KR20230159118A - Gas Spring - Google Patents

Abstract

In the present invention, when the rod reciprocates up and down by gas pressure while applying or releasing pressure on the rod to process the object to be processed into the desired structure, the rod is restored by the gas pressure after processing the object to be processed. It relates to a gas spring that adjusts the lifting speed. The configuration is to install a gas return means on the inner cylinder body of the gas spring, which consists of a cylinder with a cylinder gas chamber and a rod with a load gas chamber that reciprocates up and down. The gas in the gas chamber is returned to the cylinder gas chamber through the auxiliary gas chamber.

Description

Gas Spring

The present invention relates to a process in which the rod is restored by gas pressure after processing the processed object when the rod reciprocates up and down by gas pressure while applying or releasing pressure on the rod to process the object into a processing object of the desired structure. It is about a gas spring that controls the rod lifting speed.

In general, gas springs are widely used in the general industry because they are small in size but have the characteristic of being able to obtain a small spring constant with a large initial load. The internal gas pressure of such a gas spring must always be maintained at a high pressure and the load is repeated by load. Structural design is required so that gas does not leak even during reciprocating motion.

There is a conventional gas spring to meet the above requirements, Republic of Korea Patent No. 10-2130158, and its configuration is briefly described as follows.

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A cylinder (12) having a hollow portion (11) formed in the longitudinal direction to form a gas chamber (90);

An end cap (13) coupled to the lower end of the cylinder and sealing the lower part of the hollow portion;

a piston (30) inserted into the hollow part of the cylinder and having a rod (20);

It consists of a gas charging valve unit 70 that is coupled to the valve cavity in communication with the gas injection portion formed in the end cap 13, opens the gas chamber when gas is charged, and closes the gas chamber after gas charging is completed.

The gas spring of the Republic of Korea Patent No. 10-2130158 configured as described above is a gas spring installed with a gas charging valve unit with improved airtightness by stably securing the close contact area of the check valve member for closing the gas chamber in which gas is charged. will be.

Also, there is a gas spring of Republic of Korea Patent No. 10-1700159 as shown in Figure 1, and its configuration is as follows.

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A cylinder (12) with a hollow portion (11) formed in the longitudinal direction,

An end cap (13) coupled to the lower end of the cylinder and sealing the lower end of the cylinder,

A piston (30) that is inserted into the hollow part of the cylinder, has a rod (20), and divides the hollow part into an upper chamber (110) and a lower chamber (120),

A sealing unit (40) inserted into the outer peripheral surface of the rod and the inner peripheral surface of the corresponding cylinder to seal the upper end of the cylinder,

A check valve unit 82 formed on the piston and installed in at least one connection passage connecting the upper chamber 110 and the lower chamber 120 to allow one-way movement of the inert gas in the upper chamber to the lower chamber. ,

It consists of a gas flow control unit 90 installed in the cylinder to flow the inert gas in the upper chamber and the lower chamber.

The gas spring of the Republic of Korea Patent No. 10-1700159 configured as described above is installed so that the gas flow control unit 90 is separately exposed to the outside of the cylinder 12, so when mounted on a press machine and used, it is installed outside the cylinder 12. In addition, the exposed gas flow control unit 90 may become an obstacle, and since various connection components are used to prevent gas leakage, the length of the gas flow control unit 90 becomes longer. There is a problem in that gas leaks cannot be completely blocked.

Republic of Korea Patent No. 10-1700159 (Announcement Date: 2017.01.26.) Republic of Korea Patent No. 10-2130158 (Announcement Date: 2020.07.03.) Republic of Korea Patent No. 10-1863771 (Announcement Date: 2018.06.01.)

The purpose of the present invention is to solve the problems of the conventional gas spring as described above.

First, the gas in the cylinder gas chamber and the gas in the auxiliary gas chamber provided inside the gas spring are moved to each other by the gas return means installed inside the gas spring, so that the gas cylinder returns to its original position after processing the object. Adjust the restoration speed,

Second, in the process of the rod of the gas spring reciprocating up and down in order to process the object into the desired structure, the gas in the cylinder gas chamber and the gas in the auxiliary gas chamber are prevented from leaking to the outside and the rod reciprocates up and down smoothly. The purpose is to provide a gas spring that allows this to be achieved.

