CS240200B1 - Atmospherical pressure regulation device in pneumatical springs - Google Patents

Abstract

The device has at least the inlet one automatic master controller inlet closure member for access closure compressed air from the source; outlet outlet closure member for closing each connected pneumatic a spring that has an auxiliary for closing output closure member, and in auxiliary connection auxiliary input closing member to close access to compressed air from source. Auxiliary output closure the member may be connected to the auxiliary connection. Shut-off members may be mechanically shaped electrically, pneumatically or hydraulically one-way or two-way stop valves or taps.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for regulating the air pressure in pneumatic springs connected to automatic constant-height controllers. The device allows to increase, decrease and maintain static height of pneumatic springs.

The prior art devices which allow to increase, decrease and maintain the static height of pneumatic springs connected to automatic air pressure regulators are in the form of manually mechanically operated special multi-way valves, which are connected between the compressed air source, automatic regulator outlets and pneumatic spring inlets. Their disadvantage is the considerable structural complexity, manufacturing demands due to the required accuracy of the components, which causes a high purchase price. Another disadvantage is that they cannot be operated remotely.

The principle of the air pressure control device in the pneumatic springs connected to the automatic constant static height regulators according to the invention consists in having, before the supply of at least one automatic regulator, a main inlet shut-off member for closing compressed air access from the source and downstream of the outlet any associated pneumatic spring having an auxiliary outlet closure member for closing and an auxiliary inlet closure member for closing the compressed air access from the source in an auxiliary connection. The auxiliary outlet closure member can be connected to the auxiliary connection. The main inlet shut-off member, the main outlet shut-off member, the auxiliary inlet shut-off member and the auxiliary outlet shut-off member may be a mechanically, electrically, pneumatically or hydraulically operated one-way shut-off valve or one-way shut-off valve,

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- 3 or 2-way stop valve or 2-way stopcock. The main closure member and the auxiliary inlet closure member as well as the main outlet closure member and the auxiliary outlet closure member may be a twin-way closure member with independent control.

The main advantage of the device according to the invention is that it utilizes simple, normally large-scale, cheap and functionally reliable closure members. When using electrically, pneumatically or hydraulically operated shut-off members, the device can be operated remotely. The use of dual two-way shut-off members with independent control provides the advantage of simplifying pneumatic connections.

Embodiments of the air pressure control device in the air springs according to the invention are shown schematically in the accompanying drawings. Fig. 1 is a pneumatic spring pressure control device connected to an automatic regulator comprising four shut-off members in the form of two mechanically operated one-way stopcocks and two mechanically operated two-way stopcocks. The apparatus of Fig. 2 differs in that it has four shut-off members in the form of mechanically operated one-way shut-off valves and also in that it has an auxiliary outlet shut-off member connected to the auxiliary connection. The device according to FIG. 3 is designed to control the air pressure in two pneumatic springs connected to a common automatic regulator and its shut-off members form electromagnetically operated two-way shut-off valves. The device according to Fig. 4 is designed to control the air pressure in two pairs of pneumatic springs, which are connected to two automatic regulators and comprises shut-off members in the form of electromagnetically operated two-way shut-off valves as well as the device according to Fig. 5 air in two air springs connected to two automatic controllers. The same closure members also comprise the device of FIG. 6 designed to regulate air pressure in six pneumatic springs connected to three automatic regulators. The device according to FIG. 7 is intended for two pneumatic springs connected to two

240 200 automatic controllers and includes three double two-way shut-off members with independent electromagnetic control.

In the device according to FIG. 1, the pneumatic spring 1 is connected to an automatic regulator 2, which has a main inlet closing member 5 before the inlet 3 for closing compressed air access from the source 10 and has a main outlet closing member 6 behind the outlet 4 For closing, the pneumatic spring 1 also has an auxiliary outlet closure member 2. In the auxiliary connection 7, the pneumatic spring 1 has an auxiliary inlet closure member 8 for closing the access of compressed air from the source 10. The main inlet and outlet shut-off members 5, 6 form mechanically operated two-way shut-off valves 14. The auxiliary inlet and outlet shut-off members 8, 9 form mechanically operated one-way shut-off taps 18.

In the apparatus of FIG. 2, the auxiliary outlet closure member 9 is connected to the auxiliary connection 6. All shut-off members 5 _Z 6 _Z 8 _Z 9 are mechanically operated one-way shut-off valves 11U of the device of Fig. 3, two pneumatic springs 1 are connected to a common automatic regulator 2 which has both main outlets 4 main outlet shutter 6 and before main 3 an inlet closure member 5. In the auxiliary connection 7, the ancillary inlet closure member 8 has for closing the compressed air access from the source 10 and an auxiliary outlet closure member 9 for closing each pneumatic spring J.

In the device according to FIG. 4, two pairs of air springs 1 are connected to two automatic regulators g _z behind whose outlets 4 are the main output closing members 6.

In the auxiliary connection 7 there are two auxiliary outlet shut-off members 2 ^{and a} common inlet shut-off member 8.

