KR100888028B1 - A pressure-controlled change-over valve of grease feeding apparatus - Google Patents

Abstract

A pressure-controlled change-over valve of a grease feeding apparatus is provided to facilitate the change-over operation by quickly responding to the sensing of a change-over pressure. In a pressure-controlled change-over valve of grease feeding apparatus, a housing(100) comprises a first and second exhaust ports, a pressure port(P), a relief port(R), a first, second, and third operating chambers(111,121,131) formed inside and an adjusting chamber(141); and a plurality of channels connecting the first, second exhaust port, the pressure port, the relief port, the first, second, and third operating chamber and the adjusting chamber. The adjusting unit comprises a case(240) installed at one side of the housing; an adjusting body(210) installed movably inside the adjusting chamber of the housing; an adjusting screw(230) installed on the top of the case in order to adjust the height; and a spring(220) installed between the adjusting body and the adjusting screw. A first and second change-over pistons(110,120) are installed to the first and second operating chamber of the housing. A pre-selecting piston(130) is installed inside the third operating chamber of the housing.

Description

Mechanical switching valve of grease supply unit {A PRESSURE-CONTROLLED CHANGE-OVER VALVE OF GREASE FEEDING APPARATUS}

The present invention relates to a grease supply device for supplying grease to a required location, and more particularly, to a mechanical switching valve for alternately switching the grease discharged by the grease pump of the grease supply device to two supply mains. will be.

Grease is a kind of lubricating oil used in semi-solid state. It is mainly used in the part where lubricating oil is difficult to be injected. It shows liquid state during movement, and when it stops, it loses its mobility and becomes semi-solid state.

These greases have a variety of products depending on their use and composition. Most of these greases are prepared by adding a metal soap and a small amount of water to a liquid mineral oil-based lubricant and mixing them in a colloidal state. When friction deformation is caused by the movement of the machine or the temperature rises, oil in the inside leaks outwardly, and it is used in the friction part where the load of the rotating shaft against the bearing is large, and the part which is difficult to refuel. Recently, synthetic oils such as silicone oil are also used instead of mineral oils, and fatty acid salts such as calcium, aluminum, and lithium are frequently used for metal soaps.

On the other hand, various apparatuses for automatically supplying such greases automatically or manually to a place requiring lubrication in various production facilities such as a vehicle manufacturing facility or an ironworks are disclosed or implemented.

FIG. 1 shows a general electric grease supply device which is widely used for steel making facilities or transportation facilities. The electric grease supply device includes an electric grease pump 10 and greases fed from the pump 10. 2 is composed of a mechanical switching valve 30 alternately switching through the supply pipes (21, 22), and a grease charge pump (40) filled with a predetermined amount of grease. Here, reference numeral 50 denotes a control panel, 60 denotes a distribution valve, 70 denotes a supply pipe, and 80 denotes an oil supply pipe.

The conventional grease supply device is a device for automatically supplying a predetermined oil supply interval to the system timer of the electric control panel 50. For this purpose, the grease fed from the pump 10 is alternately switched by the switching valve 30. When the oil is supplied to each of the lubrication points through the first supply pipe 21 and the distribution valve 60, and at the same time the pressure of the first supply pipe 21 rises rapidly to reach the set switching pressure of the switching valve 30 As the switching valve 30 is switched, lubrication is performed through the second supply pipe 22.

However, such a conventional switching valve 30 does not respond quickly to the detection of the switching pressure, so that the switching operation is not smooth and the switching operation between the first and second supply pipes 21 and 22 is not sufficient. Frequently, a failure occurred frequently, so that the oil supply operation to the distribution valve 60 was not smooth.

The present invention has been made in view of the above, and an object of the present invention is to provide a mechanical switching valve of a grease supply device that can respond more quickly to the detection of a switching pressure to facilitate the switching operation.

In addition, an object of the present invention is to provide a mechanical switching valve of the grease supply device that can smoothly supply the grease by minimizing the occurrence of failure of the switching operation.

Mechanical switching valve of the present invention for achieving the above object,

First and second discharge ports, pressure ports, and relief ports are formed outside, and first to third operation chambers and control chambers are formed therein, and the first and second discharge ports, pressure ports, and relief ports, A housing having a plurality of flow paths connecting the first to third operating chambers and the adjustment chamber; And

A case installed on one side of the housing, an adjuster movably installed in the control chamber of the housing, an adjustment screw installed on the top of the case so as to be height adjustable, and an adjustment unit having a spring installed between the adjuster and the adjustment screw. and,

A first switching piston is movably installed in the first operating chamber of the housing, a second switching piston is movably installed in the second operating chamber of the housing, and is free in the third operating chamber of the housing. The selecting piston is characterized in that the movable installation.

