DE202019107007U1 - Air spring device - Google Patents

Abstract

Air spring device comprising:
an auxiliary chamber configured to store air;
a main chamber formed in a bellows part and configured to store air; and
a rotary solenoid valve which is arranged between the auxiliary chamber and the main chamber and which is designed to selectively connect the auxiliary chamber and the main chamber to one another,
the rotary solenoid valve having:
a hollow housing which is arranged on a connecting part between the auxiliary chamber and the main chamber and is provided with an opening formed therein; and
a locking member rotatably disposed in the housing and rotated to connect or disconnect the auxiliary chamber and the main chamber with each other, so that an air flow through the opening is selectively enabled.

Description

Background of the Invention

Technical field

Embodiments of the present disclosure relate to an air spring device, and more particularly, to an air spring device capable of suppressing the occurrence of vibrations and noises during operation.

State of the art

In general, a suspension system of a vehicle connects an axle and a vehicle body and suitably dampens vibrations or shocks applied to the axle while driving from the road, thereby reducing body damage and improving driving comfort.

Among the suspension systems, an air suspension system with an air spring device used therein can adjust a vehicle height according to a driving state of the vehicle and, due to the properties of the air spring device, can offer better driving comfort than a coil spring.

A valve used in the air spring device opens or closes a flow path to change the volume of an air chamber. Here, a rod of the valve that opens or closes the flow path is moved linearly to cause an impact force. Such an impact force can generate vibrations and noises to the outside. In unfavorable cases, the valve can be damaged by the impact force. There is therefore a need for a structure that is capable of solving the problem.

Overview of the invention

Various embodiments relate to an air spring device that can use a rotary solenoid valve when opening / closing a flow path, thereby suppressing the occurrence of vibrations and noises during operation.

In one embodiment, an air spring device may include: an auxiliary chamber configured to store air; a main chamber formed in a bellows part and configured to store air; and a rotary solenoid valve which is arranged between the auxiliary chamber and the main chamber and which is designed to selectively connect the auxiliary chamber and the main chamber to one another. The rotary solenoid valve may include: a hollow housing which is disposed on a connecting part between the auxiliary chamber and the main chamber and is provided with an opening formed therein; and a locking member rotatably disposed in the housing and rotated to connect or disconnect the auxiliary chamber and the main chamber with each other, so that an air flow through the opening is selectively allowed.

The housing may be in the form of a hollow column, and the blocking member may have a communication flow path formed therein and rotated to selectively connect the opening and the communication flow path.

The opening may include: one or more first openings facing the auxiliary chamber; and one or more second openings facing the main chamber.

The communication flow path may be arranged to overlap the first opening and the second opening when the auxiliary chamber and the main chamber are connected, and may be arranged so that it does not overlap the first opening when the auxiliary chamber and the main chamber are separated are.

The connection flow path of the blocking part can completely overlap the first opening when the auxiliary chamber and the main chamber are connected to each other.

The blocking part may be spherical, and the connecting flow path may be L-shaped such that one side thereof faces the first opening and the other side thereof faces the second opening.

In one embodiment, an air spring device may include: an auxiliary chamber configured to store air; a main chamber formed in a bellows part and configured to store air; and a rotary solenoid valve which is arranged between the auxiliary chamber and the main chamber and which is designed to selectively open or close a flow path which connects the auxiliary chamber and the main chamber. The rotary solenoid valve may include: a hollow housing disposed in the flow path and having an opening; and a blocking member rotatably installed in the housing and rotated to open or close the flow path so that an air flow through the opening is selectively enabled.

The housing can be designed as a hollow cylinder and the locking part can have: a rotating shaft rotatably installed in the center of the housing; and locking plates that extend outward from the rotating shaft in two or more directions and abut an inner wall of the housing.

The opening may include: one or more first openings facing the auxiliary chamber; and one or more second openings facing the main chamber.

The barrier plates may be arranged to overlap the first opening and the second opening when the flow path is open, and they may be arranged to not overlap the first opening and the second opening when the flow path is closed.

