DE20303885U1 - Vertical support element for movable tarpaulin arrangement of van or lorry, comprising particularly safely joined upper and lower segment - Google Patents

Abstract

At least one pair of movable vertical elements (7) is inserted between the rear and front corner posts (5) in order to support the cover, in particular designed as a sliding roof. Each of the height adjustable support elements (7) is assembled of an upper segment provided with a row of holes and a lower segment fitted with a matching projection. The lateral extensions of the upper segment are accommodated in u-shaped grooves provided at the lower segment in the overlapping area and are secured by rectangular locking elements inserted into the resulting spaces.

Description

(Ed 303 02 G)

Runge

The invention relates to a stanchion according to the preamble of claim 1.

In practice, stanchions are used to support horizontal beams of tarpaulin structures such as sliding roofs. Such a tarpaulin structure can be used for the bodies of truck beds or

&iacgr;&ogr; semi-trailers, but also containers or railway wagons. In the case of sliding roofs, the side tarpaulins hanging down from the supports can be pushed together so that they can be loaded or unloaded quickly, and the roof tarpaulin running between the longitudinal members can also be pushed together using movable bows to which the roof tarpaulin is attached. In order to further improve access to the loading area, the roof frames of the sliding roofs are designed to be easily dismantled. The central stanchions in particular should be able to be removed quickly, but often also the corner stanchions, which are also referred to as posts, although in this second case the supports also have to be removed, whereas if only the central stanchions are released, they are sufficiently supported by the posts when the sliding roof is not moving. Other tarpaulin structures support a chassis roof which, for example, is made of a lightweight plastic film riveted to the longitudinal members, so that only the side tarpaulin can be moved.

A number of stanchion arrangements are known in practice, where each stanchion can be locked to a corresponding fastening member, which is also referred to as a stanchion shoe, by means of a quick-release fastener, whereby the stanchion shoe is usually fixed to a supporting outer part of the loading area of the sliding roof, for example a metal frame that supports wooden slats, for example by screwing or welding.

The stanchions known from practice generally consist of a lower stanchion part and an upper stanchion part to adjust to the height of the body, both of which are formed as metal folding parts and have an overlapping area, whereby these can be extended or pushed together. The stanchions known from practice provide a welded plate to support one stanchion part in the direction of the loading area of the body, which supports the other stanchion part in the manner of a sandwich between the plate and the other stanchion part.

&iacgr;&ogr; in particular in a first plane facing the load. Although the known stanchions are quite flexible, for unknown reasons they tend to buckle when relatively low loads are exceeded in the area where one stanchion part emerges from the sandwich of the other stanchion part and the plate.

It is the object of the invention to provide a stanchion according to the preamble of claim 1 which can withstand higher loads and has an improved service life.

This object is achieved in the stanchion mentioned at the outset with the characterizing features of claim 1.

The invention is based on the finding that the upper stake part should be able to swing freely in the direction of the load in a base region of the overlap region 101 facing away from the center, while it is held by the abutments provided in an offset plane.

The stanchion according to the invention advantageously and surprisingly enables the outwardly directed loading force to be introduced over a continuous area of the two stanchion parts in their overlapping area, so that buckling of the weaker of the two stanchion parts no longer occurs when leaving the overlapping area.

According to a first preferred embodiment, a base of the first stake part provided in the area of a first of the two parallel planes rests against a corresponding base of the second stake part in the overlapping area, wherein in the section of the overlapping area facing the center, the base of the first stake part arranged on the side facing the load is strongly supported against the second stake part, while surprisingly in the section of the overlapping area facing away from the center, despite the load force also acting there, the

&iacgr;&ogr; Base of the first stake part is set off from the base of the second stake part and essentially the folds of the first stake part provided in a further plane are supported by abutments on the second stake part in the direction of the load.

The design according to the invention is therefore based on the knowledge that in the area facing away from the center, the end of the second stanchion part projects strongly due to the load force, while the continuous deformation course of the first stanchion part at this point does not make a maximum seem desirable and therefore lags behind the maximum deflection of the second stanchion part in the direction of the load.

This springback of the first part of the stanchion is influenced by a number of parameters, such as the elastic constant of the material chosen, which is preferably steel, but also the ratio of the width of the base to the distance between the two levels or the preset clearance between the second level and the stop of the folding of the first part of the stanchion against an abutment.

Preferably, the preset clearance is between 0.5 and 3.5 times the thickness of the material, preferably at least 2 times. Alternatively, the clearance can also be defined as a function of the distance between the two planes, whereby no more than 0.8 times the distance between the

both levels and preferably less than 0.5 times the distance.

