DE3615688A1 - LENGTH ADJUSTABLE GAS SPRINGS AND ACTUATING DEVICE HERE - Google Patents

Description

The invention relates to an adjustable length Gas spring according to the preamble of claim 1 and an actuator for this after Preamble of claim 4.

Such gas springs are for example from the DE-PS 18 12 282 (corresponding to US-PS 36 56 593) known. Because of their beneficial properties, especially as length-adjustable lifting devices in chair columns and the like, these gas springs extremely proven in practice.

There are numerous controls for this in its simplest, from DE-PS 19 31 012 (corresponding to US-PS 37 11 054) known Ausgestal tion are approximately pot-shaped, wherein a flange for attachment to the underside  a seat and a receiving section are provided who picks up and holds the end of the gas spring, in which the valve is located and from which the Valve pin protrudes to actuate the valve. In this actuator is a release He hinged, one of which is short, that lies within the actuating device End when the free end of the Operating lever the valve pin into the gas spring pushes in, which opens the valve and The piston rod moves in or out Gas spring and thus a change in length of the Gas spring can be enabled.

The in and out movement of the piston rod is damped by the fact that in the area of the valve a throttle opening is provided so that the when the pistons move in or out rod from one housing space to the other housing space flowing gas is dampened in its flow becomes.

The invention has for its object a To further develop gas springs of the generic type that a variable freely selectable by the user and extension speed of the piston rod reached will and an actuator for this give.

The object underlying the invention will with a gas spring of the generic type the features in the characterizing part of claim 1 solved. Characterized in that a throttle device can be seen, whose free throttle cross section from  Depends on the degree of insertion of the valve pin, can be inserted by inserting it accordingly different speed of length adjustment movement of the gas spring can be achieved. So that can this speed of length adjustment adapted to the personal needs of the user will.

The measures according to claim 2 lead to a structurally particularly simple and special Exact design of the throttle direction, which is also particularly sensitive is operable. Claim 3 gives a constructive Design for this.

The object underlying the invention will with regard to the actuator the features in the characterizing part of claim 4 solved. These measures will not make it Sensitivity left to the operator, the speed speed of the adjustment movements, i.e. the input and Extension movement of the piston rod relative to the housing, to stop; rather, he can use the trigger lever swivel as usual against a stop.

A particularly simple embodiment of such Device for limiting the swivel path is specified in claim 5. Through continuing education according to claim 6 it is achieved that the user the speed of the length adjustment the gas spring can adjust itself and also one Can change this setting. To this end, claim 7 specifies a concrete solution.  

Claims 8 to 10 give advantageous details again. The further training according to claim 11 ensures that there is a swivel path limitation cannot inadvertently change.

Further details of the invention emerge from the following description of execution examples using the drawing. It shows

Fig. 1 shows a longitudinal section through a gas spring according to the invention,

Fig. 2, the valve of the gas spring of FIG. 1 in an enlarged scale,

Fig. 3 is an actuating apparatus for the Gasfe, according to the invention in longitudinal section,

Fig. 4 shows a section through the actuating device according to the section line IV-IV in Fig. 3 and

Fig. 5 shows a longitudinal section through a modified embodiment of a valve of the gas spring of FIG. 1 in an enlarged scale.

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

In the inner cylinder 2 , an approximately annular piston 5 is arranged axially displaceably, 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 a cover plate 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. The end plate 9 is held axially outwards by a flange 12 of the outer cylinder 3 . On the inside is against the lens 9 a cup-shaped sleeve 13 which receives a multi-lip pen seal 14 which rests with its lips sealingly against the piston rod 8 . As a result, gas leakage along the surface of the piston rod 8 to the outside is prevented.

