KR102534467B1 - Radial Type Multistage Piston Pump - Google Patents

Abstract

The present invention relates to a multi-stage radial piston pump that allows simultaneous pumping of fluid by varying pressure by rotating one eccentric housing in the radial piston pump. The invention has the advantage of being able to use both low-pressure and high-pressure pumps at the same time by generating hydraulic pressure by separating high pressure and low pressure from a pressure generator itself that generates pressure in a radial piston pump without using an eccentric mechanism to change the position of an eccentric cam.

Description

Multistage radial piston pump {Radial Type Multistage Piston Pump}

The present invention relates to a multi-stage radial piston pump capable of simultaneously pumping fluid by varying pressure by rotation of one eccentric housing in a radial piston pump.

Hydraulic piston pumps are of the axial type, in which a piston that pressurizes fluid is drawn in and out along the path of the inclined plate by the rotation of the shaft, and the piston is radially arranged around an eccentric rotation shaft to form a radial type by rotation. It can be divided into radial type, in which the piston installed as is drawn in and out.

Since the radial type piston pump uses check valves as suction and discharge valves, there is little leakage through the valve and a relatively small number of parts, so it is mainly used as an ultra-high pressure pump that delivers pressure oil of 60 MPa or more.

As one method for pumping fluid with different pressures (ie, high pressure and low pressure) using a radial piston pump, a low pressure pump and a high pressure pump are separately provided at the fluid discharge part, and a low pressure check valve and a high pressure check There is a method of separately pumping into low pressure and high pressure using a valve, a low pressure relief valve, and a high pressure relief valve.

This method does not separate high and low pressure from the pressure generating source itself that generates pressure in the radial piston pump, but generates a pressure difference using two pumps and valves, so the pressure adjustment range of the valve is limited. It is unsuitable when the pressure difference is large.

Korean Patent Registration No. 10-0739504 (title of invention: portable automatic pump), which solves the problem of using two pumps in the aforementioned radial piston pump and improves to generate a pressure difference using one pump and valves has been disclosed.

Another method for pumping fluid by using a radial piston pump at different pressures (ie, high pressure and low pressure) may include a method of varying the capacity of a pressure generating source for generating pressure of the fluid.

In this way, there is Japanese Laid-Open Patent Publication No. 1991-111673 (Title of Invention: Fixed Cylinder Variable Displacement Radial Piston Pump).

The eccentric cam is provided with an eccentric mechanism capable of adjusting the distance between the center line of the eccentric cam and the axial line of the driving rotary shaft to adjust the amount of eccentricity and thereby change the discharge capacity so that the pressure can be adjusted.

In this method, the mechanism for changing the position of the eccentric cam is complicated, and since the eccentric cam is provided with the eccentric mechanism, it is inevitably larger than the fixed displacement type radial piston pump, and there is a problem that causes cost increase.

The present invention has been made to solve the above problems, and an object of the present invention is to generate high pressure and low pressure in a pressure generating source itself that generates pressure in a radial piston pump without using an eccentric mechanism that changes the position of an eccentric cam. It is to provide a multi-stage radial piston pump that separates to generate hydraulic pressure.