The first and second switching pistons and the preselecting piston are individually moved in the first to third working chambers by the movement of the regulator to selectively move the pressure port to the relief port from the first and second discharge ports. Characterized in that the communication.

The plurality of flow paths include a pressure line, first and second supply lines, first to third control lines, first and second relief lines, and first and second auxiliary lines,

The pressure line is formed to communicate with the third operation chamber from the pressure port via the first operation chamber, the pressure line is in communication with the control chamber,

The first supply line is formed to communicate with the first discharge port through one end of the second operation chamber at one side of the first operation chamber, the second supply line is the first operation chamber at the other side of the first operation chamber; It is formed to communicate with the second discharge port via the other end of the second operation chamber,

The first control line is formed in communication with the second operation chamber from the control chamber, the second control line is formed in communication with one end of the third operation chamber from one side of the second operation chamber, The third control line is formed to communicate with the other end of the third operation chamber from the other side of the second operation chamber,

The first relief line is formed to communicate with the relief port through the first and third operation chambers at one side of the second operation chamber, the second relief line is the first at the other side of the second operation chamber And a third communication chamber configured to communicate with the relief port.

The first auxiliary line is formed to communicate from one end of the first operation chamber to one side of the third operation chamber, and the second auxiliary line communicates from the other end of the first operation chamber to the other side of the third operation chamber. Characterized in that formed.

The present invention as described above has the effect of reacting more quickly to the detection of the switching pressure to smooth the switching operation.

In addition, the present invention can smoothly supply the grease by minimizing the occurrence of failure of the switching operation.

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

2 to 6 show a mechanical switching valve according to an embodiment of the present invention.

As shown, the mechanical switching valve of the present invention includes a housing 100, a control unit 200 provided on one side of the housing 100, and the like.

The housing 100 has first and second discharge ports A and B, a pressure port P, and a relief port R on its outer surface, and the first and second discharge ports A and B The first and second supply pipes 21, 22 (see FIG. 2) are individually communicated with each other, and the discharge pipe 11 of the grease pump 10 is connected to the pressure port P. The housing 100 has first to third working chambers 111, 121, and 131 and an adjusting chamber 141 therein. A plurality of flow paths as shown in FIGS. 5 and 6 between the first to third operating chambers (111, 121, 131), the discharge port (A, B), the pressure port (P), the relief port (R) 151 to 160 are formed.

The first switching piston 110 is movably installed in the first operating chamber 111, the second switching piston 120 is movably installed in the second operating chamber 121, and the third operating chamber is movable. The preselecting piston 130 is installed in the 131 so as to be movable, and the adjusting body 210 of the adjusting unit 200 is installed in the adjusting chamber 141. A bush 270 having a hollow portion is sealedly installed on the upper surface of the housing 100, and the hollow portion of the bush 270 serves as the adjustment chamber 141. The side of the bush 270 has one or more through holes 211, the adjuster 210 is configured to open and close the through holes 211 by the vertical movement.

The adjusting body 210 moves as the pressure in the first and second supply pipes 21 and 22 reaches the set switching pressure, and the first and second switching pistons 110 are moved by the movement of the adjusting body 210. 120 and the preselecting piston 130 are moved separately, thereby selectively communicating the pressure ports P to the relief ports R to the first and second discharge ports A and B, thereby providing grease. Switch the pressure on.

Both ends of the first to third operating chambers 111, 121, and 131 are opened, and the open portions are closed by the closing caps 115, 125, and 135.

5 and 6 conceptually illustrate a plurality of flow paths 151 to 160 formed between the first to third operating chambers 111, 121, and 131 and the adjustment chamber 141. Looking at it as follows.

The pressure line 151 is formed to communicate with the third operating chamber 131 through the first operating chamber 111 at the pressure port P, the pressure line 151 is a branch line 151a branched from one side thereof. Communicate with the control chamber 141 through).

The first supply line 152 is formed to communicate with the first discharge port A through one end of the second operation chamber 121 at one side of the first operation chamber 111, the second supply line 153 is The other side of the first operation chamber 111 is formed to communicate with the second discharge port (B) via the other end of the second operation chamber 121.

The first control line 154 is formed to communicate with the second operation chamber 121 in the adjustment chamber 141, the second control line 155 is the third operation chamber (one side of the second operation chamber 121) It is formed to communicate with one end of the 131, the third control line 156 is formed to communicate with the other end of the third operating chamber 131 on the other side of the second operating chamber (121).

