AT522352B1 - Connecting element - Google Patents

Abstract

The invention relates to a connecting element for telescopically connecting a first tube (1) and a second tube (2), the first tube (1) having a smaller diameter than the second tube (2), the first tube (1) at its outer jacket surface (7) has a groove (9), in which groove (9) a spring element (10) for producing a locking position (11) of the connecting element preventing a relative movement of the tubes (1, 2) while reducing a stress state of the spring element (10) ) is introduced, which spring element (10) is articulated displaceably on the second tube (2) at an articulation point (14), with the articulation point (14) being displaced relative to the groove (9) and the stress state of the spring element (10) being increased the spring element (10) can be removed from a groove part region of the groove (9).

Description

description

The invention disclosed below relates to a connecting element for telescopically connecting a first pipe and a second pipe, the first pipe having a smaller diameter than the second pipe.

According to the prior art, a telescopic connection is characterized in that the first tube can be transferred into a storage position when transferring from a position of use, in which position of use the tubes extending along an axis are essentially strung together. In the storage position, the first pipe is inserted into the second pipe. In the use position, the length of the entire pipe comprising the first pipe and the second pipe is formed by the length of the first pipe and the second pipe, while in the storage position the pipe has essentially only the length of the second pipe.

The first tube can have a hollow cross section or a full cross section. The second tube, into which the second tube the first tube is inserted in the position of use, has a hollow cross-section.

A telescopic connection is characterized in that the first tube and the second tube are mounted immovably with respect to one another, at least in the position of use. The telescopic connection can be released so that the first tube can be pushed into the second tube to reach the storage position.

According to the prior art, for example, locking elements are known which locking elements are biased radially outward in the first tube by a spring and in a defined position of the first tube to the second tube in a first bore in the first tube and in a second bore in the second tube are introduced, so that the presence of the locking element in the two bores, the bores and thus the tubes are not mounted displaceably with respect to each other. The locking element can, for example, have the shape of a dome or ball, which ball is pressed into the first tube to release the connection, leaving the first bore and the second bore. Such a connecting element has the disadvantage that the pipes are weakened by the hole.

US2256248 describes a telescopic connection in which connection an element articulated on the first pipe and an element articulated on the second pipe are screwed to one another by means of an eccentric thread, whereby the pipe surfaces are pressed against one another while preventing a sliding movement between the pipes. The connection disclosed in US2256248 does not include a spring.

DE19943573A1 describes a locking device for a telescopic rod. This locking device is also shown in FIG. 9 of DE19943573A1. In this case, a spring guided through bores in the first tube (provided with the reference number 57 in FIG. 9 of DE19943573A1) is introduced into a recess on the inner surface of the outer tube. In contrast to the connecting element according to the invention, the spring is mounted on the first tube. The first tube does not include a groove. Overall, the spring is transferred from the blocking position shown in FIG. 9 of DE19943573A1 into a release position exclusively by pressing the ends of the spring together.

DE1985600U discloses a connecting element for telescopic rods, one rod comprising an annular groove and another rod comprising an annular projection, the projection being pushed into the groove in order to block the relative movement. The connection disclosed in DE198560U does not include a spring.

DE29622771 discloses a connecting element comprising an eccentric locking mechanism, which locking mechanism with the inner tube can be driven into the outer tube. The locking mechanism does not include a groove, in which groove a spring mounted on the outer tube is introduced.

DE8802612 discloses a clamping coupling for locking the rods. A clamp coupling does not include a spring.

CH434404 describes a connection comprising a locking disk mounted on a first tube, which locking disk is wedged with the surface of the second tube. The connection disclosed in CH434404 does not include a tongue, which tongue is inserted into a groove.

EP0738851A1 does not disclose a groove which is provided on the surface of the first tube and in which groove a spring mounted on the second tube is introduced.

The invention disclosed below has the object of providing a connecting element for telescopically connecting two pipes, which connecting element is characterized, among other things, by the fact that the user can easily feel and / or hear the reaching of a locking position.