The first stake part will preferably be the shorter of the two stake parts. The first stake part will preferably also be the stake part that has a higher bending elasticity away from the load.

The first stanchion part can have a variety of designs, with the design having a wide base and two folds on the sides being particularly advantageous. The second stanchion part is preferably adapted in its course to the course of the first stanchion part and widened with further folds on the sides.

A further alternative embodiment of the invention is characterized in that the first stake part with a base arranged in the area of the first of the two parallel planes is given an additional possibility of springing back via a cut-out area of the second stake part, so that the first stake part, which is initially blocked from the load by the second stake part, has a corresponding cut-out. A corresponding cut-out can also be provided on a plate with which the second stake part is closed, in which case the plate must then extend downwards accordingly.

Further advantages and features of the invention will become apparent from the following description and from the dependent claims.

The invention is explained in more detail below using a preferred embodiment of a stanchion according to the invention with reference to the accompanying drawings.

Fig. 1 shows a schematic side view of a

Semi-trailer designed sliding roof with stanchions according to the invention shown in dashed lines.

Fig. 2 shows a perspective view of an inventive

Runge before securing to the loading platform.

Fig. 3 shows an enlarged view of an overlapping area of the lower and upper stanchion parts of the stanchion from Fig. 2.

Fig. 4 shows a cross section through the overlap area of

Fig.3.

&iacgr;&ogr; Fig. 5 ten different cross sections (a) to (k) through alternative

Design of overlapping areas.

The semitrailer 1 shown schematically in Fig. 1 consists of a tractor unit 2 and a semitrailer 3. The semitrailer 3 is designed as a sliding roof, in which a loading area 4 has vertical posts 5 arranged in the corners, which support horizontal longitudinal members 6 running in the direction of travel and cross members not visible in the side view, with two stanchions 7 being arranged between the two posts 5, which connect the loading area 4 to the longitudinal members 6 and support them vertically. Side tarpaulins hang down laterally from the longitudinal members 6, and a roof tarpaulin is arranged so as to be movable between the two longitudinal members 6. In order to improve the load-bearing capacity of the loading platform, in the frames of sliding roofs, as shown in Fig. 1, at least the stanchion 7 is usually designed in such a way that it can be released from its anchorage, sometimes the longitudinal members 6 and the posts 5 are also detachable.

In particular, rapid tensioning and locking or releasing is desired for the stanchions 7. Fig. 2 shows a perspective view of a preferred embodiment of a stanchion arrangement with a stanchion 7 according to the invention and a fastening member 10, in the present case designed as a stanchion shoe, which is fixed, for example screwed, to the outside of the loading area 4 of the sliding roof 3.

The stanchion 7 consists of an upper stanchion part 11 and a lower stanchion part 12, which are shaped in such a way that they can be moved relative to one another and thus the stanchions 7 can be varied in height during production. The upper stanchion part 11 has a hole 13 into which a locking bolt 14 of the lower stanchion part 12 engages and thus determines the height of the stanchion 7. The hole 13 and the locking bolt 14 make it possible to produce stanchions 7 of different heights from a standardized upper stanchion part 11 and lower stanchion part 12, without having to

&iacgr;&ogr; other parts are needed.

The lower stanchion part 12 has a flat shape in the area of its connection to the upper stanchion part 11, which has two rectangular projections 15 into which corresponding elevations 16 of the upper stanchion part 11 engage. This ensures good transmission of forces and moments from the lower stanchion part 12 to the upper stanchion part 11.

The upper stanchion part 11 has a T-shaped extension 17 in its upper section, in the ends of which two double rollers 18 are mounted, which engage in a track of the longitudinal beam 6. This means that when the stanchion 7 is unlocked, the rollers 18 can be rolled to move it along the longitudinal beam 6. A support area of the upper stanchion part 11 is designed as a flat horizontal support and is intended to come into contact with a lower flat side of the associated longitudinal beam 6 after the stanchion 7 has been raised, whereby the rollers 18 are relieved of load when the stanchion 7 is locked and any possible deflection of the longitudinal beam 6 is counteracted.

In order to achieve effective vertical support of the longitudinal beams 6, it is necessary that the stanchion 7 is raised and locked with its lower area on the fastening member 10 in such a way that the forces are introduced vertically into the stanchion 7 in a favorable manner and lateral or vertical play is also avoided. For this purpose, the stanchion 3 has a

Knee lever arrangement 19, with an intermediate lever 20 and a main lever 22.

