TELESCOPABLE SPRING SUPPORT

Abstract

A telescopable spring support which comprises a housing, a pressure plate, a load pipe, and a pressure spring and which is designed to elastically support components in a load direction. The housing has a stand side and an upper side, and the pressure plate is arranged in the housing and can be moved within the housing in the load direction. The pressure spring is arranged between the pressure plate and the stand side and applies a spring force to the pressure plate, said spring force being directed towards the upper side in the load direction. The load pipe is connected to the pressure plate and, in each position of the pressure plate, extends outwards from the interior of the housing through an opening arranged on the upper side of the housing. The housing comprises a stand housing and a movable housing. The movable housing can be moved towards the stand housing in the load direction, wherein the stand housing has a stand side, and the movable housing has the opening.

Claims

1. A telescopable spring support, comprising a housing, a pressure plate, a load pipe and a pressure spring, and is formed for the resilient support of components in a loading direction, wherein the housing comprises a stand side and an upper side, wherein the pressure plate is arranged in the housing and is displaceable within the housing in the loading direction, wherein the pressure spring is arranged between the pressure plate and the stand side and exerts a spring pressure on the pressure plate which is directed in the loading direction towards the upper side, wherein the load pipe is connected to the pressure plate and extends to the outside in each position of the pressure plate from the interior of the housing through an opening which is arranged on the upper side of the housing, wherein the housing comprises a stand housing and a movable housing, wherein the movable housing is displaceable in the loading direction relative to the stand housing, wherein the stand housing comprises the stand side and the movable housing comprises the opening, wherein the stand housing comprises a cylindrical guide, which is arranged on the side of the stand surface facing the interior space and extends with its cylindrical axis in the loading direction, wherein the cylindrical guide extends within the load pipe and is formed for guiding the load pipe.

2. The telescopable spring support according to claim 1, wherein the stand housing and the movable housing each comprise a hollow cylindrical section, wherein especially the two hollow cylindrical sections are arranged in such a way that their cylinder axes coincide and extend in the loading direction.

3. The telescopable spring support according to claim 1, wherein the stand housing comprises a first locking projection and the movable housing comprises a second locking projection, wherein the two locking projections are formed for limiting the displaceability of the movable housing relative to the stand housing in the loading direction, wherein the two locking projections are arranged in the housing in such a way that they rest on each other at a distance of the movable housing from the stand side which is at a maximum in the loading direction.

4. The telescopable spring support according to claim 1, wherein the movable housing comprises at its end facing the upper side a retaining projection which extends perpendicularly to the loading direction and which delimits the opening.

5. The telescopable spring support according to claim 1, wherein the stand housing and/or the movable housing comprises a hollow cylindrical section which is shaped from a tube, wherein at least one of the locking projections or the retaining projection is shaped by forming the tube.

6. The telescopable spring support according to claim 1, wherein the movable housing is arranged within the stand housing with regard to a direction perpendicular to the loading direction.

7. The telescopable spring support according to claim 1, wherein the pressure spring is arranged within the movable housing and within the stand housing with regard to a direction perpendicular to the loading direction.

8. The telescopable spring support according to claim 1, wherein the stand housing, on the side of its stand side facing the interior space, and/or the pressure plate, on its side facing the stand side, comprise a fixing projection which is arranged within the pressure spring with regard to a direction perpendicular to the loading direction for preventing a displacement of the pressure spring in the housing.

9. (canceled)

10. The telescopable spring support according to claim 1, wherein the pressure plate comprises a recess through which the load pipe extends.

11. The telescopable spring support according to claim 10, wherein the recess comprises an internal thread, which corresponds to an external thread arranged on the exterior side of the load pipe, wherein the load pipe is connected to the pressure plate via the corresponding exterior and internal threads, and a specific distance of the load pipe from the stand side is adjustable in the loading direction at a specific position of the pressure plate.

12. The telescopable spring support according to claim 1, wherein the movable housing comprises at least one bead, which is arranged in a depression of the pressure plate when the pressure plate rests on the upper side of the housing facing the interior space so as to prevent a twisting of the pressure plate relative to the movable housing about that the loading direction.

13. The telescopable spring support according to claim 1, wherein a load plate is arranged at the axial end of the load pipe which faces away from the stand side, on which a sliding element is arranged in particular.

14. The telescopable spring support according to claim 1, wherein the load pipe comprises at least one borehole at its axial end facing away from the stand side, which borehole extends perpendicularly to the loading direction through the load pipe.

15. The telescopable spring support according to claim 1, wherein the stand housing comprises at least two recesses in its side wall extending in the loading direction, which recesses each extend over at least half the extension of the stand housing in the loading direction and are capable of accommodating a blocking apparatus (10), which comprises a retaining device for retaining a projection arranged on the movable housing for fixing a relative position of stand housing and movable housing with respect to each other.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] The invention will be explained below in closer detail by reference to an embodiment shown in the schematic drawings, wherein:

[0029] FIG. 1a shows a schematic sectional view of an embodiment of the spring support in accordance with the invention;

[0030] FIG. 1b shows a schematic semi-sectional view of the embodiment according to FIG. 1a;

[0031] FIG. 2 shows a further schematic sectional view of the embodiment according to FIG. 1a;

[0032] FIG. 3a shows a schematic sectional view of the embodiment according to FIG. 1a with a blocking apparatus; and

[0033] FIG. 3b shows a schematic semi-sectional view of the embodiment with the blocking apparatus according to FIG. 3a.

