KR102491274B1 - Hydraulic Controller of Viscosity Variable Type - Google Patents

Abstract

The present invention relates to a variable-viscosity hydraulic pressure controller capable of adjusting the pressure of a piston according to the viscosity of a fluid, and specifically, a piston reciprocating by supplying fluid and formed on the front of the piston, and a chisel and piston moving by blow and a case accommodating the chisel therein.

Description

Viscosity variable hydraulic controller {Hydraulic Controller of Viscosity Variable Type}

The present invention relates to a variable viscosity hydraulic pressure controller capable of adjusting the pressure of a piston according to the viscosity of a fluid.

In Patent Document 001, in a hydraulic breaker capable of adjusting the number of hits and impact energy, a piston reciprocates up and down inside the cylinder body by hydraulic oil supplied from a hydraulic pump, and a chisel receiving impact force from the piston reciprocates up and down inside the front head. As configured to hit the crushing target while exercising; In the cylinder body, hydraulic oil is supplied to the inside through the inlet-side 3-way valve connected to the hydraulic pump, and hydraulic oil is discharged to the outside through the outlet-side 3-way valve, so that the piston reciprocates up and down, and the inlet-side 3-way valve The valve includes a source port connected to the hydraulic pump; a first outport that is connected to the source port and allows hydraulic oil to be supplied to the inside of the cylinder body to press upward a first piston ring provided on a lower part of the outer surface of the piston to raise the piston; A technology including a second outport connected to the first outport and lowering the piston by pressing downward the second piston ring provided on the outer surface of the piston by allowing hydraulic oil to be supplied into the cylinder body. are presenting

Patent Document 002 is a hydraulic cylinder that is formed so that the piston reciprocates back and forth and forms an appearance; a body portion coupled to the front end of the hydraulic cylinder; A crushing unit coupled with a key to the inside of the body unit, supported by the first bush and the second bush, and crushing the material to be crushed with a chisel: a striking chamber that is an empty space for hitting the chisel of the crushing unit with the piston of the hydraulic cylinder. wealth; and a fluid control unit disposed on one side of a surface of the hydraulic cylinder and formed to control the supply of fluid required for operation of the piston, wherein the fluid control unit is closely coupled to one side of the surface of the hydraulic cylinder and is attached to a coupling surface in close contact with the hydraulic cylinder. a valve housing provided with a guide groove having a predetermined depth in a vertical direction from an inlet formed to be connected to a flow path of the hydraulic cylinder; and a valve coupled to the guide groove of the valve housing and provided to move vertically along the longitudinal direction of the guide groove to control the supply of fluid.

In Patent Document 003, a hydraulic breaker is provided in the case to accommodate a case having an inlet and an outlet and a piston for hitting the chisel so as to be movable up and down, and a first chamber accommodating the pressure receiving surface at the bottom of the piston and the pressure receiving surface at the top of the piston. The first chamber is always in communication with the inlet, the second chamber is selectively communicated with the inlet and the outlet by a control valve, the first chamber is in communication with the inlet, and the second chamber is in communication with the inlet. a cylinder configured such that the piston moves upward when communicating with the outlet and the piston moves downward when both the first chamber and the second chamber communicate with the inlet; and a control valve having a valve housing installed in the case and a valve body installed to be liftable with respect to the valve housing and configured to selectively communicate or block the second chamber to the inlet and outlet depending on its position. technology is presented.

Patent Document 004 is fastened by long bolts to a case of a breaker inserted so that a piston can reciprocate inwardly, a gas chamber is formed inside, and a nozzle installation hole for filling gas into the gas chamber is formed on one side In the backhead of a hydraulic breaker, the backhead is formed with a main chamber that takes a cylindrical shape along a central axis to the inside, forms a hexahedron to the outside, and penetrates in a straight line from one end to the other end to A body portion in which a long bolt fastening hole through which a bolt is fastened is formed and integrally formed with the body portion, and an auxiliary chamber communicating with the main chamber to the inside and having a smaller size than the inner diameter of the main chamber is formed, and to the outside It has a cylindrical shape, but the periphery of the outer circumferential surface in contact with the body portion is proposed as a protrusion that is spaced apart from the long bolt fastening hole.