The configuration of the problem-solving means of the present invention to achieve the above purpose is,

A gas supply means 210 for supplying gas to the cylinder gas chamber 240 is installed at the lower part, and a through hole 220 through which a rod reciprocates up and down is formed at the upper part, and a first airtightness maintaining means is formed in the through hole. A cylinder (200) in which (230) is installed and a cylinder gas chamber is provided inside;

By reciprocating up and down along the through hole, a tool installation part 310 is formed at the top, a slider 320 with a second airtightness maintenance means 330 installed at the bottom is formed, and a load gas chamber 340 is formed inside. and a rod 300 having an discharge passage 350 formed on one side of the rod gas chamber;

An auxiliary gas chamber 410 for receiving gas is provided between the upper part of the slider and the cylinder, and a gas furnace 420 is provided with a valve 430 for supplying gas from the auxiliary gas chamber to the cylinder gas chamber inside the body of the cylinder. regression means (400);

a valve means (500) installed on the slider to supply gas from the cylinder gas chamber to the load gas chamber when the gas pressure of the cylinder gas chamber is higher than a desired pressure; It consists of

The gas spring of the present invention having the above configuration, as described for the above purpose, allows the gas in the cylinder gas chamber and the gas in the auxiliary gas chamber provided inside the gas spring to move to each other by the gas return means installed inside the gas spring. This allows the gas cylinder to adjust the restoration speed in the process of restoring the rod to its original position after processing the object to be processed, and also to control the cylinder gas chamber during the process of the rod of the gas spring reciprocating up and down to process the object into the desired structure. This has the effect of ensuring smooth up/down reciprocating movement of the rod while preventing the gas in and the auxiliary gas chamber from leaking to the outside.

1 is a cross-sectional view showing the configuration of a conventional gas spring;
Figure 2 is an exploded perspective view of the gas spring of the present invention;
Figure 3 is a partially cut away perspective view of the gas spring of the present invention;
Figure 4 is a cross-sectional view before load operation in the gas spring of the present invention;
Figure 5 is a cross-sectional view after load operation in the gas spring of the present invention;
Figure 6 is an enlarged cross-sectional view of the portion where the first airtightness maintaining means is installed in the gas spring of the present invention;
Figure 7 is an enlarged cross-sectional view of the portion where the second airtightness maintenance means and the valve means are installed in the gas spring of the present invention;
Figure 8 is an enlarged perspective view of the first and second airtightness maintenance means in the gas spring of the present invention;
Figure 9 is an enlarged perspective view of the dust seal in the gas spring of the present invention;
Figure 10 is a side schematic diagram showing an example in which the gas spring of the present invention is applied.

The present invention relates to a process in which the rod is restored by gas pressure after processing the processed object when the rod reciprocates up and down by gas pressure while applying or releasing pressure on the rod to process the object into a processing object of the desired structure. This relates to a gas spring that adjusts the load lifting speed. An embodiment will be described with reference to the attached drawings as follows.

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In one embodiment to which the gas spring of the present invention is applied, as shown in FIG. 11, each gas spring (G) is installed at the upper and lower parts centered on the object (M), and the load is applied by pressurizing the gas spring. The object to be processed (M) is processed into the desired structure through a virtual up/down reciprocating movement. At this time, when the rods of the gas springs (G) installed at the upper and lower parts move at different speeds, the object to be processed (M) is moved. As problems such as deformation or the inability to process precise structures occur, the present invention allows the rod lifting speed of the gas spring to be adjusted to solve the above problems.

The above description of the application of the gas spring of the present invention describes one embodiment, and the gas spring according to the present invention described below can be applied and used in various business fields.

