KR20160134897A - Hydraulic directional control block - Google Patents

Abstract

[0001] The present invention relates to a hydraulic direction switching block, and more particularly, to a hydraulic direction switching block, in which a plurality of pipelines through which fluids can flow can be formed in the main body, A main body and a main body including a hydraulic line, which is a line through which the fluid introduced from the oil reservoir flows into the main body, and a hydraulic line through which the fluid flowing into the main body flows to the oil reservoir A first transfer line which is a line through which the fluid in the discharge line and the main body is transferred to the hydraulic apparatus and a second transfer line which is a line through which the fluid in the main body is transferred from the hydraulic apparatus to the main body, A first extension conveyance line for connecting the third conveyance line, which is a duct, Chapter is formed of a transfer line, it is formed by further including an additional line to adjust the flow rate of the product.
It is possible to adjust the hydraulic pressure and flow rate through the valve which is able to move the fluid through the channel formed inside the hydraulic direction switching block and stacked on the upper part of the flow path plate, The mounting space can be reduced, and the assembly work can be performed easily and quickly.
In addition, the present invention provides a hydraulic direction switching block having a simple effect of maintenance and inspection because it generates less trouble due to piping such as leakage, vibration and noise, and is installed in a laminated form.

Description

[0001] Hydraulic directional control block [0002]

[0001] The present invention relates to a hydraulic direction switching block, and more particularly, to a hydraulic direction switching block, in which a plurality of pipelines through which fluids can flow can be formed in the main body, And more particularly,

In general, a modular valve is a valve that is a self-tapping valve that can be assembled into a hydraulic circuit by laminating valves and using only bolts without using a pipe that meets the diversity and rationality required by the hydraulic apparatus.

In the lower part of the valve, a plurality of valves are stacked on the plate upper end of the plate to form a circuit. The plate is used as a blocking plate used for closing a preliminary mounting surface or an unnecessary circuit, A bypass plate used for the circuit of the flow, a connecting plate used for pressure detection of each line, and the like are used.

No. 10-1236468 (Pressure type directional control valve) relates to a directional switching valve that provides a pressure type and a modular directional control valve, and relates to a control device for controlling a pressure in a channel generated by a pressure fluid supplied by a pressure fluid A switching valve unit having a switching piston having a groove formed therein to discharge the pressure fluid into the first switching channel or the second switching channel in accordance with the operation of the control valve unit, And a main valve having a main piston formed with a groove for flowing a pressure fluid, which is operated by the pressure fluid introduced into the second switching flow path and supplied to the pressure fluid inlet, to one of the first discharge port and the second discharge port, Wherein one of the first discharge port and the second discharge port discharges the pressure fluid and the other discharges the pressure fluid, Unlike a manual directional valve or a solenoid-driven directional valve, it is configured to discharge fluid to a discharge port. A pressure-type directional valve " .

SUMMARY OF THE INVENTION The present invention is directed to a hydraulic control apparatus and a control method thereof, in which fluid can be moved through a pipeline formed in a hydraulic direction switching block and a hydraulic valve and a flow rate can be controlled through a valve stacked on the top of a flow path plate, The structure is simple, and the purpose of the circuit addition and modification is easy.

Further, it is an object of the present invention that the mounting space can be reduced and the assembling work can be performed easily and quickly.

Further, troubles caused by piping such as leakage, vibration and noise are generated little and are installed in a laminated form, so that maintenance and inspection are simple.

In order to solve the problems and needs of the prior art and the prior art described above, the present invention is characterized in that a main body and a main body in which a channel through which a fluid flows are formed, a main body including a hydraulic line which is a channel through which fluid introduced from the oil reservoir flows into the main body, A first transfer line which is a line for discharging the fluid to the oil reservoir and a discharge line for transferring the fluid of the main body to the hydraulic apparatus and a second transfer line which is a line for transferring the fluid of the main body from the hydraulic apparatus to the main body, A first extension conveyance line and a second extension conveyance line for connecting the main body and the third conveyance line, which are the ducts formed on one side of the ejection line, and a second extension conveyance line for controlling the flow rate of the main body Line. ≪ / RTI >

The first transfer line and the second transfer line may be arranged in a row and may be arranged in a plurality of rows in the horizontal direction, and a first transfer line and a second transfer line may be formed in a line on one side, The first transfer line and the second extension transfer line are formed in a line on one side and a fastening groove for fixing the body so as to be extended can be formed. The hydraulic line and the discharge line may be arranged in the horizontal direction on the side surface of the main body and the first and second transfer lines may be formed in the vertical direction on one side of the hydraulic line and the discharge line, A plurality of engagement grooves are formed in the hydraulic line and the discharge line so as to be fixed when the main body is extended.