As can be seen in more detail in Fig. 3, an overlapping area 101 is defined between the lower stanchion part 12 and the upper stanchion part 11, which at the same time forms a zone for the transmission of moments. It should be noted that the lower stanchion part makes up more than half the height of the stanchion 7, so that in any case the upper end 102 of the overlapping area 101 is above a horizontal center line, if necessary.

&iacgr;&ogr; also the lower end 103. In the area of the upper end 102 of the overlap area 101, two abutments 104 designed as rectangular profiles are fixed to the lower stanchion part 12.

The upper stake part thus has a central base 11a which, in a first plane E1, lies flat against a corresponding base 12a of the lower stake part 12, while the side of the central base 11a of the upper stake part facing away from the base 12a faces the force directed outwards from the load. The required abutment in the direction of the loading area is provided solely by the abutments 104, as it is generally load-free.

The central base 11a of the upper stanchion part 11 (there could also be several central base sections 11a or 12a) is followed by a first essentially rectangular fold, which again carries out a rectangular fold in the area of a further plane E2 which is essentially parallel to the plane E1, whereby it should be noted that this profile of the upper stanchion part 11 runs essentially over the entire length of the upper stanchion part 11. The two folding sections of the upper stanchion part provided in the plane E2 are designated 11b. The lower stanchion part 12 is also folded in accordance with the double folding of the upper stanchion part 11, so that two areas 12b of the lower stanchion part also lie in the plane E2. Furthermore, the lower stanchion part 12 is folded back twice on both sides back into the area of the plane E1; this is why

expedient because the provision of cutouts in the area of the stanchion foot 10 would otherwise weaken the profile.

It can be seen that the total load absorbed by the stanchion 7 increases because in the area of the lower edge 103 of the overlapping area, when a force is introduced from the direction of the arrow over essentially the entire height of the stanchion 7, the central base 11a of the upper stanchion part is pressed against the corresponding base 12b of the lower stanchion part 12, defining a support plane there. The force

The force of the load acts equally on both stanchion parts. At the other end of the overlapping area 101, the moment of the lower stanchion part 12 around the stanchion shoe 10 is maximum, so that there the lower stanchion part has a very strong tendency to bend outwards. In contrast, the upper stanchion part is subject to a smaller lever due to its attachment to the upper longitudinal member and, in response to the contact force at 103, tends to bend against the load force, so that a gap is created between the two base areas 11a, 12a. Here the abutments 104 provided hold the upper stanchion part 11 on the lower stanchion part 12, the expansion required to carry out the elastic deformation of the two stanchion parts 11, 12 being made possible by the distance between the two planes E1-E2. Furthermore, the elastic deformation of the folds over a larger section of the overlap region 101 contributes to the fact that the upper stanchion part deforms evenly.

It is understood that the arrangement of the abutments 104 must be in the region of the lower end 103 of the overlap region 101 if the upper stanchion part 11 is longer than the lower stanchion part 12, since the loads are then kinematically reversed.

As can be seen in Fig. 4, the abutments 104 are provided at a distance from the rear side of the folding sections 11b which is less than half the distance between the planes E1-E2 and preferably not more than one fifth of the distance. In principle, the abutments can also be provided as

Angle pieces or the like, whereby the surfaces facing the rear side of the folding sections 11b are essentially important.

Fig. 5 shows further schematic representations of profiles as well as an arrow to illustrate the direction of loading, which also realize the positive properties of the stanchion according to the invention.

Fig. 5 (a) corresponds to the embodiment according to Fig. 4, with angle pieces as abutments.

Fig. 5 (b) corresponds to the embodiment according to Fig. 5 (a), in which the two folding sections 12b are connected to one another in the area of the plane E2 (top). This connection 105 increases the rigidity of the lower stanchion part.

Fig. 5 (c) corresponds to the embodiment according to Fig. 5 (a), in which the folding sections 11b were not achieved by folding outwards, but by folding inwards. The abutments 104 are attached to the inside of the folds of the lower stanchion part. This solution is visually successful because it does not give the user a view of the abutments 104.

Fig. 5 (d) corresponds to the embodiment according to Fig. 5 (c), supplemented by a connection 105 as in Fig. 5 (b), wherein the abutments are attached to the folding sections 12b of the lower stanchion part.

Fig. 5 (e) corresponds to the embodiment according to Fig. 5 (b), in which the outer folding of the upper stanchion part is not carried out.

Fig. 5 (f) corresponds to the embodiment according to Fig. 5 (b), whereby the outer folding of the upper stanchion part is not outward but inward in the plane E1.