KR 10-1693439 B1 (December 30, 2016) KR 10-2012-0050215 A (May 18, 2012) KR 10-0901145 B1 (May 29, 2009) KR 10-1402309 B1 (May 26, 2014)

The present invention relates to a variable viscosity hydraulic pressure controller capable of adjusting the pressure of a piston according to the viscosity of a fluid.

In order to solve the problems of the prior invention, the present invention is a piston 100 that reciprocates by supplying fluid; A chisel 200 formed on the front surface of the piston 100 and moved by hitting; A case 300 accommodating the piston 100 and the chisel 200 therein;

The present invention is an invention for a variable viscosity hydraulic controller, and is formed on the outside of the case 300 in the invention consisting of the piston 100 presented above;, the chisel 200;, the case 300, and the hydraulic pump A hydraulic valve 400 for controlling the fluid by the; is added.

The present invention is an invention for a variable viscosity hydraulic controller, and is formed in the case 300 in the invention consisting of the piston 100 presented above;, the chisel 200;, the case 300, and the piston 100 A gas compression chamber 500 that transmits a compressed repulsive force to the; A gas control device 600 connected to the gas compression chamber 500 and adjusting the filling amount of gas; is added.

The present invention is an invention for a variable viscosity hydraulic controller, and is formed in the gas control device 600 in the invention consisting of the piston 100; chisel 200; and case 300 presented above, and gas is supplied. A gas supply unit 700 to be added;

The present invention is an invention for a variable viscosity hydraulic controller, and is formed in the gas control device 600 in the invention consisting of the piston 100 presented above;, the chisel 200;, the case 300, and the viscosity of the fluid A pressure regulator 800 for adjusting the pressure of the gas according to; is added.

The present invention is to be able to control the pressure by the viscosity of the fluid that varies depending on the temperature.

According to the present invention, the impact of the piston can be alleviated according to the viscosity of the fluid.

The present invention can guide the reciprocating movement by applying pressure to the piston.

According to the present invention, the movement distance of the pressure cylinder can be adjusted according to the viscosity of the fluid.

The present invention is to apply pressure to the piston at regular intervals as the control panel of various sizes hits the pressure cylinder.

1 is a cross-sectional view of a variable viscosity hydraulic pressure controller of the present invention.
Figure 2 is a graph showing the viscosity of the fluid of the present invention.
3 to 4 are cross-sectional views showing a hydraulic breaker equipped with a variable viscosity hydraulic pressure controller of the present invention.
Figure 5 is a cross-sectional view showing the gas control device of the present invention.
6 to 7 are exemplary views showing reciprocating movement of a piston by the gas control device of the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described in detail in order to explain the present invention in detail to the extent that those skilled in the art can easily practice the present invention.

Numbers cited in the examples below are not limited to the referenced subject and can be applied to all examples. An object that exhibits the same purpose and effect as the configuration presented in the embodiment corresponds to an equivalent replacement object. The high-level concept presented in the examples includes sub-concept objects that are not described.

(Embodiment 1-1) In the present invention, in the variable viscosity hydraulic pressure controller, a piston 100 that reciprocates by supplying fluid; a chisel 200 formed on the front surface of the piston 100 and moved by hitting ); and a case 300 accommodating the piston 100 and the chisel 200 therein.

(Embodiment 1-2) In Embodiment 1-1, the viscosity variable hydraulic pressure controller of the present invention is formed in the case 300 and includes a body portion 310 in which the chisel 200 is formed; It is formed on the rear surface of the body part 310, and the moving part 320 in which the piston 100 is formed; includes.

(Embodiment 1-3) In Embodiment 1-2, the viscosity variable hydraulic pressure controller of the present invention is formed on the front surface of the body portion 310 and prevents movement of the chisel 200. The front cover 311 ; A plurality of bushings 312 formed to be spaced apart from the front cover 311 and preventing abrasion of the chisel 200; includes.

(Embodiment 1-4) In Embodiment 1-1, the variable viscosity hydraulic pressure controller of the present invention is formed on the body part 310 and hits the chisel 200 as the piston 100 reciprocates. It includes; a hitting chamber 313 to do.

(Embodiment 1-5) In Embodiment 1-1, the variable viscosity hydraulic pressure controller of the present invention includes a hydraulic control chamber 321 formed in the moving part 320 and moving the piston 100. .