The lock plates can extend in two directions from the rotating shaft and the angle between the two lock plates can be 180 degrees.

The first opening and the second opening can be arranged on the same line as seen from the bottom. When the flow path is open, the barrier plates may be located in the middle of the first opening and the second opening.

According to the embodiments of the present disclosure, the rotary solenoid valve can be rotated to selectively allow or block air flow, thereby suppressing an impact force during operation of the rotary solenoid valve.

Therefore, it is possible to suppress the occurrence of vibrations and noises in the operation of the air spring device, and to prevent the rotary solenoid valve from being damaged.

Furthermore, it is possible to prevent the rotary solenoid valve from malfunctioning while reducing the energy consumption.

list of figures

• 1 12 is a cross-sectional perspective view schematically illustrating an air spring device according to an embodiment of the present disclosure.
• 2 12 is a cross-sectional view schematically showing the air spring device according to the embodiment of the present disclosure.
• 3 10 is an enlarged cross-sectional perspective view showing a portion around a rotary solenoid valve in the air spring device according to the embodiment of the present disclosure.
• 4 FIG. 12 is an enlarged cross sectional view showing the area around the rotary solenoid valve in the air spring device according to the embodiment of the present disclosure.
• 5 FIG. 12 is a perspective view illustrating that the rotary solenoid valve according to the embodiment of the present disclosure connects an auxiliary chamber and a main chamber.
• 6 FIG. 12 is a bottom view showing that the rotary solenoid valve in the embodiment of the present disclosure connects the auxiliary chamber and the main chamber.
• 7 11 is a perspective view showing that the rotary solenoid valve separates the auxiliary chamber and the main chamber from each other according to the embodiment of the present disclosure.
• 8th 14 is a bottom view showing that the rotary solenoid valve separates the auxiliary chamber and the main chamber from each other according to the embodiment of the present disclosure.
• 9 10 is an enlarged cross-sectional perspective view showing a portion around a rotary solenoid valve in the air spring device according to another embodiment of the present disclosure.
• 10 FIG. 12 is an enlarged cross sectional view showing the area around the rotary solenoid valve in the air spring device according to the embodiment of the present disclosure.
• 11 FIG. 12 is a perspective view illustrating that the rotary solenoid valve according to the embodiment of the present disclosure connects an auxiliary chamber and a main chamber.
• 12 FIG. 12 is a bottom view showing that the rotary solenoid valve in the embodiment of the present disclosure connects the auxiliary chamber and the main chamber.
• 13 11 is a perspective view showing that the rotary solenoid valve separates the auxiliary chamber and the main chamber from each other according to the embodiment of the present disclosure.
• 14 14 is a bottom view showing that the rotary solenoid valve separates the auxiliary chamber and the main chamber from each other according to the embodiment of the present disclosure.

Detailed description

An air spring device is described below with reference to the associated drawings using various exemplary embodiments. It should be noted that the drawings are not to scale and that the thickness of lines or the size of components may be exaggerated only for better description and clarity.

Furthermore, the terms used here are defined taking into account functions of the disclosure and can be changed according to the habits or intentions of users or operators. The definition of the terms should therefore be in accordance with the present overall disclosure.

1 12 is a cross-sectional perspective view schematically showing an air spring device according to an embodiment of the present disclosure; 2 12 is a cross-sectional view schematically showing the air spring device according to the embodiment of the present disclosure; 3 16 is an enlarged cross-sectional perspective view showing an area around a rotary solenoid valve in the air spring device according to the embodiment of the present disclosure; 4 16 is an enlarged cross-sectional view showing the area around the rotary solenoid valve in the air spring device according to the embodiment of the present disclosure; 5 12 is a perspective view showing that the rotary solenoid valve connects an auxiliary chamber and a main chamber to each other according to the embodiment of the present disclosure, 6 12 is a bottom view showing that the rotary solenoid valve in the embodiment of the present disclosure connects the auxiliary chamber and the main chamber. 7 12 is a perspective view showing that the rotary solenoid valve separates the auxiliary chamber and the main chamber from each other in the embodiment of the present disclosure, and FIG 8th 14 is a bottom view showing that the rotary solenoid valve separates the auxiliary chamber and the main chamber from each other according to the embodiment of the present disclosure.

