DE19515368A1 - Length-adjustable gas spring with release and actuator - Google Patents

Abstract

The actuator (82) and release (40) are joined by a Bowden cable (39) which engages a trip lever (50) pivoted in the release enclosure (49) to work with the trip pin (41). The spacer sleeve (38) has a wide recess (69) adjoining the spring housing (1) and an adjacent narrower multi-edged part (67). The locking sleeve (48) has a multi-edged sector (66) matching in section the edge part (68) at the end pointed towards the gas spring facing the valve pin (31). The release can be twisted round relative the spring from release to a locked condition in which the edge sector (66) comes into contact with the inside edge part (7) where this goes over into the wide end-stop surface (69). The two edge parts (66 and 67) are of identical multi-profile, the release turning between locking and release settings relative edge part (67) through an angle equal to half the angle of the specified multi-profile. The two edge parts form hexagonal sectors and the outside (65) of the sleeve (48) where this adjoins the edge sector (66) carries a ratchet sleeve whose external surface is designed as a non-twist surface matching the inner edge part (67). The release can be twisted round in relation to this fixed ratchet sleeve exterior.

Description

The invention relates to a length-adjustable gas spring according to the Oberbe handle of claim 1.

In such a from EP 0 564 776 A1 (corresponding to JP Hei-5-64 105) known length-adjustable gas spring is the adjuster device designed as a hydraulic adjusting device, the off release device is provided with elastic locking tongues can be locked with the gas spring. The locking tongues engage Snap projections into an undercut assigned to the gas spring. While this solution is satisfactory in terms of snapping, it is is relatively expensive in terms of production costs. It also adds that the hydraulic adjustment device is difficult to operate.

DE 42 36 732 A1 (corresponding to EP 0 595 357 A2) is a gas spring known with an adjusting device in which the Bowden cable is fixed in place on the gas spring and the one surrounding the rope Hose abuts an actuating pin.

DE 41 14 101 A1 describes a gas spring with an adjusting device known that has a Bowden cable. This is at the end of the piston rod an actuating lever is articulated which forms one in the hollow th valve rod arranged actuated.  

The invention has for its object a gas spring of the genus moderate type so that with a particularly simple design the trigger device the connection of the trigger device and gas spring is possible in a particularly simple manner.

This object is achieved by the features in the characterizing part solved part of claim 1. In that a Bowden cable is provided operation is very easy for the operator. The Ge Housing of the trigger device is only in the spacer sleeve of the gas pressed in and twisted by a small angle. It is resting then automatically. Releasing this connection is the reverse Direction ahead. Unintentional loosening is practically impossible sen. Under a polygonal area is not just an even four to understand square, hexagonal or octagonal profile, but a white test senses non-circular profile, possibly with protrusions that one Allow locking after twisting.

The configuration according to the invention can be used on the one hand with so-called called double tube gas springs, as in principle from DE-PS 18 12 282 (corresponding to US-PS 3,656,593, corresponding to JP-PS 846 405) are known. They can still be used with so-called double-tube gas springs known type, which have an additional support tube or protective tube, on which the fastening section is formed. Such known gas springs are for example from EP 0 133 524 B1 (corresponding to US-PS 4 979 718).

Further advantageous and at least partially inventive configurations result from the subclaims.

Further features, details and advantages of the invention emerge from the following description of an embodiment with reference to the drawing. It shows

Fig. 1 is a length-adjustable gas spring in longitudinal section,

Fig. 2, the triggering device of the gas spring in longitudinal section in the actuated position,

Fig. 3 shows the base plate with receiving and locking sleeve the triggering device in a side view according to the arrow III in Fig. 2,

Fig. 4 an operating lever in a side view,

Fig. 5 is a locking sleeve, in longitudinal section,

Fig. 6 shows the locking sleeve in plan view according to the arrow VI in Fig. 5,

Fig. 7 shows the tripping device, in a view from below in the locked position

Fig. 8, the release device in a view from below in the unlocked position and

Fig. 9 shows a cross section through the spacing sleeve according to the section line IX in FIG. 1.