Another object of the invention is to make the locking and releasing of a relative movement of the pipes to one another as simple as possible.

The invention is further based on the task of providing a connecting element which connecting element can be used for a wide range of pipe diameters. The connecting element should be designed in such a way that the connecting element can be used for pipes with small diameters, for example a diameter of 6.0 mm.

According to the invention this is achieved in that the first tube has a groove on its outer jacket surface,

into which groove a spring element is inserted to produce a locking position of the connecting element preventing a relative movement of the tubes in a direction of separation while reducing a stress state of the spring element,

which spring element is articulated displaceably on the second tube at a pivot point,

whereby by moving a locking element away from the groove to release a movement of the spring element and by a relative movement of the tubes in a telescoping direction or in a pushing apart direction and / or by shifting the articulation point relative to the groove and the spring element from a groove part area of the groove with an increase the state of tension of the spring element can be applied.

The connecting element described below is also suitable for a first tube, which first tube has a constant cross-sectional shape over the longitudinal extension of the first tube or a cross-sectional shape that is variable over the longitudinal extension of the first tube. With a cross-sectional shape that is variable over the longitudinal extent of the first tube, the first tube can, for example, be conical.

The second tube can also have a cross-sectional shape that is constant over the longitudinal extension of the second tube or a cross-sectional shape that is variable over the longitudinal extension of the second tube. With a cross-sectional shape that is variable over the longitudinal extent of the second tube, the second tube can be designed, for example, conical.

A conical design of the first tube and a conical design of the second tube can be advantageous in that a relative movement of the tubes in a direction of pulling apart can be limited by the form fit of the tubes.

The user usually attacks the pipes on their jacket surfaces in order to transfer the pipes from their storage position to their position of use. For this reason, the user feels very well with his hands, in particular with his fingers, when an impact is exerted on the surface of the pipe held by the user. This is due to the fact that, according to the current teaching, every impact exerted on the surface of the pipe is passed on via the surface of the pipe. A shock is particularly well transmitted in a body with a low mass such as pipes, in particular thin-walled pipes.

The invention disclosed here takes advantage of the effect of transmitting impacts to the surface of a pipe.

When transferring the tubes from the storage position into the use position, the tubes are moved towards one another. The spring element can slide on the first surface of the first tube, the spring element advantageously having a state of tension, which state of tension presses the spring element against the first outer surface of the first tube. The spring element is introduced into the groove when the groove is reached, since the spring element seeks to have the lowest possible stress state. The spring element is accelerated against the groove surface of the groove, which means that the spring element hits the first surface of the first tube when it is introduced into the groove, which can be perceived by the user as a blow to the surface of the tube. The user perceives the impact with his sense of hearing and / or with his sense of touch.

In the connecting elements according to the prior art, the connecting elements can only be released by moving a locking element. As a rule, the locking element has to be moved against a spring force, the locking element being difficult to grasp for the user.

However, the tubes are easy to grasp for the user, since the tubes, in contrast to the locking elements, have a size that is easier to grasp.

The invention disclosed here makes use of the fact that the tubes are easy to grasp for the user when releasing the locking state. To release the locking state, the spring element introduced into the groove is brought out of the groove by bringing it into a higher stress state and by releasing and / or applying a deformation of the spring element.

The deformation of the spring element can be limited by a locking element. The locking element can be located in front of the opening of the groove so that the locking element prevents deformation and movement of the spring element out of the groove. By moving the spring element away from the opening of the groove and positioning the spring element at a distance from the opening of the groove, the opening of the groove is released so that the spring element can be removed from the groove while increasing the tension of the spring element. The spring element can be deployed by a relative movement of the tubes in a direction of sliding one into the other or in a direction of sliding apart.

The connecting element according to the invention can be designed such that the locking element is moved away from the opening of the groove against a force or a resistance such as a spring force and / or a force of gravity acting on the locking element, including the dead weight of the locking element and / or a bias . This further requires that, in order to release the lock, the locking element must be held at a distance from the opening of the groove and, at the same time, the tubes must be moved in a direction of being brought into one another.

