PL172937B1 - Adjustable length telescoped tube in particular for use as a sub-assembly of a supporting retractable leg for exchangeable truck bodies - Google Patents

Abstract

1. Longitudinally adjustable telescopic support, especially for a truck, having at least one internal and one external pipe section and axially spaced through holes running transversely, and a pin traversed through the openings to axially lock these pipe sections in a given position, characterized by that in the outer tubular section (1) there is a slot (6) connected to the first hole (4,5) of axially adjacent through holes, and the pin (7) has first, second and third sections (10, 11, 12 ) which extend in each case radially, with the first and second sections (10, 11) matching the first or second holes (4, 5) or (41.51) of the through holes and rest in the holes (4, 41.5, 51) in the first position of the pin (7), regulating the tubular sections (1, 2) of the support, and the third section (12) being slidably guided along the length of the support (30) the slot (6) in the second position of the longitudinally displaced pin (7), unlocking the sections (1,2) of the support PL

Description

The subject of the invention is a longitudinally adjustable telescopic support, in particular for a truck, having at least one internal and one external tubular section and axially spaced transverse through-holes, and a pin through these holes in order to axially lock these tubular sections in the desired position. stretches.

Telescopically adjustable longitudinally adjustable supports, especially known from swap bodies, generally consist of pipe sections which are mutually surrounding one another with a plurality of transverse through holes. In the desired stretched position, the pin is pushed through the through-hole. To avoid losing the pin, it must be secured with a spring pin.

The object of the invention is to provide a longitudinally adjustable telescopic support of the type mentioned at the outset, which avoids inconveniences in the operation of swap bodies for trucks.

The longitudinally adjustable telescopic support, in particular for a truck, according to the present invention is characterized in that in the outer tubular section there is a slot connected to the first opening from axially adjacent through holes, and the pin has first, second and third sections that extend each in a radial direction, the first and second sections being adapted to the first or second holes of the through-holes and resting in the holes in the first pin position locking the tubular sections of the support, and the third section being slidably guided in the slot in the longitudinal adjustment of the support. in the second position of the longitudinally displaced pin, unlocking the support sections.

Preferably, the housing seated in the inner section of the support comprises a first stop against which the second section of the pin rests when the pin is in the second position.

Moreover, preferably, the housing mounted in the inner pipe section comprises a second stop against which the first spindle section rests when the pin is in the first position.

Also preferably, a spring for the preload of the mandrel with respect to the second stop is arranged on the third spindle section.

According to the invention, the second stop can be made on a holder fixed to the inner portion of the support through which the pin is slidably guided.

According to the invention, the first stop can be formed by the open end of a sleeve fitted on the housing and coaxially surrounding the pin.

Preferably, the spring is a slipped helical spring which exerts an action between the housing and the second section of the pin.

Also preferably, a handle is attached to the first spindle section by means of which the pin is gripped and pulled to move it into its second position.

The pin is preferably pulled out towards the first stop only so that the second portion of the pin rests in the second bore in the region of the inner portion on the shoulder when the pin is in the second position.

According to the invention, a locking device rests against the mount by means of which the bolt is only longitudinally displaceable in a predetermined pivot position.

In a particularly preferred embodiment of the invention, the mount extends between two opposite walls of the inner pipe section. The fixture is made of a tube.

In this embodiment, at least a portion of the second spindle section is preferably slidably guided in the housing. The luminaire has an offset that extends into the radius4

Inward and has two opposing side surfaces which form a first stop and a second stop.

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It is also advantageous if the coil spring is partially recessed in the recess of the second spindle section.

The advantageous technical effects of the use of the telescopic support according to the present invention are, first of all, the simple and easy handling and longitudinal representation of the telescopic support. Moreover, all the parts that are needed to properly lock the mutually surrounding pipe sections of the support in the desired extended position are integrated into the telescopic support so that they are protected against external influences leading to damage or disturbances. Thanks to the use of a second stop, the pin is easily prevented from falling out.

The above-described form of the telescopic support according to the invention is distinguished by high strength and simplicity of construction, as well as by a particularly secure bearing of the pin inside the tubular mount.

The telescopic support according to the present invention is described in more detail in the drawing, in which Fig. 1 shows the longitudinally adjustable telescopic support in the telescopic adjustment area in front view and in partial section, Fig. 2 - a first embodiment of the telescopic support according to the invention in a schematic longitudinal section, Fig. 3 - a second embodiment of the telescopic support according to the invention in a schematic longitudinal section, and Fig. 4 shows an alternative embodiment of the longitudinally adjustable telescopic support in section.

