DE10011693C1 - Gas spring for adjusting height of office chair has casing containing piston which divides it into two gas-filled chambers connected by valve which has overflow channels with different throttle effects which operate together or separately - Google Patents

Abstract

The gas spring for use in adjusting the height of an office chair has a casing (2) containing a piston (6) which divides it into two gas-filled chambers (4a, 4b) connected by a valve (20). This has overflow channels (30, 31) with different throttle effects which operate together or separately, depending on the position of the valve stem (22).

Description

The invention relates to a lockable gas spring with a in a pressure housing se axially displaceable piston held on the end of a piston rod, the one housing interior in two ge with a compressed pressure medium filled and connected via a valve working chambers divided, the valve passing through a valve body and by means of a valve pin closable valve channel.

Such, e.g. B. from DE 195 01 301 A1 or from DE 42 37 495 A1 Known gas spring is often used to adjust the height of a chair. About that In addition, such a gas spring is also used as a spring element of a z. B. synchronous mechanism for tilt adjustment known from EP 087 952 A1 the backrest of an office chair, especially in a unit with its seat area.

The gas spring usually has a cylindrical pressure housing in which a piston held at the end on a piston rod is guided. On both sides of the Pistons are working chambers formed with a pressure medium, for. B. with with a gas cushion of compressed oil or gas under pressure, are filled, and which are connected to each other via a valve. The valve can be actuated by means of a valve pin, which in a first gas spring variant slidably arranged and closed within a hollow piston rod together with this is led outside of the pressure housing. At this Variant, the piston carries the valve body directly into one of the working closable valve channel opening into chambers.

In a second gas spring variant, the valve pin is on the piston rod implementation opposite end of the gas spring to the outside of the Pressure housing. In this variant, the valve channel is located with the working chamber  via an annulus connected between an inner cylinder and an outer cylinder of the pressure housing which surrounds it coaxially det.

The valve is due to the in the gas spring, i.e. H. in their single or double cylinder pressure housing prevailing internal pressure closed. By exercising A pressure force on the valve pin or stem can force the valve against the inside pressure can be opened. This closes the valve previously closed Connection between the two work rooms released with the result that by actuating the piston rod, the pistons inside the housing Space of the pressure housing is axially displaceable. Failure to exercise the Pressure on the valve pin, the valve is automatically closed, whereby the gas spring is blocked in the respective position of the piston. By renewed Opening the valve of the prestressed gas spring causes the piston to move Force imbalance within the two working chambers practically jerky moved back to the equilibrium position and can be closed there by closing of the valve can be fixed again.

In particular in connection with the synchronous mechanism of a chair means this mode of operation that the backrest as a result of actuation of the valve and together with this the seat by shifting the weight in the The person sitting in the chair can be swiveled into an inclined position. Un If actuation of the valve then remains, the blockage the gas spring fixes the respective tilt position of the backrest seat unit. Similarly, the seat height of the chair can be adjusted using such a gas spring the.

Both for ergonomic reasons and in terms of an advantageous loading operability, it is desirable that when the gas spring valve is open the Friction is as low as possible, so that the height adjustment and / or synchronism Mechanism of the chair relatively easy in both directions when the gas spring is unlocked is common. However, low friction means that when the backrest is inclined  and blocked gas spring opening the valve a quasi-explosion like provision of the result of the inclination of the backrest tensioned gas spring causes. This is particularly critical if the on the Person seated in the chair without back contact with the backrest facing forward is inclined or has left the chair before opening the valve, because then the for a functional synchronous mechanism requires a large restoring force Gas spring an undesirably violent resetting of the valve when opening the valve Backrest in the starting position or lifting the chair off the floor can effect. This effect is also un when adjusting the height of a chair he wishes.

The invention is therefore based on the object of a lockable gas spring Specify the type mentioned, which is then also with the valve open relatively relaxed slowly if in the unlocked state a sufficient light is common.

This object is achieved according to the invention by the features of the claim 1. For this purpose, the valve body has a first connecting channel and one in the open position of the valve released second connection channel, the when the valve is opened, the first connecting channel is released has a smaller passage than the second connecting channel. Under passage the volume flow resulting at a given pressure difference is ver stood. In other words: the smaller the passage, the smaller it is Volume flow.