The first and second conveyance lines formed in the main body form a first conveyance path and a second conveyance path that can move to the upper end of the main body, and the first and second conveyance paths are formed on both sides of the main body And the hydraulic line and the discharge line formed in the main body form a hydraulic pressure path and a discharge path capable of moving to the upper end of the main body, and the hydraulic pressure path and the discharge path are formed at the upper end of the main body And the first and second extension conveyance lines formed in the body include a first extension conveyance path and a second extension conveyance path which are movable to the upper portion of the main body.

The pipe sizes of the hydraulic line 110, the discharge line 120, the first and second transfer lines 130, 140 and 150, the first and second extension transfer lines 160 and 170, and the additional line 180 can be variously formed The discharge line 120, the first, second, and third transfer lines 130, 140, and 150, the first and second extended transports 130, 140 and 150, The first and second transfer paths 131 and 141 and the first and second transfer paths 131 and 141 formed at the upper end of the main body 100 in accordance with the piping sizes of the lines 160 and 170 and the additional line 180, The first and second transfer lines 130 and 140 and the first and second extension transfer lines 160 and 170 may be selectively formed in a vertical direction .

And the first and second transfer paths or the first and second extended transfer paths are respectively partitioned by the hydraulic pressure formed at the upper end of the main body so that the hydraulic line, the discharge line, the first and second transfer lines, A flow rate valve for regulating the amount of fluid at the upper end of the main body so as to allow the fluid to flow through the hydraulic pressure, the discharge path and the first and second transfer paths or the first and second extended transfer paths, And a directional valve for regulating the direction of the fluid are laminated and connected to each other like a pipe.

The flow rate valve, the pressure reducing valve, and the directional valve may be formed for each of the hydraulic line, the discharge line, and the first and second transfer lines or the first and second extension transfer lines, And a cover portion for preventing the flow of the fluid at the time of not using the additional line and the first, second and third transfer lines, the first, second and third extension lines, To be formed.

The main body may have a plurality of main bodies connected to a side surface of the main body in such a manner that the hydraulic line and the discharge line penetrate the main body. The first and second transfer lines are formed on both sides of the main body so as to constitute a plurality of hydraulic circuits .

The present invention is capable of controlling the hydraulic pressure and flow rate through a valve that can move fluid through a pipeline formed in a hydraulic direction switching block and stacked on the top of a flow path plate, And is easy to deform.

Further, it is an object of the present invention that the mounting space can be reduced and the assembling work can be performed easily and quickly.

Further, troubles caused by piping such as leakage, vibration and noise are generated little and are installed in a laminated form, so that maintenance and inspection are simple.

1 is a view showing a configuration of a hydraulic direction switching block according to the present invention.
2 is a diagram showing an internal configuration of a hydraulic direction switching block according to the present invention.
3 is a view showing an embodiment of a hydraulic direction switching block according to the present invention.
4 is a view showing a plane of a hydraulic direction switching block according to the present invention.
5 is a view showing a connection concept between the hydraulic direction switching block, the oil reservoir and the compression device according to the present invention.
FIG. 6 is a view showing a valve engagement state in the hydraulic direction switching block according to the present invention. FIG.

Hereinafter, the present invention will be described in detail with reference to the drawings.

The present invention relates to an apparatus and a method for transferring a main body 100, a hydraulic line 110, a discharge line 120, a first transfer line 130, a second transfer line 140, a third transfer line 150, 160) and a second extension transfer line (170).

Referring to FIGS. 1 to 6, the main body 100 is configured to have a channel therein to allow fluid to flow therethrough.

A fluid line 110 which is a pipe through which the fluid introduced from the oil reservoir 300 flows into the main body 100 and a fluid flowing inside the main body 100 are discharged into the oil reservoir 300 A discharge line 120 which is a channel is formed.