(Embodiment 1-6) In Embodiment 1-1, the variable viscosity hydraulic pressure controller of the present invention is formed on the outside of the piston 100 and is inserted into the hydraulic control chamber 321 to move by fluid. (322);

The present invention relates to a variable viscosity hydraulic pressure controller. Specifically, it relates to a hydraulic breaker in which the piston 100 reciprocates according to the pressure supplied with the fluid to crush concrete used in a building. In this hydraulic breaker, a case 300 is formed, and the piston 100 accommodated inside the case 300 reciprocates by hydraulic pressure to crush the material to be shredded as it strikes the chisel 200. At this time, the case 300 in which the piston 100 and the chisel 200 are accommodated is formed with a body portion 310 and a moving portion 320, and the body portion 310 is a front for preventing movement of the chisel 200. A cover 311 is formed. The front cover 311 prevents movement of the chisel 200 that strikes and crushes the material to be shredded, and is detachably formed on the front surface of the case 300. In addition, a bushing 312 is formed at a position spaced apart from the front cover 311 to prevent abrasion of the chisel 200 reciprocating by being hit by the piston 100. This bushing 312 is formed inside the case 300 . And, as the piston 100 reciprocates in the body part 310, a striking chamber 313 in which the chisel 200 strikes is formed, and the striking chamber 313 is formed with a step so that the piston 100 comes into contact with the moving distance. is adjusted to hit the chisel 200 with a constant pressure. In addition, the moving part 320 is formed to be spaced apart from the body part 310, and a hydraulic control chamber 321 for moving the piston 100 is formed. The hydraulic control room 321 accommodates the empty rudder housing 322 formed outside the piston 100, and when pressure is applied to the empty rudder housing 322 by the fluid, as the empty rudder housing 322 moves, the piston 100 ) is reciprocated. At this time, as the fluid supplied to the hydraulic control chamber 321 is supplied in both directions, the piston 100 is reciprocally moved in both directions. As such, the reciprocating piston 100 is moved by the pressure of the fluid and guides the reciprocating movement of the piston 100 according to the viscosity of the fluid. At this time, the fluid has various viscosities depending on the temperature change, and since the pressure applied to the piston 100 changes according to the viscosity of the fluid, the force for crushing the object to be crushed is reduced. Accordingly, when the viscosity is lowered, the crushing force is reduced, so the pressure acting on the piston 100 is increased to crush the material to be crushed regardless of the viscosity.

Therefore, the viscosity variable hydraulic pressure controller of the present invention has a feature of adjusting the pressure acting on the piston 100 according to the viscosity of the fluid supplied to crush the material to be crushed.

(Embodiment 2-1) The present invention relates to a variable viscosity hydraulic controller, and in Embodiment 1-1, a hydraulic valve 400 formed outside the case 300 and controlling fluid by a hydraulic pump includes;

(Example 2-2) In the variable viscosity hydraulic pressure controller of the present invention, in Example 2-1, the hydraulic valve 400 includes an inlet valve 410 for controlling the inflow of fluid; and an outlet valve 420 formed to be spaced apart from the inlet valve 410 and controlling the discharge of the fluid.

(Example 2-3) In Example 2-2, the variable viscosity hydraulic pressure controller of the present invention includes a control valve 430 formed on the hydraulic valve 400 and regulating fluid pressure.

(Example 2-4) In Example 2-1, the variable viscosity hydraulic pressure controller of the present invention includes an accumulator 440 formed outside the case 300 and accumulating and supplying the pressure of the fluid. do.

(Example 2-5) In Example 2-1, the variable viscosity hydraulic controller of the present invention includes a viscosity measurement sensor formed on the hydraulic valve 400 and measuring the viscosity of the fluid.

(Example 2-6) In Example 2-5, the variable viscosity hydraulic pressure controller of the present invention includes a temperature sensor formed on the hydraulic valve 400 and measuring the temperature of the outside and the fluid.

