KR101526714B1 - Variable volume gas lifter - Google Patents

Abstract

The present invention relates to a variable volumetric gas lifter capable of adjusting the internal volume of the cylinder to correspond to the pressure by changing the pressure in the cylinder by the temperature condition and moving the piston by the temperature compensating member provided in the cylinder under the temperature condition do. Therefore, the pressure changed by the temperature can be corrected by the amount of cylinder internal volume change, so that the reaction force of the gas lifter can be prevented from changing in accordance with the temperature condition.
In other words, a variable volume gas lifter that can solve the problem of excessive closure force generated during the summer season and lack of bearing capacity generated during the winter season is maintained with the reaction force of the gas spring maintained at an appropriate level even in a region where the temperature difference is large, such as during the summer and winter. do.

Description

[0001] VARIABLE VOLUME GAS LIFTER [0002]

The present invention relates to a variable volume gas lifter capable of maintaining a constant operating force regardless of temperature changes.

Generally, a gas lifter is used as an opening / closing device such as a hood or a trunk lid of an automobile.

As shown in FIG. 1, a conventional gas lifter is provided inside a cylinder 10 such that a piston 20 integrally formed with a rod 30 can reciprocate.

A fluid such as oil and gas is filled in the cylinder 10 and at least one orifice 22 is formed in the piston 20 so that the front and rear spaces of the piston 20 communicate with each other.

Such a gas lifter is configured such that the gas filled in the cylinder 10 as the rod 30 advances or retracts when opening or closing the hood or the luggage compartment lid is moved forward or rearward of the piston 20 through the orifice 22 of the piston 20 It is possible to perform the damping action when opening and closing the opening portion while moving, and to support the opening state of the opening portion.

The gas lifter provides a reaction force due to the opening and closing of the opening portion in proportion to the internal pressure, and the internal pressure is changed in accordance with the temperature change by the Boyle-Charles rule.

For example, when the temperature is 20 ° C at room temperature, the reaction force can be increased by about 22% as the internal temperature of the vehicle increases to 80 ° C in the summer. That is, as the pressure inside the cylinder increases, the corresponding reaction force becomes large, so that when the open portion is opened, the open portion is opened at an excessive speed, resulting in injury to the user, and a large force is required in closing the open portion. You can face a difficult situation.

Conversely, in winter the internal temperature of the vehicle will drop to a maximum of -40 ° C, at which point the reaction force can be reduced by up to 22%. That is, as the pressure inside the cylinder decreases, the operating force becomes small, which causes a problem that the opening portion moves too lightly. As a result, the reaction force for supporting the opening portion is insufficient.

In this way, the conventional gas lifter is sensitive to the ambient temperature, causing a problem of excessive closing force during the summer and insufficient support during the winter.

It should be understood that the foregoing description of the background art is merely for the purpose of promoting an understanding of the background of the present invention and is not to be construed as an admission that the prior art is known to those skilled in the art.

KR 10-2007-0055278 A (2007.05.30)

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve such a problem, and it is an object of the present invention to solve the problem of the difference in reaction force by compensating the pressure change due to the temperature by adjusting the volume in the cylinder, The present invention is directed to a variable volume gas lifter having a variable volume.

According to an aspect of the present invention, there is provided a variable volume gas lifter comprising: a cylinder having an inner space; A piston which is provided at a front end thereof with a rod which is exposed to the outside from the cylinder and which is provided at a rear end thereof with a piston which defines an internal space of the cylinder and which is moved forward and backward by a fluid inside the cylinder; And a temperature compensating member provided at the rear of the piston mechanism to partition the internal space of the cylinder and move in the direction corresponding to the piston mechanism in response to the temperature change.

The cylinder may consist of a first chamber defined by the piston of the piston mechanism, and a compensation chamber defined by the second chamber and the temperature compensating member.

A high-pressure fluid is filled in the first chamber and the second chamber of the cylinder, and the interior of the compensation chamber can be made low-pressure by circulating the atmosphere.

An atmospheric pressure holding hole is formed on the compensation chamber side of the cylinder so that the compensation chamber and the atmosphere can be circulated so that the interior of the compensation chamber can be maintained at atmospheric pressure.

Wherein the temperature compensating member includes a piston portion for defining a cylinder inner space, a bimetal having one end contacting the rear end of the piston portion and the other end supported in contact with the cylinder, Member.

The bimetallic member may be a bimetallic spring that is stretched and compressed in response to temperature to a temperature condition.

The bimetallic spring may be made of a metal having a high thermal expansion coefficient and a metal having a low thermal expansion coefficient, respectively.

