KR20150119772A - Pulsation swash plate type piston pump having the function of preventing - Google Patents

Abstract

Disclosed is a swash plate piston pump having a pulsation preventing function. The swash plate piston pump having the pulsation preventing function according to the present invention comprises: a main body wherein a swash plate is formed on one side, a hollowed hole is formed, and a suction hole and a discharge hole corresponding to the suction and discharge of a fluid are formed; a casing combined to the rear side of the main body; a rotary axis which is combined to the main body of which one end is combined to the casing; a cylinder block which rotates by being combined to the rotary axis, is accommodated inside the main body, and forms multiple piston operating grooves in a circumferential direction; a piston which is inserted into the piston operating grooves of the cylinder block and forms a globular rotary piece on one side; a chamber which is formed inside the casing and stores a partial fluid moved to the cylinder block in a compression process of the piston; and an accumulating unit to solve overpressure by including a valve formed in the chamber to discharge the fluid in small quantities and a fluid discharge unit which is formed to be connected from the chamber to the casing′s exterior. Accordingly, the suction and discharge motions of the fluid according to a reciprocating motion of the piston are executed when pressure changes such as the steering gear of a vessel are frequent. Moreover, a pulsation phenomenon due to a hard load change can be improved by discharging and storing a partial fluid in small quantities through the accumulating unit. Therefore, durability can be improved and noise can be reduced.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a swash plate type piston pump having a pulsation prevention function,

The present invention relates to a swash plate type piston pump, and more particularly, to a swash plate type piston pump having a pulsation prevention function capable of improving durability and reducing noise due to severe load fluctuation.

In general, swash plate piston pumps are mass produced in many parts of the world and are applied to all industries in addition to vessels to which high pressure hydraulic products are applied.

The swash plate type piston pump has a structure in which it is sucked and discharged by a reciprocating motion of an odd number (pore) piston on a swash plate inclined at a predetermined angle in the pump.

As a prior art related to this, Japanese Patent Application Laid-Open No. 11-50951 discloses a swash plate type piston pump.

The rear end of the piston is guided on the front face of a swash plate inclined with respect to the rotational axis, and the piston reciprocates with the rotation of the cylinder block to suck / discharge the operating oil. An arc-shaped convex portion is formed on the back surface of the swash plate, and the convex portion is supported by a concave portion of an arcuate shape of the swash plate support.

The stroke of the piston is changed by guiding the swash plate to the support surface of the swash plate support and causing the swash plate to be inclined with respect to the rotation axis, so that the discharge amount of the operating oil can be adjusted.

At this time, when the inclined moving angle of the swash plate is increased, the stroke of the piston is increased to increase the discharge amount, while when the inclined moving angle is decreased, the stroke of the piston is reduced and the discharge amount is decreased.

However, in the prior art, a one-way pump in which suction and discharge are performed equally is predominant, and when used in a ship operating condition such as a low speed pump drive and a sudden change of direction, a severe load is applied to a pump. There is a problem in that the cost of maintenance is increased and a loss due to operation interruption occurs.

The present invention has been devised to solve the problems of the prior art described above, and it is an object of the present invention to provide a steering assist system for an electrohydraulic actuator for an EHA (Electro Hydraulic Actuator), which can improve durability by improving pulsation due to severe load fluctuation, The present invention is directed to a swash plate type piston pump having a pulsation prevention function capable of preventing a swash plate.

According to an aspect of the present invention, there is provided an ink jet recording head comprising: a main body having a swash plate formed on one side thereof and formed in a hollow shape and having a suction hole and a discharge hole corresponding to suction and discharge of fluid; A casing coupled to the rear of the main body; A rotating shaft coupled to the body and having one end coupled to the casing; A cylinder block rotatably coupled to the rotating shaft and accommodated in the main body and having a plurality of piston operating grooves in the circumferential direction; A piston inserted into the piston operating groove of the cylinder block and having a spherical rotating hole formed at one end thereof; A chamber formed in the casing for storing a part of the fluid to be moved from the cylinder block during the compression of the piston, and a fluid discharge portion formed to pass from the chamber and the valve formed in the chamber to discharge a small amount, And a pressure accumulating portion for relieving the swash plate type piston pump.

The cylinder block is inserted into an inner space of the main body and is coupled to the center through a rotation shaft. A plurality of piston operating grooves, which are cylindrical, are formed in the circumferential direction around the rotating shaft. A retainer having a low through-hole for storing and transporting the fluid is coupled, and a through hole is formed in the retainer so that the fluid passes through one side of the low-pore and is connected to the accumulation portion.