The invention is based on the consideration that a pulse-like Ent voltage when opening the valve a blocked in the preloaded state Gas spring can be avoided if between opening the Ven tils, d. H. the lifting of the valve pin from the valve seat and the maximum open Position of the valve is covered a relatively long way, during which the gas spring is already relaxed slowly and thus damped. This can be done can be achieved that with the opening of the valve a certain or defined  Proportion of the pressure fluid or medium via the connection between the Working chambers flow. Thus, a slow or muffled Ent occurs Tension the gas spring before the valve pin crosses the maximum flow Cut approved for the flow of the pressure medium through this connection Has. To do this, the valve pin should be in the position lifted from the valve seat - and thus while opening the valve - initially only a relatively small flow Release cross-section that is smaller than a second, maximum flow cross cut that is only released when the valve is fully open.

The opposite to the passage of the second connection channel or maximum Flow cross section comparatively small passage of the first connection channel or correspondingly small flow cross section can be targeted by a set play between the valve pin and the valve seat the. From the area and length of the formed as a result of this valve clearance The passage of the first connecting channel for the annular space then results Volume flow of the print medium.

In an advantageous embodiment, however, the first connection channel is one in the Valve body introduced, also labyrinthine through opening that between two spaced-apart sealing elements forming the valve seat in the valve channel opens. Thus, the first connection channel, i.e. H. the ver equally small flow cross section through an additional flow formed channel that passes through a wall comprising the valve channel and thus connecting the valve channel to the working chamber assigned to the valve seat det. The first connecting channel expediently opens into the Piston facing working chamber.

The valve channel is expedient - just like the pressure housing Gas spring itself - cylindrical. The valve pin guided in the valve channel shows preferably one adjoining a constriction area at the end cylindrical valve head, the axial length of which is dimensioned such that this still closes the second connecting channel when the valve is opened,  if a shoulder contour of the valve head facing the constriction area fes already releases the first connection channel. The axial length of the valve pin head provided at the end of the valve pin is greater than or equal to that axial distance between the sealing elements. Then in the open position of the Valve between the constriction area of the valve pin and the two The second connecting channel formed by the sealing elements is only then released When the valve head has passed both sealing elements and these at the same time are covered by the constriction area. This ensures that wäh After opening the valve until it is fully open, one for egg ne slow relaxation of the gas spring sufficiently long valve path or valve hub is available. This can be due to the distance between the two Sealing elements and adjusted by the axial length of the valve head or be be true.

To be as possible as possible with the valve open and thus with the gas spring unlocked rings friction and thus a desired smooth movement of the piston movement within the pressure housing both with the gas spring relaxed in both axial to reach directions as well as with relaxing gas spring, that shows Valve in the area of the working chamber facing away from the valve seat at least one NEN relatively large passage channel or a number of smaller passage channels on. With one that promotes the smooth movement of the unlocked gas spring Ratio between the passage of the passage channels and the passage of the second connecting channel or maximum flow cross section is the latter greater than the sum of the passage cross sections of the passage channels.

The expediently in the form of radially acting sealing rings led sealing elements are preferably provided in the valve body Ring grooves. This radial seal means that when the valve is closed and Particularly high tightness even when the first connecting channel is released speed between the sealing rings forming the valve seat and the valve pin ensures. In addition, the Ven Til channel and the valve pin reaches a relatively large second connecting channel  become. If the valve channel widens conically at the end of the channel de mouth opening, this can also be used as an insertion aid for the valve pin serve head when closing the valve.

The advantages achieved with the invention are in particular that Extension of the valve path of a lockable gas spring with release next, only one small compared to the maximum valve passage Pass a comparatively slow expansion along this valve path allows a gas spring previously locked in a tensioned state is. An impulsive relaxation of the gas spring is thus easier and more reliable avoided in a casual manner, while at the same time sufficient and therefore Comfortable smoothness is given.

Such a lockable gas spring is therefore particularly suitable as a Federele ment to adjust the inclination of a backrest or a backrest Seat unit provided synchronous mechanism of a chair, in particular one Office chair. It is also suitable as a spring and adjusting element or as a ver Adjusting and blocking element for height adjustment of such a chair. The one for that One of the valve bodies moved or executed separately by the gas spring piston is one on the one hand in a particularly simple manner for an additional connection duct expandable with comparatively small passage. On the other hand, in Connection with the valve pin in the valve channel for a slow Ent tension of the gas spring required comparatively large valve lift between the closed position and the open position of the valve can be specified. This in turn, regardless of the size of the ent for ease of movement locked gas spring required passage cross-sections of the main connection between the two working chambers separated by the piston become. The passage of the first connecting channel then forms a quasi be Act already with the valve actuation and before the main connection is released de, comparatively small secondary connection between the two work rooms mern.