The piston portion may include a head portion that is in close contact with the inner circumferential surface of the cylinder to block leakage of fluid and a body portion that extends toward the rear, and a guide portion that protrudes toward the piston portion and is formed to surround the body portion of the piston portion may be formed at a rear end of the cylinder. .

The bimetal member may be a bimetal spring, and the body portion of the piston portion and the guide portion of the cylinder may be inserted.

In the variable volume gas lifter constructed as described above, the pressure in the cylinder is changed by the temperature condition, and at the same time, the temperature compensating member provided in the cylinder is extended and compressed according to the temperature condition to move the piston so that the cylinder inner volume corresponds to the pressure Can be adjusted. Therefore, the pressure changed by the temperature can be corrected by the amount of cylinder internal volume change, so that the reaction force of the gas lifter can be prevented from changing in accordance with the temperature condition.

Accordingly, the reaction force of the gas spring is maintained at an appropriate level even in a region where the temperature difference is large, such as during the summer and the winter season, thereby overcoming the problem of excessive closing force generated during the summer season and insufficient bearing capacity caused during the winter season.

1 shows a conventional gas lifter;
Figures 2 to 3 illustrate a variable volume gas lifter according to one embodiment of the present invention.
Fig. 4 shows the temperature compensating member of the variable volume gas lifter shown in Fig. 2; Fig.
5 shows the operation of the variable volume gas lifter of the present invention with temperature.

Hereinafter, a variable volume gas lifter according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

2 to 3 are views showing a variable volume gas lifter according to an embodiment of the present invention, FIG. 4 is a view showing a temperature compensating member of the variable volume gas lifter shown in FIG. 2, and FIG. FIG. 3 is a view showing operation of a volumetric gas lifter according to temperature, wherein the variable volume gas lifter of the present invention comprises: a cylinder 100 having an inner space; A rod 220 is disposed at the front end of the cylinder 100 and exposed to the outside of the cylinder 100. A piston 240 separating the inner space of the cylinder 100 is provided at the rear end of the rod, A piston mechanism 200 to be moved; And a temperature compensating member 300 provided at the rear of the piston mechanism 200 to partition the internal space of the cylinder 100 and move in a direction corresponding to the piston mechanism 200 in response to a temperature change.

In the present invention, a cylinder 100 having an internal space and a fluid such as gas and oil is provided in the internal space, and a rod 220 and a piston 240 are provided in the cylinder 100, A piston mechanism 200 for transmitting operating force by the fluid during the pressing and pulling operation of the piston mechanism 220 and a temperature compensating member for changing the piston mechanism 200 according to the temperature condition.

That is, in the prior art, only the piston 240 having the rod 220 formed inside the cylinder 100 moves the piston 240 to open and close the opening portion such as the trunk lid or the hood. However, The pressure is changed and the operating force is changed.

In the present invention, the temperature compensating member 300 is provided inside the cylinder 100 to reduce the volume of the cylinder 100 when the temperature is low, thereby inducing an increase in pressure due to the decrease in the internal volume, In the case of a high temperature, it is possible to increase the volume inside the cylinder 100 to induce a decrease in pressure due to an increase in internal volume, thereby compensating for a change in operating force according to a temperature difference, thereby providing a constant operating force of the gas lifter.

The cylinder 100 includes a first chamber 120 partitioned by a piston 240 of a piston mechanism 200, a second chamber 140, and a temperature compensating member 300, And a compensation chamber 160 partitioned by a plurality of pressure chambers.

The first chamber 120 and the second chamber 140 of the cylinder 100 are filled with a high-pressure fluid, and the interior of the compensation chamber 160 may be a low-pressure chamber.

The first chamber 120 and the second chamber 140 partitioned by the piston 240 of the piston mechanism 200 are filled with fluid and the rod 220 of the piston mechanism 200 is pulled and pressed As the piston moves within the cylinder 100, a reaction force due to expansion and compression of the fluid is formed.

In the present invention, the temperature compensating member 300 is further provided inside the cylinder 100, and the compensation chamber 160 partitioned by the temperature compensating member 300 is provided. The compensation chamber 160 ensures a space in which the temperature compensating member 300 can move forward and backward within the cylinder 100. The compensating chamber 160 circulates the atmosphere so that the temperature compensating member 300 can be moved smoothly in the front- The atmospheric pressure can be maintained.

An atmospheric pressure holding hole 162 is formed in the compensation chamber 160 of the cylinder 100 so that the compensation chamber 160 and the atmosphere can be circulated so that the interior of the compensation chamber 160 can be maintained at atmospheric pressure .

