SE432647B - SEALING DEVICE FOR INBOARD SEALING OF CONCENTRIC WITH EACH OTHER AND IN AXIAL DIRECTION RELATIVELY TO EACH OTHER - Google Patents

Description

* <1 CO ... s PO PO CO -D- I U 10 15 20 25 30 35 2 the track bottom and the ring package and thereby serves to press the rings against the other part.

The arrangement can in this case be such that the rings sit on the outer circumference of the hollow body serving as a spring element, the rings being suitably made of a preferably sealing plastic material with sliding properties, for example polytetrafluoroethylene, and the hollow body serving as a spring element is made of a plastic material with rubber-like properties. However, the arrangement can, for example, also be such that the rings are made in one piece with the hollow body.

In the sealing device according to the invention, in that the rings sit on an inflatable hollow body whose inner space is connected to an air pressure source, an automatic adaptation of the pressure with which the rings abut in the radial direction to the opposite surface, to that in the cylinder or the house chamber prevailing the pressure. For example, when in a piston and cylinder assembly the piston carrying the sealing device according to the invention moves towards one end of the cylinder, the pressure in the cylinder chamber in question may increase more and more towards the end of the piston movement, for example by compressing the existing air there. whereby the sealing device functions more and more strongly in that the pressure exerted by the hollow body in the radial direction towards the rings becomes higher and thus provides a better sealing. In addition, an automatic adjustment of the sealing function and the sliding ability to the pressure prevailing in the cylinder can now be achieved. When, as before, the sealing devices of comparable type have been set according to a predetermined cylinder pressure, and if the cylinder in question must operate with a different pressure, for example a lower pressure, so that the properties of the sealing device, which at the same time constitutes control for the piston, must change , for example by reducing the sliding capacity of the piston, an automatic adaptation to the pressure prevailing in the cylinder is now ensured.

Namely, a pressure is propagated to the inner space of the hollow body which depends on the magnitude of the pressure in the cylinder or housing chamber in question, so that also the pressure exerted by the hollow body in radial direction towards the rings adapts to the pressure change in the cylinder or housing chamber, whereby the sliding properties do not deteriorate at lower pressures and the sealing function remains just as good at higher pressures. A particularly advantageous arrangement is obtained if the ring groove in which the ring package is arranged is connected to the cylinder or housing chambers on either side of the piston via channels and between the inner mouths of the two channels and the ring groove a valve of the OR valve is placed, e.g. in the form of a flexible lip of a material with sealing properties, which valve opens the side of the piston on which the higher pressure prevails and hereby opens the channel opening on this outside of the piston.

The arrangement may, for example, be such that the ring package is arranged in a ring groove on the outer circumference of the piston in a piston and cylinder assembly and sealingly abuts against the inner surface of the cylinder, in this case the ring groove. preferably connected to both sides of the piston via, for example, axially directed channels. However, the arrangement can for instance also be such that the ring package is arranged in a ring groove on the inner circumference of a housing, for example a cylinder of piston and cylinder assembly, and sealingly abuts against the outer surface of the part controlled in the housing, e.g. a piston, in which case the annular groove is either connected via a duct to an external source of compressed air or - which is simpler - is connected to the cylinder chambers on either side of the piston via ducts. The arrangement can, for example, finally also be such that the ring package abuts sealingly against the outer circumference of the piston rod or - in a device to be used with a piston and cylinder assembly with a so-called damping piston - that the ring package is arranged in a ring groove on the outer piston circumference and abuts against the inner wall of the counterpart.

The invention is described in more detail in the following with reference to the accompanying drawing which shows several embodiments. Fig. 1 shows a first embodiment of a sealing device according to the invention from the side and partially cut, with only a part of the sealing device being shown.

Fig. 2a shows a ring included in the sealing device according to Fig. 1 from the front. Fig. 2b shows the ring according to Fig. 2a in section. Fig. 3 shows a variant of a detail of the sealing device according to Fig. 1 also here from the side and in section.

Fig. 4 shows a possible use of the sealing device according to Fig. 1 schematically from the side. Fig. 5 shows a variant of the arrangement according to Fig. 4 schematically from the side.

A piston 10 is guided in a cylinder 12 and is reciprocable in the direction of the arrow A. It should be noted that only a small part of the piston 10 is shown. The piston 10 has a ring groove in which a ring seal collectively referred to as 25 - a ring package composed of several rings - is arranged, which ring seal serves to seal the cylinder against the piston. The ring seal consists of several, for example three or four one above the other and next to each other arranged, each with its own radial, suitably continuous slot 5 provided plastic rings 1 of semi-hard material, which rings can be made for example by punching.