The multi-stage radial piston pump of the present invention for achieving the above object is a low pressure fluid inlet hole 11 into which fluid to be supplied at low pressure flows, and a high pressure fluid inlet hole 12 into which fluid to be supplied at high pressure flows. ), the low pressure fluid discharge hole 13 through which the fluid to be discharged at low pressure is discharged, the high pressure fluid discharge hole 14 through which the fluid to be discharged at high pressure is discharged, and the housing 30 is inserted to accommodate the housing to be accommodated. A pump body 10 equipped with a unit 15 and a fixed block receiving portion 16 for inflow and discharge into which the fixed block 20 for inflow and discharge is inserted and accommodated; A low pressure inlet passage 21 formed long in the longitudinal direction from one side toward the other side and communicating with the low pressure fluid inlet hole 11 to allow the low pressure fluid flowing into the low pressure fluid inlet hole 11 to flow; , A high-pressure inflow passage 22 formed long in the longitudinal direction from one side toward the other side and communicating with the high-pressure fluid inlet hole 12 to allow the high-pressure fluid flowing into the high-pressure fluid inlet hole 12 to flow And, it is formed long in the longitudinal direction from the other side toward one side, and communicates with the low pressure fluid discharge hole 13 so that the low pressure fluid increased to a low pressure flows and discharges. A low pressure discharge passage 23 and from the other side A high-pressure discharge passage 24 formed long in the longitudinal direction toward one side and communicating with the high-pressure fluid discharge hole 14 to allow the high-pressure fluid elevated to a high pressure to flow and discharge, and the low-pressure inlet passage ( 21) and a low pressure inlet fluid accommodating portion 25 in which the low pressure fluid introduced through is temporarily accommodated, and is spaced apart from the low pressure inlet fluid accommodating portion 25 in the longitudinal direction and the high pressure inflow passage 22 A fixed block 20 for inlet and outlet provided with a high-pressure inlet fluid receiving portion 26 in which the high-pressure fluid introduced through is temporarily accommodated; It is rotatably accommodated in the housing accommodating part 15, accommodated eccentrically with the central axis of the inlet and outlet fixing block 20, and a part of the inlet and outlet fixing block 20 is accommodated therein. A housing 30 having a fixing block insert 31 for inflow and discharge, which is inserted and coupled, and is inserted and coupled so that the inlet fluid accommodating part 25 for low pressure and the inlet fluid accommodating part 26 for high pressure are accommodated; It is provided in the housing 30 and is radially disposed along the circumference of the outer circumference of the inlet and outlet fixing block 20 corresponding to the portion where the high pressure discharge passage 24 is formed, but is slid outward from the center As the fixed block 20 for inflow and discharge and the housing 30 eccentric are rotated, the fluid temporarily accommodated in the inlet fluid accommodating part 26 for high pressure is pressurized to produce the pressurized high-pressure fluid. A plurality of high-pressure pistons 40 to be discharged to the discharge passage 24; It is provided in the housing 30 and is radially disposed along the circumference of the outer circumference of the inlet and outlet fixing block 20 corresponding to the portion where the low pressure discharge passage 23 is formed, but is slid outward from the center Arranged, the fluid temporarily accommodated in the low pressure inlet fluid receiving part 25 is pressurized according to the rotation of the inflow and outflow fixing block 20 and the eccentric housing 30, thereby converting the pressurized low pressure fluid into the low pressure fluid. A plurality of low-pressure pistons 50 to be discharged to the discharge passage 23; A driving shaft 60 formed on one side of the housing 30 opposite to the housing 30 into which the inflow and discharge fixing block 20 is inserted and coupled to a motor to drive the housing 30 to rotate; It is characterized by comprising a.

In addition, it is interposed between the housing accommodating part 15 and the fixing block 20 for inflow and outflow, and it is characterized in that the housing 30 is provided with a bearing 70 rotatably supported.

In addition, the diameter of the inlet passage 21 for low pressure and the diameter of the inlet passage 22 for high pressure are the same, and the diameter of the discharge passage 23 for low pressure and the diameter of the discharge passage 24 for high pressure are the same. The sliding distance of the high-pressure piston 40 and the sliding distance of the low-pressure piston 50 are the same, and the diameter of the high-pressure piston 40 is smaller than the diameter of the low-pressure piston 50. do.

In addition, the diameter of the high pressure discharge passage 24 is smaller than the diameter of the low pressure discharge passage 23, and the diameter of the low pressure discharge passage 23 and the diameter of the high pressure discharge passage 24 are The same, the sliding distance of the high pressure piston 40 and the sliding distance of the low pressure piston 50 are the same, and the diameter of the high pressure piston 40 is the same as the diameter of the low pressure piston 50 to be

In addition, the diameter of the inflow passage 21 for low pressure and the diameter of the inflow passage 22 for high pressure are the same, and the diameter of the discharge passage 23 for low pressure and the diameter of the discharge passage 24 for high pressure are the same. And, the sliding distance of the high pressure piston 40 is longer than the sliding distance of the low pressure piston 50, and the diameter of the high pressure piston 40 and the low pressure piston 50 are the same. do.

In addition, the diameter of the inlet passage 21 for low pressure and the diameter of the inlet passage 22 for high pressure are the same, and the diameter of the discharge passage 24 for high pressure is greater than the diameter of the discharge passage 23 for low pressure. The sliding distance of the high-pressure piston 40 and the sliding distance of the low-pressure piston 50 are the same, and the diameter of the high-pressure piston 40 and the low-pressure piston 50 are the same. to be

In addition, the low pressure inflow fluid accommodating part 25 and the high pressure inflow fluid accommodating part 26 form an angle of 180 degrees with respect to the inflow and discharge fixing block 20, and the low pressure discharge passage ( 23), and the high-pressure discharge passage 24 is characterized in that it forms an angle of 180 degrees with respect to the fixing block 20 for inflow and discharge.

The multi-stage radial piston pump of the present invention according to the above configuration, unlike the conventional piston pump in which the pressure is varied using an eccentric mechanism for changing the position of an eccentric cam, high pressure is used as a single power source without using an eccentric mechanism. And there is an advantage that high-pressure pumping and low-pressure pumping of the fluid can be used at the same time by separating with low pressure to generate hydraulic pressure.

In addition, the present invention has the advantage of being able to generate hydraulic pressure by separating the pressure generating source itself into high pressure and low pressure in a radial piston pump.