Wherein the pressure accumulating portion includes elastic means formed horizontally in the casing so as to allow the passage of the retainer to pass therethrough and inserted into the chamber, elastic means supported by the elastic means to open and close the through- And a disk for controlling the disk drive.

And a plurality of guide protrusions inserted in the through holes are arranged in the circumferential direction on the outer front surface of the disc.

The fluid discharge unit includes a first discharge channel formed at an inlet side of the chamber so as to communicate with one end thereof and inclined toward an upper portion of the casing toward the other end thereof and a second discharge channel formed at one end thereof connected to the outlet side of the chamber, And a second discharge flow path formed obliquely.

According to the present invention, when pressure fluctuations such as a ship steer frequently occur, a fluid is sucked and discharged according to a reciprocating motion of the piston, and a part of the fluid is discharged and stored in a small amount through the accumulation portion. It is possible to improve the durability and the noise reduction effect.

1 is a perspective view of a swash plate type piston pump having a pulsation prevention function according to the present invention,
2 is an exploded perspective view showing a swash plate type piston pump having a pulsation prevention function according to the present invention,
3 is a combined sectional view showing a swash plate type piston pump having a pulsation prevention function according to the present invention,
FIG. 4 is an exploded perspective view of a 'compression unit' in a swash plate type piston pump having a pulsation prevention function according to the present invention,
5 and 6 are cross-sectional views illustrating the operation of a swash plate type piston pump having a pulsation prevention function according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It does not mean anything.

In addition, the sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms defined specifically in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user, operator It should be noted that the definitions of these terms should be made on the basis of the contents throughout this specification.

1 is a perspective view showing a swash plate type piston pump having a pulsation prevention function according to the present invention, FIG. 2 is an exploded perspective view showing a swash plate type piston pump having a pulsation prevention function according to the present invention, and FIG. FIG. 4 is an exploded perspective view of a 'pressure accumulating portion' in a swash plate type piston pump having a pulsation preventing function according to the present invention, and FIGS. 5 and 6 show an exploded perspective view of a swash plate type piston pump, Sectional view showing the operation of the swash plate type piston pump having the pulsation prevention function according to the present invention for the 'accumulation portion'.

As shown in FIGS. 1 to 6, the swash plate type piston pump according to the present invention has a swash plate 130 formed at one side of the swash plate type piston pump and has a hollow structure. A body 100 formed with a hole 760 and a discharge hole; A casing 120 coupled to the rear of the main body 100; A rotation shaft 200 coupled to the main body 100 and having one end coupled to the casing 120; A cylinder block 300 coupled to the rotating shaft 200 and accommodated in the main body 100 and having a plurality of piston operating grooves 320 formed in the circumferential direction; A piston 400 inserted into the piston operating groove 320 of the cylinder block 300 and having a spherical rotating hole formed at one end thereof; A chamber 710 formed inside the casing 120 and storing a part of the fluid to be moved from the cylinder block 300 during the compression of the piston 400 and a valve 710 formed in the chamber 710 to discharge a small amount of fluid. And a fluid outlet 750 formed to pass from the chamber 710 to the outside of the casing 120 to relieve the overpressure.

The main body 100 is formed with a space therein and has a front end and a rear end which are respectively opened and formed with a protrusion 110 protruding inwardly adjacent to the front end, (130) is coupled to the inner space.

The casing 120 is coupled to the rear end of the main body 100.

A rotating shaft 200 is coupled through the main body 100 and the casing 120 and a cover 150 having a bearing 152 is mounted at the front end of the main body 100.

The swash plate 130 is a plate-shaped structure formed in an inclined shape and has a shoe plate 190 having a hole 192 in which a plurality of piston shoWs 500 are accommodated.

Accordingly, a plurality of holes 192 are formed in the shoe plate 190 in the circumferential direction, and the piston shoe 500 is coupled to the holes 192 formed in the number.

The inner diameter of the through hole 133 is formed to be slightly larger than the outer diameter of the rotary shaft 200 so that the rotary shaft 200 is rotated. So that it does not affect the swash plate 130.

The cylinder block 300 is inserted into the inner space of the main body 100 and is connected to the center of the rotating shaft 200. A plurality of cylindrical piston operating grooves 320 are arranged in the circumferential direction And a low hole 392 of a retainer 390, which will be described later, is communicated to the rear of each of the piston operating grooves 320 to perform a suction and discharge action of the fluid.

