DE102009024871A1 - Gas spring with grease lubrication - Google Patents

Abstract

A gas spring has in the end piece, through which passes the piston rod, an annular space which is filled with grease. In order to keep the grease in contact with the piston rod even when the annulus is gradually deflated, an annular piston in the form of an O-ring which frictionally engages the piston rod is seated in the annulus. The movement of the piston rod compresses the grease on the relevant side of the piston and thus presses it against the piston rod. A similar arrangement is provided for a piston in a gas tension spring.

Description

gas springs have one usually cylindrical cylinder tube on which provided at both ends with closure pieces is. The one closure piece contains a bore through which a piston rod into the interior of the cylinder tube ushers. On this inner end of the piston rod sits a piston which essentially the task is to prevent the gas pressure, which prevails inside the cylinder tube, the piston rod flings outward. He essentially acts as a stop in this respect and not how to initially suspect should, indeed as a piston. The extension force of the gas spring is created rather by the volume change, which arises when the piston rod penetrates into the cylinder tube or moved out of this.

In order to the gas can not escape from the cylinder chamber, sit in the closing piece with the through-hole seals, which against the piston rod caulk. These seals must be lubricated become. Usually This is done by the cylinder chamber contains a small amount of oil. Moisten this oil the piston rod, provided the installation of the gas spring is so, that the cylinder tube over the piston rod is stationary. Only then can the oil contained in the cylinder space wet the piston rod and lubricate the gasket or gaskets in the plug.

A predominantly horizontal installation is not possible because then lubrication of the seal is impossible.

at Lack of lubrication of the seal, the seals despite special surface treatment the piston rod relatively fast rubbed off and it also suffers the sealing effect.

Similar conditions prevail at a gas tension spring. In this case, however, is the piston indeed designed as a piston, which is sealed against the cylinder wall.

outgoing It is the object of the invention to provide a fluid cylinder arrangement to create, which also allows a horizontal installation.

These Task is according to the invention with the Fluid cylinder arrangement according to claim 1 or the fluid cylinder arrangement solved according to claim 2.

at The fluid cylinder assembly according to claim 1 is the closure piece, through that passes the piston rod, provided with an annular space, which preferably concentric the piston rod surrounds. In this annulus sits a corresponding ring piston, the frictionally engaged cooperates at least with the piston rod. This allows the ring piston upon movement of the piston rod in the annulus between the Both ends are moved back and forth.

Of the Contains annulus a grease filling, either on both sides of the ring piston or only on one side of the ring piston.

by virtue of of the frictionally cooperating with the piston rod annular piston During the movement of the piston rod, the grease filling between the ring piston and compressed in the direction of movement end face of the annular space. Thereby the grease is pressed on all sides to the piston rod and takes care of a lubrication of the piston rod.

Without the ring piston, the fat filling compressed in the direction of movement, the situation would occur that by the movement of the piston rod, which wets the piston rod Fat gradually at each stroke is transported away from the grease chamber past the seals. After a corresponding number of strokes, the contacts between the grease and the piston rod are lost, bringing the lubricating effect also disappears.

Of the on the piston rod sitting ring piston prevented this effect, because he has the fat, as explained above is compressed against the lying in the direction of travel end wall and so that the grease also moves against the piston rod again.

If in a fluid cylinder arrangement an effective seal between the piston and the cylinder wall is to be made, the above-described Annular space housed in the piston. This annulus is also limited in both directions by end faces. Furthermore, the Piston outside this annulus sealed against the wall of the cylinder chamber. The annular piston acts in this case frictionally engaged with the wall of the cylinder chamber together. The grease filling contained in the ring chamber is in the same pressed against the wall of the cylinder chamber described above, when the piston along of the cylinder is moved. In this way it is constantly ensured that the wall of the cylinder chamber is wetted with a thin layer of grease, the opposite to the friction reduces the seals in the piston and the life of the seals elevated.

