside of the plug body 61. The compression stroke of the piston spring 64 can be adjusted by rotating the piston plug 65. Accordingly, the pressure of the hydraulic oil compressed by the piston 63 can be set arbitrarily.

One end of the piston 63 is in contact with the outer circumferential surface of the cam portion 111, and the other end thereof is supported by the piston spring 64. Accordingly, when the piston 63 is reciprocated, the piston spring 64 is selectively compressed to maintain the end of the piston 63 in contact with the outer surface of the cam portion 111 at all times.

The inside of the high pressure chamber 614 defined by the inside of the body accommodating portion 613 by the reciprocating movement of the piston 63 and more specifically the space between the piston plug 65 and the piston 63 The operating oil can be secondarily compressed by the reciprocating movement of the piston 63. [0064]

The high-pressure chamber 614 is formed by secondarily compressing the hydraulic fluid discharged from the low-pressure pump 50, and is connected to the first high-pressure passage 66 and the second high-pressure passage 67, Lt; / RTI >

The first high-pressure flow path 66 is formed on the plug body 61 so as to communicate with the low-pressure supply flow path 413, and the first high-pressure flow path 66 is formed between the low-pressure supply path 413 and the high- As shown in FIG.

The first high pressure passage 66 is formed through the plug body 61 and the input check valve 661 is provided on the first high pressure passage 66. The input check valve 661 may be configured to be supported by a valve spring 662 so that the input check valve 661 can be opened or closed when the pressure of the hydraulic fluid flowing into the high pressure chamber 614 is equal to or higher than a set pressure.

5 is a cross-sectional view taken along line 5-5 'of FIG. 6 is a cross-sectional view taken along line 6-6 'of FIG. 7 is a cross-sectional view taken along line 7-7 'of FIG.

Referring to these drawings, the flow path structure of the high-pressure pump 60 will be described in more detail. One end of the first high-pressure flow path 66 is formed so as to communicate with the low-pressure supply flow path 413, And one end is formed so as to be able to communicate with the high-pressure chamber (614).

To this end, the first high-pressure flow path 66 extends in the same direction as the extending direction of the body accommodating portion 613 on the plug body 61, and two through-holes formed in the direction crossing the high- Lt; / RTI >

The input check valve 661 may be provided between the high-pressure chamber 614 and the low-pressure supply passage 413. The input check valve 661 may be configured to be supported by a valve spring 662 so that the input check valve 661 can be opened or closed when the pressure of the operating oil flowing into the high pressure chamber 614 from the low pressure supply passage 413 is equal to or higher than a set pressure .

Therefore, when the operating oil is firstly compressed by the low-pressure pump 50 and the inflow degree through the low-pressure supply passage becomes equal to or higher than the set pressure, the input check valve 661 is opened and the operating oil is supplied to the high- So that it can be introduced.

The plug body 61 may be provided with a second high pressure passage 67 and the second high pressure passage 67 may communicate with the high pressure chamber 614 and the high pressure discharge passage 43 inside the housing 40 As shown in FIG. The second high pressure passage (67) extends downward from the high pressure chamber (614) and extends toward the high pressure discharge passage (43) of the housing (40).

An output check valve 671 may be provided on the second high-pressure flow path 67. The output check valve 671 may be configured to be supported by a valve spring 672 so that the output check valve 671 can be opened or closed when the pressure of the hydraulic oil flowing into the high pressure discharge passage 43 from the high pressure chamber 614 is equal to or higher than a set pressure .

Accordingly, the high-pressure hydraulic fluid, which is secondarily compressed in the high-pressure chamber 614 by the reciprocating motion of the piston 63, opens the output check valve 671 and is discharged through the second high-pressure flow path 67 to the high- So that it can flow into the discharge flow path 43.

The high pressure discharge passage 43 is formed to open on the outer surface of the housing 40 so as to communicate with the second high pressure passage 67. The high pressure discharge passage 43 is formed on the inside of the housing 40, And the high-pressure discharge port 434 are connected to each other.

8 is a diagram showing the flow path structure of the discharge port and the high-pressure pump.

The high pressure discharge passage 43 is connected to the connection passage 431 connected to the second high pressure passage 67 provided on each plug body 61, A mixing flow path 432 connected to the plurality of connection flow paths 431 and a discharge flow path 433 connecting the mixing flow path 432 to the high pressure discharge port 434, .