In the device according to Fig. 5 there are two air springs 1 are connected to two automatic regulators _of £ Each has a front inlet j3 main input £ closing member for closing off the access of the compressed air from the source 10 and the output terminal 4 main closing member 6. In both the auxiliary connections 2 is the auxiliary outlet closure member 9 and the auxiliary inlet closure member

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5 a member § for closing the access of compressed air from the source JO.

II of the device according to FIG. 6, three pairs of air springs 1 are connected to three automatic regulators g. Prior to the inlet 5 of each there is a main inlet shut-off member 5 to close the compressed air access from the χθ _ζ source. the connection 7 is the auxiliary exit shutter 2 θ the auxiliary entry shutter 8.

In the device according to FIG. 7, the two pneumatic springs 1 are connected to two automatic regulators 2, which have, after the outlet b, a main output closure member 5 and in the auxiliary line 7 an auxiliary output closure member 6 in the form of a double two-way closure member 5 with independent electromagnetic control. In auxiliary connection g, it has an auxiliary input closure member 8 and, prior to the supply J of both automatic controllers 2, has a main input closure member 5 also in the form of a double two-way closure member 5 with independent electromagnetic control for closing access from source χθ.

The devices according to FIGS. 3 to 6 have two-way solenoid actuating valves XJ5, which may be remote, in place of the main and auxiliary inlet and outlet valves 5, 6, 8, 2.

If one-way stop valves and taps are used χΐ _ζ Iζ open / connect their inlet to outlet. After closing, they close the inlet access. When used, two-way shut-off valves or taps χ3 _ζ χ4 _ζ connect their inlet and outlet. After closing, they close the access from the inlet and open the outlet connection with the air. The same function also has the two two-way shut-off members with a common supply (which form an associated two-way shut-off member J5 with independent control).

If they are closed auxiliary inlet and outlet closure members § ₂ ^and open the main inlet and outlet closure members £ _Z $ _Z keeps the device according to the invention a constant static height of the air springs χ connected to automatic controllers g. A generally known manner according to the needs of each automatic regulator g opens coupling the connected pneumatic springs χ either to a source X stlač of compressed air or to the atmosphere _z

240 200 or both. When the main inlet and outlet shut-off members 5, 6 are closed and the auxiliary inlet and outlet shut-off members 8, 9 are opened, the static height of the pneumatic springs 1 increases as the compressed air flows from the source 10 via auxiliary connection 7 into the connected pneumatic springs. When the main inlet and outlet shut-off members 6, 6 and the auxiliary inlet shut-off members 8 are closed and the auxiliary outlet shut-off members 9 are opened, the static height of the pneumatic springs 1 decreases as compressed air flows therefrom into the atmosphere. When the main inlet and outlet shut-off members 5, 6 as well as the auxiliary inlet and outlet shut-off members 8, 9 are closed, the static height of the pneumatic springs 1 is seeded because the connection of the air springs 1 to the compressed air source 10 is closed.

The air pressure control device for air springs according to the invention is applicable to a flexible pneumatic or combined vehicle body support and a flexible pneumatic seat support. It allows to maintain, increase or decrease the height of resiliently pneumatically mounted parts as required, making it easier and easier for passengers to board, loading and unloading on ramps, off-road clearance, underpasses, body replacement and repairs. It is also suitable for flexible pneumatic storage of stable masses, where the regulation of air pressure in the pneumatic springs can change their static height and thus change the static position of the elastically pneumatically stored masses and the frequency of the natural oscillations of the system.

Claims (5)

An apparatus for regulating the air pressure in pneumatic springs connected to automatic controllers of constant static height, characterized in that a main inlet closure member (5) is connected upstream of the inlet (3) of the at least one automatic regulator (5) to close the compressed air access from a main outlet closure member (6) is connected downstream of the outlet (4) to close each connected pneumatic spring A / to which an auxiliary outlet closure member (9) is connected for closure and an outlet closure member (1) is connected in auxiliary connection (1) / 8 / to close compressed air access from AO source / · 2. The device for regulating the air pressure in the pneumatic springs according to claim 1, characterized in that the auxiliary outlet closure member (9) is connected to the auxiliary connection (7). 3. The air pressure regulating device according to claim 1, characterized in that the main inlet closure member (5), the main outlet closure member (6), the auxiliary inlet closure member (8) and the auxiliary outlet closure member (9) it forms a mechanically, electrically, pneumatically or hydraulically operated one-way stop valve (11), or a one-way stop valve (12), or a two-way stop valve (13), or a two-way stop valve (14). 4. The air pressure control device according to claim 1, characterized in that the main inlet closure member (5) and the auxiliary inlet closure member (8) form a double-way closure member (15) with independent control. 5. The pneumatic spring pressure control device according to claim 1, characterized in that the main outlet shut-off member (6) and the auxiliary outlet shut-off member (9) form a double-way shut-off member (15) with independent control.