The following are exemplary embodiments of the invention with reference to a drawing explained in more detail. In it show:

Fig. 1a-c in the longitudinal section of a first variant of a Gasfe the invention, with operable valve via a piston rod in three various valve positions which

Fig. 2a-c, in a representation according to FIG. 1, an alternative embodiment of the first gas spring variant,

Fig. 3 in longitudinal section a second variant of a gas spring according to the invention with a double-cylinder pressure housing, and

Fig. 4 in a side view of the gas spring as a spring element of an office chair.

Corresponding parts are in all figures with the same reference numerals Chen provided.

The gas spring 1 shown in Fig. 1a to 1c comprises a cylindrical pressure housing 2 , in which a housing interior 4 is divided by a piston 6 into two working chambers 4 a and 4 b. The two working chambers 4 a and 4 b are with a highly compressed pressure medium M, z. B. filled with oil and / or gas. The piston 6 is sealed by means of a sealing ring 8 against the inner housing wall 10 of the pressure housing 2 and forms a part of its axial length within the working chamber 4 a with the housing inner wall 10 an annular space 12th

The piston 6 is held at one end of a piston rod 14 which extends coaxially to the longitudinal axis 16 of the gas spring 1 within the working chamber 4 a. The piston rod 14 is with the end facing away from the piston 6 z. B. sealed in the manner shown in Fig. 3 out of the pressure housing 2 out. The piston 6 and the piston rod 14 , which is hollow in this gas spring variant and has a cavity 18 for this purpose, form a valve 20 with a valve body 21, which also serves as the piston 6, and with a valve pin which can be axially displaced within the cavity 18 of the piston rod 14 and can be actuated from the outside 22 . This carries at the end a valve pin head 22 a, which connects to a waisted pin section or constriction section 22 b. The valve pin 22 is outside or above the Einschnürungsab section 22 b by means of a sealing ring 23 against the cavity 18 of the piston rod 14 sealed.

In the area of the constriction section 22 b, a valve channel 24 with an annular cross section is formed within the valve 20 , which has two passage channels 25 a and 25 b running opposite one another and, in the exemplary embodiment, transverse to the longitudinal axis 16 , with the annular channel 12 and thus with the working chamber 4 a communicates. This in turn is connected to the working chamber 4 b via the valve channel 24 . This extends beyond a valve seat provided in the valve body 21 or in the piston 6 and expediently formed by two sealing rings 26 a, 26 b axially spaced apart in the longitudinal direction 16 into the working chamber 4 b. This can be seen comparatively clearly from the Dar positions according to FIGS. 1a and 1b. The sealing rings 26 a, 26 b are in the valve body 21 - and thus in this Gasfe der variant in the piston 6 - provided, not specified ring grooves. The or each sealing ring 26 a, 26 b may also einliegen in a valve pin 22 before seen groove. The valve channel 24 extends axially in the longitudinal direction 16 of the valve body 21 and thus in the opening direction 27 of the valve 20 .

The valve channel 24 is cylindrical and comprises a wall 28 formed on the piston 6 or the valve body 21 to form a circular opening opening 29 . In the area of this mouth opening or channel mouth 29 , the valve channel 24 is flared, which is particularly advantageous as an insertion aid for the valve pin head 22 a when closing the valve 20 .

While in the illustrated in Fig. 1c closed position of the valve 20 of the valve pin head 22 a at both the valve seat forming the seal rings 26 a, 26 b is applied, is a purely already from the sealing ring 26 a lifted in the position shown in Fig. 1b valve position of the valve pin head 22 , but is still within the valve channel 24 on the second sealing ring 26 b of the valve seat. In order with this valve position, that is during opening or during the opening of the valve 20, but to achieve already a slow relaxation of the gas spring 1 in FIG. Full or maximum open position of the valve 20 shown 1a before, only a first connection channel 30 is first coated with a comparatively small passage for the medium flowing between the working chambers 4 a, 4 b around M released.