In both cases, the radially outer wall of the annular space can form a small gap with the adjacent surface of the annular piston. If this causes fat on the other side of the ring piston, the fat is transported back in the reverse movement. However, the smaller the annular gap, the better the effect, preferably the arrangement is such that virtually no annular gap is created. It is also possible to work without an annular gap at this point, provided that the frictional force which the annular piston generates on the wall of the annular chamber is smaller than the friction which is effective between the annular piston and the piston rod or the cylinder wall. In this case prevents grease from passing on the ring piston on the other side of the ring piston, when the grease is compressed during movement.

in the The simplest case, the annular piston consists of an O-ring, the corresponding frictionally arranged is.

at the fluid cylinder assembly according to the invention it may be a gas spring or a gas tension spring. It is also conceivable to produce a gas spring with damping characteristic, at which the piston actually is sealed against the cylinder wall and contains a throttle bore.

Incidentally, are Further developments of the invention was subject of subclaims.

The The following description of the figures explains aspects for the understanding of Invention. Other details not described to those skilled in take the usual way the drawings, the extent the Complete the description of the character. It is clear that the invention is not limited to the illustrated embodiment limited is, but includes all the modifications that the specialist in the study the description of the figures are familiar.

The Subsequent drawings are not necessarily to scale. to Illustration of details can possibly certain areas exaggerated shown big be. About that In addition, the drawings are simplistic and do not contain each in the practical execution possibly existing detail.

In the drawing are embodiments of the Subject of the invention shown.

1 shows the gas spring according to the invention in a side view.

2 illustrates the closure piece of the gas spring through which the piston rod passes, in a longitudinal section.

3 shows an enlarged section of a gas spring with sealed piston.

1 shows a gas spring in a side view 1 , To the throttle cable spring 1 belongs to a cylinder tube 2 , the egg nen cylindrical interior 3 ( 2 ) limited.

At the left end is the cylinder tube 2 through a plugged in closure or tail 4 sealed sealed. The tail 4 carries on its outside a fastening strap 5 ,

The attachment of the tail 4 happens with the help of two indented grooves 6 . 7 through which the material of the cylinder tube 2 in corresponding annular grooves of the tail 4 is displaced. The seal is done in a known manner by O-rings, either in the annular grooves for the beads 6 . 7 or by O-rings in a separate place.

In the in 1 right end of the cylinder tube 2 also sits an end or closure piece 8th through which a piston rod 9 leads through. The piston rod 9 runs through a corresponding hole 10 in the end or closure piece 8th , It carries on the outer end of a thread 11 , The design of the closure or tail 8th follows from the sectional view of 2 ,

The lock or tail 8th consists of two insert pieces 12 and 13 , The insert 12 has the shape of a cup with a bottom 14 and a circumferential collar 15 which ends with a flat face. Or in other words, the insert 12 is a cylindrical piece, in which a stepped bore is sunk. Part of the stepped bore is the hole 10 for the piston rod 9 ,

For attachment in the cylinder tube 2 has the insert 12 a circumferential annular groove 16 on, in which a polymer seal 17 lies. A circumferential embossed bead 18 displaces the material of the cylinder tube 2 in the ring groove 16 so the insert 12 axially secure and at the same time using the elastomer seal 17 to effect a gas-tight seal.

The insert 13 is in the embodiment shown, a substantially simple planar annular disc 13 with the hole 10 , The insert 13 contains a circumferential annular groove 19 with a seated polymer seal 21 ,

One in the cylinder tube 2 embossed circumferential bead 22 sticks out like the bead 18 on its inside in the annular groove 19 in order to achieve axial securing and sealing there.

Due to the shape of the insert 12 creates a cylindrical annulus 23 , concentrically the piston rod 9 surrounds. The annulus 23 is from one to the axis of the piston rod 9 concentric cylindrical wall 24 and two end faces 25 and 26 limited. The face 25 is as shown in the insert 12 formed while the plane end face 26 the adjacent end of the insert 13 is.