By moving the support point of the spring element, the spring element can be partially brought out of the groove, so that the locking effect of the spring element is canceled. The support points can, for example, be moved in a direction parallel to the pipe's longitudinal axes. The complete movement of the spring element can be carried out by a relative movement of the tubes from the state of use to the state of storage. In contrast to some connecting elements according to the prior art, the connecting element according to the invention can be designed in such a way that only a relative movement of the tubes in one direction of being brought into one another is prevented. A direction of movement apart is characterized by a relative movement of the pipes mainly parallel to the longitudinal directions of the pipes, whereby the length of the pipe as a whole is increased. The tubes can, for example, be mounted such that they can rotate relative to one another.

The connecting element can comprise an arrangement stop arranged on the second tube, which arrangement stop when the tubes are pushed into one another in sliding

viewed direction is arranged after the groove and brings the spring element in a position parallel to the groove when the tubes are pushed together.

The connecting element can comprise a discharge stop arranged on the second tube, which discharge stop is arranged after the groove when the tubes are pushed apart in the sliding direction and takes the spring element with it for discharge from the groove.

[0031] The arrangement stop and the discharge stop are advantageously designed in one piece.

The spring element can at least partially enclose the first rod. The spring element can have a U-shape, which U-shape is adapted to the cross-sectional shape of the first tube. The person skilled in the art recognizes that the spring element can have any further shape adapted to the cross section of the first tube and, based on this shape, can at least partially enclose the first tube.

The spring element can be guided around the tube in the form of a loop to reinforce the spring effect.

The connecting element can comprise an actuating ring displaceably mounted on the second rod, on which actuating ring the spring element is displaceably mounted via its support points. By moving the actuating ring relative to the first rod, the spring element is also moved relative to the first rod and thus partially out of the groove.

The connecting element can comprise two groove subareas, which groove subareas are arranged on opposite sides of the first tube. The formation of grooves on opposite sides of the first tube can in particular be combined with the formation of the spring element in a U-shape.

The invention is further discussed with reference to the possible embodiments shown in FIGS. 1 to 5. Figure 1 and Figure 2 illustrate a possible embodiment of the connecting element according to the invention. FIG. 3, FIG. 4 and FIG. 5 show a further possible embodiment of the connecting element according to the invention.

The person skilled in the art is able to look at the embodiments of the connecting element according to the invention shown in the figures as well as one of the embodiments with the above general description part of the invention.

The following elements are identified in the figures with the following reference symbols.

1 first tube 2 second tube 3 (free) 4 first longitudinal axis 5 second longitudinal axis 6 relative direction of movement 7 first outer jacket surface 8 second outer jacket surface 9 groove 10 spring element 11 locking position of the spring element 12 release position of the spring element

13 Longitudinal direction of the groove

14 support point

15 end of spring element

16 Spring bow area

17 Distance between the ends of the spring element in the blocking position 18 Distance between the ends of the spring element in the release position 19 actuating ring

20 direction of actuation

21 cover ring

22 Mutual sliding direction

23 Direction of separation

24 Layout notice

25 Spreading stop

26 locking element

1 and 2 show schematic sectional views of a possible embodiment of a connecting element according to the invention for telescopically connecting a first pipe 1 and a second pipe 2, the cutting planes being entered in FIGS.

The first tube has a smaller diameter than the second tube. The first pipe 1 and the second pipe 2 are arranged centrally with respect to one another. The first longitudinal axis 4 of the first tube 1 and the second longitudinal axis 5 of the second tube 2 are arranged congruently in both sectional layers. The first tube 1 and the second tube 2 can be displaced with respect to one another in a relative movement direction 6, which relative movement direction 6 is oriented parallel to the longitudinal axes 4, 5. The relative direction of movement 6 runs normal to the image plane in FIG. 1 and parallel to the image plane in FIG. 2.