To form this small passage or flow cross-section, a straight, oblique or labyrinth-like transverse bore is formed in the valve body 21 as the first connecting channel 30 , the shortest possible and straightest channel course being advantageous solely for manufacturing reasons. The connec tion channel 30 is passed through the valve body 21 and opens between the two sealing rings forming the valve seat 26 a and 26 b in the valve channel 24 . The size of the passage formed by the first connecting channel 30 determines the volume flow between the two working chambers 4 a and 4 b that results at a given pressure difference.

The smaller the passage of the first connecting channel 30 , the smaller the volume flow. As a result, the degree of relaxation of the gas spring 1 and thus the relaxation rate can be set. Thus, the gas spring 1 can at least partially relax before the valve pin head 22 a has released a maximum, second connecting channel 31 corresponding to the valve position of the valve 20 shown in FIG. 1 a . Its passage is significantly larger than the passage of the first connecting channel 30 . The valve stroke between the closed position shown in FIG. 1c and the open position of the valve 20 shown in FIG. 1a is determined by the distance a between the two sealing rings 26 a and 26 b forming the valve seat, this distance a being greater than or equal to the axial Length or head length b of the valve pin head 22 a.

The passage of the two passage channels 25 a and 25 b is expediently dimensioned such that the total passage formed by this and by the valve channel 24 is greater than or equal to the passage of the maximum, second connection channel 31 . Overall, the total passage determined by the two passage channels 25 a and 25 b is dimensioned such that the friction is as low as possible when the valve 20 is completely open and thus when the gas spring 1 is unlocked.

In the embodiment shown to 2b in Fig. 2a this gas spring variant for the formation of the comparatively small first connecting channel 30 between the valve pin head 22 a and the here made only by the single sealing ring 26 a formed valve seat, a defined play. The game the first connec tion channel 30 is dimensioned such that in the valve position shown in Fig. 2b, a defined annular passage is formed. This - compared to the passage of the second valve channel 31 - small passage already allows an at least low medium flow or volume flow between the two working chambers 4 a and 4 b before the valve 20 has reached the full open position shown in FIG. 2a and the valve pin head 22 a in turn releases the second maximum connecting channel 31 .

The blocked gas spring 1 shown in FIGS. 1c and 2c in the closed valve position can thus slowly relax already during the opening process of the valve 20 . The time period during which the gas spring 1 slowly released upon opening of the valve 20 depends on the valve stroke, and thus on the valve travel, the valve pin head 22 a at a given Öffnungsgeschwin speed, that from the closed position to the open position of the valve 20 to the release of passes through second connecting channel 31 . This period, during which the gas spring 1 first relaxes slowly, can be determined by the channel length or cylinder height of the valve channel 24 , which is greater than or equal to the head length b of the valve pin head 22 a, and thus by the length of the valve path. In the exemplary embodiment according to FIG. 2, the axial length b of the valve pin head 22 a corresponds to the cylinder height of the section A of the valve channel 24 surrounding it in the closed position of the valve 20 . While in the execution 1 of this section A shown in FIG. Of the valve channel 24, the length of the head B via rises, the diameter d of this section A for both versions accelerator as Figs. 1 and 2, preferably equal to, or at least only slightly klei ner than the cylinder height .

In the gas spring variant shown in FIG. 3, the gas spring 1 comprises a double fur-cylindrical pressure housing 2 with an outer cylinder 2 a and an inner cylinder 2 b co-axially surrounded by the latter. Between these, an annular channel 32 is formed as a connection between the two working chambers 4 a and 4 b. The in the working chamber 4 b in the exemplary embodiment in turn axially displaceable piston 6 is opposite the valve body 21 , which is sealed by means of a sealing ring 33 against the outer cylinder 2 a. The valve pin 22 of the valve 20 is guided on the front side of the gas spring 1 opposite the piston rod 14 via a cylindrical shaft 35 provided with an external thread 34 to the outside of the pressure housing 2 .

The piston-back working chamber 4 a is via openings 36 with the ring channel 32 in connection. In this exemplary embodiment, this in turn is connected to the second working chamber 4 b via only a single passage channel 25 , which in turn opens into the valve channel 24 , when the valve 20 is at least partially open. The valve pin head 22 a, which in turn is sealed by means of the sealing rings 26 a and 26 b forming the valve seat, initially also only opens the first connecting channel 30 when the valve 20 is opened, which in turn opens into the valve channel 24 between the two sealing rings 26 a and 26 b and the latter connects to the working chamber 4 b.