Referring to the 1 and 2 The air spring device according to the embodiment of the present disclosure has a structure in which a piston 40 into one end of a bellows part 10 is inserted and the other end of the bellows part 10 through a cap 30 is closed to seal the inside of the air spring device. Outside the bellows part 10 a protective device is provided to prevent damage to the bellows part 10 prevent while blocking the entry of foreign matter.

The air spring device is on a lower arm 60 attached and is mounted on each wheel. In other words, a total of four air suspension devices can be attached to the front left wheel, the front right wheel, the rear left wheel and the rear right wheel of the vehicle.

The air spring device according to the embodiment of the present invention has a main chamber 310 , an auxiliary chamber 320 and a rotary solenoid valve 100 on.

The main chamber 310 is in the bellows part 10 educated. As in 2 the main chamber can be shown 310 through the bellows part 10 be limited. The main chamber 310 has an interior 315 that contains air while being tight to the outside.

The auxiliary chamber 320 can in the flask 40 be trained. As in 2 the auxiliary chamber can be shown 320 in an auxiliary chamber housing 50 be formed by the piston 40 is formed separately. The auxiliary chamber housing 50 and the piston 40 can be formed as one body.

Referring to the 3 and 4 can the auxiliary chamber housing 50 be designed in the form of a hollow column with an open bottom. According to one embodiment, the auxiliary chamber housing 50 a hollow cylindrical side wall plate 52 , one the top end of the side panel 52 closing top plate 52 , and a partition plate 53 on that between the top end and the bottom end of the side wall panel 52 is arranged.

The partition plate 53 has a hole formed in the center thereof and has a protrusion extending downward 54 connected. The lead 54 may have an inside diameter equal to the diameter of the hole in the partition plate 53 is.

The auxiliary chamber 320 can through the top plate 51 who have favourited Side Wall Plate 52 and the partition plate 53 be limited. The interior 325 the auxiliary chamber 320 contains air while it is locked out. The auxiliary chamber 320 can with the main chamber 310 about the lead 54 be connected.

As in the 3 to 8th shown, the rotary solenoid valve 100 according to the embodiment of the present disclosure between the main chamber 310 and the auxiliary chamber 320 be arranged and the main chamber 310 and the auxiliary chamber 320 either connect or disconnect. Operation of the rotary solenoid valve 100 can be controlled by an electronic control unit (not shown).

The rotary solenoid valve 100 according to the present embodiment has a magnetic body 110 , a housing 120 and a locking part 130 on.

The magnetic body 110 has a (not shown) drive unit, the locking part 130 supplied with rotational energy. The magnetic body 110 can be connected to the electronic control unit and the locking part 130 Apply turning energy under operational control by the electrical control unit.

The housing 120 is on a connecting part between the auxiliary chamber 320 and the main chamber 310 arranged. The housing 120 can be in the form of a hollow column and openings 121 and 122 exhibit. The openings 121 and 122 can a first opening 121 and a second opening 122 exhibit. In the present embodiment, the housing 120 on a base plate 111 of the magnetic body 110 appropriate.

The first opening 121 can in a side surface of the housing 120 be designed so that they the auxiliary chamber 320 is facing. The housing 120 can be a first opening 121 or two or more first openings 121 exhibit.

The second opening 122 can in the bottom surface of the case 120 be designed such that they are the main chamber 310 is facing. The housing 120 can have a second opening 122 or two or more second openings 122 exhibit.

The housing 120 is in the auxiliary chamber 320 arranged, and the bottom surface of the housing 120 that closes in the middle of the partition plate 53 formed hole. Because the auxiliary chamber 320 through the top plate 51 who have favourited Side Wall Plate 52 and the partition plate 53 is formed such that it is blocked from the outside, the auxiliary chamber 320 and the main chamber 310 just over the case 120 be connected to each other.

