CS274025B1 - Gas spring - Google Patents

Abstract

The invention concerns the gas pressure spring suitable for suspended and height-adjustable devices. It consists of the box, filled with pressurized gas, composed of two sealed cylindrical tubes, which are centrically arranged between each other, and are mounted to cases on both ends of the box, forming annular area. Inside the inner cylindrical tube there are two movable and sealed pistons connected with sealed piston rods, which protrude from the box on both ends.Its principle consists in the fact that the annular area (11) is interconnected through the first case (13) by means of by-pass channel (12) with the working space above the first piston (13), which is through at least one throttling hole (26), passing through tubular wall of the first piston rod (18), through its bottom axial recession (19), interconnected with working space above the second piston (29), and concurrently in the second case (4) there is an extra-axial longitudinal hole (44), in which there is a slide by-pass valve (43) with annular hole (53) interconnecting the space above the second piston (29) through holes (55) of ring (47) and the third throttling hole (56) passing transversally through the body of the second case (4), into annular area (11).The body of the by-pass valve (43) is connected with control rod (51) brought out and sealed through extra-axial longitudinal hole (44) from the gas pressure spring box. The control rod (51) is in the point above the by-pass valve (43) equipped with the second narrowed diameter (58) and on the upper end outside the gas pressure spring with axial feeding hole (59), which is mouthed under the third packing flange (60) into the space of extra-axial longitudinal hole (44).<IMAGE>

Description

The invention relates to a gas spring suitable for use in various spring-loaded and height-adjustable devices, such as car seats and various means of transport.

Hitherto known suspension solutions of, for example, seats of various means of transport are provided by means of mechanical and mechanical-hydraulic and gas springs (telescopes), and their height adjustment is ensured either mechanically by means of ore adjustment with rftznyin positioning or by other but long Adjustable mechanical, mechanical-pneumatic, hydraulic-pneumatic and pneumatic (gas) springs. Previously known gas springs for suspension are designed as single-tube pressure filled gas containers in which aveonly mounted on the inside of the container are sealed, with one piston connected from the container by a protruding and sealed piston rod, or two pistons connected and piston rods protruding at both ends out of the receptacle. The pistons are provided with throttle orifices and pressurized gas directly without actuation from one side of the piston to the other. And to date known gas-adjustable gas springs for adjusting their height are solved, either in the design as so-called. a tubular, or two-tube, pressure-filled gas canister in which a sliding piston is displaceable along the inner wall of the receptacle, connected to the receptacle by a protruding and sealed piston rod. The control of the release of the pressure gas from one side of the piston to the other is, in the case of a single-pipe design, from the piston rod side, for example through a BOTH recess from the tube consisting of the piston rod.

The gas springs in such a configuration have the disadvantage that there are springs intended solely for the spring only, and in particular springs for the height adjustment. They do not address both of these activities simultaneously for one product (one spring).

The above-mentioned drawbacks are remedied by a gas spring, which is characterized in that the annular space is connected through a first housing through a passageway to a working space above the first piston, which is through at least one first choke hole passing through the tubular tent of the first pioot. its bottom part in the axial bore of the first piston, connected to the work space above the second piston, and at the same time in the second sleeve sealed to the inner cylindrical tube by the first sealing ring, a non-axial longitudinal bore is formed, formed between the spacer ring and the first constricted diameter of the relief valve body, sealed from both sides on the unconstrained body diameters and on the inside of the off-axis longitudinal opening by sealing collars and connected from the space above the second piston through a third throttle orifice extending transversely of the second housing body into the annular space, the relief valve body being connected to a control rod extending and sealed through an off-axis longitudinal opening out of the gas spring housing.

The control rod is provided at a point above the relief valve with a second tapered diameter and at the upper end from the outside of the gas spring with an axial filling opening that extends below the third sealing collar into the off-axis longitudinal opening.

The advantages of the gas spring according to the invention are that it is relatively simple and inexpensive to manufacture and, in particular, unlike a gas spring for springing and a gas spring for height adjustment, this spring is intended for both of these activities. , ie. for both suspension and height adjustment simultaneously.