The length-adjustable gas spring shown in FIG. 1 has a housing 1 , which essentially consists of two concentrically nested tubes with different diameters, namely an inner cylinder 2 and an outer cylinder 3 . An annular space 4 is formed between the outer cylinder 3 and the inner cylinder 2 due to the different diameter of the inner cylinder 2 and the outer cylinder 3 .

In the inner cylinder 2 , an approximately annular piston 5 is axially slidably arranged ver, which is sealed gas-tight with its outer circumference against the inner wall 7 of the inner cylinder 2 via a sealing ring 6 . The piston 5 is attached to one end of a piston rod 8 guided coaxially to the housing 1 . This piston rod 8 is led out of one end of the housing 1 . At this end, the housing 1 is closed by an end ring 9 , which is sealed gas-tight on its outer circumference by means of an annular seal 10 with respect to the inner wall 11 of the outer cylinder 3 . The end ring 9 is held axially outwards by flanging 12 of the outer cylinder 3 . On the inside is against the end ring 9 a cup-shaped sleeve 13 which receives a multi-lip seal 14 which rests with its lips sealingly against the piston rod 8 . As a result, gas escape along the surface of the piston rod 8 to the outside is prevented.

Against the sleeve 13 , a centering piece 15 which bears against the inner wall 11 of the outer cylinder 3 is supported from the interior of the housing 1 and is provided with ribs 16 on which the inner cylinder 2 is supported radially, that is to say centered, with its inner wall 7 . The inner cylinder 2 is also axially firmly supported on these ribs 16 , that is to say axially fixed on one side. Characterized in that only ribs 16 for centering and axial support from the inner cylinder 2 are provided, in this area the annular space 4 is connected to the housing space 17 in the inner cylinder 2 , which between the piston 5 , the piston rod outlet end of the Ge housing 1 and the inner wall 7th of the inner cylinder 2 is limited. Between the ribs 16 so overflow channels 18 between the housing space 17 and the annular space 4 are formed.

At the piston rod outlet opposite end of the housing 1 , a valve 19 is arranged, by means of which in the inner cylinder 2 between the piston 5 and the valve 19 located housing space 20 with the annular space 4 and thus the other housing space 17 connected or separated therefrom can.

The entire gas spring including the valve 19 is constructed essentially symmetrically to the central longitudinal axis 21 . The valve 19 has a valve body 22 which is formed from an outer section 23 and an inner section 24 . The outer portion 23 bears against the inner wall 11 of the outer cylinder 3 , whereby the valve body 22 is rela tively centered on the outer cylinder 3 . From the cylindrical section 24 of smaller diameter is against the inner wall 7 of the inner cylinder 2 , whereby a centering between the valve body 22 and the inner cylinder 2 and thus between the inner cylinder 2 and outer cylinder 3 takes place. In the transition area from section 23 to section 24 , a stop collar 25 is formed, by means of which the valve body 22 bears against the inner cylinder 2 in the axial direction. In the area of section 23, on the one hand, and section 24, on the other hand, ring seals 28 , 29 are arranged in corresponding ring grooves 26 , 27 , by means of which a gas-tight connection between section 23 and the inner wall 11 of the outer cylinder 3, on the one hand, and between the inner section 24 and the inner wall 7 of the inner cylinder 2 is reached on the other hand.

The valve body 22 is provided in the region of its outer portion 23 with a cylindrical, coaxial guide bore 30 in which a valve pin 31 is arranged, which protrudes outwards from the valve body 22 . This substantially cylindrical valve pin 31 is guided in the Füh approximately 30 bore. The valve body 22 has an overflow channel 32 which runs radially to the axis 21 and connects the annular space 4 to the guide bore 30 . The valve pin 31 has a constriction 33 which is always in overlap with the confluence of the overflow channel 32 in the guide bore 30 . On both sides of the Einschnü tion 33 22 ring seals 34 , 35 are arranged in the valve body, which bear sealingly against the valve pin 31 . The ring seal 34 always prevents gas escaping from the valve 19 to the outside. The ring seal 35 seals the housing space 20 against the ring space 4 and thus the housing space 17 when the valve is closed. When the valve pin 31 is pressed in the direction of the housing space 20 into the valve body 22 , the constriction 33 bridges the ring seal 35 , where the housing space 20 connects to the annular space 4 and thus to the other housing space 17 via the overflow channel 32 . Length adjustments of the gas spring are then possible. The basic structure and the principle of operation of this at least partially filled with compressed gas, length-adjustable gas spring is generally known, for example from DE-PS 18 12 282 (corresponding to US-PS 3,656,593, corresponding to JP-PS 846 405).