The locking part 130 is rotatable in the housing 120 built-in. The locking part 130 is rotated to the auxiliary chamber 320 and the main chamber 310 connect or disconnect from each other such that air flows through the openings 121 and 122 is selectively possible.

The locking part 130 can be spherical. The locking part 130 has a connection flow path formed therein 133 on. The connection flow path 133 has an auxiliary chamber communication hole 131 formed at one end thereof and a main chamber communication hole 132 formed at the other of its ends.

When turning the locking part 130 in the housing 120 can the connecting flow path 133 selective with the openings 121 and 122 connected or disconnected from them.

The connection flow path 133 may have an L-shaped structure in which the auxiliary chamber communication hole is formed on one side thereof 131 the first opening 121 faces and the main chamber communication hole formed on the other side thereof 132 the second opening 122 is facing.

The locking part 130 can be spherical, and that in the locking part 130 trained L-shaped connection flow path 133 can be arranged so that it with the openings 121 and 122 is connected, whereby the auxiliary chamber 320 and the main chamber 310 are interconnected. Conversely, if the connection flow path 133 and the openings 121 and 122 are arranged so that they are not connected to each other, are the auxiliary chamber 320 and the main chamber 310 not connected.

Because the connection flow path 133 in the locking part 130 is formed, it is preferred 133 also by turning the locking part 130 turned. In the present embodiment, the main chamber communication hole is 132 arranged so that it with the second opening 122 is connected at all times.

Although the locking part 130 is rotated in any direction is the main chamber communication hole 132 arranged so that it is the second opening 122 overlaps. Therefore the connection between the auxiliary chamber is decided 320 and the main chamber 310 after that whether the auxiliary chamber connection hole 131 is arranged so that it is the first opening 121 overlaps.

As in the 5 and 6 the main chamber connection hole is shown 132 when the auxiliary chamber communication hole 131 the first opening 121 is arranged overlapping, arranged such that it is the second opening 122 overlaps. So the auxiliary chamber 320 with the main chamber 310 via the connecting flow path 133 connected. That means that if the auxiliary chamber 320 and the main chamber 310 are interconnected the connection flow path 133 is arranged so that it has the first opening 121 and the second opening 122 overlaps.

Although the auxiliary chamber connection hole 131 is arranged so that it is the first opening 121 partially overlap, the auxiliary chamber 320 through the connecting flow path 133 with the main chamber 131 get connected. If the auxiliary chamber connection hole 131 is arranged so that it is the first opening 121 completely overlapped as in 6 As shown, an air flow moves more smoothly through the connection flow path 133 , Therefore, the response speed can be improved during the operation control of the air spring device.

If the main chamber 310 and the auxiliary chamber 320 are connected to each other, the air volume of the air spring device corresponds to the sum of the interior 315 the main chamber 310 and the interior 325 the auxiliary chamber 320 , In this way, the air volume of the air spring device is increased more than if only the interior 315 the main chamber 310 is used. Therefore, the vibration and the shock absorbing force of the air spring device can be further improved.

As in the 7 and 8th the auxiliary chamber is shown 320 when the auxiliary chamber communication hole 131 is arranged so that it is the first opening 121 not overlapped, not with the main chamber 310 connected though the main chamber connection hole 132 the second opening 122 is arranged overlapping. That means that if the auxiliary chamber 320 and the main chamber 310 are separated from each other, the connection flow path 133 is arranged so that it has the first opening 121 not overlapped.

If the main chamber 310 and the auxiliary chamber 320 are not connected to each other, the air volume of the air spring device is equal to the interior 315 the main chamber 310 , Thus, the air spring device absorbs vibration and shock using only the main chamber 310 ,

The electronic control unit can operate the rotary solenoid valve 100 control based on vehicle height information obtained from a vehicle height sensor attached to the vehicle body. Through this process, the electronic control unit can control the main chamber 310 and the auxiliary chamber 320 connect or disconnect from each other to adjust the vehicle height of the vehicle body depending on an operating situation.

If the magnetic body 110 Energy is supplied, the locking part 130 rotated by a predetermined angle by operating the drive unit. Thus, the auxiliary chamber 320 and the main chamber 310 connected to or separated from one another during the connection flow path 133 is rotated.

