KR20110104163A - Pressure recovery mechanism using hydrostatic power transmission - Google Patents

Abstract

The present invention relates to a pressure energy recovery device in which a hydraulic pump and a hydraulic motor are integrally formed, and more particularly, the seawater is sucked using a hydraulic pump to supply the membrane at a high pressure to a membrane of a reverse osmosis desalination system, and is not discharged to production water. In the hydraulic pump and the hydraulic motor-integrated energy recovery unit, which can obtain the driving power of the hydraulic pump by recovering the pressure energy of the seawater without discharging it into the sea and driving the hydraulic motor integrally formed with the hydraulic pump, the hydraulic pump is a plate valve. Intake and discharge are made through, the hydraulic motor is supplied and discharged through the rotary valve, the plate valve for the hydraulic pump and the rotary valve for the hydraulic motor is composed of a composite valve, in the case of the plate valve of the conventional piston pump It can be designed to achieve positive pressure balance like plate valve, so it has low friction and In the right side, the sealing is easy in the circumferential direction, so there is little leakage, thereby increasing the efficiency of the pressure recoverer.

Description

Pressure Recovery Mechanism using a hydraulic pump and a hydraulic motor integrally {Pressure Recovery Mechanism using Hydrostatic Power Transmission}

The present invention relates to a pressure energy recovery device in which a hydraulic pump and a hydraulic motor are integrally formed, and more particularly, the seawater is sucked using a hydraulic pump to supply the membrane at a high pressure to a membrane of a reverse osmosis desalination system, and is not discharged to production water. In the hydraulic pump and the hydraulic motor-integrated energy recovery unit, which can obtain the driving power of the hydraulic pump by recovering the pressure energy of the seawater without discharging it into the sea and driving the hydraulic motor integrally formed with the hydraulic pump, the hydraulic pump is a plate valve. Intake and discharge are made through, the hydraulic motor is supplied and discharged through the rotary valve, the plate valve for the hydraulic pump and the rotary valve for the hydraulic motor is composed of a composite valve, in the case of the plate valve of the conventional piston pump It can be designed to achieve positive pressure balance like plate valve, so it has low friction and On the other hand, it is easy to seal in the circumferential direction so that there is little leakage, and the pressure energy recovery device which consists of a hydraulic pump and a hydraulic motor in which the efficiency of a pressure recovery machine becomes high is integrated.

In general, the reverse osmosis filtration apparatus for generating purified water by filtering seawater or wastewater (hereinafter referred to as "sea water") includes a pumping means for pumping seawater, and some of the seawater pumped in the reverse osmosis filtration apparatus It is filtered through a predetermined filtering means and the remaining sea water is discharged as it is in a concentrated state.

The concentrated seawater discharged from the reverse osmosis filtration device maintains the pressure pumped by the high pressure pump as described above.

However, the high pressure seawater is consumed by discharging it as it is, and as a means for compensating for these disadvantages, many kinds of pressure recovery mechanisms have been developed and distributed.

Such pressure recovery mechanisms include turbo type such as pelton and francis, but these have low efficiency and cannot be used in small devices.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art,

It uses the hydraulic pump to inhale the seawater to supply the membrane of the reverse osmosis desalination device at high pressure and to recover the pressure energy of the concentrated seawater which is not discharged into the production water without throwing it into the sea to drive the hydraulic motor that is integrated with the hydraulic pump. In the energy pump and the hydraulic motor-integrated energy recovery unit which can obtain the driving power of the hydraulic pump, the hydraulic pump is sucked and discharged through the plate valve, the hydraulic motor is supplied and discharged through the rotary valve, Since the plate valve for the pump and the rotary valve for the hydraulic motor are composed of a composite valve, the plate valve can be designed to achieve a positive pressure balance like the plate valve of a conventional piston pump, so that the friction is low, and in the case of the rotary valve, Water pressure pump with easy leakage in the direction and less leakage The pressure motor has a purpose to provide a pressure energy collector configured integrally.