The present invention relates to the hydraulic valve 400, and specifically, the hydraulic valve 400 is formed on the outside of the case 300 to supply fluid. The hydraulic valve 400 supplies and discharges fluid by a hydraulic pump and reciprocates the piston 100 by the fluid. At this time, the case 300 has an inlet and an outlet, and the inlet and outlet are formed by the hydraulic valve 400 penetrating the case 300 . In the hydraulic valve 400, an inlet valve 410 for controlling the inflow of fluid is formed, and an outlet valve 420 for controlling the discharge of the fluid formed at a distance from the inlet valve 410 is formed. The inlet valve 410 controls the amount of fluid introduced by the hydraulic pump, and variously adjusts the hydraulic pressure according to the viscosity of the fluid. And the outlet valve 420 controls the reciprocating movement of the piston 100 by adjusting the pressure of the fluid flowing out through the outlet. And the hydraulic valve 400 controls the pressure of the fluid flowing in and out through the inlet valve 410 and the outlet valve 420 as the control valve 430 for adjusting the fluid pressure is formed. In addition, an accumulator 440 is formed in the hydraulic valve 400 to temporarily store hydraulic oil and use it as a kinetic energy source. And the hydraulic valve 400 is formed by a separate main body outside the case 300, and a viscosity measurement sensor for measuring the viscosity of the fluid is formed in the main body. The viscosity measuring sensor measures the viscosity of the fluid according to the temperature and measures the viscosity by the temperature measured by the temperature measuring sensor. As the viscosity of the fluid is affected by the temperature, the pressure of the piston 100 can be lowered, so the viscosity and temperature of the fluid are measured and the pressure of the fluid supplied to the piston 100 is adjusted.

(Embodiment 3-1) The present invention relates to a variable-viscosity hydraulic pressure controller, and in Embodiment 2-1, a gas compression chamber formed in the case 300 and transmitting a compressed repulsive force to the piston 100 (500); It is connected to the gas compression chamber 500 and includes a gas control device 600 for adjusting the filling amount of gas.

(Example 3-2) In Example 3-1, the variable viscosity hydraulic pressure controller of the present invention includes a buffer pad 510 formed in the gas compression chamber 500 and mitigating the impact of the piston 100; includes

(Example 3-3) In the variable viscosity hydraulic pressure controller of the present invention, in Example 3-2, the gas compression chamber 500 includes a compression cover 520 detachably formed on the rear surface of the case 300; includes

(Example 3-4) In the variable viscosity hydraulic pressure controller of the present invention, in Example 3-2, the gas compression chamber 500 is formed on the rear side of the case 300, and the front side of the compression cover 520 It includes; a buffer space 530 formed open to.

(Example 3-5) In Example 3-4, the viscosity variable hydraulic pressure controller of the present invention is formed in the buffer space 530 and measures the internal pressure of the gas compression chamber 500. 540);

(Embodiment 3-6) In Embodiment 3-1, the variable viscosity hydraulic pressure controller of the present invention includes that the gas control device 600 is formed integrally with and separated from the compression cover 520.

The present invention relates to a gas compression chamber 500, and specifically, is to improve the impact energy of the piston 100 formed on the rear surface of the case 300 to reciprocate. The case 300 has a gas compression chamber 500 filled with nitrogen gas on the rear side, and one end of the piston 100 is accommodated in the gas compression chamber 500 . At this time, a buffer pad 510 is formed in the gas compression chamber 500 to act as a buffer so that the rear surface of the case 300 is not hit when the piston 100 reciprocates. In addition, the gas compression chamber 500 has a compression cover 520 on the rear side, which is detachably formed and fastened by long bolts, and nitrogen gas is supplied to the gas compression chamber 500 by the gas control device 600. In addition, the gas compression chamber 500 has a buffer space 530 filled with nitrogen gas, and a pressure measuring device 540 is formed in the buffer space 530. The pressure of the gas compression chamber 500 is formed higher than the outside, so when the piston 100 moves to the rear after striking the chisel 200, the pressure of the buffer space 530 acts as a buffer and at the same time the piston 100 As a result, the pressure of the gas compression chamber 500 is increased to generate a repulsive force to the piston 100. Accordingly, the piston 100 moves forward to increase the strength of hitting the chisel 200 . And the gas control device 600 controls the gas pressure in the gas compression chamber 500 according to the viscosity of the fluid that guides the reciprocating movement of the piston 100 . At this time, the gas control device 600 is formed integrally with the compression cover 520 or is formed separately from the outside to adjust the pressure of the gas compression chamber 500 according to the viscosity of the fluid.