In addition, since the present invention does not use an eccentric mechanism, unlike the conventional piston pump in which the pressure is varied using an eccentric mechanism, the radial piston pump can be made compact, has a simple structure and is inexpensive.

1 is a perspective view showing a multi-stage radial piston pump of the present invention.
2 is an exploded perspective view showing a multi-stage radial piston pump of the present invention.
Figure 3 is a cross-sectional view showing the operating state of the high-pressure piston of the multi-stage radial piston pump according to the present invention.
Figure 4 is a longitudinal cross-sectional view showing the operating state of the low-pressure piston of the multi-stage radial piston pump according to the present invention.
5 and 6 are views showing the operating state of the high-pressure piston of the multi-stage radial piston pump according to the present invention.
7 and 8 are views showing the operating state of the low-pressure piston of the multi-stage radial piston pump according to the present invention.
9 is a view showing the flow path structure of the pump body of the multi-stage radial piston pump according to the present invention.
10 is an exploded perspective view of another type of multi-stage radial piston pump according to the present invention.
11 is a cross-sectional view showing an operating state of a high-pressure piston of another type of multi-stage radial piston pump according to the present invention.
12 is a longitudinal cross-sectional view showing an operating state of a low-pressure piston of another type of multi-stage radial piston pump according to the present invention.

Hereinafter, the multi-stage radial piston pump of the present invention will be described in detail with reference to the drawings.

1 is a perspective view showing a multi-stage radial piston pump of the present invention, Figure 2 is an exploded perspective view showing a multi-stage radial piston pump of the present invention, Figure 3 is a high-pressure piston of a multi-stage radial piston pump according to the present invention A cross-sectional view showing the operating state, Figure 4 is a longitudinal cross-sectional view showing the operating state of the low pressure piston of the multi-stage radial piston pump according to the present invention, Figures 5 and 6 are for high pressure of the multi-stage radial piston pump according to the present invention 7 and 8 are views showing the operating state of the low-pressure piston of the multi-stage radial piston pump according to the present invention, and FIG. 9 is the pump body of the multi-stage radial piston pump according to the present invention. It is a drawing showing the negative flow path structure.

Multi-stage radial piston pump according to the present invention, the pump body portion (10); Fixed block 20 for inflow and outflow; housing 30; Piston 40 for high pressure; Piston 50 for low pressure; drive shaft 60; is made including.

The pump body part 10 has a block shape, and the pump body part 10 includes a low pressure fluid inlet hole 11, a high pressure fluid inlet hole 12, a low pressure fluid outlet hole 13, , a high-pressure fluid discharge hole 14, a housing accommodating portion 15, and a fixed block accommodating portion 16 for inlet and discharge are provided.

The pump body part 10 allows the housing 30 to be inserted into and accommodated in the housing accommodating part 15, and is fixed to the inflow and outflow fixing block accommodating part 16 for inlet and discharge. It is provided with a cover so that the block 20 can be inserted and accommodated so that it can be assembled.

The low pressure fluid and the high pressure fluid respectively flow into the pump body 10, and are boosted to low pressure and high pressure respectively by the low pressure piston 50 and the high pressure piston 40 to be described later, and the low pressure fluid and the high pressure fluid respectively. The fluid is discharged from each.

The low pressure fluid inlet hole 11 allows fluid to be supplied at low pressure to flow in.

The high-pressure fluid inlet hole 12 allows fluid to be supplied at high pressure to flow in.

At this time, the fluid flowing into the low pressure fluid inlet hole 11 and the fluid flowing into the high pressure fluid inlet hole 12 may use the same fluid or different fluids. When the fluid flowing into the low pressure fluid inlet 11 and the fluid flowing into the high pressure fluid inlet 12 use the same fluid, they may be supplied from one tank.

The low pressure fluid discharge hole 13 serves to discharge the fluid pressure increased to a low pressure by the low pressure piston 50 to be described later.

The high-pressure fluid discharge hole 14 serves to discharge the fluid that has been increased to a high pressure by the high-pressure piston 40 to be described later.

The housing accommodating portion 15 accommodates a housing 30 to be described later inserted therein.

The fixing block 20 for inlet and outlet, which will be described later, is inserted into and accommodated in the inlet and outlet fixing block accommodating part 16 .

The fixing block 20 for inflow and outflow transfers the fluid introduced into the low-pressure fluid inlet hole 11 and the high-pressure fluid inlet hole 12 of the pump body 10 to the housing 30 to be described later. The high pressure piston 40 and the low pressure piston 50 to be described later transfer the fluid that has been increased to high pressure and low pressure, respectively, from the housing 30 to the low pressure fluid discharge hole 13 of the pump body 10 and It serves to flow into the high pressure fluid discharge hole 14.