In order to achieve the above object, the present invention includes a housing in which a rotating shaft is installed in the axial direction to rotate the inside, and a sealing cover is detachably installed at one side to support the rotating shaft therethrough;

An inclined cam installed to be inclined at the stop of the rotating shaft, and having a plurality of hydraulic motor pistons and a plurality of hydraulic pump pistons on one end thereof to reciprocate the hydraulic motor piston and the hydraulic pump piston by rotating the cylinder barrel;

The end of the rotary shaft is inserted is provided on one side of the inclined cam, the plurality of hydraulic motor pistons and the plurality of hydraulic pump pistons are inserted into the reciprocating movement of a plurality of pressure motors and a plurality of pressure pumps pressure chambers A cylinder barrel formed;

A connection path for the hydraulic motor is provided on one side of the cylinder barrel and communicates with the pressure chambers for the plurality of hydraulic motors, and a connection flow path for the hydraulic pump for communication with the pressure chambers of the plurality of hydraulic pumps is formed, and a through hole is formed in the center. A flow path plate;

A hydraulic pump plate valve which is provided on one side of the flow path plate and is provided with a hydraulic pump through-hole so as to control the fluid flowing into / out of the hydraulic pump pressure chamber by the hydraulic pump piston;

Removably installed in the housing on the opposite side of the sealing cover, the rotary valve is formed to be inserted into the through-hole of the flow path plate through the valve valve for the hydraulic pump in the center, the connection path for the hydraulic motor and the hydraulic pump of the flow path plate The water pressure pump and the water pressure motor comprising a hydraulic pump and a hydraulic motor, characterized in that it comprises a; a water supply cover which is formed for connecting the hydraulic motor connection port and the hydraulic pump connection port respectively connected to the flow path.

As described above, the pressure energy recovery device, which is composed of the hydraulic pump and the hydraulic motor of the present invention, is integrated with a high pressure to the membrane of the reverse osmosis desalination apparatus by suctioning seawater using a hydraulic pump and not being discharged to production water. In the hydraulic pump and the hydraulic motor-integrated energy recovery unit, which can obtain the driving power of the hydraulic pump by recovering the pressure energy of the seawater without discharging it into the sea and driving the hydraulic motor integrally formed with the hydraulic pump, the hydraulic pump is a plate valve. Intake and discharge are made through, the hydraulic motor is supplied and discharged through the rotary valve, the plate valve for the hydraulic pump and the rotary valve for the hydraulic motor is composed of a composite valve, in the case of the plate valve of the conventional piston pump It can be designed to achieve static pressure balance like plate valve, so it has low friction. Is less leakage sealing is easy in the circumferential direction, and therefore the effect due to the increased pressure of the collector efficiency.

1 is a cross-sectional view showing a pressure energy recovery device according to an embodiment of the present invention,
2 is an exploded perspective view showing a cylinder barrel, a flow path plate and a plate valve for a hydraulic pump according to an embodiment of the present invention;
3 is a perspective view showing a flow path plate according to an embodiment of the present invention,
Figure 4 is a rear view showing a flow path plate according to an embodiment of the present invention,
5 is a cross-sectional view showing a flow path plate and a water passage cover according to an embodiment of the present invention;
Figure 6 is a front perspective view showing a water flow cover according to an embodiment of the present invention,
Figure 7 is a rear perspective view showing a water flow cover according to an embodiment of the present invention.

The present invention has the following features to achieve the above object.

The present invention includes a housing in which the rotating shaft is installed in the axial direction and rotates and the sealing cover is detachably installed at one side to support the rotating shaft therethrough;

An inclined cam installed at an inclined end of the rotating shaft and having a plurality of hydraulic motor pistons and a plurality of hydraulic pump pistons on one end thereof to reciprocate the hydraulic motor piston and the hydraulic pump piston by rotation;

The end of the rotary shaft is inserted is provided on one side of the inclined cam, the plurality of hydraulic motor pistons and the plurality of hydraulic pump pistons are inserted into the reciprocating movement of a plurality of pressure motors and a plurality of pressure pumps pressure chambers A cylinder barrel formed;

A connection path for the hydraulic motor is provided on one side of the cylinder barrel and communicates with the pressure chambers for the plurality of hydraulic motors, and a connection flow path for the hydraulic pump for communication with the pressure chambers of the plurality of hydraulic pumps is formed, and a through hole is formed in the center. A flow path plate;

