FR2515295A1 - PNEUMATIC SPRING - Google Patents

Abstract

The invention relates to an air spring having a jacket which consists of flexible, elastomeric material and is connected in the region of both of its open ends to in each case one rigid body. The connection of the jacket to the rigid bodies is produced by using rings which clamp the ends of the jacket against the rigid bodies.

Description

 The present invention relates to an air spring, that is to say a spring essentially constituted by an envelope made of flexible material, containing air, provided with two openings at the level of which the envelope is connected to elements made of rigid material. which constitute the ends of this spring.

 Different types of pneumatic springs are known which all fall within the general definition indicated above and which differ from one another, either by the shape of the casing, or by the shape of the rigid material elements constituting the ends of the spring.

 All types of pneumatic springs already known have the drawback of requiring, in order to guarantee perfect sealing in the connection between the envelope of flexible material and the elements of rigid material, high precision in machining the edges of the openings of the enclosure and areas of rigid elements with which the edges of the enclosure openings should come into contact.

 This high machining precision implies, for all known springs, the need to form a rigid heel at the edges of the openings of the envelope.

 In addition, the already known pneumatic springs do not make it possible to achieve large elongations because, if one wishes to avoid the risk of loss of tightness at the level of the contact between the edges of the openings of the envelope and the rigid elements, loss which would occur if the elongation of known pneumatic springs were sufficient for a tensile stress between the heels provided at the edges of the openings of the envelope and the zones of the rigid elements with which the heels are in contact.

 One of the aims of the invention is to eliminate the drawbacks of the air springs which have been mentioned above.

 The subject of the invention is a pneumatic spring comprising an envelope made of flexible material provided with two openings at the level of which are elements made of rigid material and means of connection between the envelope and these elements, characterized in that the envelope made of flexible material is a cylindrical membrane of elastomeric material whose edges, which are also made of elastomeric material, have a thickness greater than that of the remaining part of the cylindrical membrane.

 The description which follows and which has no limiting character, should be read with reference to the single appended figure which is a sectional view of a pneumatic spring according to the invention.

 In general, in accordance with the present invention, an air spring comprises an envelope of flexible material constituted by a cylindrical membrane of elastomeric material which optionally contains a reinforcing fabric and the edges of which lie at the bases of the cylindrical shape. entirely of elastomeric material, possibly contain the edges of the tubular fabric mentioned above and have a thickness greater than the thickness of the remaining part of the same cylindrical.

The cylindrical membrane carries rigid elements tight on it at the right of its bases.

 In the single figure, a particular embodiment is shown of an air spring conforming to the general principle of solving the problem described above.

 As can be seen in this figure, the pneumatic spring comprises a casing 1 constituted by a membrane of elastomeric material which optionally contains a tubular fabric as a structure resistant to stresses, casing which has a cylindrical shape when the spring is fully extended while, under the conditions of normal working conditions of the spring, the envelope has the configuration of two coaxial cylindrical segments 2 and 3 connected together by a curved segment 4.

 At the ends of the membrane or of the envelope 1, the edges 5 and 6 of this membrane have a thickness greater than the thickness of the wall of the membrane.

 More particularly, the edges 5 and 6 of the membrane or envelope 1 have a frustoconical outer surface 7, the large base of the frustoconical shape being located at the outermost part of the edges while the inner surface 8 is cylindrical.

 In line with the ends of the membrane and of the casing 1, where the edge 5 is located, a first element or bucket. 9 made of rigid material, for example metallic, is mounted in the cavity of the casing 1.

 The bucket 9 comprises a cylindrical wall 10 closed at a base by a disc 11 on which there is a folded tiller piece 12 which serves to connect the spring to a support. In addition, the edge 13 of the cylindrical wall 10 of the cup 9 is profiled in the shape of a flared lip towards the outside of the cylindrical shape, the wall 10 of which is formed, and a circular ring 14 surrounds the membrane or envelope 1 and the press against the cylindrical wall 10 of the cup 9.

 More particularly, the ring 14 is arranged on the casing 1 so as to leave the edge 5 of the latter in contact with the cylindrical part 10 of the bucket 9 but towards the outside of the pneumatic spring.

 Likewise, at the end of the membrane or envelope 1 where the edge 6 is located, the second element or cup 15 made of rigid material, for example metallic, is embedded in the cavity of the membrane or envelope 1.

 The bucket 15 comprises a cylindrical wall 16 closed at a base by a disc 17. In this disc is provided an opening 18 from which leaves, towards the inside of the bucket, a sleeve 19 by means of which the spring tire is fixed to a support, not shown.