The inlet and outlet fixing block 20 is accommodated in the inlet and outlet fixing block accommodating portion 16 of the pump body 10, and includes a low pressure inflow passage 21 and a high pressure inflow passage. 22, a low pressure discharge passage 23, a high pressure discharge passage 24, a low pressure inflow fluid accommodating portion 25, and a high pressure inflow fluid accommodating portion 26 are provided. The overall shape of the fixing block 20 for inlet and outlet is a cylindrical shape.

The low pressure inlet passage 21 is formed long in the longitudinal direction from one side to the other side, and communicates with the low pressure fluid inlet hole 11 to supply the low pressure fluid introduced into the low pressure fluid inlet hole 11. It serves to flow to the inside of the housing 30.

Like the low pressure inflow passage 21, the high pressure inflow passage 22 is formed long in the longitudinal direction from one side to the other side, and communicates with the high pressure fluid inlet hole 12 to allow the high pressure fluid to flow in. It serves to allow the high-pressure fluid introduced into the ball 12 to flow into the housing 30. The high-pressure inflow passage 22 is provided separately from the low-pressure inflow passage 21 .

The low pressure discharge passage 23 is formed long in the longitudinal direction from the other side toward one side, and communicates with the low pressure fluid discharge hole 13 to pass the low pressure fluid increased to a low pressure to the outside of the housing 30. It serves to be discharged through the low pressure fluid discharge hole 13 by allowing it to flow.

The high-pressure discharge passage 24 is formed long in the longitudinal direction from the other side toward one side, and communicates with the high-pressure fluid discharge hole 14 to pass the high-pressure fluid that has been increased to a high pressure to the outside of the housing 30. It serves to be discharged through the high-pressure fluid discharge hole 14 by allowing it to flow.

The low-pressure inflow fluid accommodating part 25 temporarily accommodates the low-pressure fluid introduced through the low-pressure inflow passage 21 . The received low-pressure fluid is boosted to a low pressure by a low-pressure piston 50 to be described later, and flows to the outside of the housing 30 through the low-pressure discharge passage 23 to open the low-pressure fluid discharge hole 13. will be released through

The high pressure inlet fluid accommodating part 26 is spaced apart from the low pressure inlet fluid accommodating part 25 in the longitudinal direction and provided separately from the low pressure inlet fluid accommodating part 25, and the high pressure inlet fluid accommodating part 22 ), the high-pressure fluid introduced through is temporarily accommodated. The received high-pressure fluid is boosted to a high pressure by a high-pressure piston 40 to be described later, and flows to the outside of the housing 30 through the high-pressure discharge passage 24 to open the high-pressure fluid discharge hole 14. will be released through

In addition, the present invention, like the low pressure inlet fluid accommodating portion 25 and the high pressure inlet fluid accommodating portion 26, the low pressure discharge fluid accommodating portion 27 and the high pressure discharge fluid accommodating portion on the discharge side of the flow path ( 28) may be provided.

The low pressure discharge fluid accommodating portion 27 and the high pressure discharge fluid accommodating portion 28 temporarily discharge the low pressure fluid and the high pressure fluid to be discharged through the low pressure discharge passage 23 and the high pressure discharge passage 24, respectively. The received low-pressure fluid and high-pressure fluid are discharged through the low-pressure discharge passage 23 and the high-pressure discharge passage 24, respectively.

The housing 30 is rotatably accommodated in the housing accommodating portion 15, and is accommodated eccentrically with the central axis of the inlet and outlet fixing block 20, and the inlet and outlet fixing block ( 20) is inserted and coupled so that a part thereof is accommodated, and the inlet and discharge fixing block insert 31 is inserted and coupled so that the low pressure inlet fluid accommodating part 25 and the high pressure inlet fluid accommodating part 26 are accommodated. are provided A high-pressure piston 40 and a low-pressure piston 50, which will be described later, are separately provided on the inner periphery of the housing 30, respectively.

In a typical radial piston pump, a housing is provided eccentrically from the center of an axis to pressurize and pump fluid introduced by radially disposed pistons as the housing rotates. In addition, the piston is supported by a spring and is moved by the elastic force of the spring to pressurize the fluid. and pressurizes the fluid. Since this structure is known, detailed structure and operation will be omitted.

The high-pressure piston 40 is provided in the housing 30 and radially along the circumference of the outer circumference of the inlet and outlet fixing block 20 corresponding to the portion where the high-pressure discharge passage 24 is formed. It is arranged but is arranged so as to slide outward from the center. According to the rotation of the inlet and outlet fixing block 20 and the eccentric housing 30, the fluid temporarily accommodated in the inlet fluid receiving portion 26 for high pressure is pressurized It serves to discharge the pressurized high-pressure fluid to the high-pressure discharge passage 24, and consists of a plurality of them.