1 shows a telescopic support that can be moved longitudinally for a swap body of a truck. The telescopic support 30 consists essentially of an outer tubular section 1 and an inner tubular section 2. At the lower end, the telescopic support 30 is closed by a bottom plate 3. Furthermore, the telescopic support 30 has transverse through holes extending substantially perpendicular to the axis of the support and converging with correspondingly aligned provided in the opposite walls of both the inner and outer tubular sections of the support, first holes 4. 5 and second holes 41. 51. These through holes are spaced along the axis of the telescopic support 30.

Moreover, a slot 6 is provided in the outer tubular section 1 of the support, which connects on one side the axially adjacent first openings 4 and 5.

Next, Fig. 1 shows a pin 7 which, by means of a handle 8, can be partially pulled out of the through hole, i.e. it can be displaced longitudinally.

FIG. 2 shows a part of a telescopic support with through holes with an inserted pin 7. The pin 7 is in a first position in which the support 30 is axially locked. In this position, the two opposite holes 4, 41 are filled by the first section 10 or the second section 11 of the pin 7, so that the outer section 1 of the support is fixed in relation to the inner section 2 of the support.

The pin 7 further has a third section 12 which is located between the first section 10 and the second section 11, passes through the through hole 15 of the bezel 16 and is slidably guided therein. The mount 16 is mounted on the inner tubular section 2 of the support. A sleeve 18 is also mounted on the housing 16, coaxially surrounding the third section of the pin 7, the free end of which forms a first stop 13 for the second section 1 and the pin 7.

The side of the bezel 16, which is opposite to the sleeve 18 in the axial direction of the pin 7, forms a second stop 14 for the first section 10 of the pin 7.

In the exemplary embodiment shown, the pin 7 has a rotation-symmetrical shape with respect to its longitudinal axis, and its sections 10 and 11 have a diameter that is slightly smaller than that of the through holes.

In addition, a helical spring 17 is provided which, in the area of the sleeve 18, is pushed over the third section 12 of the pin 7, with an action between the housing 16 and the second section 11.

172 937 such that the pin 7 is biased in the first position shown in Fig. 2, in which the first portion 10 abuts the second stop 14.

By pulling the pin 7 with the handle 8, the pin is brought to a second position, where the second section 11 abuts the first stop 13. In this position, the first section 10 is completely projected from the first opening 4, while the second section 11 exposes the second opening 41 at least. in the area of the outer support section 1 and rests on the shoulder 19 surrounding this opening 41. The axial dimensions of the sleeve 18 and the second section 11 are adapted to one another for this purpose. The two prop sections 1 and 2 are now axially unlocked and are able to slide relative to each other into a second extrusion position, the third portion 12 of the pin 7 adjacent to the first portion 10 being slidably guided in the slot 6 of the outer portion 1 of the prop. The new pull-out position is reached when the holes 5, 51 in the inner 1 and outer support section 2 are opposed to each other and the pin 7 can be moved back to its first position by the force of the spring 17.

FIG. 3 shows a second embodiment of the invention, in which a locking device 20 is additionally provided. The device essentially consists of a fastening pin 21, which is fastened to the third pin section 12, preferably in a corresponding transverse hole. The fastening pin 21 is, according to FIG. 3, arranged in the area of the exit of the third section 12 from the through hole 15 of the housing 16. The opening 15 is further slit-widened so that the pin 7 is only longitudinally displaceable in a certain pivotal position, in which the fastening pin 21 has its regions. projecting beyond the periphery of the third section 12 may engage the slotted extensions of the opening 15.

The spring 17 rests in this embodiment on the shoulder 22 in order to ensure that the spindle 7 can be rotated and moved unimpeded.

The locking device 20 supports the operation of the spring 17, so that the intended longitudinal displacement of the pin 7 into the second position and the associated unlocking of the tubular support sections 1, 2 is reliably prevented. Moreover, the pin 7 can thus also be locked in its second position, when it is turned by approx. 90 [deg.] After it has been pulled out. As a result, the adjustment of the telescopic support 30 is possible in a particularly simple and unobstructed manner.

Fig. 4 shows a further embodiment of the telescopic support according to the invention, which is structurally simplified with respect to the previously described embodiments. The pin 7 is in its first position so that the outer tubular portion 1 of the prop and the inner tubular portion 2 of the prop cannot slide relative to each other.

The tubular mount 16 'is mounted inside the inner tubular section 2 of the support transverse to the longitudinal axis of the telescopic support 30 on the walls of the inner tubular section 2 of the support, for example by welding. The pin 7 rests with a large part of its second section 11 and a part of its first section 10 against the inner wall of the mount 16 'and slidably therein. A portion of the first section 10 and the second section 11 are located inside both opposite holes 4 or 41 of the telescopic support 30.