Against the sleeve 13 , from the interior of the housing 1, a centering piece 15 resting against the inner wall 11 of the outer cylinder 3 is provided, which is provided with ribs 16 , on which the inner cylinder 2 is radially supported, ie centered, with its inner wall 7 . On these ribs 16 , the inner cylinder 2 is also axially firmly supported, that is, axially fixed on one side. The fact that only ribs 16 are provided for centering and axial support of the inner cylinder 2 , 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 housing 1 and the inner wall 7th of the inner cylinder 2 is limited. Between the ribs 16 Überströmka channels 18 between the housing space 17 and the ring space 4 are formed.

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

The valve 19 shown enlarged in FIG. 2 has a valve body 21 which has an outer section 22 abutting the inner wall 11 of the outer cylinder 3 and an inner section 23 abutting the inner wall 7 of the inner cylinder 2 . Both sections 22 , 23 are formed coaxially to one another and center the inner cylinder 2 and the outer cylinder 3 coaxially to one another. If one speaks in the description of "axial" or "coaxial", this always refers to the central longitudinal axis 24 of the gas spring, which is also the axis of symmetry of all individual parts and assemblies.

At the transition from the inner section 23 to the outer section 22 , a shoulder 25 is formed in the outer surface of the valve body, against which the associated edge of the inner cylinder 2 abuts.

In both sections 22 , 23 , a sealing ring 26 , 27 is in each case in a corresponding annular groove, the sealing wall against the corresponding inner wall 11 and 7 , so that the gas spring is sealed gas-tight in this area. The outer cylinder 3 is guided over the outer section 22 and fixed at its outer end with a flange 28 , so that the valve body 19 abutting against the inner cylinder 2 is fixed in the housing 1 and also all assemblies of the gas spring are axially fixed against one another. Coaxial to the flange 28 and within it, the outer section 22 protrudes slightly from the housing 1 of the gas spring.

In the outer section 22 of the valve body 21 , a cylindrical coaxial guide bore 29 is provided, to which a likewise cylindrical valve body interior space 30 connects to the housing space 20 . This interior space 30 has a larger diameter than the guide bore 29 . An overflow channel 31 , which penetrates radially through the valve body 21 and opens into the annular space 4 on its outside, opens into the interior 30 .

In the valve body 21, a valve pin 32 is arranged, the maximum protruding outward from the outer portion 22 of the valve body 21 by a valve pin stroke a. This essentially cylindrical valve pin is guided in the guide bore 29 . At the transition from the guide bore 29 to the inner space 30 , an inner ring seal 33 is arranged, which is fixed axially to the outside by the transition from the inner space 30 to the guide bore 29 and which rests radially on the one hand on the valve pin 32 and on the other hand on the wall of the interior 30 , so that a gas leak through the guide bore 29 is excluded. The inner-ring seal 33 is axially fixed in the direction of the housing space 20 by a distance sleeve 34 which is provided with a throttle opening 35, so that the gas from the annular chamber 4 through the overflow 31 in the spacer sleeve 34 can pass.

At the housing space 20 facing the end of the spacer sleeve 34 is also an inner ring seal 36 , which rests radially against the inner wall of the interior 30 and against the valve pin 32 . Axially towards the housing space 20 , it bears against a contact surface of a flange sleeve 37 , the flange 38 of which bears against the end face 39 of the valve body 21 facing the housing space 20 and is overlapped and held axially by an axially projecting annular cylindrical edge 40 of the valve body. The flange sleeve 37 has a coaxial bore 41 , the diameter of which is somewhat larger than the diameter of the valve pin 32 in this area, so that an annular passage channel 42 is formed here.

The valve pin 32 has a stop plate 43 at its end located in the housing space 20 , so that it cannot be pushed outwards by the gas pressure. In the rest position shown, the stop plate 43 adjacent cylindrical portion 44 of the valve pin 32 is in the system against the housing ring 20 adjacent inner ring seal 36 , so that when the valve 19 is closed, a gas flow between the housing space 20 and the annular space 4 is prevented.