The advantage is that the gas spring can be installed in the device in any direction, either through the through-flow valve upwards, for example to the seat, or downwards to the base chair, and also through the upward or downwardly-actuated piston rod. This means that either the hand or the foot can be adjusted. Another advantage of this gas spring is the possibility of easily replenishing or relieving (releasing) the pressure of the gas in the gas spring housing even during operation of the gas spring. it is possible to increase or decrease the required compression force on the gas spring. The advantage over the single-pipe version of the gas spring for springing and adjustment is that in the same gas spring both pistons and piston rods can be used in the same and simple construction. The overflow valve and its control from the box body are also simpler. discharge of gas pressure mainly during operation.

An example of a gas spring embodiment is shown in the attached drawing. The gas spring consists of a pressurized gas-filled receptacle composed of an outer cylindrical tube 4 and an inner cylindrical tube 2 into which a sleeve 6 is inserted or pressed at its upper shoulder. On the lower end of the cylindrical tube 2, a second sleeve 6 is inserted or pressed, in which a first groove 6 is formed, into which a first sealing ring 6 of elaetic material is inserted to seal the inner cylindrical tube 2. a larger circumference of the first sleeve 3 is mounted and rolled thereon by forming a flush edge 7 of the outer tubular tube 6 and the outer flange f). At the lower end, the outer cylindrical tube 4 is slid onto the stepped larger circumference of the second housing 4 and rolled thereon by forming a leading edge 4 of the outer cylindrical tube 4.

In the second holders 9 of the first sleeve 6 and the second sleeve 6 the second sealing rings 60 of elastic material are inserted. This arrangement provides us with a non-detachable, non-removable and sealed unit with an annular space 44, which is connected to the working space through the passage channel 12 of the first housing 3. In the gas spring receptacle thus formed, a first piston 13 is displaceably mounted within the inner cylindrical tube 2 and sealed by a third sealing ring 14 of elastic material inserted in the third groove 65 of the first piston. Into the axial bore 16 of the first piston 13, after its external shoulder 17, a cylindrical rod consisting of a first piston rod 18 is formed with an axial bore 19 formed therein at the pressing location. With the tubular end 20 thus formed, the first piston rod 48 is rolled onto the face of the first piston 13 by forming a leading edge 21 thereof, thereby forming a single non-detachable unit. The first piston rod 18 is led out through the axial bore 22 of the first housing 6 out of the gas spring receptacle sealed by the first sealing element 23 disposed in the axial recess 24 of the first housing 4 and guided by the first sliding housing 25 positioned above the first sealing element 23. is through an axial bore 19 of the first piston rod 18 and through at least one first throttle bore 26 extending transversely through the wall of the tubular end 20 of the first piston rod 18 into the working space above the first piston. This link is still and without control. Against the end positions, the first piston 13 together with the first piston rod 18 is provided with a stop 27 pressed from the inside of the receptacle onto the first bushing 8 and a stop 48 pressed on the outwardly projecting end of the first piston rod 48. Furthermore, a second piston 29 is displaceably received in the gas spring housing within the inner cylindrical tube 2 and sealed by a third elastic material sealing ring 54 inserted in the third groove 15 of the second piston 29. The axial bore 30 of the second piston 29 has an outer shoulder 31 pressed from a cylindrical rod consisting of a second piston rod 32 with an axial bore 33 formed therein at the pressing location.

With the tubular end 34 thus formed, the second piston rod 32 is rolled onto the face of the second piston 29 by forming its leading edge 65, thereby forming a single non-detachable assembly. The second piston rod 32 is led out through the axial bore 36 of the second housing 5 out of the gas spring receptacle, sealed by the second sealing element 37 disposed in the axial recess 48 of the second housing 54 and guided by the second sliding housing 39 disposed below the second sealing element 37. the piston 29 together with the second piston rod 32 provided with a stop 40 molded from the interior of the receptacle onto the second housing 54 and a stop 41 molded on the outwardly projecting end of the second piston rod 32.

