DE1809854U - DOOR BUFFER. - Google Patents

Description

Paul Garthe KG
Ennepetal-Milspe / Westf.

Sliding door buffer

Heavy sliding doors, and especially those on leaning Hollen, bump with one through the weight and the approach speed certain force on the intended stop. To damage the component forming the door frame and to avoid the sliding door, these collisions are avoided by all kinds of buffers, such as spring bolts or rubber pads caught. An absolute destruction of the impact force is hardly possible in this way. The approach speeds that are known determine the rear end balance are too different. This is particularly evident with sliding doors rail-bound boxcars. A door that is not locked is opened at one speed in the event of shunting impacts up to 15 and 20 km per hour thrown onto their buffer · The powerful impact that takes effect here should be just as good be caught and destroyed by the buffer than the one generated by hand pushing. By means of a combination of springs an attempt was made to achieve this effect. The total stroke of the buffer is restrained with several springs, the weakest of which a part of the braking effect achieved alone, to its power after fixed intervals with the second, the third and so forth to unite. The same effect could also be achieved by means of friction brakes. The impact forces are different in their Effect destroyed by working strokes of different lengths of the evenly braked ram. All of these door buffers have the disadvantage of only up to one due to the sum of the spring forces or the friction work of the completely pressed in To be able to be effective ram certain maximum impact force absorption. In addition, the force absorption of the spring sliding door buffer not continuously and the friction force sliding door buffer seal up too quickly with the wear and tear of the friction medium.

The sliding door buffer according to the invention is in principle a liquid brake. The braking medium is forced to flow around through narrow channels from one chamber into another with the upward thrust of the sliding door. The friction on the canal walls in combination with the inertia of the flow of the liquid determine the power consumption of the collision impact. A cylinder with continuously tapering and axially extending channels in its bore is divided into the required two chambers by a piston. Depending on the position of the piston, these chambers have different volumes into which the brake fluid must flow. In the direction of action, the brake medium can only flow through the narrow inner cylinder wall channels, which means that the piston can only make its work path with increasingly narrowed channel cross-sections with steadily increasing thrust can. Accordingly, the sliding door buffer, which works in this way, guarantees that every type of pushing force is absorbed softly over a more or less long path. Since a compression spring located behind it is also tensioned during the working stroke of the piston, its relaxation brings about the return after the push has been stopped. The spring force would probably not bring about the return at all or it would do it very slowly against the flow resistance of the braking medium in the narrow cylinder inner wall channels.

Therefore, an additional one must be opened by opening a return flow channel Uninhibited Umflussmögliehkeit the braking medium can be created. This is given by the arrangement of a valve that has its seat in the piston housing and its plate rests on the piston rod · At the beginning of the working stroke, a short Advance of the piston rod first closes the valve and then the piston for its braking effect through the cylinder pressed during the return movement, the spring force causes and in turn first the valve is opened by a short advance of the piston rod and the piston and piston rod brought to the starting position quickly and without great effort.

With the attached drawing is the door buffer according to the invention for example and shown schematically as an axial central section.

In the bore of the cylinder 1, which is with the molded Plansch 2 is attached to the door frame »from 14 to 15 continuously tapering channels 13 are incorporated. The dash-dotted one Drawn cylinder bore cross section 17 shows the dimensioning of the channels, which are created here rectangular, but any other Ροπή, such as triangular or semicircular · The molded base 6 closes the cylinder on one side and the screwed-on cover 8 on the other Page down · Sealed on both sides with the seals 7, the base and cover with a central fitting bore serve the piston rod 4 as storage and guidance. The valve plate 9 formed on the piston rod settles when the door opening impact is pressed in the direction of force P with the sealing ring 10 fitted to it against the valve seat assigned to it and also as a valve seat acting rim 11 of the piston bore and presses the piston 12 through the cylinder space. This will be the cylinder volume Filling brake fluid is forced to flow from chamber B through channels 13 to chamber A. With advancing Piston movement, the flow channels narrow more and more and require the flow of the brake medium and thus a steadily increasing thrust for the piston stroke. Every door opening impact is therefore over a sufficiently long piston path caught softly and destroyed. On the piston rod 4, the three drivers 16 are perpendicular to the piston rod axis and at the same intervals (in this case offset by 120 each). With advancing piston movement During the working stroke (i.e. in the direction of force P), the compression spring 5 resting on the drivers is tensioned. the stored force of the compression spring moves after exposure of the thrust force P first the piston rod 4 up to the Attacks of the driver 16 on the piston face. At the same time, the sealing ring 10 of the valve moves away from the rim 11 on the piston crown. The open valve allows the brake fluid to flow unchecked around chamber A in Chamber B and thus the transport of the piston 12 into the starting position without great effort.