The housing 1 has in its drawing upper, the exit of the piston rod 8 opposite area a conically tapered BEFE stigungsabschnitt 36 , the edge 37 is drawn inwards towards the axis 21 . This edge 37 thus forms a stop for a spacer sleeve 38 , against which the valve body 22 is supported in the direction of the axis 21 . In the spacer sleeve 38 can be actuated by means of a Bowden cable 39 triggering device 40 is releasably held, the one arranged in alignment with the valve pin 31 and has lying against it to actuating pin 41st An actuation of the gas spring from the outside is done by moving the actuating pin 41 to the gas spring, whereby the valve pin 31 is pushed into the valve body 22 , which has the described effect.

The length-adjustable gas spring is used in a generally conventional manner in such a way that the conically tapered fastening section 36 is fastened in a corresponding holding device 42 to the underside of the seat 43 of a chair by means of cone clamping, and that otherwise the housing 1 of the gas spring in a guide bush 44 is one with a Fußge stell 45 of a chair connected standpipe 46 is displaceable in the direction of axis 21 , but is arranged transversely to it. The piston rod 8 is attached to a bottom of such a standpipe 46 . This configuration is very general practice.

The trigger device 40 has a base plate 47 on which a locking sleeve 48 is formed. On this opposite side of the base plate 47 , a receptacle 49 for an actuating lever 50 is formed on this. The base plate 47 , the locking sleeve 48 and the receptacle 49 are a one-piece component. In the locking sleeve 48 , the actuating pin 41 is guided. It comprises 48 abuts a collar 51 on the development sleeve against a corresponding stop 52 in the INTERLOCKS when the actuating pin 41 is inserted so far into the locking sleeve 48, that the valve pin 31 as far inserted into the valve body 22 derum 50 that the valve 19 is open. The collar 51 and the stop 52 thus form an insertion limit for the actuating pin 41st

The actuating lever 50 has a bearing pin 53 which is suspended in corresponding bearing openings 54 in side cheeks 55 of the receptacle 49 , so that the actuating lever 50 is pivotable about the pivot bearing 56 formed by the pivot pin 53 and the bearing opening 54 . The geometrically approximately the shape of an acute-angled triangle Be actuating lever 50 adjacent to the bearing pin 53 has a pressure surface 57 abutting against the actuating pin 41 . Above the bearing pin 53 and the pressure surface 57 and at a distance from this, a receiving eyelet 58 is formed on the actuating lever 50 for a fastening pin 59 of the cable 60 of the Bowden cable 39 . The flexible hose 61 surrounding the rope 69 of the Bowden cable 39 is fixed in a recess 63 in the rear wall 64 of the receptacle 49 by means of a support sleeve 62 . If the rope 60 is shifted relative to the hose 61 , then the actuating lever 50 is pivoted ver toward the rear wall 64 and thereby presses the actuating pin 41 into the locking sleeve 48 and thus opens the valve 19 . When the cable 60 is relieved, the valve pin 31 , which is pressed outwards by the gas pressure in the housing 1 , pushes the actuating pin 41 outwards again and there with the actuating lever 50 back into its starting position.

The locking sleeve 48 has a cylindrical outer wall 65 which extends over most of its total length. At its free end, that is to say away from the base plate 47 , it has an external hexagon section 66 . The spacer sleeve 38 has an inner hexagon area 67 concentric with the axis 21 , which is designed such that the outer hexagonal section 66 of the locking sleeve 48 is inserted slightly but essentially without play into the spacer sleeve 38 , who can.

The spacer sleeve 38 has in connection with the hollow inner hexagon area 67 to the gas spring towards the area 67 extended to the axis 21 concentric cylindrical recess 68 . A stop surface 69 is formed at the transition from area 67 to recess 68 .