According to the present embodiment, since the auxiliary chamber 320 and the main chamber 310 by turning the rotary solenoid valve 100 connected or disconnected from each other, an impact force during operation of the air spring device can be reduced.

In the present embodiment, it has been described that the air spring device is an auxiliary chamber 320 having. However, the present embodiment is not limited to this, but the air spring device can have two auxiliary chambers 320 or three or more auxiliary chambers 320 exhibit.

9 16 is an enlarged cross-sectional perspective view showing an area around a rotary solenoid valve in the air spring device according to another embodiment of the present disclosure; 10 16 is an enlarged cross-sectional view showing the area around the rotary solenoid valve in the air spring device according to the embodiment of the present disclosure; 11 12 is a perspective view showing that the rotary solenoid valve connects an auxiliary chamber and a main chamber to each other according to the embodiment of the present disclosure, 12 12 is a bottom view showing that the rotary solenoid valve in the embodiment of the present disclosure connects the auxiliary chamber and the main chamber. 13 12 is a perspective view showing that the rotary solenoid valve separates the auxiliary chamber and the main chamber from each other in the embodiment of the present disclosure, and FIG 14 14 is a bottom view showing that the rotary solenoid valve separates the auxiliary chamber and the main chamber from each other according to the embodiment of the present disclosure.

The air spring device according to the present embodiment has a main chamber 310 , an auxiliary chamber 320 and a rotary solenoid valve 200 on. Since the air spring device according to the present embodiment except for the rotary solenoid valve 200 has the same structure as the air spring device according to the previously described embodiment, the description of overlapping contents is omitted.

As in the 9 to 14 the rotary solenoid valve can be shown 200 according to the present embodiment between the main chamber 310 and the auxiliary chamber 320 disposed be and the main chamber 310 and the auxiliary chamber 320 selectively connect or disconnect from each other by creating a flow path P which is the main chamber 310 and the auxiliary chamber 320 connects, selectively opens or closes. Operation of the rotary solenoid valve 200 can be controlled by an electronic control unit (not shown).

The rotary solenoid valve 200 according to the present embodiment has a magnetic body 210 , a housing 220 and a locking part 230 on.

The magnetic body 210 has a drive unit (not shown) around the locking part 230 To supply rotational energy. The magnetic body 210 can be connected to an electrical control unit and the locking part 230 Apply turning energy under operational control by the electronic control unit.

Gas casing 220 is on a connecting part between the auxiliary chamber 320 and the main chamber 310 arranged. That means the housing 220 between the auxiliary chamber 320 and the main chamber 310 is arranged and the interior of the housing 220 in the flow path P is arranged, the auxiliary chamber 320 and the main chamber 310 connects with each other.

The housing 220 can be hollow cylindrical and openings 221 and 222 exhibit. The openings 221 and 222 have a first opening 221 and a second opening 222 on. In the present embodiment, the housing 220 on a base plate 211 of the magnetic body 210 appropriate.

The first opening 221 can in a side surface of the housing 220 be designed so that they the auxiliary chamber 320 is facing. The housing 220 can be a first opening 221 or two or more first openings 221 exhibit.

The second opening 222 can in the bottom surface of the case 220 be designed such that they are the main chamber 310 is facing. The housing 220 can have a second opening 222 or two or more second openings 222 exhibit.

The housing 220 is in the auxiliary chamber 320 arranged and the bottom surface of the housing 220 includes in the middle of the partition plate 53 formed hole. Because the auxiliary chamber 320 through the top plate 51 who have favourited Side Wall Plate 52 and the partition plate 53 is limited so that it is locked to the outside, the auxiliary chamber can 320 and the main chamber 310 just over the case 220 be connected to each other.

The locking part 230 is rotatable in the housing 220 built-in. The locking part 230 is rotated to the auxiliary chamber 320 and the main chamber 310 connect or disconnect from each other such that air flows through the openings 221 and 222 is selectively possible. That is, the locking part 230 can the auxiliary chamber 320 and the main chamber 310 connect or disconnect from each other by placing it inside the case 220 formed flow path P opens or closes.