In detail, the connection passage 431 is formed to open on the outer surface of the housing 40, and extends toward the drive shaft 11. At this time, the connection passage 431 extends toward the center of the housing 40 where the drive shaft 11 is located, and is not in communication with the space in which the drive shaft 11 is accommodated.

A plurality of connection channels 431 connected to the respective high-pressure pumps 60 are communicated with the mixing channel 432 inside the housing 40. The mixing passage 432 may be formed in a closed loop shape with respect to the center of the driving shaft 11 and has a rectangular structure corresponding to the sectional structure of the housing 40.

That is, the mixing passage 432 is defined by a passage extending from the peripheral surface of the housing 40 and extending by a predetermined depth, so that the mixing passage 432 is extended in a direction intersecting the adjacent peripheral surfaces, So that it is possible to form a closed loop shape that is connected as a whole.

Accordingly, the high-pressure hydraulic fluid discharged from each of the high-pressure pumps 60 supplied through the plurality of connection channels 431 can be introduced into the mixing channel 432.

The discharge passage 433 is communicated with the mixing passage 432 and extended to communicate with the high pressure discharge port 434 formed on one side of the housing 40. The discharge passage 433 may include a passage extending upwardly from the lower surface of the housing 40 to be connected to the mixing passage 432 and another passage extending from the high-pressure discharge port 434 to cross the passage Can be defined by the passage.

Hereinafter, the operation of the high-pressure hydraulic pump according to the embodiment of the present invention will be described.

Fig. 9 is a view showing an oil flow state in a low load state. Fig.

8, when a low load is required in the actuator and a low-pressure operating fluid is required, the pressure on the low-pressure discharge port 412 becomes higher than the backpressure exerted by the actuator, so that the low-pressure discharge port 412 connected to the low- Pressure hydraulic oil can be supplied through the pipe 23. [

When the motor 10 is driven in this state, the driving shaft 11 of the motor 10 rotates. The oil stored in the oil tank 20 flows into the low pressure pump 50 through the suction port 511 and the suction passage 513 by driving the motor 10.

The hydraulic oil flowing into the low pressure chamber 41 can be compressed by the vane assembly 53. The pressure of the working oil in the low pressure chamber 41 is lower than the elastic force of the valve spring 662 of the input check valve 661 so that the input check valve 661 is connected to the first high pressure oil passage 66 The operating fluid compressed by the low pressure pump 50 can not be introduced into the high pressure pump 60 and can be discharged through the low pressure discharge port 412 and the low pressure discharge pipe 23 to the distribution block 21, As shown in Fig.

10 is a view showing an oil flow state under a high load condition.

10, when a high load is required for the actuator and a high-pressure operating fluid is required, the driving shaft is rotated in accordance with the driving of the motor 10, and the low-pressure pump 50 and the high- .

The oil stored in the oil tank 20 flows into the low pressure pump 50 through the suction port 511 and the suction passage 513. [ The hydraulic oil flowing into the low-pressure chamber (41) is primarily compressed by the rotation of the vane assembly (53).

The operating fluid primarily compressed by the low pressure pump 50 is supplied from the inside of the low pressure chamber 41 to the high pressure pump 60 through the low pressure supply passage 413. [ At this time, a separate check valve (not shown) or a valve is provided on the low-pressure discharge passage 411 to block the discharge of the primary-compressed operating oil toward the low-pressure discharge port 412.

The operating oil supplied to the high pressure pump 60 through the low pressure supply passage 413 flows into the first high pressure passage 66. The pressure of the operating oil then flows through the valve spring 662 of the input check valve 661, This branch is larger than the elastic force and opens the first high-pressure flow path 66.

The hydraulic fluid having passed through the first high-pressure flow path (66) flows into the high pressure chamber (614) of the high-pressure pump (60). The pressure of the secondarily compressed hydraulic oil can be adjusted by the valve spring 672 of the output check valve 671, ) Pressure so that the secondarily compressed hydraulic fluid can be discharged through the second high-pressure flow path 67.

That is, the input check valve 661 on the first high pressure passage and the output check valve 671 on the second high pressure passage are selectively opened and closed according to reciprocation of the piston 63, and the input check valve 661 Pressure chamber 614 in accordance with the selective opening and closing of the output check valve 671, and can be discharged after being compressed in the high-pressure chamber 614.