The provided with a cylindrical outer wall 65 portion of the locking sleeve 48 is surrounded by a locking sleeve 70 which has a cylindrical outer wall 65 of the locking sleeve 48 adapted recess 71 and a longitudinal slot 72 , so that they deform under elastic deformation on the cylindrical outer wall 65 can be snapped and there between the base plate 47 and the outer hex section 66 in the direction of the axis 21 immovable, but relative to the locking sleeve 48 is rotatably held. The locking sleeve 70 has a continuous hexagonal outer surface 73 , which corresponds in its dimensions to the outer hexagonal section 66 when the locking sleeve 70 is snapped onto the locking sleeve 48 . The locking sleeve 70 is thus arranged after being inserted into the hexagon area 67 of the spacer sleeve 38 so that it cannot be rotated relative to the latter.

The locking sleeve 70 has a locking lever 74 resting on the base plate 47 , which is provided on its side facing the base plate 42 with a locking projection 75 . Associated with the latching projection 75 , two latching recesses 76 , 77 are formed in the base plate 47 , which are arranged relative to each other at an angle a of 30 ° relative to the axis 21 . The angle a is half the angle b of the outer hexagon section 66 . For the fact that the outer hexagon section 66 has b = 60 °, it follows that a = 30 °.

To mount the release device 40 in the spacer sleeve 38 , the locking sleeve 70 is in a position in which its locking projection 75 is locked in the locking recess 76 . In this relative position of the locking sleeve 70 to the locking sleeve 48 , the hexagon outer surface 73 of the locking sleeve 70 is in overlap with the external hex-section 66 , so that the locking sleeve 48 with the locking sleeve 70 in the inner hexagon area 67th the locking sleeve 48 can be inserted in the direction of the axis 21 towards the gas spring. The locking sleeve 70 is now with its hexagonal outer surface 73 non-rotatably in the hexagon area 67 . Now the trigger device 40 is rotated around the win kel a, whereby - since the locking sleeve 70 can not rotate relative to the spacer sleeve 38 - the locking lever 74 is deflected elastically in such a way that the locking projection 75 disengages from the locking recess 76 and after rotation by the angle a in the Rastausneh measurement 77 engages. The tips 78 of the outer hexagon section 66 now lie against the stop surface 69 of the spacer sleeve 68 ; the trigger device 40 can thus not be pulled out of the spacer sleeve 38 in this position. For disassembly, the Auslöseein device 40 is to be rotated into the described starting position, in which the locking projection 75 is located in the locking recess 76 . The locking sleeve Ver 48 is arranged in the direction of the axis 21 substantially without play in the spacer sleeve 38 . The locking sleeve 70 consists of a hard elastic plastic, which allows snapping onto the locking sleeve 48 and pivoting of the locking lever 74 in the direction of the axis 21 .

The spacer sleeve 38 is provided on its outside with ribs 79 which are supported against the inside of the fastening section 36 . At its end facing the valve body 22 , it is designed with a stop 80 for abutment against the end face 81 of the valve body 22 . It is made of plastic or a die-cast zinc or aluminum. Basically, it consists of softer material than the steel housing 1 of the gas spring.

The Bowden cable 39 is actuated by means of an actuating device 82 , which can be attached to the underside of the seat 43 or to an armrest of a chair. It has a housing 83 in which the hose 61 of the Bowden cable 39 is fixed in a length-adjustable manner by means of a screw sleeve 87 . An actuating lever 84 is pivotally mounted in the housing 83 about a pivot axis 85 , in which the cable 60 is suspended by means of a fastening pin 86 . In Fig. 1, the position of the actuating lever 84 is shown extended when the valve 19 is closed, while the actuating position, which otherwise corresponds to the representation in Fig. 2, is shown in broken lines.

As can be seen from FIG. 1, the triggering device 40 is designed such that it is seated on the end face of the housing 1 of the gas spring and does not protrude through it here. This leads to the fact that the fastening section 36 receiving conical holding device 42 can partially overlap with the trigger device 40 .

The trigger device 40 described above can be used in the same way in length-adjustable gas springs, ie in pneumatic or hydropneumatic length adjustment elements which, in addition to a double-tube gas spring, also have a support tube or protective tube surrounding the housing of this gas spring, on which the fastening section is formed. Such length-adjustable gas springs are known from EP 0 133 524 B1 (corresponding to US Pat. No. 4,979,718). They have a spacer sleeve between the housing of the gas spring and the upper edge of the fastening section, which sleeve is then to be designed in a manner corresponding to the distance 38 , so that the triggering device 40 can be snapped into place.

