DE3920750C2 - - Google Patents

Description

The invention relates to a gas pressure spring with a cylinder the one that includes a gas space for a working pressure gas, a working piston, which is longitudinally displaceable in the gas space is, one connected to the working piston, under Sealing against the gas space from the cylinder to the outside Piston rod for transmitting a thrust force acting on it and an actuator for generating in the direction of displacement the piston rod on these acting forces.

In a known gas pressure spring shown in DE 34 10 309 A1 of this type, which are suitable for use in a so-called Bouncer is provided, can be adjusted using the actuator the extension force and thus the support force of the bounce stick adapt to the weight of the respective user. The Actuating device is designed as a pneumatically effective system and has a manually operable from the outside  Pump piston and one from the outside via an actuating tappet forth manually operable valve, via the optional pressure medium from an additional space containing the pump piston in the gas space can be supplied or discharged from the gas space can be.

A gas spring of this type is only for such applications can be used with advantage, as with a bouncing stick the case is the control elements, i.e. pump piston rod and Valve actuating tappet, directly accessible to the user are. The possible uses are very limited, if such gas springs as energy storage for Weight compensation of moving components, for example moving ones Flaps, movable protective covers, of up-and-over doors or windows and the like are to be used. If it is about such a moving component in a desired one Position and / or position the component a certain position in another defined position to move, it is not enough if a gas pressure spring Offers the possibility to change the thrust manually, it is important that the gas spring in question the function of a controllable for such an application Linear drive can meet.

The object of the invention is based on these requirements to take into account by creating a gas spring which is also suitable for use as a controllable linear drive is suitable.

In the case of a gas pressure spring of the type mentioned at the beginning, this is Object achieved according to the invention in that the actuating device for the generation of mechanically acting on the piston rod Actuating forces is formed and an electromechanical Has drive.

The fact that an electromechanically actuated position  Direction is available, with the positioning forces let generate that in the direction of displacement of the Desired piston movements, you can move the desired movements in the simplest way, namely by creating one electrical control signal. The piston rod and that connected movable component can therefore optionally brought into a desired setting position or from a be moved to another position.

Because the design of gas springs is more common is chosen so that in the rest position of the assigned Neten mechanical component the thrust of the piston rod  and the counterforce exerted by the movable component are at least approximately in equilibrium from the actuator for a desired shifting movement force of the piston rod to be generated moderately low, so that an electro for the actuator relatively low power mechanical drive is sufficient. This opens up the advantageous one Possibility of including the entire control device Lich your electromechanical drive, within the To arrange gas space of the cylinder. The dimensions of a Gas pressure spring according to such an embodiment the invention are hardly larger than those of a conventional one Lichen gas pressure spring without devices for adjusting the position the piston rod.

In embodiments with in the gas space of the cylinder arranged actuator has its drive preferred have an electric motor that is concentric in the gas space motor shaft running to the longitudinal axis of the piston rod is arranged. Such an electric motor can with the circular cylindrical outer surface of its engine housing ses mounted directly on the inner wall of the cylinder be. In such embodiments with the piston rod concentrically arranged motor shaft can with this threaded spindle connected to rotation as from the electric Motor-movable actuator of the actuator available and the piston rod can have an internal longitudinal bore have an internal thread that with the external thread the threaded spindle is engaged, which is in the longitudinal drilling tion of the piston rod extends.  

The actuator is preferably for protection against any load impacts given on the piston rod cushioned if applied. With an advantageous off example with a thread serving as an actuator spindle the arrangement can be made in this regard that the threaded spindle against in the direction of the piston rod acting axial forces via a thrust bearing and with this cooperating spring arrangement resiliently against is supported over the cylinder.

Characterized in that the actuator electro according to the invention mechanically, i.e. according to an electrical control signal, can be actuated, opens up in all embodiments, So regardless of whether the actuator inside the gas space of the cylinder is housed or not, the particularly advantageous possibility of remote control or an automatic operation, so that the fiction moderate gas pressure spring can also be used at locations, where there is no direct access to an operator person is given, or in cases where an automatic Operation possible without the presence of an operator should be. Because of control signals, those of sensors, thermocouples, smoke detectors or the like. generated, for example ventilation flaps on buildings, such as warehouses or greenhouses, valves, flaps, Slider or the like actuate.