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The gas spring of the present invention, as shown in Figures 2 to 5,

A gas supply means 210 for supplying gas to the cylinder gas chamber 240 is installed at the lower part, and a through hole 220 through which a rod reciprocates up and down is formed at the upper part, and a first airtightness maintaining means is formed in the through hole. A cylinder (200) in which (230) is installed and a cylinder gas chamber is provided inside;

By reciprocating up and down along the through hole, a tool installation part 310 is formed at the top, a slider 320 with a second airtightness maintenance means 330 installed at the bottom is formed, and a load gas chamber 340 is formed inside. and a rod 300 having an discharge passage 350 formed on one side of the rod gas chamber;

An auxiliary gas chamber 410 for receiving gas is provided between the upper part of the slider and the cylinder, and a gas furnace 420 is provided with a valve 430 for supplying gas from the auxiliary gas chamber to the cylinder gas chamber inside the body of the cylinder. regression means (400);

a valve means (500) installed on the slider to supply gas from the cylinder gas chamber to the load gas chamber when the gas pressure of the cylinder gas chamber is higher than a desired pressure; It consists of

In the gas spring configuration according to the present invention, the gas supply means 210 at the lower part of the cylinder 200 supplies gas at a desired pressure to the cylinder gas chamber 240 provided inside the cylinder 200. The same gas supply means 210 preferably opens when supplying gas to the cylinder gas chamber 240 and uses a check valve that does not leak the gas supplied to the cylinder gas chamber 240.

The reason for forming the through hole 220 is to enable the rod 300 to repeatedly reciprocate up and down, and the reason for installing the first airtightness maintenance means 230 is to allow the rod 300 to move back and forth repeatedly. This is to prevent gas from the load gas chamber 340 and the auxiliary gas chamber 410 from leaking to the outside between the cylinder 200 and the rod 300 to be reciprocated up and down.

In addition, the reason for forming the tool installation part 310 on the upper part of the rod 300 is to install a work tool corresponding to the gas spring of the present invention, and the reason for forming the slider 320 is , When the rod 300 reciprocates up and down, the slider 320 reciprocates up and down in the cylinder gas chamber 240 and changes the gas pressure in the cylinder gas chamber 240 to raise and lower the rod 300. It is intended to make it happen.

In addition, the reason for installing the second airtightness maintenance means 330 is that when the slider 320 reciprocates up and down in the cylinder gas chamber 240, the gas in the cylinder gas chamber 240 flows into the slider 320 and the cylinder 200. ) This is to prevent leakage into the auxiliary gas chamber 410 through the inner peripheral surface of the gas.

In addition, the auxiliary gas chamber 410 provided between the inner slider 320 of the cylinder gas chamber 240 and the upper part of the cylinder 200 is the load gas chamber 340 in which the rod 300 moves while reciprocating up and down. This is a place to receive some of the gas when it moves to the cylinder gas chamber 240 through the gas return means 400, which will be explained below.

Gas movement as described above occurs when pressure is applied to the rod 300 to perform the desired task, and the slider 320 descends to compress the gas in the cylinder gas chamber 240, and the compression of the gas is performed to achieve the desired effect. When the pressure exceeds the pressure, it is supplied to the load gas chamber 340 through the valve 540 of the valve means 500, and when the rod 300 completes its intended work and is raised or lowered, the gas in the load gas chamber 340 is discharged through the discharge path. It is supplied to the cylinder gas chamber 240 through the gas furnace 420 and the valve 430, which are the gas return means 400, via the auxiliary gas chamber 410 and the rod 300 is raised and lowered. .

The configuration of an embodiment of the gas return means 400 through which the gas in the load gas chamber 340, which performs this function, is supplied to the cylinder gas chamber 240 via the auxiliary gas chamber 410 is as shown in Figures 2 to 5. Likewise, a gas passage 420 in which the cylinder gas chamber 240 and the auxiliary gas chamber 410 are connected to each other is formed inside the body of the cylinder 200, and a valve 430 is installed on one side of the gas passage 420.

In one embodiment of the gas furnace 420, as shown in FIGS. 4 and 5, a line 421 communicating with the auxiliary gas chamber 410 and a line 422 communicating with the cylinder gas chamber 240 are formed. , It consists of a regression line 423 connecting each of the lines 421 and 422.