The first relief line 157 is formed to communicate with the relief port R via the first and third operation chambers 111 and 131 at one side of the second operation chamber 121 and the second relief line 158. The other side of the second operation chamber 121 is formed to communicate with the relief port (R) via the first and third operating chambers (111, 131).

The first auxiliary line 159 is formed to communicate with one side of the third operating chamber 131 at one end of the first operating chamber 111, the second auxiliary line 160 is the other end of the first operating chamber 111 In the third operation chamber 131 is formed to communicate with the other side.

The control unit 200 is installed in the case 240 installed on one side of the housing 100, the control body 210 installed in the control chamber 141 of the housing 100, the case 240, and the control body. A spring 220 for elastically supporting the 210, the adjustment screw 230 is provided to be adjustable height on the upper side of the case 240, the spring 220 is the adjuster 210 and the adjustment Interposed between the screws 230, the spring force of the spring 220 can be adjusted by adjusting the height of the adjustment screw 230. The adjusting body 210 is set by the spring force of the spring 220 of the switching pressure.

An indicator pin 132 is installed at one end of the preselecting piston 130. The indicator pin 132 penetrates through a closing cap 135 that ends one end of the third operation chamber 131, and moves together with the preselecting piston 130 to move the preselecting piston 130. Can be detected. In addition, a sealing member 133 having a U-cup shape may be interposed between the indicator pin 132 and the closing cap 135 to maintain the sealing property.

The movement of the pre-selecting piston 130 is detected by the sensor 300 located opposite the indicator pin 132, the sensor 300 is a kind of position switch of the indicator pin 132 By detecting the position, the switching operation of the switching valve is detected, and the switching signal by the detection sensor 300 is transmitted to the electric control panel 50 (see FIG. 1) of the grease supply device to temporarily stop the operation of the grease pump 10. Then, the grease supply enters the standby state for a predetermined time. By such a sensor 300, the switching valve of the present invention can minimize the occurrence of failure due to excessive pressure generated during the switching operation, thereby having an advantage that can facilitate a smooth switching operation.

The operating relationship of the present invention configured as described above will be described in detail with reference to FIGS. 5 and 6.

The grease pressurized from the grease pump 10 (see Fig. 1) proceeds to supply oil to the lubrication points while operating the distribution valve 60 (see Fig. 1) via the switching valve of the present invention, and all the distribution valves 60 are operated. Refueling is completed when this is completed. When the pressure in the supply main (21, 22) is soared and reaches the set switching pressure at the time when the lubrication is completed in this way, the switching valve 100 of the present invention is the switching operation is made, the switching operation of the switching valve is sensed Sensing by the sensor 300, the sensed signal causes the electrical control panel 50 to stop the operation of the grease pump 10 so that the entire system enters the standby state for a predetermined time.

On the other hand, Figure 5 is an operating principle showing the state in which grease is pushed to the distribution valve 60 side via the first discharge port (A) and the first supply main body 21 by the switching valve of the present invention.

As shown in FIG. 5, the first control line 154 and the second control line 155 communicate with each other, and the preselecting piston 130 has a second discharge port B in the third operation chamber 131. In the state of moving in the () direction (ie, downward in FIG. 5), when grease is introduced through the pressure port P in the grease pump 10, a part of the grease is first operated through the second auxiliary line 160. The first switching piston 110 is moved into the chamber 111 and moves in the first discharge port A in the direction of the first discharge port A (upward in FIG. 5), and thus the first operating chamber 111. ) And the first supply line 152 are in communication with each other. In this state, the grease is pumped through the first discharge port A and the first supply pipe 21 after passing through the first supply line 152. At this time, the second switching piston 120 is moved in the direction of the second discharge port B of the second operation chamber 121 (down direction in FIG. 5), so that the second supply line 153 is connected to the first operation chamber 111. ) Is blocked, so grease is not supplied to the second discharge port (B).
FIG. 6 is an operation principle diagram illustrating a state in which grease is pumped to the distribution valve 60 through the second discharge port B and the second supply main body 22 by the switching valve of the present invention.