Therefore, the gas compression chamber 500 is formed on the rear side of the case 300, and when the piston 100 moves to the rear side after striking the chisel 200, the piston 100 is pushed by the pressure formed by filling the gas with a repulsive force. It has a feature of striking the chisel 200 again by moving to.

(Embodiment 4-1) The present invention relates to a variable viscosity hydraulic pressure controller, and in Embodiment 3-1, it is formed in the gas control device 600 and includes a gas supply unit 700 to which gas is supplied. .

(Example 4-2) In Example 4-1, the viscosity variable hydraulic pressure controller of the present invention includes a connection part 710 formed in the gas supply part 700 and connected to the gas compression chamber 500; A supply unit 720 for supplying gas through the connection unit 710; includes.

(Example 4-3) In Example 4-1, the variable viscosity hydraulic pressure controller of the present invention includes a supply box 721 formed in the supply unit 720 and connected to the connection unit 710; A pressure cylinder 723 formed inside the supply box 721 and repetitively moving in both directions.

(Example 4-4) In Example 4-1, the variable viscosity hydraulic pressure controller of the present invention includes a gas filling device 722 formed in the supply box 721 and filling gas.

(Example 4-5) In Example 4-1, the variable viscosity hydraulic pressure controller of the present invention, the pressure cylinder 723 has a moving interval adjusted according to the pressure of the gas compression chamber 500; including do.

The present invention relates to the gas supply unit 700, and specifically, the gas supply unit 700 supplies nitrogen gas to the gas compression chamber 500. The gas supply unit 700 is formed with a connection unit 710 connected to the gas compression chamber 500, and the connection unit 710 is formed of a pipe. At this time, the connection unit 710 is connected to the supply unit 720 and the gas supplied from the supply unit 720 is transferred to the gas compression chamber 500 . In addition, the supply unit 720 controls the pressure of the gas compression chamber 500 as the supply box 721 is formed and the pressure cylinder 723 inside the supply box 721 repeatedly moves up and down and left and right. In detail about this, when the gas supply unit 700 moves before the piston 100 comes into contact with the rear surface, the pressure cylinder 723 moves into the supply box 721 to increase the pressure in the gas compression chamber 500. And when the piston 100 hits the chisel 200, the pressure in the gas compression chamber 500 is lowered to smoothly move the piston 100 to the rear. As the pressure cylinder 723 repeatedly moves inside the supply box 721 as described above, gas is supplied and discharged to and from the gas compression chamber 500 to adjust the pressure. In addition, the distance between the pressure cylinders 723 moving into the supply box 721 is adjusted according to the pressure of the gas compression chamber 500, which controls the amount of gas supplied to the gas compression chamber 500 according to the viscosity of the fluid. It is to guide the forward and backward reciprocating movement of the piston 100 by adjusting. In addition, a gas filling device 722 is formed in the supply box 721 to fill gas lost when gas is supplied and discharged, and the gas filling device 722 generates nitrogen gas equal to the amount of gas lost. charge

Therefore, the gas supply unit 700 controls the amount of gas supplied to the gas compression chamber 500, and has a feature of controlling the supply and discharge of gas according to the moving direction of the piston 100.

(Embodiment 5-1) The present invention relates to a variable viscosity hydraulic pressure controller, and in Embodiment 4-1, it is formed in the gas control device 600 and controls the pressure of gas according to the viscosity of the fluid. part 800; includes.

(Example 5-2) In Example 5-1, the variable viscosity hydraulic pressure controller of the present invention includes a rotation shaft 810 formed in the pressure controller 800 and rotated by a motor 830; A plurality of control panels 820 connected to the rotary shaft 810 and controlling the pressure cylinder 723;

(Example 5-3) In Example 5-2, the variable viscosity hydraulic pressure controller of the present invention includes a variable cylinder 811 formed on the rotation shaft 810 and varying the rotation shaft 810.

(Example 5-4) In Example 5-2, the variable viscosity hydraulic pressure controller of the present invention includes the control panel 820 having one surface protruding and being formed in plural.

(Example 5-5) In Example 5-2, the variable viscosity hydraulic pressure controller of the present invention includes a plurality of control panels 820 spaced apart from each other at equal intervals.