A first conveyance line 130 which is a conduit through which the fluid of the main body 100 is transferred to the hydraulic apparatus 400 and a second conveyance line which is a conduit through which the fluid discharged from the hydraulic apparatus 400 is transferred to the main body 100, A line 140 is formed.

The first transfer line 130 and the second transfer line 140 are formed so that fluid can be transferred to the main body 100 and the hydraulic apparatus 400 in both directions.

A first extension conveyance line 160 in which a third conveyance line 150 which is a duct formed at one side of the discharge line 120 of the main body 100 is formed and which can be connected to the main body 100, Two extension conveyance lines 171 are formed.

The first transfer line 130 and the second transfer line 140 formed in the main body 100 are formed in the vertical direction of the inflow line 110 and the discharge line 120, 2 transferring lines 140 are formed on both sides and the first transferring line 130 and the second transferring line 140 are formed to correspond to the upper and lower sides, respectively.

The first and second transfer lines 130 and 140 formed in the main body 100 form a first transfer path 131 and a second transfer path 141 which can move to the upper end of the main body 100, The transfer paths 131 and 141 are formed so that the first and second transfer lines 130 and 140 correspond to each other as they are formed on both sides of the main body 100.

The hydraulic line 110 and the discharge line 120 formed in the main body 100 form a hydraulic passage 111 and a discharge passage 121 capable of moving to the upper end of the main body 100, And the discharge path 121 are formed so as to correspond to each other as long as the first and second transfer paths 131 and 141 are formed at the upper end of the main body 100.

The first and second extension conveyance lines 160 and 170 formed in the main body 100 are formed with a first extension conveyance path 161 and a second extension conveyance path 171 that can move to the upper end of the main body 100.

The hydraulic line 110, the discharge line 121, the first transfer path 131, and the second transfer path 141 formed in the upper portion of the main body 100 form one compartment, The first extension feed path 161 and the second extension feed path 130 are formed so that the fluid can flow into the first extension feed path 120 and the first and second feed lines 130 and 140, 171 are formed to be another compartment so that the fluid can flow to the hydraulic line 110, the discharge line 120, and the first and second extended transfer lines 160, 170.

The additional line 180 may be further connected to the first and second transfer lines 131 and 141 so as to control the flow rates of the first and second transfer lines 131 and 141, So that the flow rate of the refrigerant flowing through the first and second flow passages 130 and 140 can be controlled and extended to other channels.

3, the hydraulic line 110, the discharge line 120, the first and second transfer lines 130, 140 and 150, the first and second extension transfer lines 160 and 170, and the additional line 180 ) Is shown as an embodiment.

FIG. 3A is a side view of an apparatus in which an additional line 180, a first transfer line 130, and a second transfer line 140 are formed in a row on one side of a main body and a plurality of the first transfer lines 130 and the second transfer line 140 are aligned in a horizontal direction, The first transfer line 130 and the second transfer line 140 may be formed in a line and a plurality of lines may be arranged in the horizontal direction.

The first extension conveyance line 160 and the second extension conveyance line 170 are formed in a row on one side and a coupling groove 190 for fixing the main body to be extended is formed.

FIG. 3B illustrates a plurality of third transfer lines 150 arranged in the horizontal direction on the other side of the main body.

3C is a sectional view of the hydraulic line 110 and the discharge line 120 arranged in the horizontal direction on the side of the main body and the first and second transfer lines 130 and 140 are formed on one side of the hydraulic line 110 and the discharge line 120 And may be formed in the vertical direction.

A plurality of coupling grooves 190 are formed in the hydraulic line 110 and the discharge line 120 so that the main body 100 can be fixed when the main body 100 is extended.

The hydraulic line 110, the discharge line 120, the first, second and third transfer lines 130, 140,

50, the first and second extension transfer lines 160, 170, and the additional line 180 may be formed in various sizes, and it is preferable that the user can determine the size of the pipe according to the flow rate difference and use the pipe.

The main body 100 (100) may be moved in accordance with the piping size of the hydraulic line 110, the discharge line 120, the first, second and third transfer lines 130, 140 and 150, the first and second extension transfer lines 160 and 170, And the first and second extension conveying paths 161 and 171 formed on the upper portion of the upper portion of the first conveying path 121 may be proportionally formed.