The low-pressure piston 50 is provided in the housing 30 and radially along the circumference of the outer circumference of the inlet and outlet fixing block 20 corresponding to the portion where the low-pressure discharge passage 23 is formed. It is arranged but is arranged so as to slide outward from the center, and according to the rotation of the inlet and outlet fixing block 20 and the eccentric housing 30, the fluid temporarily accommodated in the low pressure inlet fluid receiving part 25 is pressurized It serves to discharge the pressurized low-pressure fluid to the low-pressure discharge passage 23, and consists of a plurality of them.

In the drawing, it is shown that the high-pressure piston 40 and the low-pressure piston 50 are five.

5 is a state before the low pressure fluid introduced through the low pressure inflow passage 21 and temporarily accommodated in the low pressure inflow fluid accommodating part 25 is pressurized by the low pressure piston 50 A. FIG. 6 shows a state in which the housing 30 is rotated 180 degrees in the state of FIG. 5 and the low pressure fluid is pressurized by the low pressure piston 50 A. The pressurized low-pressure fluid is temporarily accommodated in the low-pressure discharge fluid receiving portion 27 and flows through the low-pressure discharge passage 23 by the pressurization of the low-pressure piston 50 through the low-pressure fluid discharge hole 13. will be ejected

7 is a state before the high-pressure fluid introduced through the high-pressure inflow passage 22 and temporarily accommodated in the low-pressure inflow fluid accommodating part 26 is pressurized by the high-pressure piston 40 A. FIG. 8 shows a state in which the housing 30 is rotated 180 degrees in the state of FIG. 7 and the high-pressure fluid is pressurized by the high-pressure piston 40 A. The pressurized high-pressure fluid is temporarily accommodated in the high-pressure discharge fluid accommodating portion 28, flows through the high-pressure discharge passage 23 by the pressurization of the high-pressure piston 40, and passes through the high-pressure fluid discharge hole 14. will be ejected

The driving shaft 60 is formed on one side of the housing 30 opposite to the housing 30 into which the inflow and outflow fixing block 20 is inserted, and is coupled to a motor to drive the housing 30 to rotate. play a role in

The multi-stage radial piston pump of the present invention configured as described above differs from conventional piston pumps in which pressure is varied by using an eccentric mechanism for changing the position of an eccentric cam, and high pressure with one power source without using an eccentric mechanism. And there is an advantage that high-pressure pumping and low-pressure pumping of the fluid can be used at the same time by separating with low pressure to generate hydraulic pressure. In addition, unlike conventional piston pumps that vary pressure using an eccentric mechanism, the present invention does not use an eccentric mechanism, so that the radial piston pump can be made compact, has a simple structure and is inexpensive.

The present invention is interposed between the housing accommodating portion 15 and the fixing block 20 for inflow and outflow for rotation of the housing 30, and the housing 30 is provided with a bearing 70 rotatably supported. it is desirable that The bearing 70 is installed at a location where the high-pressure piston 40 and the low-pressure piston 50 are located, respectively, so that the high-pressure piston 40 and the low-pressure piston 50 rotate when the housing 30 rotates. ) is preferably slid.

Various methods may be used in order for the high-pressure piston 40 and the low-pressure piston 50 to step up each fluid to a high pressure and a low pressure, respectively.

In the first case, the diameter of the inflow passage 21 for low pressure and the diameter of the inflow passage 22 for high pressure are the same, and the diameter of the discharge passage 23 for low pressure and the diameter of the discharge passage 24 for high pressure are the same. The diameter of ) is the same, and the sliding distance of the high pressure piston 40 and the sliding distance of the low pressure piston 50 are the same, and the diameter of the high pressure piston 40 is the low pressure piston 50 It is a way to make it smaller than the diameter of

3 to 8 show that the diameter of the high-pressure piston 40 is smaller than that of the low-pressure piston 50.

When the sliding distance of the piston is the same and the diameter of the piston is small, the pressure increases when pumping the same flow rate. The pressure of the fluid pumped by the piston 40 becomes high pressure, and the pressure of the fluid pumped by the piston 50 for low pressure becomes low pressure.

In the second case, the diameter of the low pressure discharge passage 23 and the diameter of the high pressure discharge passage 24 are the same, and the sliding distance of the high pressure piston 40 and the low pressure piston 50 The sliding distance of is the same, the diameter of the high pressure piston 40 is the same as the diameter of the low pressure piston 50, and the high pressure discharge passage 24 is smaller than the diameter of the low pressure discharge passage 23 It is a way to make the diameter of the smaller.

Since the sliding distance of the piston is the same and the diameter of the piston is the same, when the same flow rate is pumped, if the diameter of the high pressure discharge passage 24 is smaller than the diameter of the low pressure discharge passage 23, the high pressure discharge passage 24 The pressure of the fluid pumped by the piston 40 becomes high pressure, and the pressure of the fluid pumped by the low pressure piston 50 becomes low pressure.