The outer cylindrical section 45 of the valve pin 32 is always in contact with the outer inner ring seal 33 . Between these two cylindrical portions 44, 45 of the valve pin 32 is a constriction 46, so that the housing space 20 facing the inner-ring seal 36 bridges during insertion of the valve pin 32 in the valve body 21, the constriction 46, so that the gas spring filling pressure gas can flow from the housing space 17 through the annular space 4 , the Ventilkör by interior 30 and the passage 42 in the housing space 20 and vice versa. This basic mode of operation of this length-adjustable gas spring and its suspension properties when the valve 19 is closed are generally known, for example from DE-PS 18 12 282 (corresponding to US-PS 36 56 593).

The valve pin 32 is in the area of the constriction, starting from the inner cylindrical section 44 facing the housing space 20 , tapering slowly, ie it has a continuously tapering frustoconical throttle section 47 , the axial length b of which is approximately the valve pin Stroke a corresponds. The taper of this throttle section 47 is so small that a throttle gap 48 is formed between the throttle section 47 when the valve pin 32 is partially inserted into the valve body 21 , the cross section F of which depends on how deep the valve pin 32 is pushed into the valve body 21 , ie by which Fraction of a the valve pin 32 is inserted into the valve body 21 .

The retraction and extension speed of the piston rod 8 can thus be influenced by pressing the valve pin 32 into the valve body 21 at different depths. The transition from the throttle section 47 to the outer cylindrical section 45 of the valve pin 32 is formed in the usual way by a short cylindrical core section 49 and a transition surface 50 . If, in the usual way, the valve pin stroke a is between 6 and 8 mm, as is the case when such gas springs are used for chair columns, then the length b of the throttle section is also approximately 6 to 8 mm.

An actuating device for inserting the valve pin 32 into the housing 1 at different depths is shown in FIGS. 3 and 4. In the application shown, the gas spring is used as part of a chair column for height adjustment of the seat of a chair or armchair, as is known in principle from DE-PS 19 31 012 (accordingly US-PS 37 11 054). A fastening device 51 is provided which is cup-shaped and has a fastening flange 52 to be attached to the underside of a seat. A on this flange 52 on receiving portion 53 has a slightly conical receiving bore 54 into which a corresponding slightly conical housing valve 55 surrounding the valve 19 is inserted, so that the gas spring is axially fixed but releasable and also non-rotatable is held clamped in the fastening device 51 . The axial position of the housing 1 of the gas spring relative to the fastening device 51 can also be determined very precisely by correspondingly precise manufacture. Otherwise, any other suitable type of axial and tangential fixing of the gas spring can be used in such a fastening device, as are known in many variants.

Between the receiving section 53 and the BEFE stigungsflansch 52 of the device 51 , a bearing section 56 is ausgebil det for a trigger lever 57 . This section 56 has an opening 58 through which the lever 57 is inserted into the fastening device 51 so that its one end is above the pressure surface 59 of the valve pin 32 formed by its end face. The lever 57 is mounted directly adjacent to the opening 58 in the bearing section 56 so as to be pivotable about an axis 60 or the like by means of a pin, an adapter sleeve. is formed. The direction of this axis 60 is perpendicular to the central longitudinal axis 24 , so that the actuating end 61 of the lever 57 assigned to the pressure surface 59 of the valve pin 32 moves in the direction of the axis 24 during pivoting movements. The trigger-He bel 57 is provided at its end 61 opposite the actuator operating end 62 with a handle 63rd On the lever 57 between the handle 63 and the axis 60, a tubular adjusting sleeve 64 is freely rotatable and axially displaceable, which is provided on its end face adjacent to the axis 60 with locking recesses 65 . At its end adjacent to the handle 63 , it is provided with a rotary handle 66 which surrounds a prestressed helical compression spring 67 which presses the adjusting sleeve 64 against the axis 60 . The axis 60 engages with part of its circumference in two diametrically opposed locking recesses 65 , so that the adjusting sleeve 64 is secured against unintentional rotation relative to the trigger lever 57 . When the adjusting sleeve 64 is deliberately rotated by applying a corresponding torque to the rotary handle 66 , the adjusting sleeve 64 is rotated with respective axial displacement.