 In addition, the edge 20 of the cylindrical wall 16 of the cup 15 is profiled in the form of a flared lip towards the outside of the cylindrical shape from which the wall 16 is formed, and a cylindrical ring 21 surrounds the membrane or in cylindrical velvet 1 and the press against the cylindrical wall 16 of the cup 15.

More particularly, the cylindrical ring 21 is arranged on the membrane or envelope 1 so as to leave the edge 6 of the latter in contact with the cylindrical wall 16 of the body 15, but towards the outside of the pneumatic spring.
As mentioned above, the casing 1 is constituted by a membrane of elastomeric material, which optionally contains a tubular fabric resistant to stresses, and by its structure which has a cylindrical shape when the spring is fully in extension while, when the spring is in normal working condition, the membrane constituting the envelope 1 has the configuration of two coaxial cylindrical segments 2 and 3 connected together by a curved segment 4.

 More particularly, the cylindrical segment 3 is in direct contact with the outer surface of the cylindrical ring 21 and bears against this surface.

 The operation of the air spring according to the invention is as follows. The air spring is interposed between two supports (not shown) between which there is a possibility of movement in antagonism with respect to the action of an elastic means.

 One of the supports is fixed to the bucket 9 by means of the folded sheet metal part 12 while the other support is connected to the bucket 15 by the sleeve 19.

 When the supports between which the spring is interposed, are subjected to forces which act in the direction tending to bring them closer, there is a mutual approach between the discs 11 and 17 of the cups 9 and 15, respectively.

 The magnitude of this approximation depends on the modulus of the forces applied to the supports and on the pressure prevailing inside the pneumatic spring, that is to say on the pressure of the air contained in the space delimited by l '' casing 1 and wells 9 and 15.

Indeed, the movement of approximation of the supports and, consequently, of the buckets 9 and 15 which are connected to them, ends when the pressure of the air contained in the spring reaches a value capable of generating forces of the same modulus as those which had given rise to the movement of rapprochement but of opposite direction
When, on the contrary, the supports between which the spring is interposed, are subjected to forces which act in the direction tending to move them away, there is a reciprocal movement between the buckets 9 and 15.

 In this case, the maximum elongation which can occur between the buckets 9 and 15, is that for which the membrane or the envelope 1 takes a perfectly cylindrical shape, with the possibility of having the membrane or envelope 1 subjected to tensile stresses directed parallel to the generatrices of the cylindrical shape taken by the membrane or envelope 1.

 Under these conditions, the air spring has no drawbacks, in the sense that the tightness of the connection between the casing I and the buckets 9 and 15 is maintained.

It is easy to understand on reading the above that with a pneumatic spring according to the invention, the goals proposed and indicated above are achieved
Indeed, everything goes wrong, with a spring according to the invention, it is possible to reach an extensibility which it would be inconceivable to obtain with known pneumatic springs, since with this spring, it is not only possible to obtain l extensibility resulting from the cylindrical configuration of the envelope or membrane without losing the seal in the connection zone between the buckets and said envelope or membrane, but it is even possible to obtain, without drawbacks, the extensibility allowed by the elastic extension of the membrane under tension0
It is therefore also possible to work the pneumatic spring according to the invention as a thrust cylinder, this qdil is not possible to achieve with known pneumatic springs.

 In addition, the particular conformation of the envelope or membrane and the particular mode of connection between the ends of the envelope or membrane and the buckets which form the pneumatic spring in combination with this envelope, eliminate the need to form rigid heels in the envelope or membrane and to provide precision machined surfaces on the buckets.

Claims (4)

 1.- Pneumatic spring comprising an envelope made of flexible material, provided with two openings at the level of which are elements made of rigid material and means of connection between the envelope and these elements, this spring being characterized in that the envelope in flexible material (1) is a cylindrical membrane of elastomeric material whose edges (5 and 6) which are also made of elastomeric material, have a thickness greater than that of the remaining part of the cylindrical membrane.  2.- pneumatic spring according to claim 1, characterized in that at the edges (5 and 6) the cylindrical membrane of elastomeric material (1) has its outer surface profiled in a truncated cone, with the large base of the shape frustoconical located on the outermost edge of the edge of the membrane  3. A pneumatic spring according to any one of claims 1 and 2, characterized in that the elements made of rigid material provided with means for fixing to the cylindrical membrane of elastomeric material comprise a cylindrical element (9, 15) in the form of a bucket, substantially closed at a base, which is in contact by its cylindrical surface with the inner cylindrical surface of the membrane at one end thereof, a rigid ring (14, 21) being provided in contact with the outer cylindrical surface of the membrane, the thickest edge of the membrane resting on this ring.  4. A pneumatic spring according to claim 3, characterized in that at its base which is the innermost relative to the membrane the edge of the cylindrical element (9, 15) in the form of a bucket is provided with a lip that flares outward from the cylindrical shape.