In the third method, the diameter of the low pressure inlet passage 21 and the high pressure inflow passage 22 are the same, and the low pressure discharge passage 23 has a diameter and the high pressure discharge passage 24 The diameter of is the same, the diameter of the high pressure piston 40 and the diameter of the low pressure piston 50 are the same, and the sliding distance of the high pressure piston 40 is of the low pressure piston 50 It is a way to make it longer than the sliding distance.

Since the sliding distance of the pistons is the same and the diameter of the pistons is the same, when the same flow rate is pumped, when the sliding distance of the high pressure piston 40 is longer than the sliding distance of the low pressure piston 50, the high pressure piston The pressure of the fluid pumped by 40 becomes high pressure, and the pressure of the fluid pumped by the low pressure piston 50 becomes low pressure.

In the fourth method, the diameter of the low pressure inflow passage 21 and the diameter of the high pressure inflow passage 22 are the same, and the sliding distance of the high pressure piston 40 and the low pressure piston 50 The sliding distance is the same, the diameter of the high pressure piston 40 and the low pressure piston 50 are the same, and the diameter of the high pressure discharge passage 24 is greater than the diameter of the low pressure discharge passage 23 A way to make the diameter smaller.

Since the sliding distance of the pistons is the same and the diameter of the pistons is the same, when the same flow rate is pumped, when the diameter of the high pressure discharge passage 24 is smaller than the diameter of the low pressure discharge passage 23, the The pressure of the fluid pumped by the high pressure piston 40 becomes high pressure, and the pressure of the fluid pumped by the low pressure piston 50 becomes low pressure.

As described above, the present invention has the advantage of simultaneously using high-pressure pumping and low-pressure pumping of fluid by generating hydraulic pressure by separating the pressure generating source itself into high pressure and low pressure in the radial piston pump. .

In addition, in the present invention, the low pressure inlet fluid accommodating portion 25 and the high pressure inlet fluid accommodating portion 26 form an angle of 90 degrees around the inflow and discharge fixing block 20, and the low pressure It is preferable that the discharge passage 23 for high pressure and the discharge passage 24 for high pressure form an angle of 180 degrees with respect to the fixing block 20 for inflow and discharge.

In FIG. 2 , the inlet fluid accommodating part 25 for low pressure and the inlet fluid accommodating part 26 for high pressure form an angle of 90 degrees around the fixing block 20 for inflow and discharge.

As described above, the low pressure inflow fluid accommodating part 25 and the high pressure inflow fluid accommodating part 26 form an angle of 90 degrees around the inflow and discharge fixing block 20, and the low pressure discharge When the flow path 23 and the high-pressure discharge flow path 24 form an angle of 180 degrees around the inlet and discharge fixing block 20, when the fluid is introduced and pressurized, the fluid is symmetrically formed and pressurized. Since is pressurized and discharged symmetrically, pulsation and vibration due to the inflow and discharge of fluid cancel each other, so smooth operation is possible.

Figure 10 is an exploded perspective view of another type of multi-stage radial piston pump according to the present invention, Figure 11 is a cross-sectional view showing the operating state of the high-pressure piston of another type of multi-stage radial piston pump according to the present invention, Figure 12 is It is a longitudinal cross-sectional view showing the operating state of the low-pressure piston of another type of multi-stage radial piston pump according to the present invention.

Another type of multi-stage radial piston pump according to the present invention, like the above-described multi-stage radial piston pump according to the present invention, the pump body portion 10; Fixed block 20 for inflow and outflow; housing 30; Piston 40 for high pressure; Piston 50 for low pressure; drive shaft 60; is made including.

The structure of the pump body 10, the fixing block 20 for inlet and outlet, and the drive shaft 60 is the same as that of the above-described multi-stage radial piston pump according to the present invention.

However, it is different from the multi-stage radial piston pump according to the present invention described above in that the housing 30 is formed stepwise to pressurize the introduced fluid at high and low pressures and discharge it.

The housing 30 is rotatably accommodated in the housing accommodating portion 15, and is accommodated eccentrically with the central axis of the inlet and outlet fixing block 20, and the inlet and outlet fixing block ( 20) is inserted and coupled so that a part thereof is accommodated, and the inlet and discharge fixing block insert 31 is inserted and coupled so that the low pressure inlet fluid accommodating part 25 and the high pressure inlet fluid accommodating part 26 are accommodated. What is provided is the same as the multi-stage radial piston pump according to the present invention described above.

The diameter of the inner periphery of the housing 30 is the same, and the diameter of the outer periphery of the housing 30 is that the part where the high-pressure piston 40 is coupled and the part where the low-pressure piston 50 is coupled have different diameters. It is different from the multi-stage radial piston pump according to the present invention described above in that it is formed stepwise so as to be different.

10 to 12, it can be seen that the diameter of the outer circumference of the housing 30, the diameter of the part to which the high-pressure piston 40 is coupled is large, and the diameter of the part to which the low-pressure piston 50 is coupled is small. there is.

