DE1284692B - Shock-absorbing support to protect an object against impact movements - Google Patents

Description

The invention relates to a shock absorbing support for protection of an object against impact movements, in particular for a ship's chair.

If z. B. a ship runs into a mine or is torpedoed receives there is a violent first thrust, which is quickly followed by several thrusts. By doing Endeavor to protect seated people and equipment against such impact movements, supports have been developed in which a hydraulic medium and / or springs to dampen these shock movements are used. However, such supports are impractical, and they have not been used because the shock absorbing agents are frequent transfer all or part of the impact forces to the seated person or equipment, and under certain conditions, d. i.e. when the vibrations of the spring used and the supported equipment are in resonance, it can happen that the Spring actually amplifies the impact forces. It also follows that the hydraulic Medium and / or the spring form the only means of supporting the object that, if the ship gives a pitching motion while traveling through rough seas becomes, the object due to its weight acting on the medium and the pen swings up and down. Therefore, if desired, a rigid, inevitable to create a stable seat for the supported object, such shock absorbing supports not be used, and if so desired, a support to protect against To create impacts, then no inevitably rigid support can be used. One of these desirable traits must be sacrificed for the other.

A shock absorbing support is known, with two relative to each other moving parts, one of which is grooved into one on the other Partly supported locking pin engages under spring force, with stronger impacts the locking connection is released and the pin engages in one of the following grooves. With this support, when an impact force occurs, a predetermined value exceeds, the locking pin is lifted out of its groove against the spring force and pushed back into one of the next grooves.

The invention is based on a shock-absorbing support of the latter Type, and such a support is characterized according to the invention that the locking pin is a shear pin that is so long that it shears off several times can be.

Such a design is in contrast to the known resilient Latching or locking pin absorbs more energy by shearing off the pin possible, which in many cases, for example under the conditions outlined above on a ship, can matter.

The shear pin is preferably exchangeable. According to a preferred Embodiment of the invention, the shear pin is mounted in a tube and with connected to a rod that protrudes through a cover of the tube and attached to her End carries a handle.

According to another preferred embodiment of the invention is in the part in which the shear pin is mounted, below the same an opening formed through which the sheared part of the shear pin can fall out. The invention is explained below with reference to the drawing, for example.

F i g. 1 is a side view of one embodiment of a shock absorbing Support according to the invention on which a chair is placed; F i g. 2 is a Longitudinal sectional view of the support according to FIG. 1.

In F i g.1 a chair 6 is shown on a shock-absorbing Support 5 is arranged. The support 5 has, as shown in FIG. 2 can be seen, a hollow, upwardly open lower Stützenteilll in the form of a cylinder, the welded at its lower end 15 at 9 to a platform 8 or in another Way is attached. The platform 8 can in turn on a floor or the Deck of a ship to be attached. If desired, the lower end 15 of the lower cylinder 11 also directly on the floor or deck of the ship be attached, so that the need to use the platform 8 is eliminated.

In the upper end 14 of the lower cylinder 11 is a hollow upper one Support part 16 received telescopically in the form of a cylinder. The upper cylinder 16 has an open lower end 18 and a closed upper end 17 that extends over a console 26 a seat part? can support. The seat part? can turn carry the chair 6 according to Fig. 1 or any other piece of equipment or object, that is to be protected against impact movements.

A damping device is arranged within the cylinders 11 and 16, the collision between the upper and lower cylinders or between the upper cylinder and the platform 8 after the upper cylinder of is isolated from the movement of the lower cylinder. This damping device includes a liquid 29, a throttle piston 33 and one provided with an opening Nozzle 25. The liquid should reach the lower cylinder 11 into the lower end piece 18 of the upper cylinder 16 fill.

The elongated throttle piston 33 is at its upper end 35 on the inside 27 of the closed upper end 17 of the upper cylinder 16 by means a retaining bolt 34 and extends coaxially in the upper cylinder downward. The lower end of the throttle piston 33 can have the shape of a cone 36, which extends into the lower end piece 18 of the upper cylinder 16. The one with a orifice provided plate or nozzle 25 inside the open lower end piece 18 of the upper cylinder 16 can be attached or formed in one piece with it, cooperates with piston 33 and liquid 29 to collide between the upper and the lower cylinder or between the upper cylinder and to prevent the platform 8, as will be explained below.

Between the upper closed end 17 of the upper cylinder 16 and the platform 8 a spring 31 is arranged, which the cylinders 11 and 16 pushes into its starting position (which is shown in FIG. 2). Between the lower end of the spring 31 and the platform 8 or the floor or deck on which or on which the lower cylinder 11 is arranged, a buffering cushion 32 be interposed, which consists of a in the liquid 29 insoluble material. In one in the lower End piece 18 of the upper cylinder 16 is formed annular groove, a sealing ring 23 is arranged, which prevents liquid from seeping through between the outer surface of the upper cylinder 16 and the inner surface of the lower Cylinder 11 prevented.

A pin 22 is arranged in the upper end piece 14 of the lower cylinder 11, which extends inwardly into a longitudinal guide groove 21 in the outer surface of the upper cylinder 16 extends. The pin 22 and the groove 21 work together to the movement of the upper Cylinder 16 with respect to the lower cylinder 11 to limit.

A vertical row of grooves 19 is also formed in the outer surface of the upper cylinder 16 for the purpose described below. Each groove 19 has a horizontal upper wall 19 a, a vertical inner wall 19 b and a downward sloping lower wall 19 c.