That is, when the temperature compensating member 300 moves due to the temperature change, the compensating chamber 160 moves the atmosphere through the atmospheric pressure maintaining hole 162 to keep the atmospheric pressure, The movement of the compensating member 300 can be prevented from being restricted.

Here, the compensation chamber 160 is a target for maintaining the atmospheric pressure and maintaining the low pressure so as not to be affected by the high-pressure portions of the first chamber 120 and the second chamber 140, and is a most preferred embodiment . The compensation chamber 160 may be filled with a low-pressure fluid under a condition that the high-pressure region of the first chamber 120 and the second chamber 140 is not affected.

The temperature compensating member 300 includes a piston 320 which defines an internal space of the cylinder 100 and a piston 320 which is in contact with the rear end of the piston 320 and whose other end is in contact with the cylinder 100 And a bimetal member 340 whose length changes in the forward and backward directions depending on a temperature condition in response to a temperature change.

That is, the temperature compensating member 300 is provided with a bimetal member 340 having a variable length depending on the temperature. As the length of the bimetal member 340 increases or decreases with the temperature change, the piston 320 is moved The volume of the internal space of the cylinder 100 can be increased or decreased. As the volume of the internal space increases, the internal pressure of the cylinder 100 decreases as the volume increases. As the volume decreases, the internal pressure of the cylinder 100 decreases.

In detail, the bimetal member 340 may be a bimetal spring which is expanded and compressed in response to a temperature according to a temperature condition. The bimetallic spring 340 may be made of a metal having a high thermal expansion coefficient and a metal having a low thermal expansion coefficient.

As described above, the bimetallic spring is made of a metal having a different thermal expansion coefficient. The bimetallic spring has a property that the inner metal has a high coefficient of thermal expansion, and the outer metal has a property of having a low coefficient of thermal expansion relative to the inner metal.

Because of this, in the region of high temperature, the thermal expansion coefficient of the inner metal is relatively higher than the thermal expansion coefficient of the outer metal, so the height decreases while increasing the outer diameter of the spring. In the low temperature region, the outer diameter decreases and the height increases .

In addition, the bimetal spring must be set to have a higher reaction force than the pressure inside the cylinder 100. That is, by setting the reaction force higher than the internal pressures of the first chamber 120 and the second chamber 140 of the cylinder 100, the length of the spring can be prevented from being changed by the internal pressure of the cylinder 100.

By providing the bimetal spring inside the cylinder 100, the internal pressure of the cylinder 100 is reduced when the external temperature is lowered, and the length of the bimetal spring is increased by the lower temperature, The amount of pressure change can be canceled as the volume inside the chamber 100 is reduced.

On the contrary, when the external temperature is increased, the internal pressure of the cylinder 100 is increased, and when the length of the bimetal spring is decreased by the increased temperature, the piston portion 320 can compensate for the pressure change by increasing the volume inside the milling cylinder 100.

The piston 320 includes a head portion 322 that is in close contact with the inner circumferential surface of the cylinder 100 to block leakage of fluid and a body portion 324 that extends toward the rear, A guide portion 180 may be formed to protrude toward the piston portion 320 and surround the body portion 324 of the piston portion 320.

In other words, the head portion 322 of the piston portion 320 divides the internal space of the cylinder 100 into the second chamber 140 and the compensation chamber 160, and prevents the fluid and air from flowing into the respective spaces . A separate sealing member may be further provided on the head portion 322 of the piston 320 to increase the sealing effect. The body portion 324 is formed to have a width that is less than the width of the head portion 322 and extends a predetermined length backward from the head portion 322 of the piston portion 320.

A guide portion 180 is formed at the rear end of the cylinder 100 so as to protrude in a direction corresponding to the body portion 324 of the piston portion 320 and surround the body portion 324 of the piston portion 320 . The guide portion 180 is formed so that the body portion 324 of the piston portion 320 is slidable therein so that the body portion moves along the guide portion 180 when the piston portion 320 is moved, So that stable sliding movement can be performed without any change of the sliding position.

The bimetal member 340 may be a bimetal spring and may be inserted into the body portion 324 of the piston portion 320 and the guide portion 180 of the cylinder 100.

By providing the bimetal spring around the axis of the body part of the piston part 320 and the guide part 180 of the cylinder 100, the variable operation of the bimetal spring can be accurately operated in the longitudinal direction of the cylinder 100 And the bimetal spring is located at the center, so that the outer circumferential surface is not brought into contact with the inner circumferential surface of the cylinder 100, thereby ensuring durability.

Operation of the present invention will now be described with reference to FIG. 5. At ambient temperature, the fluid in the cylinder 100 is not changed by temperature, and the operating force of the gas lifter is not changed.