A stop element 68 is formed on the adjusting sleeve 64 in the vicinity of the axis 60 . This stop element 68 is approximately annular disc-shaped and arranged eccentrically to the longitudinal axis 69 of the release lever 57 and the adjusting sleeve 64 . The outer circumferential surface of the stop element 68 serves as a stop surface 70 . This is in the assigned area of the mounting flange 52 of the fastening device 51 a support surface 71 is assigned, against which the stop surface 70 at a Hochschwen ken the operating end 62 of the lever 57 according to the pivot direction arrow 72 for inserting the valve pin 32 into the gas spring comes to rest. If - as shown in Fig. 3 and 4 - the A-adjusting sleeve 64 is set so that the effective stop surface 70 has the radially largest possible distance c from the longitudinal axis 69 , then there is only the least possible pivoting, ie only the least possible insertion of the valve pin 32 possible in the gas spring. It is therefore only possible to set the smallest possible throttle gap 48 ; the speed of the retraction and extension movements of the piston rod 8 , ie the lifting and lowering speed of the chair seat has the lowest possible value.

If, on the other hand, the effective stop surface 70 is where its distance d from the longitudinal axis 69 is the smallest, then the valve pin 32 can be inserted by its full stroke a , ie the throttle gap 48 has its largest possible cross section; the damping of the retraction and extension movements is lowest when the eccentricity e of the stop element 68 formed by c - d = e is somewhat greater than the maximum valve pin stroke a ; then the adjusting sleeve 64 can also be used to adjust the axial position of the valve pin 32, which is not absolutely identical in every installation case, relative to the fastening device 51 .

Instead of the stop element 68 with a stop surface 70 extending eccentrically on the outer circumference, a stop element can also be provided which has a screw-shaped stop surface which runs in the manner of a partial screw turn and which is assigned a nose-shaped support surface on the underside of the flange 52 . Depending on the rotary setting of the adjusting sleeve comes in this case with pivoting movements of the trigger lever 57 according to the pivoting direction 72 then the helical stop surface to bear against such a support surface.

The modified embodiment of a valve 19 'according to FIG. 5 differs essentially from the embodiment according to FIGS. 1 and 2 in that the valve pin 32 ' is not pressed by a, but is twisted into the valve body 21 . For this reason, all parts identical to the embodiment according to FIGS . 1 and 2 are provided with identical reference numbers, with respect to which a new description will not be given. As far as parts are functionally identical, but structurally different, they are denoted with the same reference number and also with a hochge put '.

In this embodiment, at the housing 20 facing the end of the valve pin 32 ', a guide member 74 rotatably - for example by riveting - attached, which is provided with a non-perpendicular to the axis 24 , so inclined guide surface 75 . At the housing space 20 side of the flange sleeve is' provided with a corresponding inclined guiding surface 76 so that tes 32 upon rotation of the Ventilstif '37 inserted according to the direction of rotation arrow 77, the valve pin 32' in the valve body 21 inserted is such that the effects described above occur. Of course, the flange sleeve 37 'must also be held non-rotatably in the valve body 21 . It may also be sufficient if, instead of the guide part 74, only one on the guide surface 76 of the flange sleeve 37 'guided radially from the valve pin 32 ' projecting pin is provided.

The maximum stroke a 'is predetermined by the slope of the guide surfaces 75 , 76 . So that the valve pin 32 'can be rotated according to the direction of rotation arrow 77 , at the end lying outside the gas spring at least one flat surface for rotationally fixed attachment of a corresponding pivot lever is formed.

The configurations of the valves 19 and 19 'can of course also be used in an embodiment of the gas spring according to EP-OS 01 69 418 or DE-OS 31 02 276.