Since, as already mentioned, a drive for the actuating device relatively low power is sufficient if the extension force of the gas spring and that of the movable one Component generated counterforce almost in equilibrium are connected to the power supply of the drive requirements are relatively low.  

This results in the particularly advantageous possibility its own energy supply unit on the gas pressure spring device for driving the actuator. At for example, one that is spatially assigned to the gas pressure spring Solar cell arrangement may be provided, preferably via a rechargeable battery, the electric Provides energy for the drive. With such execution examples that differ because of their independence from the utility supply network, in particular for emergency, protection or alarm own energy supply can be suitable direction also for supplying one for wireless remote serve to control the drive remote control receiver. To operate such embodiments are therefore neither electrical supply lines nor control lines required.

The invention is based on one in the drawing illustrated embodiment explained in detail.

Show it:

Figure 1 is a partially broken and cut and schematically simplified view of an embodiment of the gas pressure spring.

Fig. 2 is a sectional view of the execution example according to the section line II-II of Fig. 1 and

Fig. 3 shows a comparison with FIG. 1 and 2 in a larger scale longitudinal section of a drawn cylinder end part of the embodiment with in these adjacent components.

A fabricated from a precision steel tube cylinder 1 has at its one end, a cylinder end piece 3, which forms a centrally located slide 5 in the usual gas springs way through which a piston rod 7 pieces under seal against the closure 3 from the interior of the cylinder 1 is led to the outside. The inner end of the piston rod 7 is connected to a mobile in the cylinder 1 the working piston 9, which is sealed at its outer circumferential surface by means of a sealing ring 11 to the inner wall 13 of the cylinder. 1 In the usual way with gas pressure springs in the piston 9, a passage from piston side 15 to piston side 17 , not shown, is provided, which forms a nozzle opening which can be flowed through by the compressed gas inside the cylinder 1 during displacement movements of the working piston 9 .

At its end opposite the end piece 3 , the cylinder 1 is sealed off by a second end piece (cylinder end part) 19 , of which further details are shown in FIG. 3, to which reference will be made below.

The piston rod 7 has a concentric to the longitudinal axis 21 , inner longitudinal bore 23 which extends over a large part of the length of the piston rod 7 , more precisely, from the inner end of the piston rod 7 , where it is adjacent to the piston side 17 of the piston 9 , extends into the vicinity of the outer end, where the piston rod 7 ends in a connecting thread 25 . The bore 23 has an internal thread 27 which engages with the external thread of a threaded spindle 29 which extends from the gas space adjacent to the piston side 17 into the bore 23 of the piston rod 7 .

The free end of the threaded spindle 29 is connected to the driven side of a coupling 31 , which is able to transmit both torques and axial forces between its drive and its driven sides. With the drive side of the clutch 31 , a motor shaft 33 of an electric motor 35 is firmly connected. The electric motor 35 is a direct current motor which can be operated in both directions of rotation depending on the polarity of the operating voltage supplied. With its circular-cylindrical motor housing, the electric motor 35 is mounted directly on the inner wall 13 of the cylinder 1 , so that the motor shaft 33 is concentric with the longitudinal axis 21 . The electric motor 35 is secured against rotation relative to the cylinder 1 by an indentation 37 of the cylinder 1 engaging in a longitudinal groove of the motor housing. Against an axial Verschiebebe movement in the direction of the retracting movement of the piston 9 and the piston rod 7 , the electric motor 35 is supported via its motor shaft 33 , the rear, facing away from the coupling 31 shaft end 39 is supported on a pressure piece 41 , which in turn on the facing bearing ring one Axial bearing 43 is supported. The other bearing ring of the axial bearing 43 rests on a spring assembly 45 made of plate springs, which in turn is axially supported on the adjacent end piece 19 of the cylinder 1 . In this arrangement, the electric motor 35 with its rear shaft end 39 via the thrust bearing 43 and the spring assembly 45 against axial forces acting in the direction of retraction of the piston rod 7 and piston 9 is resiliently secured, so that impacts from the piston rod 7 via the with this engaged threaded spindle 29 and the coupling 31 arranged between this and the motor shaft 33 are transmitted to the electric motor 35 , which can be shifted somewhat against the force of the spring assembly 45 in the longitudinal direction, the indentation 37 sliding along the associated longitudinal groove in the motor housing.