At low temperatures such as in the winter season, the operating force is reduced as the fluid in the cylinder 100 reacts to the external temperature and the pressure is reduced. At this time, the bimetal spring of the temperature compensating member 300 provided inside the cylinder 100 is extended in the low temperature region to increase the length thereof, thereby pushing the piston portion 320 to move the first chamber 120 of the cylinder 100, Thereby reducing the volume of the two chamber 140. As the volume of the first chamber 120 and the second chamber 140 decreases, the pressure inside the cylinder 100 increases, thereby compensating the reduced pressure reduction in the low temperature region to compensate the operating force.

Conversely, at high temperatures such as during the summer, the operating force is increased as the fluid in the cylinder 100 reacts with a high external temperature to increase the pressure. At this time, the bimetal spring of the temperature compensating member 300 provided inside the cylinder 100 is compressed in the high temperature region to be shortened in length, so that the pressure of the first chamber 120 and the second chamber 140 The piston 320 is pushed toward the bimetal member 340 by the first and second chambers 120 and 140 to increase the volume of the first chamber 120 and the second chamber 140 of the cylinder 100. As the volume of the first chamber 120 and the second chamber 140 increases, the pressure inside the cylinder 100 is reduced to compensate for the increased pressure in the high temperature region to compensate for the operating force.

In the variable volume gas lifter constructed as described above, the temperature in the cylinder 100 is changed by the temperature condition, and the temperature compensating member 300 provided in the cylinder 100 is expanded and compressed according to the temperature condition to move the piston The internal volume of the cylinder 100 can be adjusted to correspond to the pressure. Therefore, the pressure changed by the temperature can be corrected by the amount of change in the volume of the cylinder 100, so that the reaction force of the gas lifter can not be changed finally according to the temperature condition.

Accordingly, the reaction force of the gas spring is maintained at an appropriate level even in a region where the temperature difference is large, such as during the summer and the winter season, thereby overcoming the problem of excessive closing force generated during the summer season and insufficient bearing capacity caused during the winter season.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

100: cylinder 120: first chamber
140: second chamber 160: compensation chamber
162 atmospheric pressure holding hole 180: guide portion
200: piston mechanism 220: rod
240: piston 300: temperature compensating member
320: piston part 340: bimetal member

Claims (9)

A cylinder having an inner space;
A rod 220 is disposed at the front end of the cylinder 100 and exposed to the outside of the cylinder 100. A piston 240 separating the inner space of the cylinder 100 is provided at the rear end of the rod, A piston mechanism 200 to be moved; And
And a temperature compensating member 300 provided at the rear of the piston mechanism 200 to partition the internal space of the cylinder 100 and move in a direction corresponding to the piston mechanism 200 in response to a temperature change,
The cylinder 100 is divided into a first chamber 120 defined by the piston 240 of the piston mechanism 200 and a compensation chamber 160 defined by the second chamber 140 and the temperature compensating member 300 Lt; / RTI &
Wherein a high-pressure fluid is filled in the first chamber (120) and the second chamber (140) of the cylinder (100), and the interior of the compensation chamber (160) Gas lifter. delete delete The method according to claim 1,
Pressure holding hole 162 is formed in the compensation chamber 160 side of the cylinder 100 so that the compensation chamber 160 and the atmosphere can be circulated so that the interior of the compensation chamber 160 is maintained at atmospheric pressure. Gas lifter. The method according to claim 1,
The temperature compensating member 300 includes a piston 320 which defines an internal space of the cylinder 100,
And a bimetal member 340 whose one end is in contact with the rear end of the piston part 320 and the other end thereof is in contact with the cylinder 100 and which is supported in contact with the cylinder 100 and whose length changes in the forward and backward direction in response to a temperature change. And a gas-liquid separator. The method of claim 5,
Wherein the bimetal member (340) is a bimetallic spring that is responsive to temperature and stretched and compressed according to temperature conditions. The method of claim 6,
Wherein the bimetallic spring is made of a metal having a relatively high thermal expansion coefficient and a metal having a relatively low thermal expansion coefficient. The method of claim 5,
The piston portion 320 is composed of a head portion which is in close contact with the inner circumferential surface of the cylinder 100 to block the leakage of the fluid and a body portion extending toward the rear,
Wherein a guide part (180) is formed at a rear end of the cylinder (100) to protrude toward the piston part (320) and surround the body part of the piston part (320). The method of claim 8,
Wherein the bimetal member (340) is a bimetal spring, and the body portion of the piston portion (320) and the guide portion (180) of the cylinder (100) are inserted.

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