A shoulder 42 is mounted on the mount 16 'in the area of the third section 12 of the pin 7, which extends radially inward and has a through hole 15' through which a part of the third section 12 of the pin passes 7. The shoulder 42 is disc-shaped and has two parallel flat surfaces. side, which form a first stop 14 and a second stop 13 for the spindle 7. The section 10 of the spindle 7 rests against the stop 14.

The helical spring 17 abuts with one end of the stop portion 13. With its other end it abuts inside the recess 45 against the second section 11 of the pin 7 and pushes it to its first position.

When the pin 7 is displaced axially against the direction of the helical spring 17 by means of the handle 8, it reaches its second position, not shown in the figure, and rests with its second section 11 against a stop 13 formed by a shoulder 42.

The width of the deicing 42, i.e. the spacing of its side surfaces and the axial dimension of the second section 11 and the third section 12, are such that the first section 10 and the second section 11 in the first pin position 7 completely fill the holes 4.41, and in the second pin position 7, that is, when the second section 11 abuts the first stop 13, they reveal the openings 4 or 41 so that the inner and outer tubular section 2, 1 of the prop can be moved relative to each other to change the length of the telescopic prop 30.

In the illustrated embodiment, the first section 10 and the second section 11 have approximately the same outer diameter that matches the inner diameter of the bezel 16 '. A hole 46 is made in the mount 16 ', through which possible impurities are forced out of the inner space of the mount 16' when the pin 7 is moved.

Fig.2

172 937 \

Fig.4

Publishing Department of the UP RP. Circulation of 90 copies. Price PLN 2.00

Claims (16)

Patent claims 1.Longitudinally adjustable telescopic support, in particular for a truck, having at least one inner and one outer tubular section and axially spaced transverse through holes, and a pin inserted through the holes to axially lock these tubular sections in the desired stretched position, characterized in that the outer tubular section (1) has a slot (6) connected to the first bore (4, 5) of axially adjacent through holes, and the spindle (7) has a first, second and third section (10, 11) , 12), which each extend in a radial direction, the first and second sections (10, 11) matching the first or second holes (4, 5) or (41, 51) of the through holes and resting in the holes (4, 41.5, 51) in the first position of the pin (7) adjusting the tubular sections (1, 2) of the support, and the third section (12) being slidably guided on the longitudinal representation of the support (30) in the slot (6) in the second position of the longitudinally displaced pin (7), unlocking the support sections (1, 2). 2. A support according to claim The mount according to claim 1, characterized in that the mount (16 ') mounted in its inner section (2) comprises a first stop (13) against which the second pin section (11) rests when the pin (7) is in the second position. 3. A support according to claim The holder as claimed in claim 1 or 2, characterized in that the mount (16 ') mounted in the inner section (2) comprises a second stop (14) against which the first section (10) of the pin rests when the pin (7) is in the first position. 4. A support according to claim A spring (17) for biasing the pin (7) against the second stop (14) is provided on the third spindle section (12). 5. A support according to claim 4. The holder according to claim 4, characterized in that the second stop (14) is formed on a mount (16, 16 ') attached to the inner portion (2) of the support through which the pin (7) is slidably guided. 6. A support according to claim 2. The device of claim 2, characterized in that the first stop (13) is formed by the open end of a sleeve (18) fitted on the housing (16) and coaxially surrounding the pin (7). 7. A support according to claim A coil spring as claimed in claim 4, characterized in that the spring (17) is a coiled spring that slides over the spindle (7), which exerts an action between the housing (16) and the second section (11) of the spindle (7). 8. A support according to claim A handle (8) is attached to the first section (10) of the pin (7) by means of which the pin (7) is gripped and pulled to move it into its second position. 9. A support according to claim The method according to claim 7, characterized in that the second portion (11) of the pin (7) rests in the second bore (41, 51) in the region of the inner tubular portion (2) of the support on the shoulder (19) when the pin is in the second position. 10. A support according to claim A locking device (20) rests against the mount (16) by means of which the pin (7) is only longitudinally displaceable in a predetermined rotation position. 11. A support according to claim 5. The mount according to claim 5, characterized in that the mount (16 ') extends between two opposing inner walls of the tubular section (2) of the support. 12. A support according to claim The mount according to claim 11, characterized in that the mount (16 ') is made of a tube. 13. A support according to claim The shaft of claim 9, characterized in that at least a portion of the second section (11) of the shank (7) is slidably guided in the housing (16 '). 14. A support according to claim 14. The mount according to claim 13, characterized in that the mount (16 ') has a shoulder (42) that extends radially inward and has two opposing side surfaces that form a first stop (13) and a second stop (14). 172 937 15. A support according to claim A device as claimed in claim 14, characterized in that the shoulder (42) has the shape of a circular disc and has an opening through which part of the third section (12) of the shaft (7) is guided. 16. A support according to claim 7. The coil spring (17) is partially housed in a recess (45) of the second section (11) of the shank (7).