The high-pressure piston 40 is provided in the housing 30 and radially along the circumference of the outer circumference of the inlet and outlet fixing block 20 corresponding to the portion where the high-pressure discharge passage 24 is formed. It is arranged but is arranged so as to slide outward from the center. According to the rotation of the inlet and outlet fixing block 20 and the eccentric housing 30, the fluid temporarily accommodated in the inlet fluid receiving portion 26 for high pressure is pressurized It serves to discharge the pressurized high-pressure fluid to the high-pressure discharge passage 24, and a plurality of them is the same as the above-described multi-stage radial piston pump according to the present invention.

The low-pressure piston 50 is provided in the housing 30 and radially along the circumference of the outer circumference of the inlet and outlet fixing block 20 corresponding to the portion where the low-pressure discharge passage 23 is formed. It is arranged but is arranged so as to slide outward from the center, and according to the rotation of the inlet and outlet fixing block 20 and the eccentric housing 30, the fluid temporarily accommodated in the low pressure inlet fluid receiving part 25 is pressurized It serves to discharge the pressurized low-pressure fluid to the low-pressure discharge passage 23, and a plurality of them is the same as the above-described multi-stage radial piston pump according to the present invention.

At this time, the same piston 40 for high pressure and the piston 50 for low pressure are used, and between the housing accommodating part 15 and the fixing block 20 for inflow and discharge for rotation of the housing 30 When the inner diameter of the inner bearing is the same in the bearing 70 interposed therebetween and on which the housing 30 is rotatably supported, the diameter of the outer circumference of the housing 30 is formed differently, so that the high pressure piston 40 ) The stroke length of the low pressure piston 50 is longer than the stroke length. Therefore, when the stroke length of the piston is long, the high-pressure piston 40 having a relatively longer stroke length can pump the high-pressure fluid when pumping the same flow rate.

As described above, in the multistage radial piston pump of another type according to the present invention, the diameter of the outer circumference of the housing 30 is such that the part where the high pressure piston 40 is coupled and the part where the low pressure piston 50 is coupled are mutually exclusive. By being formed stepwise so that the diameter is different, there is an advantage in that high-pressure and low-pressure pumping of the fluid can be used simultaneously by generating hydraulic pressure by separating high and low pressure with one power source.

Of course, various methods described above may be used to increase the pressure of the high-pressure piston 40 and the low-pressure piston 50 respectively to high pressure and low pressure, respectively.

Technical ideas should not be interpreted as being limited to the above-described embodiments of the present invention. Not only the scope of application is diverse, but also various modifications and implementations are possible at the level of those skilled in the art without departing from the gist of the present invention claimed in the claims. Therefore, such improvements and changes fall within the protection scope of the present invention as long as they are obvious to those skilled in the art.

10: pump body
11: fluid inlet hole for low pressure
12: fluid inlet hole for high pressure
13: fluid discharge hole for low pressure
14: fluid discharge hole for high pressure
15: housing receiving part
16: fixed block receiving part for inflow and outflow
20: Fixed block for inflow and outflow
21: inflow passage for low pressure
22: inflow passage for high pressure
23: discharge passage for low pressure
24: discharge passage for high pressure
25: inlet fluid receiving part for low pressure
26: inlet fluid receiving unit for high pressure
30: housing
31: Inlet and outlet fixing block insertion part
40: high pressure piston
50: piston for low pressure
60: drive shaft
70: bearing

Claims (7)