In addition, the ends of the line 421 communicating with the auxiliary gas chamber 410 and the line 422 communicating with the cylinder gas chamber 240 are formed to communicate with the outside of the body of the cylinder 200, and each of the communicating lines 421 and 422 ) The end was blocked with a blocking member 440 to prevent gas from leaking.

The reason for forming each of the lines 421 and 422 above is to easily form the gas furnace 420 inside the body of the cylinder 200, and the blocking member 440 provides airtightness at the ends of each of the lines 421 and 422. Anything that can prevent this from continuing is possible.

The valve 430 is installed at the neck where the line 422 in communication with the cylinder gas chamber 240 and the return line 423 formed in the body of the cylinder 200 meet to adjust the amount of gas return, and is installed in the gas furnace ( In order to increase the amount of gas returning to 420, the valve 430 is adjusted to increase the gap, or open amount, of the neck where the tip of the valve 430 meets the line 422 and the return line 423, and the gas In order to reduce the amount of gas returning to the furnace 420, the valve 430 can be adjusted to reduce the gap at the neck where the tip of the valve 430 meets the line 422 and the return line 423, that is, the opening amount. .

As described above, the lifting and lowering speed of the rod 300 varies depending on the opening amount of the neck where the line 422 and the return line 423 meet, and the lifting and lowering speed of the rod 300 is adjusted according to the present invention. It can be adjusted depending on the gas spring application.

One embodiment of the valve 430 that functions as described above is to install the valve 430 in the valve seating groove 450 formed in series with the return line 423 and directly install the valve 430 using a hand tool. By rotating it, it is possible to adjust the gap, or open amount, of the neck where the line 422 and the return line 423 meet, or

In another embodiment, a valve cover 460 is installed via a spring 470 at the rear end of the valve 430 installed in the valve seating groove 450, and the valve cover 460 is rotated using a hand tool to rotate the spring ( By changing the elastic force of 470), it is possible to adjust the gap, or open amount, of the neck where the line 422 and the return line 423 meet.

In another embodiment, in the case of the valve 430 on which the spring 470 is installed, the elastic force of the spring 470 changes depending on the pressure of the gas returning to the return line 423, and the line 422 and the return line 423 ) has the advantage of being able to finely control the gap between the necks, i.e. the amount of opening.

In addition, the valve means 500 with the valve 540 installed on the slider 320 serves to raise and lower the lowered rod 300. An example configuration of the valve means 500 is: 2 and 6, a valve assembly 520 is installed in the coupling hole 510 penetrating the slider 320, and a valve seating groove 530 is formed in the valve assembly 520 to attach the valve 540. ) is seated, and the valve 540 is fixed to the valve cover 560 via the spring 550, so that the valve 540 is stably fixed.

The configuration of the valve 540 as described above is a preferred embodiment according to the present invention. In addition, a check valve may be installed in the valve seating groove 530, or a valve whose opening and closing degree may vary depending on the gas pressure may be installed and used.

The valve means 500 as described above, when a lot of gas returns to the cylinder gas chamber 240 through the gas return means 400, the gas pressure in the cylinder gas chamber 240 becomes stronger in proportion to the slider 320. A strong gas pressure is applied to the valve 540, which changes the elastic force of the spring 550 and opens the inlet of the valve seating groove 530 to supply gas from the cylinder gas chamber 240 to the load gas chamber 340. The rod 300 is raised and lowered together with the slider 320, that is, returned to its original position.

The valve means 500, which acts as described above, changes the elastic force of the spring 550 and raises and lowers the rod 300 together with the slider 320 according to the degree to which the inlet of the valve seating groove 530 is opened. The speed of returning to the original position varies, and this is determined by the gap, or open amount, of the neck where the line 422 and the return line 423 of the valve means 400 meet.