The present invention relates to the pressure adjusting unit 800, and specifically, the pressure adjusting unit 800 constantly supplies gas to the gas compression chamber 500 by hitting the pressure cylinder 723 of the gas supply unit 700. . The pressure control unit 800 constantly strikes the pressure cylinder 723 formed in the supply unit 720 of the gas supply unit 700 to constantly supply and discharge gas into the gas compression chamber 500 . The pressure regulator 800 has a rotation shaft 810 that rotates by a motor 830, and a plurality of control panels 820 are formed at regular intervals on the rotation shaft 810. Further, the rotational speed of the rotating shaft 810 is adjusted according to the reciprocating speed of the piston 100, and the position is changed by the variable cylinder 811. The variable cylinder 811 controls the length of the rotating shaft 810 in order to adjust the position of the control panels 820 spaced apart from each other at equal intervals, and the control panels 820 of different sizes are respectively pressured by the variable cylinder 811. It is in contact with the cylinder 723. The control panel 820 maintains a circular shape, but is formed in the shape of a cam with one surface protruding to contact the pressure cylinder 723. Thus, as the control panel 820 rotates by the rotating shaft 810, the pressure cylinder 723 is hit at regular intervals to move the pressure cylinder 723 into the supply box 721 so as to reduce pressure in the gas compression chamber 500. is to regulate

Therefore, the pressure adjusting unit 800 of the present invention is formed at one end of the gas supply unit 700 and has a feature of adjusting the pressure in the gas compression chamber 500 by varying the pressure cylinder 723 as it rotates.

100: piston 200: chisel
300: case 310: body
311: front cover 312: bushing
313: hitting room 320: moving unit
321: hydraulic control room 322: empty housing
400: hydraulic valve 410: inlet valve
420: outlet valve 430: control valve
440: accumulator 500: gas compression chamber
510: buffer pad 520: compression cover
530: buffer space 540: pressure measuring device
600: gas control device 700: gas supply unit
710: connection part 720: supply part
721: supply box 722: gas filling device
723: pressure cylinder 800: pressure control unit
810: rotation shaft 811: variable cylinder
820: control panel 830: motor

Claims (5)

A piston 100 reciprocating by supplying fluid;
A chisel 200 formed on the front surface of the piston 100 and moved by hitting;
A case 300 accommodating the piston 100 and the chisel 200 therein; includes,
A hydraulic valve 400 formed outside the case 300 and controlling fluid by means of a hydraulic pump;
a gas compression chamber 500 formed in the case 300 and transmitting a compressed repulsive force to the piston 100;
A gas control device 600 connected to the gas compression chamber 500 and adjusting the filling amount of gas;
a gas supply unit 700 formed in the gas control device 600 and supplied with gas;
It is formed in the gas control device 600, and a pressure control unit 800 for adjusting the pressure of the gas according to the viscosity of the fluid; includes,
a body portion 310 formed in the case 300 and having the chisel 200 formed therein;
A moving part 320 formed on the rear surface of the body part 310 and having the piston 100 formed therein;
It is formed in the body part 310, and as the piston 100 reciprocates, the striking chamber 313 hitting the chisel 200; includes,
A hydraulic control chamber 321 formed in the moving unit 320 and moving the piston 100; includes,
A hollow housing 322 formed outside the piston 100 and inserted into the hydraulic control chamber 321 to move by fluid; includes,
a viscosity measuring sensor formed in the hydraulic valve 400 and measuring the viscosity of the fluid; And a temperature sensor for measuring the temperature of the fluid;
In the gas compression chamber 500,
a buffer pad 510 for alleviating the impact of the piston 100;
A compression cover 520 formed to be detachable from the rear surface of the case 300;
A buffer space 530 formed on the rear surface of the case 300 and opened on the front surface of the compression cover 520; includes,
A rotary shaft 810 formed in the pressure regulator 800 and rotated by a motor 830;
A plurality of control panels 820 connected to the rotational shaft 810, controlling the pressure cylinder 723 and having one surface protruding and spaced apart from each other at equal intervals; includes,
A variable viscosity hydraulic controller including a variable cylinder 811 formed on the rotational shaft 810 and varying the rotational shaft 810.
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