The interconnection of the working space below the second piston 29 with the working space above the second piston 29 and vice versa is operable by a relief valve 43 located in the off-axis longitudinal bore 44 extending from the working space above the second piston 29 through the second housing outside of the gas spring housing. From the outside ^J CS 274025 B1 of the second sleeve 4, the first sealing sleeve 46, the thrust ring 47 and the second sealing sleeve 48, are inserted into the off-axis longitudinal bore 44 after its inner shoulder 45, and all this is caught from below by the press-on guide sleeve. 9 · C ^{e of} the guide opening 50 and through the sleeve vodiacc £ 9, and optionally with locking bushes 61 on the off-axial bore 44 pozdi'žnom guided operating bar 51 partially protruding out of the second sleeve £. The control rod 51 passes into the valve body 52 of the spool valve 43. relief valve 43 with an annular aperture 53 provided between the spacer ring 47 and the first tapered diameter 54 of the relief valve body 43, sealed on one side by the first sealing collar 46 and the other by the other sealing collar 48. The annular opening 53 is through the thrust holes 55 of the a ring 47 through at least one third throttle bore 56 extending through the wall of the second housing 2 ^and extending into the annular space 11 and through the at least one first throttle bore 26 of the first piston 22 »connected to the working space below the second piston 29. for example by crimping and crimping at the end thereof into the interior of the gas spring receptacle, with a stopper plate 57 which is pressed by the gas pressure in the gas spring receptacle at the front of the second housing 5 and thereby prevents axial ejection of the body 52 respectively. control rod 51 out of the gas spring receptacle.

The rod 51 is provided with a second constricted seas 50 at a predetermined distance and at an appropriate length below the first constricted diameter 54 of the body 52 for filling or refilling. discharge of pressurized gas even during operation.

In such a built-up spring, only one piston or one piston is used. the lower portion of its piston rod is provided with at least one throttle orifice for passing pressurized gas from one side of the piston to the other. For example, if there is a second piston 29 in the gas spring so constructed. a lower portion of the second piston rod 32, provided with at least one second throttle bore 42, and a first piston 13, respectively. the lower portion of the first piston rod 18 is free of the throttle orifice, then control of the pressure gas leakage through the relief valve 43 from one side of the piston to the other at the first piston 13 is provided.

A gas spring built in such a way as, for example, in the truck seat and fixed, for example, by the first piston rod 18 on the seat of the seat and the second piston rod 32 on the lower part of the seat, operates as follows:

When the seat is not loaded, ie. when the gas spring is not loaded with the required axial force of the pressurized gas spring receptacle, the first piston rod 18 is fully extended, i. the seat is extended in the up position, based on the principle of spreading and equalizing the gas pressure in the enclosure and the principle of equilibrium of forces under and over the first piston 13.

The second piston rod 32 remains extended in the set position. Conversely, when the gas spring is loaded with an axial force greater than the product of the gas pressure in the gas spring housing and the difference in area below and above the first piston 17, the pressure gas medium flows through the first throttle opening 26 from the working space below the first piston 13 to the working space above the first piston. 13 and the first piston rod 18 is inserted into the interior of the gas spring receptacle until it reaches the stop 28 of the first piston rod 18 relative to the first housing 3, respectively. then, as long as the axial force does. When relieving the gas spring, i. when imparting an axial force less than the product of the gas pressure in the receptacle and the difference in the operating surfaces, the pressure gas medium flows through the first throttle opening 26 from the working space above the first piston 13 into the working space below the first piston 13 and the first piston rod extends out of inside the gas spring, up to the stop 27 of the first housing 3, respectively. then, until a greater axial force is again applied to the spring. By alternating the axial force on the spring, the suspension (spring) of the gas spring and thus of the entire seat is achieved.

In addition to such suspension, ie. from the flow of the compressed gaseous medium from one side of the first piston 13 to the other side, the compression and the compressibility of the gas, i.e. the compressed gas in the gas spring receptacle is more or less compressed according to the load,

CS 274025 Bl resp. expands and partially retracts, respectively. ejects the first and second piston rod, 18, 32 and thus does not occur in the spring and steeper impacts. The second piston rod 32, whose protrusion is adjusted when it is retracted, respectively. odl'ahčoní, springs, only between ¹ stl'ačitol the company compressed gas in the gas spring box.

By longitudinally pushing the control rod 51 into the off-axis longitudinal opening 44 of the second housing 4, for example by means of a foot or manually operated lever, a portion of the tapered diameter 54 of the valve leakage valve 43 moves below the sealing edge of the first sealing collar 46 and remains above the sealing edge. of the first sealing collar 46.