The rings 1 are mutually offset in the circumferential direction in such a way that the slots 5 are mutually offset. In total, a sealing device is thus obtained for mutual sealing of concentrically arranged and axially movable relative parts mutually arranged, which sealing device has a side arranged in a ring groove in one part and with a side extending transversely to the ring plane towards the other. the part closely abutting ring seal, which is package-like composed of several side-by-side abutting rings, which are resiliently resilient in radial direction.

According to the invention, the rings 1 turn their end sides 2a, 2b, 2c, 2d lying in the annular plane towards each other and the rings sit on an inflatable hollow body 3 acting as a spring element of, for example, flexible, suitably elastic material, the inner space 4 of the hollow body being in connection with a source of air pressure in such a way that the pressure exerted by the hollow body in the radial direction according to the arrow 3a towards the rings adapts to the change of the pressure in the cylinder or housing chamber in question. The rings 1, 10 15 20 25 30 35 5 whose continuous slots are mutually offset 1800 in the circumferential direction, may in cross-section have the shape of a rectangle placed relatively vertically on a vertical edge, as is shown, for example, in Fig. 2b. The rings can be circular according to Fig. 2a, but they can also have a rectangular or square contour.

Three or four rings 1 composed of a package 25 are arranged in a ring groove 6, on the bottom of which the spring element 3 is arranged. The spring element 3 is located between the groove bottom 4a and the ring package 25 and serves to press the rings against the second part in the direction of the arrow 3a. In the embodiment according to Fig. 1, the rings 1 are located on the outer circumference of the hollow body 3 serving as a spring element, on which the rings are, for example, pressed. In this case, the rings 1 consist of a suitably sealing plastic material with sliding properties, for example of polytetrafluoroethylene. The rings 1 have, on the one hand, the task of sealing the two cylinder chambers separated by the piston from each other and, on the other hand, the task of controlling the piston. The rings must thus have, on the one hand, sealing properties and, on the other hand, good sliding properties. The hollow body serving as a spring element suitably consists of rubber or a plastic material with rubber-like properties. The function of the hollow body is to elastically actuate the rings 1 and, depending on the pressure prevailing in its inner space, the rings are pressed more or less strongly against the counterpart in the radial direction. In an embodiment not shown, the rings are made in one piece with the hollow body. A prerequisite for this is a material which has good sliding properties as well as good sealing properties and also the necessary elasticity.

In the embodiment according to Fig. 1, the ring package 25 is arranged in an annular groove 6 on the outer circumference of the piston 10 of a piston and cylinder assembly, the ring package thereby abutting sealingly against the inner surface 11 of the cylinder 12. This annular groove 6 is connected via axial channels 13 and 14 to both outer sides of the piston 10, whereby between the inner mouths 13a and 14a of the two channels 13 and 14 and the annular groove 6 there is a valve 15 of the type OR valve, for example in the form of a flexible lip of a material with sealing properties or in the form of a flap, the valve opening to the side of the piston at which the higher pressure prevails and thereby releasing the channel opening towards this outside of the piston. In the embodiment shown in Fig. 1, the valve 15 closes the channel 14, while the channel 13 is open, so that the pressure prevailing on the piston side 13b propagates to the inner space 4 of the hollow body 3 and inflates this hollow body so that it exerts a radial pressure against the rings. 1 in the direction of the arrow 3a, which rings 1 are in this way pressed against the inner surface 11 of the cylinder 12 in dependence on the pressure prevailing on the piston side 13b.

The rings 1 are thus pressed harder against the inner surface of the cylinder 12 the higher the pressure on the piston side 13b, so that in this way one has a stronger pressing at higher pressure in the cylinder and at lower pressure a smaller pressing, ie less friction. In addition, the pressure becomes stronger the closer the piston approaches the end of the cylinder chamber in question. As a result, a better seal is produced at higher pressures, while at lower pressures - when the seal is easier to achieve - the friction, on the other hand, becomes lower, whereby the sliding ability is improved. In this way, a certain improvement of the damping of the piston movement at the end of the stroke can also be achieved. Finally, this also provides an adaptation of the sealing function to the speed of the piston movement and to the resulting leakage losses. Overall, the new sealing device thus achieves an adaptation to the pressure currently prevailing in the cylinder and on the piston side in question, respectively, and an improvement of the sealing properties, sliding properties and control properties of the piston.

The valve 15, lip or a pivotally mounted flap and which can occupy what may for instance consist of an elastic position shown in Fig. 1 in solid lines or alternatively the position 1Sa shown in dashed lines in the same figure, serves to prevent short circuit of channels - 10 15 20 25 35 7812284-5 7 na l3 and 14 and that the pressure in the space 4 is built up with delay.