When the pressure in the first supply main body 21 communicating with the first discharge port A reaches the switching pressure, the pressure in the first supply main body 21 and the first supply line 152 increases, and As shown in FIG. 6, as the grease of the first supply line 152 is transferred to the branch line 151a of the pressure line 151, the adjuster 210 rises. As the regulator 210 rises, the through hole 211 of the bush 270 is opened so that the adjustment chamber 141 communicates with the first control line 154. Then, the grease in the teeth passes through the first control line 154 into the second operation chamber 121, so that the second switching piston 120 is formed in the second operation chamber 121 as shown in FIG. 6. It moves to the direction of one discharge port A (upward direction of FIG. 6). Accordingly, the second supply line 153 communicates with the first operation chamber 111.

In this state, when grease is introduced through the pressure port P in the grease pump 10, the grease is transferred to the first operation chamber 111 via the pressure line 151. Then, some grease is transferred to the third operation chamber 131, whereby the pre-selecting piston 130 moves in the first discharge port A in the third operation chamber 131 (the upward direction in FIG. 6). ), And as the grease in the third operating chamber 131 is transferred back into the first operating chamber 111 through the first auxiliary line 159, the first switching piston 110 moves to the second discharge port B. ) Direction (downward in Fig. 6). By the movement of the first switching piston 110, the first supply line 152 is blocked from communication with the first operation chamber 111, the grease supplied to the first operation chamber 111 is the second supply line It is pumped to the second discharge passage B and the second supply pipe 22 via 153.

Similarly, when the pressure in the second supply pipe 22 communicating with the second discharge port B reaches the switching pressure, the first and second switching pistons 110 and 120 and the preselecting piston 130 operate. On the contrary, it progresses to the state of FIG.

The present invention as described above is the switching pressure by the structure of the first and second switching piston (110, 120) and the pre-selecting piston 130 which is movable in the first to third operating chamber (111, 121, 131) It is easy to detect the advantage of implementing a more smooth switching operation.

1 is a view schematically showing a general grease supply device.

Figure 2 is a perspective view showing a mechanical switching valve of the grease supply apparatus according to an embodiment of the present invention.

Figure 3 is a side cross-sectional view showing a mechanical switching valve according to an embodiment of the present invention.

Figure 4 is a partial plan cross-sectional view showing a mechanical switching valve according to an embodiment of the present invention.

5 and 6 are schematic views showing the switching operation of the mechanical switching valve according to the present invention.

Brief description of symbols for the main parts of the drawings

100: housing 110: first switching piston

111: first operating chamber 120: second switching piston

121: second operating chamber 130: preselecting piston

131: third operation chamber 141: adjustment chamber

200: control unit 210: control body

Claims (3)

First and second discharge ports, pressure ports, and relief ports are formed outside, and first to third operation chambers and control chambers are formed therein, and the first and second discharge ports, pressure ports, and relief ports, A housing having a plurality of flow paths connecting the first to third operating chambers and the adjustment chamber; And A case installed on one side of the housing, an adjuster movably installed in the control chamber of the housing, an adjustment screw installed on the top of the case so as to be height adjustable, and an adjustment unit having a spring installed between the adjuster and the adjustment screw. and, A first switching piston is movably installed in the first operating chamber of the housing, a second switching piston is movably installed in the second operating chamber of the housing, and is free in the third operating chamber of the housing. Mechanical switching valve of the grease supply unit, characterized in that the selecting piston is movable. The method of claim 1, The first and second switching pistons and the preselecting piston are configured to selectively communicate the pressure ports to the first and second discharge ports by individually moving in the first to third working chambers by the movement of the adjusting body. Mechanical switching valve for grease supply. The method of claim 2, The plurality of flow paths include a pressure line, first and second supply lines, first to third control lines, first and second relief lines, and first and second auxiliary lines, The pressure line is formed to communicate with the third operating chamber through the first operating chamber in the pressure port, the pressure line is communicated to the control chamber through a branch line branched from one side, The first supply line is formed to communicate with the first discharge port through one end of the second operation chamber at one side of the first operation chamber, the second supply line is the first operation chamber at the other side of the first operation chamber; It is formed to communicate with the second discharge port via the other end of the second operation chamber, The first control line is formed in communication with the second operation chamber from the control chamber, the second control line is formed in communication with one end of the third operation chamber from one side of the second operation chamber, The third control line is formed to communicate with the other end of the third operation chamber from the other side of the second operation chamber, The first relief line is formed to communicate with the relief port through the first and third operation chambers at one side of the second operation chamber, the second relief line is the first at the other side of the second operation chamber And a third communication chamber configured to communicate with the relief port. The first auxiliary line is formed to communicate from one end of the first operation chamber to one side of the third operation chamber, and the second auxiliary line communicates from the other end of the first operation chamber to the other side of the third operation chamber. Mechanical switching valve of the grease supply unit, characterized in that formed.

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