In addition, in one embodiment of the cylinder 200 of the present invention, as shown in FIGS. 2 to 5, the lower cap 250 is installed to maintain airtightness through the sealing member 260, so that the cylinder gas chamber 240 ) gas does not leak to the outside.

In the above description, one embodiment of the first airtightness maintenance means 230 is installed to prevent gas from the auxiliary gas chamber 410 and the load gas chamber 340 from leaking to the outside, and the through hole 220 A seating groove 231 is formed on one side of the seating groove 231, and as shown in FIG. 8, a body 232a and an airtight piece 232c forming a gas pressure hole 232b at the tip of the body are provided. A first cup-shaped chamber ( 232) is installed.

In addition, one embodiment of the second airtightness maintenance means 330 is to prevent gas from the auxiliary gas chamber 410 and the cylinder gas chamber 240 from leaking between the slider 320 and the inner peripheral surface of the cylinder 200, A seating groove 331 is formed in the slider 320, and an airtight piece 332c is formed in the seating groove 331 with a body 332a and a gas pressure hole 332b at the tip of the body as shown in FIG. 8. ) is formed on both sides, so that when gas pressure is applied to the gas pressure hole (332b), the airtight piece (332c) opens to both sides, thereby strengthening the airtightness between the outer peripheral surface of the slider (320) and the inner peripheral surface of the cylinder (200). A mold room 332 is installed.

However, it is preferable that each of the gas pressure holes (232b, 332b) is installed so that the open inlet faces the auxiliary gas chamber 410. This is because the gas pressure holes (232b, 332b) receive gas pressure, effectively ensuring airtightness. This is to make it happen.

In addition, a guide ring 270 and a dust seal 280 are installed between the upper through hole 220 of the first airtightness maintenance means 230 and the outer peripheral surface of the rod 300, so that the rod 300 moves up and down. In addition to making it smooth, it also prevented external foreign substances from flowing into each auxiliary gas chamber (410) and load gas chamber (340).

In one embodiment of the configuration of the dust seal 280, a seating groove 281 is formed on the upper inner peripheral surface of the cylinder 200, and the seating groove 281 has a seating groove 281 as shown in FIG. 9. ) is formed by forming a body 282 that is seated on the body 282 and an extension piece 283 that branches off from the body and whose tip is in close contact with the outer peripheral surface of the rod 300 so that foreign substances from the outside enter the auxiliary gas chamber 410 and the rod gas chamber. This was done to prevent it from flowing into (340).

In addition, the guide ring 360 is seated in the guide ring seating groove 361 between the lower slider 320 of the second airtightness maintenance means 330 and the inner peripheral surface of the cylinder 200, so that the slider 320 can be slid up and down. Up/down repetitive movements were made to occur smoothly.

In addition, it is preferable that each valve installed at each location of the gas spring of the present invention is installed through a sealing member to maintain airtightness.

As described above, the gas spring of the present invention, as explained in the above effect, allows the gas in the cylinder gas chamber and the gas in the auxiliary gas chamber provided inside the gas spring to move to each other by the gas return means installed inside the gas spring. After the gas cylinder processes the object to be processed, the rod is restored to its original position to control the restoration speed, and the rod of the gas spring reciprocates up and down in order to process the object into the desired structure. It has the advantage of allowing the rod to move up and down smoothly while preventing gas and gas from the auxiliary gas chamber from leaking to the outside.

200: Cylinder 210: Gas supply means
220: Through hole 230: First means of maintaining confidentiality
231: Seating groove 232: First cup-shaped chamber
240: Cylinder gas chamber 250: Lower cap
251: valve installation part 260: sealing member
270: guiding ring 280: dust seal
300: Rod 310: Tool installation part
320: Slider 330: Second means of maintaining confidentiality
331: Seating groove 332: Second cup type chamber
340: Load gas chamber 350: Discharge path
360: Guiding ring 400: Gas return means
410: Auxiliary gas chamber 420: Gas furnace
421,422,423: Line 430: Valve
440: blocking member 500: valve fixing means
510: coupling hole 520: coupling body
530: Valve 540: Valve seating groove
550: Valve fixing cover