The first valve channel 30 , again with a comparatively small passage, is formed by a preferably obliquely extending through-hole, which - starting from a starting point between the two sealing rings 26 a and 26 b, which in turn is preferably closer to the upper sealing ring 26 a - expediently in this variant for Front side of the valve body 21 runs.

Only when the valve pin head 22 a has passed through the sealing rings 26 a and 26 in the fully open position of the valve 20 , is the second connecting channel 31 with the comparatively large passage released. In this position - analogous to the illustration in FIG. 1a - the insertion area 22 b covers the entire valve seat and thus both sealing rings 26 a and 26 b, between which and the constriction area 22 b there is then a correspondingly large passage for the medium M.

In contrast, the constriction area 22 b in the only partially open valve position - as shown in FIG. 1 b - only covers the area of the upper sealing ring 26 a in the illustrations and the first connecting channel 30 . The valve pin head 22 a, which extends from a region at the transition to Einschnürungsbe 22 b resulting shoulder contour 37 to the front end 38 of which he then lies on the valve seat formed by the lower sealing ring 26 b Ven. Thus, in this position of the valve 20, in turn only the first connecting channel 30 is released, the passage of which is substantially smaller than the passage of the second connecting channel 31 released in the open position of the valve 20 , which is not illustrated in this illustration.

While only a small volume flow is passed through the annular space 32 and the passage channel 25 and via the connection channel 24 between the two working chambers 4 a and 4 b due to their pressure difference when the first connecting channel 30 is released, due to the comparatively large passage of the valve 20 when it is open released second Verbindungska nals 31 the volume flow of the medium M is comparatively large. In this gas spring variant, compressed gas is expediently provided as the medium M, while in the gas spring variant according to FIGS. 1 and 2, compressed oil is preferably used by means of a gas cushion.

When the valve 20 is open - as in the gas spring variant shown in FIGS . 1 and 2 - the piston 6 is axially displaceable, while it is blocked when the valve 20 is closed. When the valve 20 opens and the gas spring 1 is pre-tensioned, the piston 6 is initially guided slowly within the pressure housing 2 in the direction of its equilibrium position. Only when the valve 20 is fully open is the piston 6 returned relatively quickly to the equilibrium position over the remaining piston travel.

The low friction in the unlocked state of the gas spring 1 on the one hand as well as during the opening of the valve 20 initially slow relaxation of the gas spring 1 on the other hand combines two particularly advantageous properties of the gas spring 1 in its use as a spring element of a synchronous mechanism nes ei in Fig. Office chair 40 shown in Figure 4 . In such a chair 40 with an unspecified synchronous mechanism for the inclination adjustment of a backrest 42 , this is articulated via a ben beneath a seat 44 extending linkage 46 to a frame stand 48 via a swivel 50 articulated Lich. The frame stand 48 is part of a bogie 52 with a frame base 56 provided with rollers 54 . The gas spring 1 is on the one hand - in the exemplary embodiment with its pressure housing 2 - attached to the frame stand 48 and on the other hand with the piston rod 14 on the backrest arm 56 . Such a gas spring 1 can alternatively or additionally also be used as a spring and adjustment element for height adjustment, the gas spring variant according to FIG. 3 and the gas spring variant according to FIGS. 1 or 2 being particularly suitable for height adjustment.

With the valve 20 open and thus with the gas spring 1 unlocked, the backrest 42 can be pivoted backwards and downwards. The valve 20 is opened as a result of pressure being exerted on the valve pin 22 by usually manual actuation via an actuating element (not shown) provided on the chair 40 below the seat surface 44 . If the pressure on the actuating lever and thus released on the valve pin 22 , the valve 20 is automatically closed as a result of the internal pressure prevailing in the working chamber 4 b facing the valve pin head 22 a and the gas spring 1 is blocked. The backrest 42 then remains in the set inclination position.

The backrest 42 pivots back into the upright position and thus into the starting position when the valve 20 is opened again. The opening process of the valve 20 is initiated by lifting the valve pin head 22 a from the valve seat 26 a, from which point in time a slow relaxation of the gas spring 1 takes place due to the release of the first, comparatively small connecting channel 30 . Only when the valve pin 22 has moved through the valve channel 24 until the release of the two, comparatively large connecting channel 31 by moving the valve pin 22 in the longitudinal direction 16 of the valve pin head 22 , does the gas spring 1 completely relax. At this time, however, the gas spring 1 is already at least partially relaxed. The restoring force of the gas spring 1 is thus already so low when the valve 20 is fully open that no pulse-like resetting of the backrest 42 into the starting position can take place, especially since the backrest 42 has already reached the starting position at least approximately at this point in time. The effect and the mode of operation of the gas spring 1 used for height adjustment is analogous.