A shear pin mechanism 41, which has a tubular housing 44, is arranged within an opening 12 in the upper end piece 14 of the lower cylinder 11. One end of the housing 44 can be fastened in the opening 12 and in an extension piece 42 by screwing, welding or in some other way. The other end of the housing 44 is closed by a cup-shaped cover 45 which is provided with a central hole 46. One end 51 of a rod 48 extends through the hole in the cover 45, and the other end 49 of the rod 48 is widened and provided with a recess in which an exchangeable shear pin 53 is received. A handle 52 is attached to the end 51 of the rod 48 protruding from the cover 45. A spring 54, which presses the shear pin 53 against the wall of the upper cylinder 16, is arranged between the widened end 49 of the rod 48 and the cover 45. If the housing 44 is permanently attached to the lower cylinder 11, the cover 45 should be attached to the housing 44 by screwing or vice versa, in order to facilitate the replacement of the shear pin 53.

In the lower cylinder 11 is immediately below the opening 12 Slot 13 is formed which allows an exit of the shear pin end piece, the is sheared when the lower cylinder 11 is relative to the upper cylinder 16 moved up. As shown in FIG. 2, the shear pin 53 engages into one of the grooves 19 of the upper cylinder 16 to provide a rigid mount for the to create upper cylinder 16.

To explain the operation of the support 5, it is assumed that at the beginning, the upper cylinder 16 and the lower cylinder 11 are the same as those shown in FIG. 2 reproduced Take up the position which is the starting position and that the support according to F i g. 2 is arranged on the deck of a ship. When the ship hits a mine runs, then the first impact force acts on the deck and moves the lower cylinder 11 upwards, however, this movement is caused by the in the groove 19 of the upper cylinder 16 seated shear pin 53 resisted. If this first impact force is greater than a predetermined value, it calls between the upper cylinder 16 and the lower cylinder 11 a relative movement, so that the end piece of the shear pin 53 is sheared and the lower cylinder 11 is allowed to sit on top of the upper cylinder 16 move upwards, causing the upper cylinder to resist the initial impact force is isolated.

If the impact force is large enough, it gives the lower cylinder 11 such a great acceleration that it would cause it to hit the top cylinder bounces and thereby gives the supported object a shock. The damping device prevents such impact. When the lower cylinder 11 accelerates upwards is, liquid 29 is pressed from the lower cylinder into the upper cylinder 16, however, the throttle piston 33 and the nozzle 25 act on the flow of the liquid in this way against that part of the energy of the lower cylinder 11 on the upper cylinder 16 is transmitted, which causes the upper cylinder to move a small distance moved upwards. When the liquid 29 around the piston 33 into the upper cylinder 16 is displaced, it compresses the air in it that was previously was at atmospheric pressure.

During the time that the lower cylinder 11 is moving relative to the upper cylinder 16, the spring 54 pushes the shear pin 53 against the wall of the upper cylinder 16, but since the shock wave has given the lower cylinder 11 a very high acceleration, skips the shear pin 53 some of the lowermost grooves 19. Although the spring 54 of the shear pin mechanism 41 is a relatively weak spring, it can push the shear pin 53 into one of the central grooves when the lower cylinder 11 moves upwards. When this happens, an end piece of the shear pin 53 is sheared off again due to the relative movement between the cylinders.

As soon as the lower cylinder 11 finishes its upward movement, the shear pin 53 will automatically seat itself in the groove 19 closest to it and the compressed air in the upper cylinder 16 and the compressed spring 31 push the upper cylinder 16 and lower cylinder 11 apart in their starting position. Since the lower wall 19 c of each groove 19 is inclined downwards, it forms a cam surface, and the force exerted by the compressed air and the spring 31 on the cylinders 11 and 16 is sufficient to guide the shear pin 53 out of the groove 19 receiving it allowing the upper and lower cylinders to be pushed apart.

As soon as the lower cylinder 11 reaches its starting position, lowers the upper cylinder 11 is again, and the shear pin 53 engages in one of the lower Grooves 19 a. The support is now ready to support you again To create protection against subsequent shock pulses. The duty cycle described above takes place in a fraction of a second.

Neither the spring 31, the liquid 29, the nozzle 25 and the conical Piston end 36 nor the air in the upper cylinder 16 could stand alone or in combination the upper cylinder 16 in the FIG. 1 position shown prop up. They only serve to prevent a collision between the cylinders to prevent and to push the cylinders back to their original position. Consequently the shock absorbing support is also effective without the damping device, so that the the latter can be omitted under certain circumstances. The shear pin mechanism 41 allows the seat part 7 by means of the handle 52 by hand in a desired Raise or lower the height.

Claims (5)

Claims: 1. Shock-absorbing support to protect an object against impact movements, especially for a ship's chair, with two relative to each other moving parts, one of which is grooved into one on the other Partly supported locking pin engages under spring force, with stronger impacts the locking connection is released and the pin engages in one of the following grooves, characterized in that the locking pin is a shear pin (53) which is so long is that it can be sheared multiple times. 2. Support according to claim 1, characterized characterized in that the shear pin (53) is replaceable. 3. Support according to the claims 1 and 2, characterized in that the shear pin (53) is mounted in a tube (44) and is connected to a rod (48) which is passed through a cover (45) of the tube protrudes and carries a handle (52) at its end. 4. Support according to the claims 1 to 3, characterized in that in the part (11) in which the shear pin (53) is stored, -below the same an opening (13) is formed through which the sheared part of the shear pin can fall out. 5. Support according to the claims 1 to 4, characterized in that one (19 c) of the side walls of the grooves (19) is beveled.