Fig. 5 (g) corresponds to the embodiment according to Fig. 5 (a), in which the upper stanchion part 11 has a base which is folded again in a central region so that the folded base region comes to rest against the base 12a in the plane E2. Due to the multiple folding arrangement of the upper stanchion part 11, the base 11a and folds 11b provided in the region of the plane E2 are decoupled so that they can act in different directions. The multiple folding of the upper stanchion part 11 provides a particularly favorable elasticity in the region of the upper end 10.

Fig. 5 (h) corresponds to the embodiment according to Fig. 5 (e), in which a further folding is provided in the area of the folds 11b, and instead of an abutment, the fastening is carried out by a pin 106 guided through both stanchion parts 11, 12. Here too, the rigidity of the two stanchion parts is sufficient to carry out the desired elastic deformation.

Fig. 5 (i) and (k) differ from the previous embodiments in that the force illustrated by the arrow is initially opposed by the lower stanchion part 12'. However, in the upper region of the lower stanchion part 12, a notch 107 is provided which just exposes the base of the upper stanchion part, so that at this point an elastic bending and the appropriate bending open between the two stanchion parts can occur.

The invention now works as follows:

To lock a stanchion 7 to a fastening member 10, the latter is first moved into the correct position via the rollers 18 and then the recess 30 of the stanchion 7 is pivoted over the fastening member 10. The main lever 22 is then pivoted in the direction of the stanchion 7, whereby the intermediate lever 20 and in particular the joint with the stanchion 7 is displaced upwards.

To unlock the stanchion 7, the main lever 22 - after releasing the snap device - and thus the support element 29 attached to it is pulled away from the lower stanchion part 12 and thus the flow of force between the fastening member 10 and the stanchion 7 is interrupted, whereby the weight of the stanchion 7 first rests on the levers 20, 22 and after a further distance on the rollers 18, so that the stanchion can be moved along the longitudinal member 6.

&iacgr;&ogr; It can be seen that it is particularly advantageous if the upper stake part can swing out freely in an upper base region of the overlap region 101 and is held by the abutments 104 provided in an offset plane.

The invention has been explained above using several embodiments. It is understood that any combinations and modifications of the embodiments presented are possible to achieve further solutions according to the invention.

Claims (22)