Claims (10)

A gas supply means 210 for supplying gas to the cylinder gas chamber 240 is installed at the lower part, and a through hole 220 through which a rod reciprocates up and down is formed at the upper part, and a first airtightness maintaining means is formed in the through hole. A cylinder (200) in which (230) is installed and a cylinder gas chamber is provided inside;
By reciprocating up and down along the through hole, a tool installation part 310 is formed at the top, a slider 320 with a second airtightness maintenance means 330 installed at the bottom is formed, and a load gas chamber 340 is formed inside. and a rod 300 having an discharge passage 350 formed on one side of the rod gas chamber;
An auxiliary gas chamber 410 for receiving gas is provided between the upper part of the slider and the cylinder, and a gas furnace 420 is provided with a valve 430 for supplying gas from the auxiliary gas chamber to the cylinder gas chamber inside the body of the cylinder. regression means (400);
a valve means (500) installed on the slider to supply gas from the cylinder gas chamber to the load gas chamber when the gas pressure of the cylinder gas chamber is higher than a desired pressure; A gas spring characterized in that it consists of.
According to paragraph 1,
The gas supply means (210) is a gas spring, characterized in that installed on the valve installation portion (251) penetrating the center of the lower cap (250) installed at the lower part of the cylinder through a sealing member (260). According to paragraph 1,
The first airtightness maintenance means 230 is installed to prevent gas from the auxiliary gas chamber and the load gas chamber from leaking to the outside. A seating groove 231 is formed in the through hole, and a body (231) is formed in the seating groove. 232a) and an airtight piece 232c that forms a gas pressure hole 232b at the tip of the body are formed on both sides, so that when gas pressure is applied to the gas pressure hole, the airtight piece opens to both sides and the inner peripheral surface of the cylinder and the outer peripheral surface of the rod A gas spring characterized by consisting of a first cup-shaped chamber (232) that strengthens the airtightness of the liver.
According to claim 1 or 3,
A gas spring, characterized in that a guide ring (270) and a dust seal (280) are installed between the upper through hole of the first airtightness maintaining means (230) and the outer peripheral surface of the rod.
According to paragraph 1,
The second airtightness maintenance means 330 is to prevent gas from the auxiliary gas chamber and the cylinder gas chamber from leaking between the slider and the inner peripheral surface of the cylinder. A seating groove 331 is formed on the slider, and a body (331) is formed in the seating groove. 332a) and an airtight piece 332c that forms a gas pressure hole 332b at the tip of the body are formed on both sides, so that when gas pressure is applied to the gas pressure hole, the airtight piece opens to both sides and the outer peripheral surface of the slider and the inner peripheral surface of the cylinder A gas spring characterized by consisting of a second cup-shaped chamber (332) that strengthens the airtightness between the liver.
According to claim 1 or 5,
A gas spring, characterized in that a guide ring (360) is installed between the lower slider of the second airtightness maintenance means (330) and the inner peripheral surface of the cylinder.
According to paragraph 1,
The gas return means (400) is a gas spring, characterized in that a gas passage (420) in which a cylinder gas chamber and an auxiliary gas chamber are connected to each other is formed inside the body of the cylinder, and a valve (430) is installed on one side of the gas passage.
In clause 7,
In the gas furnace 420, the ends of the line 421 communicating with the auxiliary gas chamber and the line 422 communicating with the cylinder gas chamber are formed to communicate with the outside of the cylinder body, and the ends of each communicating line are formed with a blocking member ( 440) A gas spring characterized in that it is formed by blocking. In clause 7,
The valve 430 is a gas spring, characterized in that it is installed at the neck where the line 422 communicating with the cylinder gas chamber and the return line 423 formed in the cylinder body meet to adjust the amount of gas return.
According to paragraph 1,
In the valve means 500, a valve assembly 520 is installed in a coupling hole 510 penetrating the center of the slider, and a valve seating groove 530 is formed in the valve assembly to seat the valve 540, A gas spring, characterized in that the valve is fixed with a valve cover (560) via a spring (550).