The first tube 1 has two grooves 9 on its first outer jacket surface 7. The grooves 9 are arranged on opposite sides of the first outer jacket surface 7. The grooves 9 extend essentially at a defined angle to the first longitudinal axis 4. Figures 1 and 2 show the special case that the groove longitudinal axes 13 of the grooves 9 extend at a right angle to the first longitudinal axis 4 and parallel to one another; an extension of the grooves 9 at an angle deviating from the right angle and an arrangement of the grooves 9 deviating from a parallel arrangement of the grooves 9 is also conceivable. For example, one groove 9 can be arranged at an angle of 80 degrees and the other groove 9 at an angle of 100 degrees to the first longitudinal axis 4.

The grooves 9 are designed so that a spring element 10 can be introduced into the groove in order to produce a locking position 10 of the connecting element which prevents a relative movement in the direction 23 of the tubes 1, 2 being moved apart. The spring element 10 extends in the locked state 11 between the first tube 1 and the second tube 2. The spring element 10 is not rotatably mounted on the first tube 1 due to the introduction into the grooves 9 and is not displaceable transversely to the longitudinal direction 13 groove 9. Figure 1 and Figure 2 show the special case that the spring element 10 in the locked state 11 is displaceable in the longitudinal direction 13 of the grooves 9, which has no significant influence on the functionality of the embodiment of the connecting element according to the invention shown in Figure 1 and Figure 2. The spring element 10 is also at least rotatably mounted on the second tube 2 at a support point.

As can be seen in FIG. 1, the spring element 10 has an essentially U-shape both in the blocking position 11 and in the release position 12. The spring element 10 is on

its ends 15 are mounted on the second pipe 2 via support points 14 and is guided around the first pipe 1 on the side of the first pipe 1 facing the support points 14, forming a spring element arch 16. In the blocking position 11, the spring element 10 is guided in its area between the ends 15 and the spring element bow 16 in the grooves 9, so that the spring element 9 is tangent to the first tube 1 in its grooves 9. In the release position 12, the spring element 10 is guided in its area between its ends 15 and the spring element bow 16 in a tangent to the first tube 1 on its first outer jacket surface 7. It can be seen in FIG. 1 that the distance 17 between the ends 15 of the spring element 10 in the blocking position 11 is less than the distance 18 between the ends 15 of the spring element 10 in the release position 12. The transfer of the spring element 10 from the blocking position 11 to the release position 12 is thus associated with a deformation of the spring element 10 and the creation or increase of a stress state associated therewith in the spring element 10. The spring element 10 thus has a lower tension state in its blocking position 11 than in its release position 12.

It can be clearly seen in FIG. 1 and in FIG. 2 how the spring element 10 can be transferred from its blocking position 11 to its release position 12. The spring element 10 is mounted on an actuating ring 19 at its ends 14. The actuating ring 19 surrounds the second tube 2 and is mounted so as to be displaceable relative to the second tube 2 in an actuating direction 20. The actuating ring 20 comprises the support points 15 for the rotatable mounting of the ends 15 of the spring element 10. The embodiment shown in Figure 1 and Figure 2 has the special shape that the ends 15 in the support points 15 immovable in a direction parallel to the longitudinal direction 13 of the groove and so are rigidly mounted. As a result, the tension state of the spring element 10, which is generated by the transfer of the spring element 10 from the locking position 11 to the release position 12 by a deformation of the spring element 10, is increased compared to a mounting that is also possible in the direction of the longitudinal direction 13 of the groove. In the embodiment shown in Figure 1 and Figure 2, in addition to the deformation of the spring element 10, the actuating ring 19 is expanded to generate a state of tension in the actuating ring 19 (not shown in Figure 1 and Figure 2 for reasons of clarity), which feature is by no means mandatory is. The spring element 10 is thus not only deformed by widening the distance 17 to the distance 18, but also in the longitudinal direction of the spring element 10. The mounting of the ends 15 at the support points 14 allows the ends 15 to move in the sense of widening the distance 17 to the distance 18.