The annulus 23 is sealed to the outside substantially. Why the insert 12 is provided with a planar end face on which the adjacent planar end face of the insert 13 is applied.

Inside the annulus 23 There is an annular piston in the form of an O-ring 27 , which frictionally on the piston rod 9 sitting. The O-ring 27 forms optionally with the wall 24 an annular gap or lies at this only slightly. In any case, the frictional force between the O-ring 27 and the piston rod 9 greater than the frictional force between the O-ring 27 and the wall 24 ,

In 2 the arrangement is shown as the O-ring 27 essentially in the middle between the two end faces 25 and 26 stands. This will make the annulus 23 divided into two chambers. Both chambers are each provided with a grease. This grease filling should be the piston rod 9 lubricate around piston rod seals 29 and 31 to lubricate, which are schematically indicated as O-rings. The seals 29 and 31 intended to be the pressurized interior of the gas spring 2 against the outside atmosphere or against the piston rod 9 caulk. They sit in corresponding annular grooves.

When moving the piston rod 9 For example, to the right, the frictionally engaged on the piston rod 9 sitting O-ring 23 taken in the direction of movement. He has thereby the tendency against the face 26 to move and ensures that the existing there grease is pressurized. In this way it is ensured that the grease located in this area always against the piston rod 9 is pressed, even if, during the use of the gas spring 1 gradually by the movement of the piston rod 9 the fat from the annular chamber 23 is being transported out.

The same effect occurs when inserting the piston rod. Here, the acting as an annular piston O-ring 27 , referred to 2 , moved to the left. This will make the left of the O-ring 27 located fat compressed and against the piston rod 9 pressed.

The fat that gradually moves left out of the annular chamber 23 would be transported out without the O-ring 27 in the annulus 23 leave a free space with the result that the grease is no longer with the piston rod 9 is in contact and can lubricate this. As the ring piston in the shape of the O-ring 27 However, frictionally engaged with the piston rod 9 is taken along, this resulting space by the pressure, which is the O-ring 27 exerts, each closed and the grease against the piston rod 9 pressed.

Analogously, the same arrangement is possible in the area of a sealed piston as well 3 shows.

The in the cylinder tube 2 slidable pistons 35 is with the inside end of the piston rod 9 connected. It contains a total of 3 circumferential grooves 36 . 37 and 38 , The ring grooves 36 and 38 serve to receive seals 39 respectively. 41 that the piston 35 against the inner wall of the cylinder tube 2 seals during movement. The ring groove 37 however, forms an annulus 42 , of two parallel front ends or faces 43 . 44 and a cylindrical bottom surface 45 is limited. The floor area 45 concentrically surrounds the axis of the piston rod 9 or is concentric with the inner surface of the cylinder tube 2 , In the chamber so contained 42 in turn sits an annular piston 46 in the form of an O-ring. This ring piston 46 is frictionally engaged on the inside of the cylinder tube 2 while he is on the ground 45 the ring groove 37 forms a slight gap. This gap can also disappear, provided the frictional force of the O-ring 46 on the wall of the cylinder tube 2 experiences is greater than the frictional force between the O-ring 46 and the grooved ring 37 is effective.

The O-ring 46 in turn divides the annulus 42 in two chambers, each filled with fat. As the piston moves, the O-ring is displaced counter to the direction of movement, thus compressing the grease in the grease chamber, as viewed from the O-ring 46 lie against the direction of movement. This ensures that the grease contained is constantly against the inner wall of the cylinder tube 2 is pressed to this area for the seal 41 to keep lubricated.

In the opposite direction, namely the movement of the piston 35 to the right, the grease is on the left side of the O-ring 46 compressed and thus against the inner wall of the cylinder tube 2 ,

In each direction of movement, that is on the respective side of the O-ring 46 fat also pressed against the cylinder wall to keep them wetted with grease.