A low pressure fluid inlet hole 11 into which a fluid to be supplied at low pressure is introduced;
A high-pressure fluid inlet hole 12 into which fluid to be supplied at high pressure flows;
A low pressure fluid discharge hole 13 through which fluid to be discharged at low pressure is discharged;
A high-pressure fluid discharge hole 14 through which fluid to be discharged at high pressure is discharged;
A housing accommodating portion 15 into which the housing 30 is inserted and accommodated;
A pump body 10 having an inlet and outlet fixing block accommodating portion 16 into which the inlet and outlet fixing block 20 is inserted and accommodated;
A low pressure inlet passage 21 formed long in the longitudinal direction from one side toward the other side and communicating with the low pressure fluid inlet hole 11 to allow the low pressure fluid flowing into the low pressure fluid inlet hole 11 to flow; ,
A high-pressure inlet passage 22 formed long in the longitudinal direction from one side toward the other side and communicating with the high-pressure fluid inlet hole 12 to allow the high-pressure fluid flowing into the high-pressure fluid inlet hole 12 to flow; ,
A low pressure discharge passage 23 formed long in the longitudinal direction from the other side toward one side and communicating with the low pressure fluid discharge hole 13 so that the low pressure fluid increased to a low pressure flows and is discharged;
A high-pressure discharge passage 24 formed long in the longitudinal direction from the other side toward one side and communicating with the high-pressure fluid discharge hole 14 so that the high-pressure fluid increased to a high pressure flows and is discharged;
a low pressure inflow fluid accommodating portion 25 in which the low pressure fluid introduced through the low pressure inflow passage 21 is temporarily accommodated;
An inflow having a high-pressure inlet fluid accommodating part 26 spaced apart from the low-pressure inlet fluid accommodating part 25 in the longitudinal direction and temporarily accommodating the high-pressure fluid introduced through the high-pressure inlet passage 22 And a fixed block for discharge (20);
It is rotatably accommodated in the housing accommodating part 15, accommodated eccentrically with the central axis of the inlet and outlet fixing block 20, and a part of the inlet and outlet fixing block 20 is accommodated therein. A housing 30 having a fixing block insert 31 for inflow and discharge, which is inserted and coupled, and is inserted and coupled so that the inlet fluid accommodating part 25 for low pressure and the inlet fluid accommodating part 26 for high pressure are accommodated;
It is provided in the housing 30 and is radially disposed along the circumference of the outer circumference of the inlet and outlet fixing block 20 corresponding to the portion where the high pressure discharge passage 24 is formed, but is slid outward from the center As the fixed block 20 for inflow and discharge and the housing 30 eccentric are rotated, the fluid temporarily accommodated in the inlet fluid accommodating part 26 for high pressure is pressurized to produce the pressurized high-pressure fluid. A plurality of high-pressure pistons 40 to be discharged to the discharge passage 24;
It is provided in the housing 30 and is radially disposed along the circumference of the outer circumference of the inlet and outlet fixing block 20 corresponding to the portion where the low pressure discharge passage 23 is formed, but is slid outward from the center Arranged, the fluid temporarily accommodated in the low pressure inlet fluid receiving part 25 is pressurized according to the rotation of the inflow and outflow fixing block 20 and the eccentric housing 30, thereby converting the pressurized low pressure fluid into the low pressure fluid. A plurality of low-pressure pistons 50 to be discharged to the discharge passage 23;
A driving shaft 60 formed on one side of the housing 30 opposite to the housing 30 into which the inflow and discharge fixing block 20 is inserted and coupled to a motor to drive the housing 30 to rotate; Multi-stage radial piston pump, characterized in that comprising a. According to claim 1,
A multi-stage radial piston pump, characterized in that a bearing 70 is interposed between the housing accommodating part 15 and the inlet and outlet fixing block 20 and the housing 30 is rotatably supported. According to claim 1,
The diameter of the inflow passage 21 for the low pressure and the diameter of the inflow passage 22 for the high pressure are the same,
The diameter of the low pressure discharge passage 23 and the diameter of the high pressure discharge passage 24 are the same,
The sliding distance of the high-pressure piston 40 and the sliding distance of the low-pressure piston 50 are the same,
The multi-stage radial piston pump, characterized in that the diameter of the high-pressure piston (40) is smaller than the diameter of the low-pressure piston (50). According to claim 1,
The diameter of the high pressure discharge passage 24 is smaller than the diameter of the low pressure discharge passage 23,
The diameter of the low pressure discharge passage 23 and the diameter of the high pressure discharge passage 24 are the same,
The sliding distance of the high-pressure piston 40 and the sliding distance of the low-pressure piston 50 are the same,
The multi-stage radial piston pump, characterized in that the diameter of the high-pressure piston (40) is the same as the diameter of the low-pressure piston (50). According to claim 1,
The diameter of the inflow passage 21 for the low pressure and the diameter of the inflow passage 22 for the high pressure are the same,
The diameter of the low pressure discharge passage 23 and the diameter of the high pressure discharge passage 24 are the same,
The sliding distance of the high pressure piston 40 is longer than the sliding distance of the low pressure piston 50,
The multi-stage radial piston pump, characterized in that the diameter of the high-pressure piston (40) and the diameter of the low-pressure piston (50) are the same. According to claim 1,
The diameter of the inflow passage 21 for the low pressure and the diameter of the inflow passage 22 for the high pressure are the same,
The diameter of the high pressure discharge passage 24 is smaller than the diameter of the low pressure discharge passage 23,
The sliding distance of the high-pressure piston 40 and the sliding distance of the low-pressure piston 50 are the same,
The multi-stage radial piston pump, characterized in that the diameter of the high-pressure piston (40) and the diameter of the low-pressure piston (50) are the same. According to claim 1,
The low pressure inflow fluid accommodating part 25 and the high pressure inflow fluid accommodating part 26 form an angle of 90 degrees with respect to the inlet and discharge fixing block 20, and the low pressure discharge passage 23 And, the multi-stage radial piston pump, characterized in that the high-pressure discharge passage (24) forms an angle of 180 degrees with respect to the inlet and outlet fixing block (20).

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