A hydraulic pump plate valve which is provided on one side of the flow path plate and is provided with a hydraulic pump through-hole so as to control the fluid flowing into / out of the hydraulic pump pressure chamber by the hydraulic pump piston;

Removably installed in the housing on the opposite side of the sealing cover, the rotary valve is formed to be inserted into the through-hole of the flow path plate through the valve valve for the hydraulic pump in the center, the connection path for the hydraulic motor and the hydraulic pump of the flow path plate It is characterized in that it comprises a; water passing cover which is formed with a connection port for the hydraulic motor and a hydraulic pump connection port communicated with each flow path.

The present invention having such characteristics can be more clearly described by the preferred embodiments thereof.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a cross-sectional view showing a pressure energy recovery device according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing a cylinder barrel, a flow path plate and a hydraulic valve plate valve according to an embodiment of the present invention, Figure 3 4 is a perspective view illustrating a flow path plate according to an embodiment of the present invention, FIG. 4 is a rear view showing a flow path plate according to an embodiment of the present invention, and FIG. 5 illustrates a flow path plate and a water passage cover according to an embodiment of the present invention. 6 is a front perspective view showing a water flow cover according to an embodiment of the present invention, and FIG. 7 is a rear perspective view showing a water flow cover according to an embodiment of the present invention.

1 to 7, the pressure energy recoverer 100 having the hydraulic pump and the hydraulic motor of the present invention integrally includes only one cylinder barrel 30, which is formed in the cylinder barrel 30. In the pressure chambers 31 and 32, the pistons 23 and 24 reciprocate to operate so that the fluid flows in and out of the water supply cover 60 only, the housing 10, the inclined cam 20, and the cylinder barrel ( 30, a flow path plate 40, a hydraulic valve plate valve 50, and a water passage cover 60.

As shown in FIG. 1, the housing 10 has a hollow interior and is formed at both sides thereof. A sealing cover 11 is detachably installed at one side, and a water repellent cover 60 is detachably installed at the other side. do.

Here, the inside of the housing 10 is provided with a rotating shaft 12 extending in the axial direction, the rotating shaft 12 penetrates the central portion of the sealing cover 11, the end is formed to protrude to the outside, the end of the electric When the motor (not shown) is installed and rotates by the reciprocating motion of the hydraulic pump piston 23 described later, which is rotated by the driving of the electric motor, the hydraulic pump piston 23 when the electric motor is overloaded. It will play a role of auxiliary power in driving.

As shown in FIG. 1, the inclined cam 20 is installed on a thrust bearing 22 fixed to the swash plate 21 to be inclined at a predetermined angle, and the rotary shaft 12 rotates so that the piston for the hydraulic pump ( 23) the reciprocating motion, when the hydraulic motor piston 24 is pushed by the pressure of the discharged fluid, the inclined cam 20 is rotated to serve to rotate the rotating shaft (12). At this time, the hydraulic pump piston 23 and the hydraulic motor piston 24 are alternately coupled to one end surface of the inclined cam 20 in the circumferential direction.

Here, the inclined cam 20 is installed to form a constant angle with the center line of the rotary shaft 12, the greater the angle between the inclined cam 20 and the rotary shaft 12, the reciprocating movement distance of the pistons (23, 24) If the angle is too large, but the load is too large to rotate, the angle formed by the inclined cam 20 and the rotating shaft 12 is preferably formed to 6 degrees to 45 degrees.

In addition, when the inclined cam 20 is pushed toward the swash plate 21 installed in contact with the airtight cover 11, the reciprocating movement of the pistons 23 and 24 is not performed well, and thus the inclined cam 20 moves to the swash plate 21 side. It is preferable to be able to prevent the push, so that the thrust bearing 22 between the inclined cam 20 and the swash plate 21 as a means for preventing the inclined cam 20 to be rotated at the same time to support the rotation. Is installed more.