In the present embodiment, the locking part 230 a rotating shaft 231 and a locking plate 232 on. The rotating shaft 231 is rotatable in the middle of the housing 220 appropriate. The locking plate 232 extends from the rotating shaft 231 outwards and lies on the inner wall of the housing 220 on.

One end of the lock plate 232 is with the rotating shaft 231 connected and the other end lies on the inner wall of the housing 220 on. The locking plate 232 blocks air flow between one end of the lock plate 232 and the inner wall of the housing 220 while on the inside wall of the case 220 is applied.

The locking plate 232 can extend outward in two or more directions around the rotating shaft 231 extend. In the present embodiment, two locking plates extend 232 in two directions outwards, and the angle between the two locking plates 232 is set to 180 degrees. In addition, three or more locking plates 232 be provided which extend outward in three or more different directions.

When turning the locking plates 232 in the housing 220 around the rotating shaft 231 , the flow path P can be selectively opened or closed. Depending on the positions where the locking plates 232 in the housing 220 are arranged, the auxiliary chamber 320 and the main chamber 310 connected or separated from each other.

If the locking plates 232 are arranged so that the flow path P between the first and second openings 221 and 222 lock, are the auxiliary chamber 320 and the main chamber 310 separated from each other. If, however, the locking plates 232 are arranged so that the flow path P between the first and second openings 221 and 222 not lock, are the auxiliary chamber 320 and the main chamber 310 connected with each other.

As in the 11 and 12 are shown when a locking plate 232 the first opening 221 is overlapping and the other locking plate 232 the second opening 222 is arranged to overlap, the first and the second opening 221 and 222 with each other through the interior of the housing 220 connected.

Because the locking plates 232 are arranged so that they the flow path P not close, is the auxiliary chamber 320 through the flow path P with the main chamber 310 connected. If the flow path P the locking plates can be opened 232 be arranged so that they have the first and second openings 221 and 222 overlap.

If, in the event that the angle between the two locking plates 232 Is 180 degrees, which is a locking plate 232 in the middle of the first opening 221 is arranged and the other locking plate 232 in the middle of the second opening 222 is arranged, the air due to each of the locking plates 232 are divided equally, and thus are moved more smoothly, thereby making it possible to improve the response speed during the operation control of the air spring device.

The first and the second opening 221 and 222 can be arranged on the same line when viewed from below. If that's a locking plate 232 in the middle of the first opening 221 is arranged and the other locking plate 232 located in the middle of the second opening are therefore the left and right areas of each of the locking plates 232 divided such that they are symmetrical to each other. It is thus possible to make differences between the amount and the speed of the left path of the locking plate 232 air moved and the amount and speed of the right path of the locking plate 232 reduce moving air.

If the main chamber 310 and the auxiliary chamber 320 are connected to each other, the air volume of the air spring device corresponds to the sum of the interior 315 the main chamber 320 and the interior 325 the auxiliary chamber 320 , In this way, the air volume of the air spring device is increased more than if only the interior 315 the main chamber 310 is used. The vibration and shock absorption force of the air spring device can therefore be further improved.

As in the 13 and 14 are shown if the one locking plate 232 is arranged so that it is the first opening 221 not overlapped, and the other locking plate 232 is arranged to have the second opening 222 are not overlapped, the first and the second opening 221 and 222 through the locking plates 232 isolated from each other. Because the locking plates 232 to close the flow path P are arranged is the auxiliary chamber 320 over the flow path P not with the main chamber 310 connected.

Therefore, the in the housing 220 through the first opening 221 air introduced through the barrier plates 232 blocked so that they are not towards the second opening 222 can move. The second opening is similar 22 in the housing 220 air introduced through the barrier plates 232 blocked so that it cannot move towards the first opening.