As can be seen from FIG. 3, the facing end of the spring assembly 45 does not lie directly on the end piece 19 , but on the base 47 of a cup-shaped sleeve 49 . The sleeve 49 not only forms the spring housing for the spring assembly 45 , but also forms a guide with its inner wall 51 , in which the bearing ring of the axial bearing 43 adjacent to the spring assembly 45 is accommodated in the manner of a sliding fit. The sleeve 49 is secured in the cylinder 1 by an indentation 53 provided thereon which engages in a longitudinal groove 55 of the sleeve 49 .

As can be seen in particular from FIG. 3, the sleeve 49 has, at the end section adjoining the end piece 19 , a lateral recess 57 which merges into a longitudinal groove 59 at its end region, which is radially outward with respect to the longitudinal axis 21 , and which merges extends continuously to the end of the sleeve 49 adjacent to the electric motor 35 . The recess 57 and the longitudinal groove 59 together form a cable duct, through which an insulated line 61 extends, one end of which is connected to the electric motor 35 and the other end of which is connected to a sealed cable duct on the end piece 19 .

This cable bushing has a contact body 63 located in a central recess 62 of the end piece 19 , with which the conductor of the associated end of the line 81 is soldered. The circular cylindrical contact body 63 , the diameter of which is smaller than that of the recess 62 of the end piece 19 , is surrounded by an insulating sleeve 65 , which, acting in the manner of a free piston, by the working pressure gas which is in the piece 19 adjacent to the end pressure chamber of the cylinder 1 is pressed with an axial thrust against an O-ring 67 , which is compressed and forming a sealing device against the adjacent wall surfaces of the insulating sleeve 65 , the contact body 63 , the inner wall of the recess 82 in the end piece 19 and an insulating washer 69 on Bottom of the recess 62 is pressed. Through a central bore of the insulating washer 69 and an adjoining the recess 62 in the end piece 19 , through bore 71 extending to the outside, an outer insulated connecting line 73 extends outward, the inner end of the conductor of the connecting line 73 being soldered to the contact body 63 , as is the case with the conductor of the inner line 61 .

From Fig. 1 and 2 it can be seen that the cylinder 1 of the gas pressure spring in a central position within an elongated housing 75 is approximately square cross-section, the end part 19 is screwed with a fastening thread 77 to a transverse wall 79 of the housing. Rod-shaped accumulators 81 are accommodated in the housing 75 along the corner regions in a symmetrical arrangement next to the cylinder 1 . In the present exemplary embodiment, the batteries can be charged by means of solar cells 83 , which are arranged on the outer sides of the housing 75 and a lower housing 85 , which adjoins the transverse wall 79 of the housing 75 . The lower housing 85 , which forms a unit which can be removed from the housing 75 , contains a charge controller 87 which controls the charging current of the batteries 81 and prevents their overcharging in the manner customary in solar cell arrangements, and a control unit for the control of the electric motor 35 , specifically for both on-off control and control of the direction of rotation. In the embodiment, the control unit is provided in the form of a remote control receiver 89 for wireless remote control of the gas pressure spring. The output of the receiver 89 is connected to the connecting line 73 guided through the end piece 19 and to a ground line 91 , via which a ground connection to the electric motor 35 via the housings 75 and 85 and the cylinder 1 mechanically connected to it is produced.

When using the gas pressure spring, the piston rod 7 is connected by means of its connecting thread 25 on the one hand to a movable component and on the other hand to its housing-side connection thread 93 , which is provided on the end facing away from the piston rod 7 on the lower housing 85 , with a joint forming the support of the gas pressure spring connected. The piston rod 7 is secured against rotation by being attached to the associated movable component. When the threaded spindle 29 is rotated by the electric motor 35 , the piston rod 7 and the piston 9 are therefore displaced in the direction of the longitudinal axis 21 . The force exerted by the movable member to the piston rod 7 in the retraction direction is mainly preferably selected so that they generated by the action of the working pressure gas on the piston 9 and the piston rod 7 extension force acting only slightly exceeds, so that the electric motor 35 via the Threaded spindle 29 for an actuating force to be generated is relatively low.