1. Stanchion for a tarpaulin structure, comprising an upper stanchion part ( 11 ) and a lower stanchion part ( 12 ) which engages with the upper stanchion part ( 11 ) in an overlapping region ( 101 ), wherein the upper stanchion part ( 11 ) can be secured to an upper longitudinal member ( 6 ) of the tarpaulin structure and the lower stanchion part ( 12 ) can be secured to a counter bearing ( 10 ) in the region of a loading platform of the tarpaulin structure, wherein at least a first ( 11 ) of the lower and upper stanchion parts (11, 12) has a fold which runs in at least two essentially parallel planes (E1, E2), which planes (E1, E2) are arranged transversely to an outwardly directed loading force, characterized in that
that the first stake part ( 11 ) with a base ( 11 a) arranged in the region of the first (E1) of the two parallel planes faces the loading force on the one hand, and
that in the region of the end ( 102 ) of the overlap region ( 101 ) further away from a center line, at least one abutment ( 104 ) is arranged, on which the first stanchion part ( 11 ) is supported outside the base ( 11a ). 2. Stanchion according to claim 1, characterized in that the first stanchion part ( 11 ) with a base ( 11a ) arranged in the region of the first (E1) of the two parallel planes, on the other hand, faces the second ( 12 ) of the lower and upper stanchion parts ( 11 , 12 ). 3. Stanchion according to claim 1 or 2, characterized in that the first stanchion part ( 11 ) faces the second stanchion part ( 12 ) with its fold ( 11b ) arranged in the region of the second (E2) of the two parallel planes. 4. Stanchion according to one of claims 1 to 3, characterized in that the abutment ( 104 ) is provided in a region close to the second plane (E2) on the side of the fold ( 11b ) of the first stanchion part ( 11 ) facing the loading force. 5. Stanchion according to one of claims 1 to 4, characterized in that the first and the second stanchion part ( 11 , 12 ) are designed to be extendable. 6. Stanchion according to claim 5, characterized in that the first and the second stanchion part ( 11 , 12 ) each have a hole ( 13 ) through which a pin can pass for connecting the two stanchion parts ( 11 , 12 ). 7. Stanchion according to one of claims 1 to 6, characterized in that at least one of the first and second stanchion parts ( 11 , 12 ) has a profile with projections running in the longitudinal direction of the stanchion, which have a rectangular profile. 8. Stanchion according to one of claims 1 to 7, characterized in that a support surface is provided which comes into contact with a longitudinal beam ( 6 ) when the stanchion is raised, and that an extension ( 17 ) provided with rollers ( 18 ) projects above the support surface. 9. Stanchion according to one of claims 1 to 7, characterized in that the stanchion is a non-displaceable post ( 5 ). 10. Stanchion, in particular according to one of claims 1 to 9, for a tarpaulin structure, comprising an upper stanchion part ( 11 ) and a lower stanchion part ( 12 ) engaging with the upper stanchion part ( 11 ) in an overlapping area ( 101 ), wherein the upper stanchion part ( 11 ) can be secured to an upper longitudinal beam ( 6 ) of the tarpaulin structure and the lower stanchion part ( 12 ) can be secured to a counter bearing ( 10 ) in the area of a loading platform of the tarpaulin structure, wherein at least a first ( 11 ) of the lower and upper stanchion parts ( 11 , 12 ) has a fold which runs in at least two essentially parallel planes (E1, E2), which planes (E1, E2) are arranged transversely to an outwardly directed loading force, characterized in that when the stanchion ( 7 ) is stressed by the Loading force, the first stanchion part ( 11 ) is supported on the second stanchion part (12) at an end ( 103 ) of the overlapping region ( 101 ) facing the center with the second stanchion part ( 12 ) in the direction away from the load, while the first stanchion part ( 11 ) is supported on the second stanchion part (12 ) at an end ( 102 ) of the overlapping region ( 101 ) facing away from the center in the direction of the load. 11. Stanchion according to claim 10, characterized in that the support at the end facing away from the center ( 102 ) is provided by abutments. 12. Stanchion according to claim 12, characterized in that the abutment ( 104 ) is a rectangular profile or an angle piece which is arranged on the second stanchion part ( 12 ). 13. Stanchion according to claim 12, characterized in that the abutment is a pin ( 106 ) connecting the two stanchion parts to one another. 14. Stanchion for a tarpaulin structure, in particular according to one of claims 1 to 13, comprising an upper stanchion part ( 11 ') and a lower stanchion part ( 12 ') which engages with the upper stanchion part ( 11 ') in an overlapping area ( 101 ), wherein the upper stanchion part ( 11 ') can be secured to an upper longitudinal member ( 6 ) of the tarpaulin structure and the lower stanchion part ( 12 ') can be secured to a counter bearing ( 10 ) in the area of a loading platform of the tarpaulin structure, wherein at least a first ( 11 ') of the lower and upper stanchion parts ( 11 ', 12 ') has a fold which runs in at least two essentially parallel planes (E1, E2), which planes (E1, E2) are arranged transversely to an outwardly directed loading force, characterized in that the first stanchion part ( 11 ') with a base ( 11 a) arranged in the region of the first (E1) of the two parallel planes, facing the loading force via a cut-out region ( 107 ) of the second ( 12 ') of the lower and upper stake parts ( 11 ', 12 '). 15. Stanchion according to claim 14, characterized in that the first stanchion part ( 11 ') can spring in the cut-out region ( 107 ) in the direction of the loading force. 16. Stanchion according to claim 14 or 15, characterized in that at least one abutment ( 104 ) is arranged in the region of the end ( 102 ) of the overlap region ( 101 ) further away from a center line. 17. Stanchion according to one of claims 14 to 16, characterized in that the first and the second stanchion part ( 11 ', 12 ') are designed to be extendable. 18. Stanchion according to claim 17, characterized in that the first and the second stanchion part ( 11 ', 12 ') each have a hole ( 13 ) through which a pin can pass for connecting the two stanchion parts ( 11 ', 12 '). 19. Stanchion according to one of claims 14 to 18, characterized in that at least one of the first and second stanchion parts ( 11 ', 12 ') has a profile with projections running in the longitudinal direction of the stanchion, which have a rectangular profile. 20. Stanchion according to one of claims 14 to 19, characterized in that a support surface is provided which comes into contact with a longitudinal beam ( 6 ) when the stanchion is raised, and that an extension ( 17 ) provided with rollers ( 18 ) projects above the support surface. 21. Stanchion according to one of claims 14 to 20, characterized in that the stanchion is a non-displaceable post ( 5 ). 22. Stanchions according to one of claims 1 to 21, characterized in that the overlap region ( 101 ) is continuously bent from the end ( 103 ) facing the center to the end ( 102 ) facing away from the center when the stanchion ( 7 ) is loaded.