However, in this case, the depth of the push rod 51 into the off-axis longitudinal opening 44 is limited by the fact that the second tapered diameter 68 of the push rod 51 must not be moved below the type of gasket 48 when adjusting the height of the gas spring.

This opens the path of the pressurized gaseous medium from the preheater over the second piston 29 through the apertures 55 of the ring 47 through the annular aperture 53 of this relief valve 43 and through at least one third throttle orifice 56 leading to the annular space 11 connected through the a working space above the first piston 13 and thrust through the first throttle opening 26 into the working space below the first piston 13 identical to the working space under the second piston 29.

When such a pressure gas (air) flow is opened and the axial force is not loaded by the gas spring (seat), the pressure gas medium passes from the working space above the second piston 29 to the working space below the second piston 29, due to the unequal number of surfaces below and above. the second piston 29, the principle of expanding and equalizing the gas pressure in the enclosure and the principle of equilibrium of forces. Thereby, the second piston rod 32 starts to slide out of the gas spring receptacle until the gas flow is stopped by releasing the control rod 51, for example by releasing the control lever. By releasing the control rod 51, it is achieved that with the reduced diameter 54 of the valve body 52 of the relief valve 43 is moved in the off-axis longitudinal opening 44 of the second housing 4 into the space between the sealing collars 46, 48 and gas flow is stopped. In this way, the extension height of the second piston rod 32 can be arbitrarily adjusted within the range of its effective working height.

Conversely, when such a pressure gas flow is opened and a gas spring load is axially greater than the gas pressure in the gas spring housing and the difference between the operating surfaces below and above the second piston 29, the pressure gas medium flows from the working space below the second piston 29 to the working space above. the second piston 29 and the second piston rod 32 are inserted into the interior of the gas spring receptacle until the gas flow is closed by releasing the control rod 51. Also, the insertion depth can be arbitrarily adjusted in the range of: Adjusting the depth of insertion of the second piston rod 32 is advantageous for better estimation of the insertion depth when the gas spring (seat, seat) is loaded and only after the first insertion of the first piston rod 18. »ie. On the other hand, adjusting the height of extension of the second piston rod 32 is advantageous to make a better estimate of the height of the extension when the gas spring is completely pulled out and only after the first extension of the first piston rod 18, ie. to the stop 27 of the first housing 3..

Filling, respectively. According to the invention, the gas spring is discharged by a pressure gas according to the invention <-

By inserting the control rod 51 into the off-center bore 44 of the second housing 4, but deeper than when adjusting the stroke height, and for example by using a thicker control lever or the same lever but with adjusted stops, a larger portion of the tapered diameter 54 of the body 52 of the valve 43 below the sealing edge of the first sealing sleeve 46 and a minor portion will remain above the sealing edge of the first sealing sleeve 46 and the portion of the second tapered diameter 58 of the control rod 51 will fall below the sealing edge of the second sealing sleeve CS 274025 B1. By such an insertion, the entire unconstrained control rod primer 62 located between the two tapered diameters 54 and 58 is moved into the space between the first sealing sleeve 46 and the kinds of sealing sleeve 48, i.e. the sealing sleeve. it reaches the level of the spacer ring 47. This opens the way for the filling pressurized gaseous medium into the interior of the gas box. springs, respectively. a path for releasing (forgiving) the pressure of the gas from the gas spring receptacle, from the space or into the space above the second piston 29 and at the same time from the space or into the space below the second piston 29, i. into the entire gas spring box.

However, the control rod 51 is required after filling or refilling. releasing the gas spring box to return it to its original working position, for example by means of a cylindrical spring or by pulling the control lever. For filling, respectively. In the present case, the discharge of the pressurized gas (air) from the gas spring receptacle serves the filling opening 59. to the orifice below the third sealing collar 60 into the annular space of the off-axis longitudinal opening 21 of the second housing 2, i.e.. The third sealing cuff 60 is located at the top of the off-axis opening 21 and is retained on both sides by the closure sleeves 61. The filling opening can also be made, for example, from the side through the wall of the outer cylindrical tube and a second housing 4 extending into the annular space of the off-axis longitudinal opening 44 of the second housing 4, i. into the space between the kinds of sealing sleeve 48 and the third sealing sleeve 60.