As shown in FIGS. 1 and 2, the cylinder barrel 30 is splined to the rotating shaft 12 to rotate simultaneously with the rotating shaft 12, and the above-described means for rotating the cylinder barrel 30 is described above. Pistons 23 and 24 comprising an inclined cam 20 and the constant velocity joint 25 are used. At this time, the constant velocity joint 25 is coupled to the spline formed on the rotation shaft 12, the inner ring 26 is formed with a plurality of hemispherical grooves on the outer circumferential surface, and inserted into the hemispherical groove formed in the inner ring 26 to the outside The side is configured to include a ball 27 is installed in the hemispherical groove formed in the axial direction on the central inner surface of the inclined cam 20.

Here, the cylinder barrel 30 has a hole (not shown) is formed in the center portion so that the end of the rotary shaft 12 is inserted, provided on one side of the inclined cam 20 and a plurality of hydraulic motor piston 24 and A plurality of hydraulic pump pressure chambers 32 and a plurality of hydraulic pump pressure chambers 31 are formed to penetrate one end surface so that the plurality of hydraulic pump pistons 23 are inserted and reciprocated.

The pressure chambers 31 and 32 formed in the cylinder barrel 30 configured as described above cause friction with the piston to the space where the pistons 23 and 24 reciprocate, and the inner wall is worn or the fluid is pressed out by such friction. There is concern. In order to solve this disadvantage, the inner walls of the pressure chambers 31 and 32 formed in the cylinder barrel 30 reduce friction with the pistons 23 and 24, and oil seals for preventing the leakage of fluid. C) may be further formed, and such an oil seal may be formed using a high strength metal or a synthetic resin and the like, and thus, a detailed description of the material or method is omitted since it is generally similar to the piston seal.

In addition, as shown in FIG. 2, the large diameter pressure chambers 31 are for hydraulic pumps, and the smaller diameter pressure chambers 32 are for hydraulic motors, which are centered on the center of the cylinder barrel 30. A large diameter pressure chamber 31 and a small diameter pressure chamber 32 are alternately provided on the same pitch circumference.

1 to 5, the flow path plate 40 is provided between one side surface of the cylinder barrel 30 (opposite side of the inclined cam 20) and the plate valve 50 for the hydraulic pump. A hydraulic motor connection flow path 42 is formed to communicate with the hydraulic chamber pressure chamber 32 of the cylinder barrel 30, and the hydraulic pump communicates with the pressure chamber 31 for the hydraulic pump of the cylinder barrel 30. The connection passage 41 is formed, and a through hole 43 is formed in the center portion of the flow path plate 40 so that the rotary valve 63 of the water passage cover 60 is inserted.

Here, the flow path plate 40 is connected to the cylinder barrel 30 and the connecting pipe 70 by referring to Figure 2, the connecting pipe 70 is for the pressure chamber 32 for the hydraulic motor and the hydraulic motor It is provided between the connection passage 42 and the plurality of pressure chambers 31 for the hydraulic pump and the connection passage 41 for the hydraulic pump, thereby, the flow path plate (the same as the rotation of the cylinder barrel 30) 40) is also rotated.

In addition, the flow path plate 40 is a pressure port for the hydraulic pump and the hydraulic motor of the cylinder barrel 30 and the connection port for the hydraulic pump and hydraulic motor of the water supply cover 60, 61, 62 As shown in Figures 3 and 4 to connect the hydraulic passage for the hydraulic pump 41 is formed in an arc shape on the surface facing the water flow cover 60, the cylinder barrel 30 The facing surface is formed in a circular shape, and the hole of the circularly formed portion is connected with a plurality of pressure chambers 31 for the hydraulic pump formed in the cylinder barrel 30.

In addition, the hydraulic motor connection flow path 42 of the flow path plate 40 is circular on one side, that is, one side surface of the flow path plate 40 facing the cylinder barrel 30, as shown in FIGS. A hole formed in the circularly formed portion is connected to the pressure chambers 32 for the hydraulic motors formed in the cylinder barrel 30, and the other side, that is, the water passage cover 60, is connected to the flow path plate 40. The through hole 43 of the inner peripheral surface is formed in an arc shape. At this time, the other side of the hydraulic motor connection flow path 42 formed in the through hole 43 of the flow path plate 40 is connected to the hydraulic motor connection port 62 of the water passage cover 60.

