DE3503318A1 - Hydraulic recoil damper - Google Patents

Abstract

The invention relates to a hyraulic recoil damper for preventing recoil in weapons, suitable means being specified in order on the one hand to achieve optimum damping of the recoil and on the other hand to achieve a controlled return rate as well.

Description

Hydraulic non-return dam

Type The invention relates to a hydraulic non-return damper for automatic or semi-automatic handguns or for weapons with a spring-return piston and a pressure tube, which is a linear or approximate has a linear acting throttle system.

State of the art Since the first muzzle-loaders, it has been known that each Firearm - due to the system - has a more or less strong kickback. This Kickback can not only lead to bruises and injuries to the user. Of the The barrel of the weapon deviates from the target direction after the first shot, so that the following shots miss the target. Therefore the barrel of the gun must be after each Shot to be aimed over and over again. This deficiency works particularly serious with bursts of fire, i.e. short series of shots, or with longer series of shots, off.

It is known that to achieve a certain shot follow the The following shot is triggered automatically, e.g. with gas pressure guns.

The sequence of shots must not be too slow, but also not too fast. For a certain weapon an optimal firing sequence is sought and is therefore known.

To automatically trigger the next shot, mechanical or pressure-controlled / mechanical release mechanisms used.

Spring dampers are used to dampen the unpleasant kickback used, which, however, due to the spring characteristic, only work very hard, so that much of the undesirable recoil cannot be avoided. At the same time, such attenuations are still used in a great many known weapons.

Not long ago there was a major improvement through the use of hydraulic damping systems reached which same or similar to the known industrial shock absorbers. Here the kinetic energy converted into heat and a linear or approximately linear Force-travel characteristic reached, so that the kickback is significantly reduced. To the The next shot is triggered again mechanically, mechanically spring-actuated or mechanical-gas-controlled systems are used.

All previously known systems, however, have the disadvantage that they mean an additional element, which is costly and weight-consuming.

Another disadvantage is that it depends on the degree of Soiling, from moisture, from lubrication or from temperature work, that is act differently, especially under extreme weather conditions, and thus are unreliable. This can also change the firing sequence or the firing sequence time result, which not only applies to rifles and handguns, but also e.g. can have unpleasant consequences in the case of on-board cannons of aircraft.

The object of the invention is to provide a hydraulic To design a non-return damper according to the generic term of claim 1, that the hydraulic return shock absorber as a release device for the return stroke the shot can be used and thereby the disadvantages of the previously known types be eliminated.

Solution Based on a hydraulic non-return damper from im This task is carried out by the generic term of claim 1 described the characterizing features of claim 1 solved.

Some advantages result from an embodiment according to the invention a speed-controlled return, which is used to automatically trigger the Follow-up shot can be used and independent of maintenance and lubrication and is insensitive to moisture and pollution and climatic fluctuations and so that it always works reliably.

In addition, the result is a compact, roughly cartridge-shaped construction, which can be found e.g. in shotguns, rifles, submachine guns or the like without significant design changes the weapon can be accommodated without any problems.

It is particularly advantageous that according to the invention the return time and / or the extension speed can be precisely determined.

Further designs for designs according to claim 2 can be the check valve very simply by an elastic ring, for example an O-ring, which at the same time forms the shut-off body.

If an embodiment according to claim 3 is selected, it results a particularly tight seal both inwards and outwards, so that neither Leak leakage leakage or dirt, moisture or the like. get inside can.

In the embodiment according to claim 4, any impurities filtered out so that particularly small throttle cross-sections can be selected.

The embodiment according to claim 5 enables a change of the clear flow cross-section of the throttle opening in question, so that the speed at which the moving parts move relative to each other, predetermine accordingly, so can be adjusted In the drawing is the invention - Partly schematically - illustrated in two exemplary embodiments. They show: Fig. 1 A non-return damper according to the invention in longitudinal section; Fig. 2 is a section Enlargement from FIG. 1 and FIG. 3 corresponds to a further partial enlargement Fig. 2, but in a different embodiment of the invention.

The reference number 1 denotes a baffle plate, which Via a compression spring 2 against one arranged in a housing 3, e.g. as a locking ring trained stop 4 is supported. This stop 4 sets on one side at the same time a bushing 5 axially fixed via a seal 6 in a cylinder 7 of the housing 3 pressure medium tight is sealed.

A piston rod 8 is integral with the baffle plate 1 via a thread 9, but releasably connected, the end facing away from the baffle plate 1 has a piston 10, which is axially displaceable on the cylindrical inner wall 11 of a pressure pipe 12 and is sliding.

The pressure pipe 12 is arranged immovably in a cylinder 13 and has one or more longitudinal grooves 14 or flats on its outer circumference, which are in communication with a valve chamber 15 in a fluid-conducting manner. The longitudinal groove 14 is through a plurality of throttle channels 16 arranged radially in the pressure pipe 12 to one Pressure chamber 17 of the pressure pipe 12 is connected.

To the piston rod 8, a guide tube 18 is arranged, which with axial spacing from one another has two annular collars 19 and 20, which are between them a memory 21, for example from a closed-cell body, in particular from a Elastomers, take up, which can be compressed by the pressure medium, in particular silicone oil and after the pressure that occurs has ceased to exist, its apparent from FIG. 1 again Assumes the basic shape in which it is between the annular collar 19, 20 and on the inner wall of the cylinder 22nd of the housing 3 as well as on the facing annular surface of the socket 5.

The guide tube 18 also engages in a corresponding formation 23 of socket 5. Furthermore, the bush 5 has an axially extending one Chamber 24 in which two seals 25 or 26 are arranged back to back, so that on the one hand a seal to the outside and on the other hand one is given within.