The first and second transfer lines 130 and 140 and the first and second extension transfer lines 160 and 170 may be selectively formed in the vertical direction.

Referring to FIGS. 1 and 6, the hydraulic pressure passage 111, the discharge passage 121 and the first and second transfer passages 131 and 141 or the first and second extension passages 161 and 171 formed at the upper end of the main body 100 A pressure reducing valve 210, and a directional valve 220 are stacked and coupled to the upper part of the compartment.

The flow rate valve 200 regulates the flow rate of the fluid flowing into the conduit, and the regulator 210 controls the fluid pressure of the fluid flowing into the conduit.

The directional valve 220 moves the fluid flowing into the hydraulic line 110 to the first conveying path 131 or the second conveying path 141 through the hydraulic path 111 and then to the first conveying path 131 The fluid to be transferred to the first transfer line 130 or the fluid to be transferred to the second transfer path 141 is formed to be transferred to the second transfer line 140 and discharged to the first and second transfer paths 131 and 141 The fluid flowing from the discharge line 121 is formed to be able to automatically or manually flow the fluid so as to adjust the direction of the flow so as to be discharged to the discharge line 120. [

The flow rate valve 200, the pressure reducing valve 210 and the direction valve 220 are connected to the hydraulic pressure passage 111, the discharge passage 121, the first and second transfer passages 131 and 141, (161, 171), and it is preferable that a fastening groove (190) for fixing the fastening groove (190) is further formed.

The coupling groove 190 is also formed at the lower end of the main body 100 so that the coupling groove 190 can be stacked and coupled.

The hydraulic passage 111 and the discharge passage 121, the first transfer passage 131 and the second transfer passage 141 are connected to each other through a flow valve 200, The pressure reducing valve 210, and the directional valve 220, as shown in FIG.

The hydraulic passage 111 and the discharge passage 121, the first extension feed passage 161 and the second extension feed passage 171 are not connected to each other in the main body 100, The pressure reducing valve 210, and the directional valve 220, as shown in FIG.

The hydraulic line 110, the discharge line 120, the first, second and third transfer lines 130, 140 and 150, the first and second extension transfer lines 160 and 170, and the additional line 180 prevent the flow of fluid The cover portion is formed so that the cover portion can be opened and closed in a detachable manner.

Referring to FIGS. 5 and 6, the main body 100 is connected to the oil reservoir 300 and the compression device 400.

A hydraulic pipe 310 is connected to the hydraulic line 110 of the main body 100 and a discharge pipe 320 is connected to the discharge line 120. The hydraulic pipe 310 and the discharge pipe 320 are connected to the oil reservoir 300 As shown in FIG.

The hydraulic pipe 310 is further formed with a pump unit 330 for introducing the fluid from the oil reservoir 300 to the main body 100.

The fluid is drawn into the oil reservoir 300 by the pump unit 330 and is introduced into the hydraulic line 110 of the main body 100 through the hydraulic pipe 310 and discharged to the discharge line 120 of the main body 100, Is discharged to the oil reservoir (300) through the discharge pipe (320).

The first conveyance line 410 is connected to the first conveyance line 130 of the main body 100 and the second conveyance line 420 is connected to the second conveyance line 140, The second transfer pipe 420 is connected to the lower fluid port 421 of the compression device 400 and the first and second transfer pipes 410 and 420 are connected to the upper fluid port 411 of the compression device 400, It is preferable to selectively connect the upper and lower fluid ports 411 and 421 to the upper and lower fluid ports 411 and 421, respectively.

So that the fluid can be transferred to the oil storage tank 300 through the main body 100 to the compression apparatus 400 or to be transferred to the compression apparatus 400 in both directions so as to transfer the fluid to the oil storage tank 300 .

4 and 6, a plurality of compartments may be formed by the hydraulic pressure passage 111, the discharge passage 121, the first conveyance passage 131 and the second conveyance passage 141, The flow rate valve 200, the pressure reducing valve 210, and the directional valve 220 are stacked and joined together.

In addition, a plurality of units are connected to the first and second transfer lines 130 and 140 to constitute a plurality of hydraulic circuits so as to be utilized in various ways. It is also formed so that it can be laminated in various ways.