Claims (11)

1. Length-adjustable gas spring, with at least one at least partially filled with a compressed gas cylinder ( 2 , 3 ) with a sliding in the cylinder ( 2 ) and on the inner wall with a seal ( 6 ), the interior of the cylinder ( 2 ) in two housing spaces ( 17 , 20 ) separating piston ( 5 ), which is connected to a cylinder end sealed to the outside led out piston rod ( 8 ), with a cylinder ( 2 , 3 ) at one end to the outside from closing valve (19, 19 '), said valve (19, 19') comprises a valve body (21) sealed to the inner wall (7) abuts the cylinder (2), wherein the valve body (21) by a valve pin (32 , 32 ') axially penetrated valve body interior ( 30 ) is formed, which by an inner ring seal ( 33 ) bearing against the valve pin ( 32 , 32 ') and a spaced inner ring seal ( 36 ) to the adjacent housing space ( 20 ) h is sealed in, wherein the valve ( 19 , 19 ') adjacent housing space ( 20 ) when the valve ( 19 , 19 ') is open via the valve and a bridging channel (ring space 4 ) with the other housing space ( 17 ), and wherein the valve pin ( 32 , 32 ') with a closed valve ( 19 ) between the inner ring seals ( 33 , 36 ) arranged constriction ( 46 ) is provided which when inserting the Ventilstif tes ( 32 , 32 ') in the Valve body ( 21 ) by a maximum of a maximum valve pin stroke ( a , a ') bridges the inner ring seal ( 36 ) assigned to the adjacent housing space ( 20 ) and thus opens the valve ( 19 , 19 '), characterized in that the valve pin ( 32 , 32 ') is associated with a throttle device, the free throttle cross section ( F ) of the degree of insertion of the valve pin ( 32 , 32 ') - based on the maximum valve pin stroke ( a , a ') - depends. 2. Gas spring according to claim 1, characterized in that the valve pin ( 32 , 32 ') is provided in the region of its constriction ( 46 ) with an outwardly tapering throttle section ( 47 ), between which and the adjacent housing space ( 20 ) associated inner ring seal ( 36 ) when inserting the valve pin ( 32 , 32 ') a throttle gap ( 48 ) is formed. 3. Gas spring according to claim 2, characterized in that the valve pin ( 32 , 32 ') tapers conically in the region of the constriction ( 46 ). 4. Actuating device for a length-adjustable gas spring according to claim 1, with an axis ( 60 ) mounted trigger lever ( 57 ), by means of which one end of the valve pin ( 32 ) of the gas spring can be pushed into the gas spring by pivoting the lever ( 57 ) is characterized in that a device for limiting the pivoting path of the trigger lever ( 57 ) to a part of the maximum valve pin stroke ( a ) is provided. 5. Actuating device according to claim 4, characterized in that the trigger lever ( 57 ) is provided with a stop element ( 68 ), the stop surface ( 70 ) of which is assigned a support surface ( 71 ) which is stationary relative to the gas spring. 6. Actuating device according to claim 4, characterized in that the device for limiting the pivoting path of the release lever ( 57 ) to under different parts of the maximum valve pin stroke ( a ) is adjustable. 7. Actuating device according to claim 5, characterized in that the stop element ( 68 ) and / or the support surface ( 71 ) are adjustable. 8. Actuating device according to claim 5, characterized in that the stop element ( 68 ) is rotatably arranged ver on the release lever ( 57 ) and that the position of its stop surface ( 70 ) relative to the support surface ( 71 ) is adjustable by turning. 9. Actuating device according to claim 5, characterized in that the stop element ( 68 ) is designed eccentrically. 10. Actuating device according to claim 5, characterized in that the trigger lever ( 57 ) is mounted in a fastening device holding the gas spring ( 51 ), on which the support surface ( 71 ) is formed. 11. Actuating device according to claim 8, characterized in that the rotatable stop element ( 68 ) can be fixed in detent positions.