The rotary shaft 200 is coupled to the cylinder block 300 in a splined or serrated manner.

A retainer 390 is connected to the rear of the cylinder block 300 and communicates with the piston operating grooves 320 to form a low-flow hole 392 for storing and transporting the fluid.

The lower holes 392 are arc-shaped and symmetrically symmetrical with respect to the center with respect to the center. The lower holes 392 communicate with the openings of the plurality of piston operating grooves 320 arranged in the circumferential direction, And then can be transported by suction and discharge operations.

2 to 4, a conveying passage 340 communicating with the piston operating groove 320 is formed at the rear of the cylinder block 300 and an arcuate opening 720 communicating with the conveying passage 340 is formed. A suction pipe passage 740 or a discharge pipe passage (not shown) formed inside the casing 120 and communicating with the arcuate opening 720 is formed inside the casing 120, A suction hole 760 communicating with the discharge port 740 and a discharge hole (not shown) communicating with the discharge pipe are formed.

A through hole 394 is formed in the retainer 390 to allow the fluid to pass through one side of the low-pore hole 392 and to be connected to the accumulation portion 700.

The through hole 394 is formed between the two low-porosities 392. Since the retainer 390 is separate and fixed from the cylinder block 300, when the cylinder block 300 rotates and sucks and discharges are performed Most of the fluid is moved through the low holes 392, but a small amount of fluid is also moved through the holes 394.

Here, the fluid to be delivered through the through hole 394 is mainly a discharged fluid, and the diameter of the through hole 394 is significantly smaller than that of the low hole 392, so that the discharged fluid is small.

The pressure accumulating portion 700 includes a chamber 710 formed horizontally in the casing 120 and communicating with the through hole 394 of the retainer 390, 730).

The valve 730 includes an elastic means 732 inserted into the chamber 710 and a disk 732 which is elastically supported by the elastic means 732 and controls the opening and closing of the through hole 394 of the retainer 390 734).

The disk 734 has a cylindrical shape with one side opened and a space formed inside and the other end closed, and the clogged outer front surface serves to close the through hole 394 of the retainer 390, A plurality of guide protrusions 736 inserted in the through holes 394 are arranged in the circumferential direction.

The guide protrusion 736 is formed so as to have a diameter corresponding to the inner diameter of the through hole 394 so that when the front surface of the disc 734 is in close contact with the retainer 390 to close the through hole 394, The guide protrusions 736 can be engaged with each other to stably maintain the engagement state, thereby improving the sealing performance.

The elastic means 732 is preferably a coil spring.

On the other hand, a fluid discharge portion 750 is formed so as to communicate from the chamber 710 to the outside of the casing 120 to guide the fluid to be sucked and discharged by operating the valve 730.

The fluid discharge part 750 is formed to discharge the fluid of the accumulation part 700 and is formed so as to communicate with one end at the inlet side of the chamber 710 and to be inclined toward the upper part of the casing 120 toward the other end And a second discharge passage 752 formed at one end of the chamber 710 and connected to the outlet of the chamber 710 and inclined downward toward the other end of the chamber 710.

The piston 400 is formed of a cylindrical tube and has an opening formed at one end thereof, a hollow portion 410 formed therein to communicate with the opening portion, and a spherical rotation hole 420 formed at the other end thereof. And a piston hole (192) communicating with the hollow portion (410) and passing through the rotation hole (420).

And a piston shoe 500 having one side supported by the swash plate 130 and the other side having a fitting groove 520 for engaging with a rotation hole 420 of the piston 400.

The piston shoe 500 is formed with an opening at one end thereof and has a spherical fitting groove communicating with the opening. The piston shoe 500 is in contact with the swash plate 130 at its front surface, and the fluid transfer hole 550 is formed do.

Therefore, since the rotary shaft 420 of the piston 400 is coupled to the fitting groove of the piston shoe 500 and the rotary shaft 420 is spherical, the piston shoe 500 is driven to rotate and rotate along the swash plate 130 The angle of inclination varies from time to time. However, due to the spherical coupling structure of the rotation hole 420, the piston shoe 500 can be rotationally driven and interlocked with the piston shoe 500 to reciprocate motion of the piston 400.

Hereinafter, the operation of the present invention will be described.

When the rotation shaft 200 receives the power of an external actuator (not shown), the cylinder block 300 coupled to the rotation shaft 200 is rotated.