The main body 100 is formed so that a plurality of main bodies 100 are connected to a side surface of the main body 100 in such a manner that the hydraulic line 110 and the discharge line 120 penetrate through the main body 100, Also, a plurality of main body 100 may be connected to the extension transfer lines 160 and 170 to form a plurality of hydraulic circuits, and a plurality of coupling grooves 190 may be formed.

It is possible to control the hydraulic pressure and the flow rate through the valve which is able to move the fluid through the pipeline formed in the hydraulic direction switching block and stacked on the upper part of the flow path plate and to control the moving direction of the fluid, It is easy to deform, the mounting space can be reduced, and the assembly work can be performed easily and quickly.

In addition, the present invention provides a hydraulic direction switching block having a simple effect of maintenance and inspection because it generates less trouble due to piping such as leakage, vibration and noise, and is installed in a laminated form.

100: main body 110: hydraulic line
111: Hydraulic pressure 120: Discharge line
121: discharge path 130: first transfer line
131 to first fluid 140: second transfer line
141: to the second fluid 150: third transfer line
160: first extension feed line 161: first extension feed line
170: second extension feed line 171: second extension feed path
180: additional line 190: fastening groove
200: Flow valve 210: Pressure reducing valve
220: directional valve 300: oil storage tank
400: compression device

Claims (4)

A main body having a channel through which fluid flows;
The main body includes a hydraulic line that is a line through which fluid introduced from the oil storage tank flows into the main body;
A discharge line which is a channel through which the fluid flowing into the main body is discharged to the oil storage tank;
A first transfer line that is a line through which the fluid in the main body is transferred to the hydraulic device;
A second transfer line that is a conduit through which the fluid in the main body is transferred from the hydraulic device to the main body;
A third transfer line in which fluid of the main body is a line formed at one side of the discharge line;
A first extension conveyance line and a second extension conveyance line for connecting the body and extending the extension body,
Wherein the hydraulic line direction switching block further comprises an additional line for adjusting the flow rate of the main body.
The method according to claim 1,
The first transfer line and the second transfer line may be arranged in a row and may be arranged in a plurality of rows in the horizontal direction, and a first transfer line and a second transfer line may be formed in a line on one side, A first extension conveyance line and a second extension conveyance line are formed in a line and a fastening groove is formed to fix the body so that the body can be extended,
A plurality of third conveyance lines may be arranged in a horizontal direction on the other side surface of the main body,
A hydraulic line and a discharge line may be arranged in a horizontal direction on a side surface of the main body and first and second transfer lines may be formed in a vertical direction on one side of the hydraulic line and the discharge line, Wherein a plurality of engaging grooves are formed to allow the engaging portions to be fixed at a predetermined position.
3. The method of claim 2,
The first and second transfer lines formed in the main body may form a first transfer path and a second transfer path,
The first and second transfer paths are formed to correspond to each other as long as the first and second transfer lines are formed on both sides of the main body,
The hydraulic line and the discharge line formed in the main body form a hydraulic pressure path and a discharge path that can move to the upper end of the main body,
The hydraulic pressure path and the discharge path are formed so as to correspond to each other as long as the first and second transfer paths are formed at the upper end of the main body,
Wherein the first and second extension conveying lines formed in the main body are formed to include a first extending conveying path and a second extending conveying path which are movable to an upper end of the main body.
3. The method of claim 2,
The pipe sizes of the hydraulic line 110, the discharge line 120, the first and second transfer lines 130, 140 and 150, the first and second extension transfer lines 160 and 170, and the additional line 180 can be variously formed The user can judge the flow rate according to the difference in flow rate,
The main body 100 is moved in accordance with the piping sizes of the hydraulic line 110, the discharge line 120, the first and second transfer lines 130, 140 and 150, the first and second extension transfer lines 160 and 170, The channel length of the hydraulic pressure passage 111, the discharge passage 121, the first and second transfer passages 131 and 141, and the first and second extended transfer passages 161 and 171 formed at the upper portion may be proportionally formed,
The vertical direction of the first and second transfer lines (130, 140) and the first and second extension transfer lines (160, 170) can be selectively formed.

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