Limit the foregoing description and drawings referring only to the specification of characteristics for the example wise embodiment of the invention are essential.

Claims (14)

1. Gas pressure spring with

• a) a cylinder ( 1 ), which includes a gas space for a working pressure gas,
• b) a working piston ( 9 ) which is longitudinally displaceable in the gas space,
• c) a piston rod ( 7 ) connected to the working piston ( 9 ) and sealed to the gas space from the cylinder ( 1 ) to the outside for transmitting a thrust force acting thereon and
• d) an actuating device for generating actuating forces acting on the piston rod ( 7 ) in the displacement direction thereof,

characterized in that the actuating device is designed to generate actuating forces acting mechanically on the piston rod ( 7 ) and has an electromechanical drive ( 35 ). 2. Gas pressure spring according to claim 1, characterized in that the actuating device is arranged within the gas space of the cylinder ( 1 ). 3. Gas pressure spring according to claim 2, characterized in that the actuating device is arranged in that part of the gas space which is adjacent to the piston side ( 17 ) facing away from the piston rod ( 7 ), and that an electric motor ( 35 ) provided as a drive for the actuating device is adjacent. is arranged in the gas space with a motor shaft ( 33 ) running concentrically to the longitudinal axis ( 21 ) of the piston rod ( 7 ). 4. Gas pressure spring according to claim 3, characterized in that the piston rod ( 7 ) has a central longitudinal bore ( 23 ) which is accessible from that piston side ( 17 ) ago, which faces the electric motor ( 35 ) of the actuating device, that the longitudinal bore ( 23 ) the piston rod ( 7 ) has an internal thread ( 27 ) over at least part of its length and that a threaded spindle ( 29 ) which is connected to the motor shaft ( 33 ) for rotation and forms an extension of the motor shaft ( 33 ) and has an external thread Movable actuator of the adjusting device projects into the longitudinal bore ( 23 ) of the piston rod ( 7 ) and engages with its internal thread ( 27 ). 5. Gas pressure spring according to claim 4, characterized in that the threaded spindle ( 29 ) against axial forces acting in the retracting direction of the piston rod ( 7 ) via an axial bearing ( 43 ) and a cooperating arrangement with it is resiliently supported with respect to the cylinder ( 1 ). 6. Gas pressure spring according to claim 5, characterized in that the spring arrangement has at least one compression spring which is supported on the one hand on the adjacent cylinder end part ( 19 ) and on the other hand on a bearing ring of the axial bearing ( 43 ), the other bearing ring serves as a support for the motor shaft ( 33 ) Which in turn forms the axial support from the threaded spindle ( 29 ) connected to it. 7. Gas pressure spring according to claim 6, characterized in that the spring arrangement has a package ( 45 ) made of disc springs. 8. Gas pressure spring according to one of claims 1 to 7, characterized characterized that they have their own energy supply device for the electromechanical drive of the actuator has facility. 9. Gas pressure spring according to one of claims 1 to 8, characterized characterized in that the electromechanical drive of the Actuator is remotely controllable. 10. Gas pressure spring according to claims 8 and 9, characterized in that the energy supply device of the drive is also provided for the energy supply of a receiver ( 89 ) serving for wireless remote control of the drive. 11. Gas pressure spring according to one of claims 8 to 10, characterized in that the energy supply device has at least one accumulator ( 81 ) and at least one for charging the accumulator ( 81 ) with this in electrical circuit connection photovoltaic cell. 12. Gas pressure spring according to claim 11, characterized in that the circuit connection between the battery ( 81 ) and the photovoltaic cell has a charge controller ( 87 ). 13. Gas pressure spring according to claim 12, characterized in that it is mounted in a housing ( 75 , 85 ) containing the accumulator ( 81 ) and / or charge controller ( 87 ) and / or receiver ( 89 ), on the outside of which a plurality of photovoltaic Cells containing solar cell assembly ( 83 ) is attached.