In the embodiment according to Fig. 4, the ring package 30 is arranged in a ring groove 31 on the outer circumference of a piston 32, the ring package abutting sealingly against the inner surface of a cylinder or housing 33. According to Fig. 5, however, the arrangement may also be such that the ring package 27 is arranged in an annular groove 26 on the inner circumference of a housing 20, for example a cylinder of a piston and cylinder assembly, and abuts sealingly against the outer surface 21 of the piston 22 of the assembly - the part guided in the housing -. In this case, in an embodiment not shown in the drawing, the ring groove can be connected to an external source of compressed air. The compressed air supply can meet the prevailing requirements. However, the arrangement can also be via a channel, measures being set such that according to Fig. 5 the ring groove 26 is connected via channels 26 and 24 to the cylinder chambers 25 and 26 on either side of the piston 22, as shown schematically in Fig. 5. Also in in this case there may be between the inner mouths of the two channels 23 and 24 and the annular groove a valve 28 of the type ELLÉR valve, for example in the form of a flexible lip of a material with sealing properties or a flap, the valve opening to the cylinder chamber in which it the higher pressure prevails and thereby the channel opening into this cylinder chamber opens. The function is approximately the same as in the embodiment according to Fig. 1 and Fig. 4, respectively, and provides the same advantages.

In an embodiment not shown, the ring package abuts sealingly against the outer circumference of a piston rod. The ring package can in this case be arranged in a wall through which the piston rod is passed. Optionally, the ring package can be arranged on the piston rod itself. In any case, such measures must be taken that the hollow body is connected to the space or chamber with the higher pressure. In an embodiment which can be used with a piston and cylinder assembly with a so-called damping piston - this embodiment is not shown in the drawing - the ring package is arranged in a ring groove on the outer circumference of the damping piston, the ring package abutting against the inner wall of the counterpart 7812284-5 10 15 8 . Of course, even in this case, the opposite can be done, as already described above. According to Fig. 3, the hollow body 35 can also be provided with shaped, flange-like projections 36 and 37, between which the rings 38 are fixed, so that the rings 38 form a unit with the hollow body 35 which can be pre-assembled and fitted in the ring groove as a whole.

The sealing device according to the invention also has the advantage that the path between the high and low pressure sides of the pressure medium to be sealed is long, since the pressure medium must first pass a slot in the sealing device in the axial direction from the high pressure side of the sealing device, then through the gap arranged transversely to the axis between two adjacent rings to reach the circumferentially offset slot on the connecting ring, then after passing the second slot flow through the gap between the subsequent adjacent rings, and so on. A good sealing function is thus obtained as a result of the long sealing path due to the construction.

Claims (7)

7812284-5 PATENT REQUIREMENTS 1. A sealing device for mutual sealing of concentrically arranged and axially movable parts (10, 12; 20; 32, 33), for example piston and cylinder, which sealing device (25; 30) has a a ring groove (6; 26; 31) in one part arranged and with a side sealing ring extending transversely to the ring plane towards the other part sealing ring seal (1; 27; 38), which in a radial direction is resiliently pressed against the wall (11; 21) to be sealed, by means of an inflatable hollow body (3; 35), which communicates with a source of pressure via a channel (13, 14; 23, 24), characterized in that the channel (13, 14; 23, 24) communicates with pressure chambers on either side of the seal (1; 27; 38) and in the inlet to the hollow body (3; 35) has a valve (15; 28) which has OR function and opens to the side of the piston (10; 22; 32) at which the higher pressure prevails and thereby releases the passage through the channel opening on this outside of the piston len (l3a, l4a). Sealing device according to claim 1, characterized in that the hollow body (3; 35) consists of rubber or rubber-like plastic and is insertable into the ring groove (6; 26; 31), in which it lies loosely on the groove bottom (4a) , and that the ring seal (25) consists of a package of side-by-side, separate rings (1), which abut directly against the outside of the track bottom (3; 35) facing away from the groove bottom and have radially directed slots (5) , the slots (5) of adjacent rings (1) in the package being mutually offset in the circumferential direction, preferably 1800. Sealing device according to claim 2, characterized in that the rings are suspended on the outside of the hollow body (3; 35). Sealing device according to claim 3, characterized in that there are flange-like projections (36, 37) on the outside of the sliding body (35), between which the rings (38) are fixable. Sealing device according to one of Claims 2 to 4, characterized in that the rings (1; 38) are made of a sealing plastic material with good sliding properties and are produced by punching. Sealing device according to claim 1, characterized in that the rings (1; 38) are made in one piece with the sliding body (35). Sealing device according to claim 1, characterized in that the valve (15:28) with OR function has the shape of a flexible lip or a pivotally mounted flap of sealing material.