As described above, the hydraulic motor connection flow path 42 is formed in a right angle shape in the inward direction of the flow path plate on the cross section.

As shown in FIGS. 1 and 2, the plate valve 50 for the hydraulic pump is fixedly provided between the flow path plate 40 and the water passage cover 60, and the cylinder is formed by the piston 23 for the hydraulic pump. A hydraulic pump through-hole 51 is formed so as to control the flow of fluid into / out of the pressure chamber 31 for the hydraulic pump of the barrel 30.

Here, the valve for the hydraulic pump 50 means for intermittent fluid flow between the hydraulic pump connection flow path 41 of the flow path plate 40 and the hydraulic pump connection port 61 formed in the water supply cover 60. Thus, a plurality of hydraulic pump water passages 51 are connected to the pressure chamber 31 for the hydraulic pump.

And, as shown in Figure 2, the hydraulic pump through hole 51, two are formed in a pair of semi-circular arc symmetrical mutually formed, one side of the pair of hydraulic pump through hole 51 is the inlet Role and the other side acts as an outlet.

In addition, a connection hole 52 is formed in a central portion of the hydraulic valve plate 50 so that the rotary valve 63 of the hydraulic cover 60 penetrates, and the hydraulic valve plate 50 is a hydraulic cover 60. The cylinder barrel 30 and the flow path plate 40 are rotated, and friction occurs on the contact surface of the hydraulic valve plate valve 50 when the cylinder barrel 30 is rotated. In order to prevent this, a coating plate 53 similar to that formed in the pressure chambers 31 and 32 formed in the cylinder barrel 30 may be further installed between the valve valve 50 and the flow path plate 40 for the hydraulic pump. do.

1 or 5 to 7, the water flow cover 60 is detachably installed on the opposite side of the housing 10, the airtight cover 11 is installed, the central portion of the water cover 60 A rotary valve 63 is formed to penetrate the plate valve 50 for the hydraulic pump to be inserted into the through hole 43 of the flow path plate 40, and the connection path 42 for the hydraulic motor of the flow path plate 40 is formed. The connection port 62 for the hydraulic motor is formed to be connected, and is connected to the hydraulic pump connection passage 41 of the flow path plate 40 and the hydraulic pump water passage 51 of the hydraulic pump plate valve 50. The connection port 61 for the hydraulic pump is formed.

Here, the connection port 61 for the hydraulic pump, referring to Figures 6 and 7, the one end surface of the water supply cover 60 in contact with the hydraulic valve plate valve 50 of the hydraulic pump plate valve 50 It is formed in the same arc shape as the water pump 51 for the hydraulic pump, the opposite side of the water supply cover 60 is formed in the form of two circles to serve as the inlet and outlet of the fluid is connected to each one and one side of the arc shape do.

The hydraulic motor connection port 62 is formed at right angles in cross section with reference to FIGS. 5 to 7, and one side of the hydraulic motor connection port 62 penetrates through an outer circumferential surface of the rotary valve 63 to receive hydraulic pressure. In communication with the motor flow passage 42, the other side is formed in a circular shape on the opposite side of the water passage cover 60, the rotary valve 63 is formed.

At this time, one side of the hydraulic motor connection port 62 formed on the outer circumferential surface of the rotary valve 63 is formed on the outer circumferential surface of the rotary valve 63 by a predetermined interval in the circumferential direction, each of which is formed in an arc shape and flow path The inflow / exhaust of fluid can be interrupted by the rotation of the plate 40. That is, when the water flow cover 60 is rotated by the pistons 23 and 24 of the flow path plate 40 in a fixed state, the connection path 42 for the hydraulic motor is formed in the through hole 43 of the flow path plate 40. C) is intermittent with the hydraulic motor connection port 62 formed on the rotary valve 63 of the water flow cover 60 and shut off.