Claims (10)

1. Adjustable gas spring,
with a housing ( 1 ),
with a piston rod ( 8 ) led out of the housing ( 1 ),
with a valve pin ( 31 ) of a valve ( 19 ) which can be displaced in the direction of the housing ( 1 ) for length adjustment,
with an adjusting device for displacing the valve pin ( 31 ) towards the housing ( 1 ), which has a triggering device ( 40 ) which can be pushed into a spacer sleeve ( 38 ) assigned to the gas spring and an actuating device ( 82 ) connected to it, one on the valve pin ( 31 ) is coupled to the displaceable actuating pin ( 41 ) of the triggering device ( 40 ) with the actuating device ( 82 ), the adjusting device being designed as an independent assembly and with the triggering device ( 40 ) being detachably connected to the gas spring,
characterized,
that the actuating device ( 82 ) and the triggering device ( 40 ) are connected to one another by means of a Bowden cable ( 39 ), the Bow denzug ( 39 ) engaging an actuating lever ( 50 ) which in an acquisition ( 49 ) of the triggering device ( 40 ) is pivotally mounted and which interacts with the actuating pin ( 41 ),
that the spacer sleeve ( 38 ) has a recess ( 68 ) of larger width adjacent to the housing ( 1 ) of the gas spring and an adjoining inner polygonal region ( 67 ) of smaller width,
that the triggering device ( 40 ) is arranged with a locking sleeve ( 48 ), essentially in the inner polygonal region ( 67 ),
that the locking sleeve ( 48 ) on one of the valve pin ( 31 ) of the gas end facing the end with an inner polygonal region ( 67 ) in cross section adapted outer polygonal section ( 66 ) and
that the release device ( 40 ) can be rotated relative to the gas spring from an unlocking position into a locking position, that the outer polygonal section ( 66 ) in the locking position at a transition from the inner polygonal region ( 67 ) to the recess ( 68 ) larger width trained stop surface ( 69 ) comes to rest. 2. Gas spring according to claim 1, characterized in that the inner polygonal region ( 67 ) and the outer polygonal section ( 66 ) each have a uniform polygonal profile. 3. Gas spring according to claim 2, characterized in that the triggering device ( 40 ) is arranged in the locking position relative to the unlocking position by an angle (a) relative to the inner polygonal region ( 67 ) which is half the angle (b ) corresponds to the polygonal profile. 4. Gas spring according to claim 2, characterized in that the inner polygonal region as an inner hexagonal region ( 67 ) and the outer polygonal section are designed as an outer hexagonal section ( 66 ). 5. Gas spring according to claim 1, characterized in that the locking sleeve ( 48 ) adjacent to the outer polygonal section ( 66 ) has an outer wall ( 65 ) on which a locking sleeve ( 70 ) with an inner polygonal region ( 67 ) and opposite this non-rotatable polygonal outer surface ( 73 ) is arranged, against which the release device ( 40 ) between the unlocking position and the locking position is rotatable. 6. Gas spring according to claim 5, characterized in that the locking sleeve ( 70 ) is provided with a longitudinal slot ( 72 ) and is made of elastic material, and on the outer wall ( 65 ) of the locking sleeve ( 48 ) is snapped. 7. Gas spring according to claim 5, characterized in that the locking sleeve ( 70 ) in the unlocking position and in the locking position of the triggering device ( 40 ) has a stop relative to this. 8. Gas spring according to claim 6, characterized in that the locking sleeve ( 70 ) in the unlocking position and in the locking position of the release device ( 40 ) can be locked with this. 9. Gas spring according to claim 8, characterized in that the latching sleeve ( 70 ) has a latching part ( 75 ), which on the triggering device ( 40 ) are assigned two latching counterparts ( 76 , 77 ) which are arranged at an angular distance from one another, which corresponds to half the angle (b) of the polygonal profile. 10. Gas spring according to claim 9, characterized in that the locking sleeve ( 70 ) has a locking lever ( 74 ) projecting from it, on which the locking part ( 75 ) is formed.