A pressure gas (air) source can be mounted on the filler opening 59 and adjusting the necessary fill pressure inside the gas spring housing during the operation of the gas spring by means of a control fitting and thus varying the spring force, e.g. The gas (air) pressure must be released from the annular space 63 after it has been filled or partially drained.

In addition to the illustrated and illustrated solution of the slide valve 43, a further range of other bypass valves can be used in the gas spring according to the invention.

Claims (2)

CS 274025 B1 cuffs 48 and portions remain above the sealing edge of the second sealing collar 48. By this insertion, the entire unstressed primer 62 of the actuating rod 51 located by the two tapered diameters 54 and 58 is moved into the space between the first sealing collar 46 and the sealing collar type 48, i.e., reaches the level of spacer ring 47. This opens the path of the filling pressure gas medium to the interior of the gas container. springs, respectively. the way to release (release) the gas pressure from the gas spring box, namely the space 7, or into the space above the second piston 29 and simultaneously from the space or space below the second piston 29, i.e. the entire gas spring box. However, the actuating rod 51 is required after filling or refilling. returning the gas spring box to the flood working position, for example, by means of a roller spring, but by extending the operating lever. To fulfill, respectively. the discharge of pressurized gas (air) from the gas spring box in the case serves the filling opening, 59, of the orifice to underline the sealing sleeve 60 into the annular space of the off-axis longitudinal opening 44 of the second housing 4, i.e., the sealing medium 48 and the third sealing The third sealing sleeve 60 is located at the top of the off-axis aperture 44a and is retained by the shutters 61 from both sides. The filling aperture can be made, for example, from the side through the wall of the outer cylindrical tube and the second sleeve 4 through the honey-ring. the space of the off-axis longitudinal opening 44 of the second sleeve 4, ie into the space between the types of sealing sleeve 48 and the third sealing sleeve 60. On the filling opening 59 it is possible to dimension the source of pressurized gas (air and by means of a regulating fitting to adjust the necessary filling pressure inside gas spring boxes during operation of the gas spring and thereby m the springing force, i.e., for example, for the weight of the seated weight seated on such a springing and height-adjusting seat. The gas (air) pressure is required after filling, respectively. Release partial discharge from the honey-ring space 63. In addition to the embodiment of the sieve and drawn sifting valve 43 provided by the invention in the gas spring, a number of other flow valve solutions are also available. SUBJECT MATTER A gas spring suitable for spring-loaded and height-adjustable adjustable devices comprising a pressurized gas-filled receptacle consisting of two mutually interposed and at both ends of the receptacle a housing of attached and sealed cylindrical tubes forming annular space and within the inner cylindrical tube there are two pistons coupled and sealed, connected to and from the receptacle at both ends by a plurality of piston rods consisting of equal or different stroke lengths with a summing stroke of the two piston rods; characterized in that the annular space (11) is connected via a first sleeve (3) through a passage channel (12) with a working space above the first piston (13), which is via at least one first throttle opening ( 26) passing through the tubular wall of the first piston rod (18) through its lower axis a recess (19) attached by its lower part in the axial bore (16) of the first piston (13), coupled to the working space above the second piston (29), and in the second case (.4), sealed against the inner cylindrical tube (2) a first seal ring (6), an off-axial longitudinal opening (44) is formed in which a flask-like discharge valve (43) is provided with an annular opening (53) formed by an inter-ring (47, and a first tapered diameter (54) of the body (52) ) of a transfer valve (43) sealed from both sides on the non-constricted body diameters (52, and on the inner side of the off-axis longitudinal opening (44) by the sealing sleeves (46, 48) and from the space above the second piston (29) through the openings (55) a spacer ring (47, and through a third throttle hole (56) extending transversely to the second housing (4) into an annular CS 274025 B1 space (11), wherein the relief valve body (52) is coupled to the actuating ring extending and sealing off the off-axis longitudinal opening (44) out of the gas spring box. Gas spring according to claim 1, characterized in that the control rod (51) is provided with a constricted diameter (58) in the overflow valve (43) and an axial filling opening (59) at the upper end of the out-of-gas spring, resulting below a third sealing collar (CO, into the space of the off-axis longitudinal opening (44).