The coupled via the valve pin 22 to the valve 20 actuator for manual actuation of the gas spring 1 for an inclination adjustment is carried out in a manner not shown here in the form of a slide which is guided along a relatively long path. Such a sliding movement is advantageous in order to avoid a reduction in the coupling point between the actuating element and the valve pin 22 . As a result of the comparatively small passage caused by the first connecting channel 30 , only slow release of the gas spring 1 takes place during the sliding movement of the actuating element before it enables the second connecting channel and thus the comparatively large passage in a locking position. The actuating slide is preferably moved in the seat plane from the front edge of the seat to the rear edge of the seat. A long sliding path is therefore an advantage.

In a manner not shown in detail, when the gas spring 1 is actuated by means of the actuating slide, it is expediently guided into the unlocking position against the force of a spring. As a result, the gas spring 1 is blocked again when the actuating slide has not been moved completely into the locking position.

Claims (10)

1. Blockable gas spring ( 1 ) with a in a pressure housing ( 2 ) axially displaceable ver and on a piston rod ( 14 ) end-held piston ( 6 ), the one housing interior ( 4 ) in two filled with a compressed pressure medium (M) and over a valve ( 20 ) communicating with each other working chambers ( 4 a, 4 b) divided, the valve ( 20 ) ei nen a valve body ( 21 ) penetrating and by means of a valve pin ( 22 ) closable valve channel ( 24 ), characterized that the valve body (21) having a first connection channel (30), whose passage is smaller than the passage of a shared in the open position of the valve (20) second connection channel (31), said Ven tilstift (22) when opening the valve (20 ) initially only releases the first connecting channel ( 30 ). 2. Lockable gas spring according to claim 2, characterized in that in the valve channel ( 24 ) in the region of a constriction section ( 22 b) of the valve pin ( 22 ) at least one passage channel ( 25 ) opens, the passage or the total passage larger than the passage of the first connection channel ( 30 ) and at least equal to the passage of the second connection channel ( 31 ). 3. Lockable gas spring according to claim 1 or 2, characterized by a in the valve body ( 21 ) by two spaced Dichtele elements ( 26 a, 26 b) formed valve seat, the first connecting channel ( 30 ) between the sealing elements ( 26 a, 26 b ) mün det in the valve channel ( 24 ). 4. Locking gas spring according to claim 3, characterized in that the axial length (b) of one (22) of the end side provided for the valve pin head (22 a) is greater than or equal to the axial distance (a) between the sealing elements (26 a, b 26) on the valve pin is. 5. Lockable gas spring according to claims 3 or 4, characterized in that the second connecting channel ( 31 ) in the open position of the valve ( 20 ) between a constriction area ( 22 b) of the valve pin ( 22 ) and the two sealing elements ( 26 a, 26 b) is formed. 6. Locking gas spring according to one of claims 1 to 5, characterized in that the first connection channel (30) which opens to the piston (6) to the front side facing the working chamber (4 b). 7. Lockable gas spring according to one of claims 1 to 6, characterized in that the valve channel ( 24 ) has a conically widening mouth opening ( 29 ). 8. Use of a lockable gas spring ( 1 ) according to one of claims 1 to 7 as a spring element of a height adjustment and / or a synchronous mechanism of a piece of seating ( 40 ), in particular an office chair, for inclination adjustment of a backrest ( 42 ) or this unit with one Seat ( 44 ). 9. chair, in particular office chair, with a lockable gas spring ( 1 ) according to one of claims 1 to 7 as a spring element for height adjustment, wherein the gas spring ( 1 ) has a double-cylinder pressure housing ( 2 a, 2 b), and wherein the valve pin ( 21 ) and the piston rod ( 14 ) on opposite end faces of the gas spring ( 1 ) are guided outside the pressure housing ( 2 ). 10. Chair, in particular office chair, with a lockable gas spring ( 1 ) according to one of claims 1 to 7 as a spring element for tilt adjustment egg ner backrest ( 42 ) or this in unit with a seat ( 44 ), the valve pin ( 21 ) in the to the outside of the pressure housing ( 2 ) guided Kol rod ( 14 ) is arranged axially displaceable.