10 housing 11 sealing cover
12: rotating shaft 20: inclined cam
21: swash plate 22: thrust bearing
23: piston for hydraulic pump 24: piston for hydraulic motor
25: constant velocity joint 26: inner ring
27: ball 30: cylinder barrel
31 pressure chamber for hydraulic pump 32 pressure chamber for hydraulic motor
40: flow path plate 41: connection flow path for the hydraulic pump
42: connection passage for the hydraulic motor 43: through hole
50: plate valve for hydraulic pump 51: water pump for hydraulic pump
52: connecting hole 53: coated plate
60: water supply cover 61: connection port for the hydraulic pump
62: connection port for the hydraulic motor 63: rotary valve
70: connector 100: pressure energy recovery

Claims (5)

A housing 10 in which the rotating shaft 12 is installed in the axial direction to rotate and the sealing cover 11 is detachably installed at one side thereof so that the rotating shaft 12 is penetrated and supported;
It is installed to be inclined at the stop of the rotating shaft 12, a plurality of hydraulic motor piston 24 and a plurality of hydraulic pump piston 23 is provided on one end surface by rotating the hydraulic motor piston 24 and the hydraulic pump An inclined cam 20 for reciprocating the piston 23;
The end of the rotary shaft 12 is inserted is provided on one side of the inclined cam 20, the plurality of hydraulic motor piston 24 and the plurality of hydraulic pump piston 23 is inserted into a plurality of hydraulic pressure to reciprocate A cylinder barrel 30 in which a pressure chamber 32 for the motor and a plurality of pressure chambers 31 for the hydraulic pump are formed;
A connection path 42 for the hydraulic motor is formed on one side of the cylinder barrel 30 and communicates with the pressure chambers 32 for the plurality of hydraulic motors, and communicates with the pressure chambers 31 for the hydraulic pumps. A connection passage 41 for forming a hydraulic pump, the flow passage plate 40 having a through hole 43 formed at a central portion thereof;
A hydraulic pump water passage 51 is formed on one side of the flow path plate 40 so as to intermittent the fluid flowing into / out of the hydraulic pump pressure chamber 31 by the hydraulic pump piston 23. Plate valve 50 for the hydraulic pump;
It is installed detachably to the opposite housing 10 is formed with the sealing cover 11, the rotary valve to be inserted into the through-hole 43 of the flow path plate 40 through the plate valve 50 for the hydraulic pump in the central portion ( 63 is formed, a hydraulic motor connecting port 62 and a hydraulic pump connecting port 61 which are respectively connected to the hydraulic motor connecting passage 42 and the hydraulic pump connecting passage 41 of the flow path plate 40. Water cover 60 is formed;
Pressure energy recovery unit consisting of a hydraulic pump and a hydraulic motor, characterized in that configured to include a.
The method of claim 1,
The hydraulic motor connection flow passage 42 is formed at a right angle in cross section so that one side is formed at one end surface of the flow path plate 40 so as to communicate with the pressure chambers 32 for the plurality of hydraulic motors, respectively, and the other side is the flow path plate 40. Pressure energy recovery unit consisting of a hydraulic pump and a hydraulic motor integrally communicate with the inner circumferential surface of the through hole (43).
The method of claim 2,
The hydraulic motor connection port 62 of the water supply cover 60 is formed at right angles in cross section so that one side thereof is passed through the outer circumferential surface of the rotary valve 63 to communicate with the hydraulic motor connection flow passage 42, and the other side is a rotary valve ( A pressure energy collector comprising a hydraulic pump and a hydraulic motor integrally formed on an opposite side surface of the water passage cover (63) formed with the water.
The method of claim 3,
One side of the hydraulic motor connection port 62 is formed in an arc shape on the outer circumferential surface of the rotary valve 63, the pressure of the hydraulic pump and the hydraulic motor integrally formed, characterized in that the plurality is formed spaced apart from each other in the circumferential direction Energy recovery.
The method of claim 1,
The cylinder barrel 30 and the flow path plate 40 are connected between the pressure chamber 32 for the hydraulic motor and the connection passage 42 for the hydraulic motor, and the plurality of pressure chambers 31 for the hydraulic pump and the connection passage for the hydraulic pump. The connection pipe 70 is installed so as to be interconnected between the 41 and the pressure energy recovery unit consisting of a hydraulic pump and a hydraulic motor, characterized in that the flow path plate 40 is rotated in the same manner as the rotation of the cylinder barrel 30. .

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