The guide tube 18 also has one or more openings 27, which is connected to the valve chamber 15 in a pressure medium conducting manner.

The one ring collar 20 of the guide tube 18 has one in the direction on the pressure pipe 12 executed collar 28, the inside part of a Forms valve seat surface 29. This valve seat surface 29 is adapted in terms of shape and angle is a surface 30 at the front end 31 of the pressure tube 12, such that the surfaces 29 and 30 together form a valve seat against which a shut-off body 32 Able to apply pressure medium-tight, the forms in the execution according to Fig. 1 and 2 is designed as an O-ring. Between the valve seat surfaces 29 and 30 is a Valve channel 33 is formed, which is therefore through the shut-off body 32 can be closed in a pressure-tight manner.

Reference numeral 34 denotes a valve chamber, which is denoted by a filter chamber 35 is connected in a pressure medium conducting manner, in which a fine filter 36 is arranged. The filter chamber 35 is connected to the valve chamber via a throttle opening 37 15 connected to conduct the pressure medium.

The mode of operation of the embodiment shown in FIGS. 1 and 2 is as follows: Assume that an impulse acts in the direction of X (Fig.

1). This has a displacement of the piston rod via the baffle plate 1 8 and thus the piston 10 in the pressure chamber 17 of the pressure pipe 12 result in the a suitable pressure medium, in particular silicone oil, is filled This Ul is displaced by the throttle channels 16 according to the stroke and flows over the longitudinal groove 14 or the longitudinal grooves in the valve chamber 15 and deforms the memory 22. During In the pressure chamber 17, for example, pressures of about 400 to 1,200 bar can occur, the The pressure in the valve chamber 15 is, for example, only about 0.5 bar.

At the same time not only flows through the relevant opening 27 Pressure medium to the memory 21, but also through the valve channel 33, lifts the shut-off body 32 from the valve seats 29, 30 and flows into the cavity behind the piston 10. The kinetic energy is gradually converted into heat. the Parts of the kickback damper according to the invention can be used in a very small space, e.g. cartridge-shaped with an overall diameter, measured over the housing 3, of only 16 mm can be accommodated.

If the impulse disappears, the compression spring 2 pushes the baffle plate 1 opposite to the direction X back, the shut-off body 32 in its sealing or locking position reached. The oil that is between the piston 10 and the guide tube 18 must necessarily flow through the fine filter 36 and the throttle opening 37, in order to be able to get back via the valve chamber 15 into the pressure chamber 17. Depending on Cross-section of the throttle opening 37 has to be determined in advance with which one Speed the baffle plate 1 moves back.

In the embodiment according to FIG. 3, parts have the same function the same reference numerals have been used.

The embodiment according to FIG. 3 differs from the embodiment 1 and 2 in that instead of the fine filter 36 and the fine filter channel 37 an insert 39 is arranged in a chamber 38 which has a valve body 40, which is conical at one end - at 41 - and with its conical tip 41 reaches through a throttle channel 42. In addition, the valve body 40 has one an interior 43 connected to the pressure medium conducting throttle channel 42a, the opens into the valve chamber 15 at the other end.

The valve body 40 has at its end 41 facing away from the conical end End a slot 44 for inserting a screwdriver. Also is the valve body 40 here provided with an annular recess in which a seal 45 is arranged. Depending on how far the valve body 40 is screwed in or out becomes a more or less large cross-sectional area of the throttle channel 42 exposed and thus the speed with which the baffle plate 1 after recording of an impulse moved back again, predetermined.

Otherwise, the mode of operation is as in connection with FIGS. 1 and 2 described.

Both the check valve version (Fig. 1,2) and the throttle version (Fig. 3) are only described as embodiments in the present case. Of course can be used both for the shut-off body and for any throttle openings and valves other state-of-the-art components can be used.

Those in the description, in the abstract and in the claims features described and shown in the drawing can be used individually as well as in any combination essential for the implementation of the invention be.

LIST OF REFERENCE NUMERALS 1 baffle plate 2 compression spring 3 housing 4 retaining ring, Stop 5 Bush 6 Seal 7 Cylinder 8 Piston rod 9 Thread 10 Piston 11 Inner wall 12 pressure pipe 13 cylinder 14 longitudinal groove 15 valve chamber 16 throttle channel 17 pressure chamber 18 guide tube 19 Kingkraen 20 21 Storage 22 Inner cylinder wall 23 Forming 24 Chamber 25 Seal 26 27 Opening 28 Collar 29 Valve seat surface, Valve seat 30 "," 31 front end 32 shut-off body 33 valve channel 34 valve chamber 35 filter chamber 36 throttle opening 37 filter channel 38 chamber 39 insert 40 valve body 41 tip, cone 42 throttle channel 42a throttle channel 43 interior 44 Slot 45 Seal X Direction of movement

Claims (5)

Claims Hydraulic non-return damper for automatic or semi-automatic handguns, or weapons, with a spring-return Piston and a pressure tube, which is a linear or approximately linear acting throttle system possesses, characterized in that a check valve (32) at or before the Extending the piston (10) closes and the return time and / or the extension speed can be controlled by a built-in throttle opening (42) and the system to the outside and / or is sealed in a pressure-tight manner on the inside. 2. Non-return damper according to claim 1, characterized in that the check valve (32) is formed by a physically integral elastic ring is. 3. Non-return damper according to claim 1 or 2, characterized in that that the seal has two lip seals (25.26) which back lying on your back, both outwards and inwards. 4. Non-return damper according to claim 1 or one of the following, characterized characterized in that a fine filter in front of the channel (37) for returning the pressure medium (36) is arranged. 5. Non-return damper according to claim 1 or one of the following, characterized characterized in that the cross-sectional area of the for the return of the hydraulic Oil certain channel (42) changeable and in the respective desired position is lockable.