The door buffer described here is by no means a technical one Execution and is to be drawn up as an example of a schematic basis according to the guidelines given View construction. The non-return valve does not have to be designed in the indicated mode of operation.

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For example, it could be on the piston head or the piston face with brake medium pressure in the event of a door bump closing and after suspension this opening by spring force with a rigid connection τοη piston rod and piston be arranged. Or similar bypass channels on the circumference of the piston could be used, dispensing with the cylinder inner wall channels be provided, which with the effect of the door opening impact through the pressure effect of the braking medium is similar to a valve would be partially closed to open with suspension of the shock to be absorbed by spring force for full flow to become. The design options are just as varied as the choice of valves for the uninhibited Backflow of the brake fluid when the piston rod and piston return to their starting position, which is driven by spring force. In any case, the mode of operation of the door buffer according to the invention remains, in principle, determining for the execution. The door opening impact is caused by the movement of a piston through a cylinder filled with brake fluid Destroyed narrow overflow channels on the piston or the inner wall of the cylinder and the return of the piston and the piston rod takes place automatically by spring force (Opening of one or more valves for expansion or supplementation of the flow passages before the return movement begins the cylinder space is the volume required in the cylinder interior Do not change the grounding of components.

Claims (11)

HA. 121463 * 212.M protection claims 1) door buffer, as! Liquid brake and characterized in that the flow of brake fluid, which is inhibited by the narrow dimensioning of aehsial cylinder inner wall ducts 13, as the piston movement 12 progresses in a cylinder 1 which is closed on all sides under the effect of a door opening bump P gradually consumes its force. 2) door buffer according to claim 1 and characterized in that the cylinder inner wall channels 13 are in the firkrichtung Gradually taper the door opening. 3) door buffer according to claim 1 and 2 and characterized in that the piston 12 is freely movable only on the inner wall of the cylinder is guided properly and for is its movement in the direction of action the door impact against this sliding surface without blocking the flow of brake fluid is sealed by the channels 13. 4) door buffer according to claim 1 and following and characterized in that that the advance of the piston 12 in the door opening direction P by pressing the piston rod molded valve plate 9 is actuated against the associated piston ring 11 5) door buffer according to claim 1 and the following and characterized in that that the valve plate 9 forms a valve with the ring 11 assigned to it as a piston system open state through the space between piston bore 18 and piston rod 4 of the brake fluid additional Flow allowed. 6) door buffer according to claim 1 and following and characterized in that that a compression spring 5 star-shaped by bearing against several in the piston rod 4, on the same Height anchored driver 16 under the action of the door opening impact P and the associated movement of the piston rod is tensioned. 7) door buffer according to claim 1 and following and characterized in that that the distance between the articulation links of the piston rod 4, the valve disk 9 and the drivers 16 is always greater than the depth of the piston bore 18 including the piston ring 11 and thus an unimpeded displacement of the piston rod through the piston bore with optional stops of the valve head 9 and the driver 16 allows against their drive-on surfaces assigned to the piston 12. 8) door buffer according to claim 1 and following and characterized in that that after the failure of the 2ürauffalirimpuls P the stored force of the compression spring 5 by pressing against the driver 16, the piston rod 4 and after the stop transport the driver against the piston 12 in the starting position. RA. 121463 * 212.Ε0 9) ÜMirpuffer according to claim 1 and following and characterized in that that the piston rod 5 is sealed both in the piston head 6 and in the piston cover 8, both passing through, is stored and due to the uniform dimensioning of the two piston rod ends when entering and exiting from the cylinder space in this always occupy the same volume. 10) Sürbuffer according to claim 1 and following and characterized in that that the piston rod 4 penetrates through a considerably further bore 18 of the piston 12 and the gap between piston bore and piston rod cross-section serves to return the brake fluid when the valve is open. 11) door buffer according to claim 1 and following and characterized in that that between any two on the piston rod 4 any number of star-shaped llitnehmer 16 arranged there is enough space for the unrestricted flow of the brake fluid.