When the actuating ring 19 is raised in the actuating direction 20, the ends 15 are moved essentially parallel to the actuating direction 20. The spring element 10 is rotatably supported by the spring arch region 16 on the side opposite the ends 15. A movement of the arched spring area 16 approximately in the same direction as the actuating direction 20 is prevented by a cover ring 21.

When the spring element 10 is moved from the blocking position 11 to the release position 12, the spring element 10 is at least partially brought out of the groove 9. The embodiment shown in Figure 1 and Figure 2 comprises a spring element 10 with a circular cross-section. The depth of the groove 9 (measured perpendicular to the first outer jacket surface 7) is less than half the diameter of the circular cross-section, the invention being in no way limited to these geometric relationships. This geometric ratio, given here by way of example, of half the diameter of the circular cross section and the depth of the groove allows the spring element 10 to be easily extracted from subregions of the groove 9.

During a subsequent movement of the first pipe 1 to the second pipe 2 in a telescoping direction 22, the spring element 10 is driven further out of the groove 9 due to the above-described blocking of a movement by the cover ring 21.

When moving the first tube 1 relative to the second tube 2 in a direction 23 apart, the spring element which at least partially encloses the first tube 1 slides

10 along the first outer jacket surface 7. The spring element 10 has - as explained above - a state of tension and seeks to reduce this state of tension. When the spring element 10 is positioned in the area of the grooves 9, the tensioned spring element 10 is moved into the groove 9 in order to reduce the stressed state. Depending on the state of tension of the spring element 10 in the locked position and depending on the depth of the groove 9, the spring element 10 hits the groove 9, which can be easily felt and heard by the user holding the first tube 1 and the second tube 2. In the embodiment shown in FIGS. 1 and 2, the introduction of the spring element 10 into the groove 9 is reinforced by the deformed actuating ring 19. The deformation of the actuating ring 19 is not absolutely necessary to achieve the solution according to the invention.

The spring element according to the invention described can be used in an advantageous manner with a wide range of diameters of the first tube 1 and the second tube 2.

The connecting element shown in FIG. 1 and FIG. 2 comprises an arrangement stop 24 which is not absolutely necessary, which arrangement stop 24 is mounted immovably with respect to the second pipe 2. When the tubes 1, 2 are pushed apart, the arrangement stop 24 prevents the spring arc area 16 from being displaced in a direction opposite to the pushing apart direction 23 and thus ensures that the spring element 10 is arranged parallel to the longitudinal direction 13 of the groove 10 in the groove 9 is advantageous. This can ensure that the spring element 10 is introduced into the groove 9 at the same time over the length of the groove 9. The arrangement stop 24 can be provided in the connecting element according to the invention.

FIG. 3 shows views and sectional images of an embodiment of the telescopic connecting element according to the invention developed by the inventor and implemented as a prototype for telescopically connecting a first tube 1 and a second tube 2. The view II, the view II, the sectional image AA, the sectional image BB and the sectional view EE show the connecting element in a position preventing a relative movement of the tubes 1, 2. Figure 5 shows a detailed sectional view of the sectional image B-B.

In the embodiment shown in FIG. 3, the first tube 1 is arranged above the second tube 2. The first tube 1 has a smaller diameter than the second tube 2, so that the first tube 1 can be pushed into the second tube 2.

The first tube 1 has a groove 9 on its outer jacket surface 7. The groove 9 is clearly visible in the sectional images A-A and B-B. The connecting element according to the invention further comprises a spring element 10, which is guided in the groove 9 of the first tube in a clearly visible manner in the sectional view E-E. In the exemplary embodiment shown in FIG. 3, the groove 9 is designed as a groove running around the outer first jacket surface 7, whereby the tubes 1, 2 in a position of the spring element 10 that is introduced into the groove 9 and prevents the tubes 1, 2 from moving relative to one another are rotatable with each other.