If the main chamber 310 and the auxiliary chamber 520 are not connected to each other, the air volume of the air spring device is equal to the interior 315 the main chamber 310 , Thus, the air spring device absorbs vibration and shock using only the main chamber 310 ,

The electronic control unit can operate the rotary solenoid valve 200 control based on vehicle height information obtained from the vehicle height sensor attached to the vehicle body. Through this process, the electronic control unit can control the main chamber 310 and the auxiliary chamber 320 connect or disconnect to adjust the vehicle body height depending on the operating situation.

When on the magnetic body 210 Energy is supplied, the blocking part 230 rotated by a predetermined angle by operating the drive unit. The auxiliary chamber 320 and the main chamber 310 are connected or separated from each other in this way.

According to the embodiments of the present disclosure, since the auxiliary chamber 320 and the main chamber 310 by turning the rotary solenoid valve 200 connected or disconnected from each other, an impact force during operation of the air spring device can be reduced.

In the present embodiment, it has been described that the air spring device is an auxiliary chamber 320 having. However, the present embodiment is not limited to this, but the air spring device can have two auxiliary chambers 320 or three or more auxiliary chambers 320 exhibit.

While preferred embodiments of the invention have been disclosed for purposes of illustration, it will be apparent to those skilled in the art that numerous different modifications, additions and substitutions are possible without departing from the scope of the invention as defined in the accompanying claims. The actual technical scope of the disclosure is therefore defined by the following claims.

Claims (12)

Air spring device comprising: an auxiliary chamber configured to store air; a main chamber formed in a bellows part and configured to store air; and a rotary solenoid valve which is arranged between the auxiliary chamber and the main chamber and which is designed to selectively connect the auxiliary chamber and the main chamber to one another, the rotary solenoid valve having: a hollow housing which is arranged on a connecting part between the auxiliary chamber and the main chamber and is provided with an opening formed therein; and a locking member rotatably disposed in the housing and rotated to connect or disconnect the auxiliary chamber and the main chamber with each other, so that air flow through the opening is selectively enabled. Air spring device after Claim 1 , in which the housing is formed in the form of a hollow column, and the blocking member has a connection flow path formed therein and is rotated to selectively connect the opening and the connection flow path. Air spring device after Claim 2 the opening having: one or more first openings facing the auxiliary chamber; and one or more second openings facing the main chamber. Air spring device after Claim 3 , wherein the communication flow path is arranged to overlap the first opening and the second opening when the auxiliary chamber and the main chamber are connected, and is arranged such that it does not overlap the first opening when the auxiliary chamber and the main chamber are apart are separated. Air spring device after Claim 4 in which the connection flow path of the blocking part completely overlaps the first opening when the auxiliary chamber and the main chamber are connected to each other. Air spring device after Claim 4 , in which the blocking part is spherical, and the connecting flow path is L-shaped such that one side thereof faces the first opening and the other side thereof faces the second opening. Air spring device comprising: an auxiliary chamber configured to store air; a main chamber formed in a bellows part and configured to store air; and a rotary solenoid valve which is arranged between the auxiliary chamber and the main chamber and which is designed to selectively open or close a flow path which connects the auxiliary chamber and the main chamber, the rotary solenoid valve having: a hollow housing disposed in the flow path and having an opening; and a blocking member rotatably installed in the housing and rotated to open or close the flow path so that air flow through the opening is selectively enabled. Air spring device after Claim 7 , in which the housing is formed as a hollow cylinder, and the locking member comprises: a rotating shaft which is rotatably installed in the center of the housing; and locking plates that extend outward from the rotating shaft in two or more directions and abut an inner wall of the housing. Air spring device after Claim 8 the opening having: one or more first openings facing the auxiliary chamber; and one or more second openings facing the main chamber. Air spring device after Claim 9 , wherein the barrier plates are arranged to overlap the first opening and the second opening when the flow path is open, and are arranged not to overlap the first opening and the second opening when the flow path is closed. Air spring device after Claim 10 in which the locking plates extend from the rotating shaft in two directions and the angle between the two locking plates is 180 degrees. Air spring device after Claim 11 , in which the first opening and the second opening are arranged on the same line as seen from the bottom, wherein when the flow path is open, the barrier plates are arranged in the centers of the first opening and the second opening.

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