As a result, the high-pressure hydraulic fluid secondary-compressed in the high-pressure chamber 614 flows into the high-pressure discharge passage 43. Pressure operating fluid secondary compressed by the plurality of high-pressure pumps 60 can be discharged to the high-pressure discharge port through the high-pressure discharge flow path.

The high-pressure hydraulic fluid discharged through the second high-pressure flow path (67) flows into the connection flow paths (431) provided in the respective high-pressure pumps (60), and flows through the connection flow paths (431) The flow of the working oil into the mixing flow path 432.

At this time, the hydraulic fluid, which is secondarily compressed by the plurality of high-pressure pumps 60, may be introduced into the mixing flow path 432 through the plurality of connection flow paths 431. Therefore, since the high-pressure hydraulic fluid compressed by the plurality of connection flow paths flows into the mixing flow path, a sufficient flow rate can be secured.

8, the hydraulic fluid flowing into the mixing passage 432 flows along the discharge passage 433 connected to the high-pressure discharge port 434 and flows through the high-pressure discharge port 434 to the pump assembly 30). The high pressure hydraulic fluid discharged through the high pressure discharge port 434 can be supplied to the distribution block 21 or the actuator through the high pressure discharge pipe 22 connected to the high pressure discharge port 434.

Claims (8)

A motor provided on the outside of the oil tank for storing the operating oil, which provides rotational power;
A housing provided inside the oil tank and receiving a drive shaft of the motor;
A low pressure pump provided on a lower surface of the housing for sucking operating oil in the oil tank by primary rotation of the driving shaft;
A low pressure chamber which is recessed from a lower surface of the housing and accommodates the low pressure pump to provide a compression space for the hydraulic oil;
A plurality of high-pressure compressors for compressing the operating fluid supplied from the low-pressure pump by a reciprocating piston interlocked with a cam member formed on the driving shaft, the plurality of high- Pump;
A low pressure discharge passage formed in the housing and connected to the low pressure pump so that the operating fluid compressed by the low pressure pump is discharged to the outside through the outer surface of the housing;
Pressure chamber and the high-pressure pump so that the low-pressure chamber communicates with the plurality of high-pressure pumps so that the hydraulic fluid compressed by the low-pressure pump can flow into the high-pressure pump;
A high-pressure fluid passage formed inside the plurality of high-pressure pumps to form an inlet and an outlet passage for the working fluid compressed by the piston;
And a high-pressure discharge passage formed in the housing, the high-pressure discharge passage being connected to the high-pressure passage so that high-pressure hydraulic oil, which is secondarily compressed by the plurality of high-pressure pumps, is discharged to the outside through the outer surface of the housing,
The high-
A first high-pressure flow path communicating with an upper end of the low-pressure supply flow path to guide inflow of operating fluid for secondary compression;
And a second high-pressure flow path communicating with the high-pressure discharge flow path and guiding the discharge of the secondarily compressed operating fluid,
The high-
A plurality of connection flow paths connected to a lower end of the second high pressure flow path formed in each of the plurality of high pressure pumps and extending from the lower side of the first high pressure flow path toward the drive shaft;
A mixing flow path which is opened at a circumferential surface of the housing and extends to a predetermined depth so as to be connected to each other in a closed loop shape and communicates with all of the plurality of connection flow paths from the inside of the housing;
And a discharge flow path connecting one side of the mixing flow path and an outer side surface of the housing to guide discharge of the operating fluid.
delete The method according to claim 1,
The first high-pressure oil passage is provided with an input check valve for preventing reverse flow of the hydraulic oil which is secondarily compressed,
Further comprising an output check valve formed in the second high pressure passage so as to have a greater elastic force than the input check valve to compress and discharge the operating oil.
The method according to claim 1,
The housing has a polygonal cross-sectional structure,
And the high-pressure pump is disposed on each of the surfaces around the housing.
The method according to claim 1,
And a low pressure discharge port connected to the low pressure discharge passage and a high pressure discharge port connected to the high pressure discharge passage are formed on a circumferential surface of the housing.
delete The method according to claim 1,
Wherein the mixing passage is formed in a closed loop shape around the drive shaft.
The method according to claim 1,
And the upper surface of the housing is mounted so as to be shielded by the inner surface of the oil tank.

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