The spring element 10 is designed as an element which encloses at least partial areas of the first tube 1, as can be seen from the sectional view E-E. The spring element 10 has a U-shape in the sectional view E-E. The U-shape is formed on one side by the ends of the spring element 10 and on the other side by an arcuate part.

The spring element 10 is mounted on one side of the second tube 2 via an actuating ring 19 at support points 14.

The movement of the spring element 10 is prevented by the introduction into the groove 9 and thus by the positive locking of the spring element 10 and groove 9. The connecting element according to the invention comprises a locking element 26 (see sectional diagram B-B), which locking element 26 prevents the spring element 10, which is in its locking position 11, from moving out of the groove 9.

On the side of the spring element opposite the support points 14, the arcuate part of the spring element 10 is supported by the actuating ring 19 and cover ring 21, among other things. A movement of the spring element 10 is limited by the cavity formed by the actuating ring 19 and the cover ring 21. To release the locking position 11, the locking element 26 is brought into a position spaced apart from the opening of the groove 9, so that the spring element 10 can be driven out of the groove 9 by a relative movement of the rods 1, 2 in a reciprocating direction 22. The person skilled in the art recognizes that the force to be applied to drive out the spring element 10 can be controlled, for example, by the inclination of the groove surface of the groove 9 to the first outer jacket surface 7. In the embodiment shown in FIG. 3, the groove 9 has, for example, a semicircular cross-sectional shape, the tangents at the points of intersection with the outer jacket surface having a position deviating from a right angle; other shapes are conceivable here.

By driving the spring element 10 out of the groove 9 while applying a force in the telescoping direction 22, the spring element 10 is brought into a higher state of tension. FIG. 4 shows an isometric sectional view of the sectional image E-E-.

Claims (7)

Claims 1. Connecting element for telescopically connecting a first tube (1) and a second tube (2), the first tube (1) having a smaller diameter than the second tube (2), characterized in that the first tube (1) is connected to its outer jacket surface (7) has a groove (9), in which groove (9) a spring element (10) for producing a relative movement of the tubes (1, 2) in a direction of separation (23) preventing the connecting element from locking position (11) Reduction of a stress state of the spring element (10) is introduced, which spring element (10) is displaceably articulated on the second tube (2) at an articulation point (14), whereby by moving a locking element (26) away from the groove (9) to Release of a movement of the spring element (10) and a relative movement of the tubes (1, 2) in a sliding direction (22) or moving apart direction (23) and / or by shifting the articulation point (1 4) relative to the groove (9), the spring element (10) can be brought out from a partial groove area of the groove (9) while increasing the stress state of the spring element (10). 2. Connecting element according to claim 1, characterized in that the connecting element comprises an arrangement stop (24) arranged on the second tube (2), which arrangement stop (24) as seen in the sliding direction (22) when the tubes (1, 2) are pushed into one another (22) is arranged after the groove (9) and brings the spring element (10) into a position parallel to the groove (9) when the tubes (1, 2) are pushed into one another (22). 3. Connecting element according to one of claims 1 to 2, characterized in that the connecting element comprises a discharge stop (25) arranged on the second pipe (2), which discharge stop (25) when the pipes (1, 2) are pushed apart (23) in the direction of pushing apart (23) is arranged after the groove (9) and takes the spring element (10) with it for extraction from the groove (9). 4. Connecting element according to one of claims 2 to 3, characterized in that the arrangement stop (24) and the discharge stop (25) are formed in one piece. 5. Connecting element according to one of claims 1 to 4, characterized in that the spring element (10) at least partially encloses the first rod (1). 6. Connecting element according to one of claims 1 to 5, characterized in that the connecting element comprises an actuating ring (19) displaceably mounted on the second rod (2), on which actuating ring (19) the spring element (10) can be displaced via its support points (14) is stored. 7. Connecting element according to one of claims 1 to 6, characterized in that the connecting element comprises two groove subregions (9), which groove subregions are arranged on opposite sides of the first tube (1). In addition 3 sheets of drawings