The piston 400 and the piston shoe 500 coupled to the piston 400 are rotated together with the rotation of the cylinder block 300.

The plurality of piston shoes 500 are rotated in the circumferential direction along the inclination of the swash plate 130 while being restrained by the shoe plate 190.

Since the coupling hole 192 is coupled to the center of the shoe plate 190 and the coupling hole 192 is coupled to the rotary shaft 200, the rotary shaft 200 and the shoe plate 190 are rotated together .

The rotation of the cylinder block 300 causes the piston shoe 500 to rotate on the swash plate 130 to reciprocate the piston 400 to perform the suction and discharge strokes.

That is, when the piston 400 passes the highest section of the swash plate 130, the piston 400 is inserted deeply into the piston operating groove 320, so that the discharging operation is performed.

The fluid discharged into the piston operating groove 320 is discharged through the low hole 392 and the through hole 394 of the retainer 390.

80-90% of the fluid to be discharged is usually discharged through the low-pores 392, and the remaining small amount of fluid is discharged through the holes 394.

As the fluid is introduced into the chamber 710 through the through hole 394, the disc 734 is moved backward into the chamber 710 and the coil spring as the resilient means 732 is contracted.

When the chamber 710 is filled with a fluid having a predetermined pressure or more, it is discharged to the outside through the first discharge passage 751.

In addition, the fluid filled in the disk 734 flows out to the outside through the second discharge passage 752.

Accordingly, since the first discharge passage 751, the through hole 394, and the piston operating groove 320 are communicated with each other by the compression of the accumulation portion 700, a part of the hydraulic pressure can be relieved, The phenomenon can be solved.

When the piston 400 passes the lowest section of the swash plate 130, the suction operation is performed by being inserted shallowly from the piston operating groove 320.

The pressing force against the disk 734 is released so that the disk 734 is advanced by the expansion and restoration of the elastic means 732 so that the front surface of the disk 734 blocks the through hole 394 of the retainer 390, The first discharge passage 751 is closed.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, It is obvious that the claims fall within the scope of the claims.

100: main body 110:
120: casing 130: swash plate
200: rotating shaft 300: cylinder block
320: piston operating groove 340:
400: piston 420:
500: Piston shoe 520: Fitting groove
540: Body 550: Fluid feed hole
560; Plate 700:
710: chamber 730: valve
750: fluid discharge portion 732: elastic means
734: Disk

Claims (5)

A main body having a swash plate formed at one side thereof and hollow and having a suction hole and a discharge hole corresponding to suction and discharge of the fluid;
A casing coupled to the rear of the main body;
A rotating shaft coupled to the body and having one end coupled to the casing;
A cylinder block rotatably coupled to the rotating shaft and accommodated in the main body and having a plurality of piston operating grooves in the circumferential direction;
And a piston inserted into the piston operating groove of the cylinder block and having a spherical rotating hole formed at one end thereof,
A chamber formed in the casing for storing a part of the fluid which is moved from the cylinder block during the compression of the piston, and a fluid discharge portion formed to pass from the chamber and the valve formed in the chamber to discharge a small amount, An accumulating portion for relieving the load;
Wherein the swash plate type piston pump has a pulsation prevention function. The method according to claim 1,
The cylinder block
A plurality of piston operating grooves, which are cylindrically shaped, are arranged in a circumferential direction around a rotating shaft, the piston operating grooves being inserted into an inner space of the main body,
And a retainer, which is communicated with each of the piston operating grooves and formed with a low through hole for storing and conveying the fluid,
Wherein the retainer is formed with a passage through which fluid is passed and which is connected to an accumulation portion of the low-pore. 3. The method of claim 2,
The above-
Wherein the chamber is formed horizontally in the casing and is formed to pass through the through hole of the retainer,
An elastic means inserted into the chamber; and a disk elastically supported by the elastic means, the disk controlling the opening and closing of the through hole of the retainer. The method according to claim 1,
Wherein a plurality of guide protrusions inserted in the through holes are arranged in the circumferential direction on the outer front surface of the disc. The method according to claim 1,
The fluid outlet
A first discharge flow path formed at an inlet side of the chamber so as to communicate with one end thereof and inclined toward an upper portion of the casing toward the other end,
A second discharge port formed at one end of the chamber and connected to the outlet of the chamber,
Wherein the swash plate type piston pump has a pulsation prevention function.

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