A Gas spring points in the tail, through which the piston rod passes, an annular space, the filled with fat is. To keep the grease in contact with the piston rod hold when the annulus gradually emptied, sitting in the Annulus an annular piston in the form of an O-ring, the frictionally with the piston rod is in communication. By the movement of the piston rod the fat is compressed on the relevant side of the piston and thus pressed against the piston rod. An analogous arrangement is for a piston provided in a gas tension spring.

Claims (13)

Fluid cylinder arrangement with a cylinder body ( 2 ), which has a cylinder chamber ( 3 ), which is fluid-tightly sealed at at least one end, with at least one piston rod ( 9 ) in the cylinder chamber ( 3 ), with at least one closure piece ( 8th ), which has a through-hole ( 10 ) for the piston rod ( 9 ) and that at one end of the cylinder body ( 2 ) is present there to the fluid-tight completion of the cylinder chamber ( 3 ), with a lubricant space ( 23 ), which in the closure piece ( 8th ), which is used as an annular space ( 23 ) the piston rod ( 9 ) concentrically surrounds and in the longitudinal direction of two annular end faces ( 25 . 26 ) is limited, the piston rod ( 9 ), and with an annular piston ( 27 ) located within the lubricant space ( 23 ), by the piston rod ( 9 ) and preferably only with the piston rod ( 9 ) cooperates frictionally. Fluid cylinder arrangement with a cylinder body ( 2 ), which has a cylinder chamber ( 3 ), which is fluid-tightly sealed at at least one end, with at least one piston rod ( 9 ) in the cylinder chamber ( 2 ) and in the cylinder chamber ( 2 ) a piston ( 35 ) whose outer peripheral surface of the wall of the cylinder chamber ( 3 ) and which against the wall of the cylinder chamber ( 3 ) is sealed with a lubricant space ( 42 ), which as an annular groove ( 37 ) in the outer peripheral surface of the piston ( 35 ), which in the longitudinal direction of two annular end faces ( 43 . 44 ) and whose bottom surface ( 45 ) is a surface with a straight generatrix which is parallel to the longitudinal axis of the cylinder chamber ( 3 ), and with an annular piston ( 46 ) located within the lubricant space ( 42 ) and preferably only with the wall of the cylinder chamber ( 3 ) cooperates frictionally. Fluid cylinder arrangement according to claim 1, characterized in that the lubricant space ( 23 ) at both ends against the piston rod ( 9 ) is sealed. Fluid cylinder arrangement according to claim 1, characterized in that the annular piston ( 27 ) is formed by an O-ring. Fluid cylinder arrangement according to claim 1, characterized in that the annular piston ( 27 ) with the wall of the lubricant space ( 24 ) forms an annular gap. Fluid cylinder arrangement according to claim 1, characterized in that the annular piston ( 27 ) with the wall ( 24 ) of the lubricant space ( 23 ) is frictionally engaged, wherein the frictional force of this frictional connection is smaller than the frictional force between the piston rod ( 9 ) and the ring piston ( 27 ) acts. Fluid cylinder arrangement according to claim 1, characterized in that the fluid cylinder arrangement is a gas pressure spring. Fluid cylinder arrangement according to claim 1, characterized in that that it is designed to work with gas. Fluid cylinder arrangement according to claim 2, characterized in that the annular piston ( 46 ) is formed by an O-ring. Fluid cylinder arrangement according to claim 2, characterized in that the annular piston ( 46 ) with the wall ( 45 ) of the Ringeraums ( 42 ) forms an annular gap. Fluid cylinder arrangement according to claim 2, characterized in that the annular piston ( 46 ) with the wall ( 45 ) of the annulus ( 42 ) is frictionally engaged, wherein the frictional force of this frictional connection is smaller than the frictional force between the piston ( 35 ) and the ring piston ( 46 ) acts. Fluid cylinder arrangement according to claim 2, characterized in that the fluid cylinder arrangement is a gas tension spring is. Fluid cylinder arrangement according to claim 2, characterized characterized in that it is adapted to work with gas.