DETAILED DESCRIPTION

[0034] FIG. 1a shows a schematic sectional view through an embodiment of the spring support 1 in accordance with the invention. The spring support 1 comprises a housing 2, which consists of a stand housing 4 and a movable housing 3. The two-part configuration of the housing 2 which results therefrom can be generally advantageous and especially simple. The stand housing is formed in the manner of a hollow cylinder. The stand side A of the spring support 1, on which the spring support 1 is placed in its operating position, is arranged on the stand housing 4. The stand housing 4 comprises a base plate 45 in which holes 46 are provided, so that the base plate 45 can be rigidly bolted to the ground. A first fixing projection 42, a cylindrical guide 43 and a tubular section 44 are welded onto the base plate. The tubular section 44 is formed in the manner of a hollow cylinder and has an outer diameter of approximately 200 mm. At its end facing the upper side, the stand housing 4 comprises a first locking projection 41 which is formed by an inwardly formed portion of the tubular section 44. The stand housing 4 is open towards the upper side and therefore comprises a passage whose diameter is limited by the first locking projection 41.

[0035] The movable housing 3 is arranged within the stand housing 4 in a direction perpendicularly to the loading direction X. In this case, the movable housing 3 extends in the loading direction X through the passage in the stand housing 4, so that it is arranged in the loading direction X on both sides of the passage. The movable housing 3 is formed as a further hollow cylindrical section, on which a second locking projection 32 and a retaining projection 31 are arranged. The hollow cylindrical section is made of a tube, wherein the retaining projection 31 is formed by an inwardly formed portion of the tube. The second locking projection 32 is formed in the manner of a ring and welded onto the tubular section, wherein the second locking projection 32 extends to the outside perpendicularly to the loading direction X from the side wall of the movable housing 3. The tubular section forming the hollow cylindrical section of the movable housing 3 has an outer diameter of approximately 185 mm. The diameter of the passage in the stand housing 4 is approximately 190 mm, so that a substantially friction-free displaceability of the movable housing 3 in relation to the stand housing 4 is made possible. The second locking projection 32 has an outer diameter of approximately 195 mm. Accordingly, the movable housing 3 and the stand housing 4 are formed with their locking projections 41, 32 in such a way that the displaceability of the movable housing 3 in relation to the stand housing 4 is limited, wherein a maximum distance of the movable housing 3 from the stand side A of the stand housing 4 is predetermined, wherein the two locking projections 32, 41 rest on each other when reaching the maximum distance of the movable housing 3 from the stand side A. The sliding apart of the movable housing 3 and the stand housing 4 is thus effectively prevented, so that it is excluded in the illustrated embodiment that in the case of a sudden decrease in the loading force acting on the load pipe 8 the movable housing 3 and/or the pressure spring 7 and/or the pressure plate 5 jump apart and cause damage.

[0036] The pressure spring 7 is arranged in a direction perpendicularly to the loading direction X, both within the movable housing 3 and also within the stand housing 4. The pressure spring 7 always extends from the side of the base plate 45 facing the interior space of the housing 2 up to the side of the pressure plate 5 facing the stand side A. The pressure spring 7 is guided via a first fixing projection 42 on the base plate 45 of the stand housing 4 and via a second fixing projection 53 on the pressure plate 5. This effectively prevents a displacement of the pressure spring 7 in a direction perpendicularly to the loading direction X and high stability of the spring support 1 is ensured. The first fixing projection 42 is formed in an annular manner, whereas the second fixing projection 43 is provided integrally as a projection in the pressure plate 5. The two fixing projections 42, 53 each extend radially within the pressure spring 7 and rest on the radial inner side of the pressure spring 7.

[0037] As a result of the pressure spring 7, the pressure plate 5 is pressurised with a spring force in each of its possible positions along the loading direction X within the housing 2, which spring force is directed towards the upper side B of the housing 2 in the loading direction X. The pressure plate 5 comprises a recess in which a load pipe 6 is arranged. An internal thread 51 is provided in the recess of the pressure plate 5, which internal thread corresponds to an external thread 61 provided on the load pipe 6. The relative position of the pressure plate 5 and the load pipe 6 in the loading direction X is thus variable with respect to each other. In the illustrated embodiment, the internal thread 51 and the external thread 61 allow a displaceability of the load pipe 6 in relation to the pressure plate 5 in the loading direction X by approximately 20 mm. Accordingly, at a specific position of the pressure plate 5 in the housing 2 and at a specific position of the movable housing 3 and the stand housing 4 with respect to each other, the height of the spring support 1 in the loading direction X can be varied by twisting the load pipe 6 in relation to the pressure plate 5 by the aforementioned amount of approximately 20 mm. The height of the spring support 1 can thus be adjusted especially well to the operational environment. Two boreholes 62 are provided for this purpose in the load pipe 6, which boreholes extend in a direction perpendicularly to the loading direction X through the load pipe 6 and via which the load pipe 6 can be twisted easily relative to the pressure plate 5.

[0038] The load pipe 6 is guided by the cylindrical guide 43. It is thus ensured via the cylindrical guide 43 that the load pipe 6 is displaceably guided in the displacement direction X, so that tilting of the load pipe 6 relative to the base plate 45 of the stand housing 4 can effectively be prevented, which further increases the stability of the spring support 1. In the position shown in FIG. 1a, in which the pressure plate 5 rests on the upper side B of the housing 2, a centring projection 52 of the pressure plate 5 rests in a flush manner on the retaining projection 31 of the movable housing 3. This ensures especially good guidance of the pressure plate 5 relative to the housing 2, which can be especially advantageous when placing a component on the spring support 1. A load plate 8 is further provided for contact between the spring support 1 and a component, which load plate is arranged at the end of the spring support 1 on the load pipe 6, which end of the spring support 1 faces away from the stand side in the loading direction X. A uniform transmission of the force exerted by the component to the load plate 8 occurs via the load plate 8 onto the load pipe 6.

[0039] The embodiment shown in FIGS. 1 to 3 of the spring support 1 in accordance with the invention is capable of supporting components which exert a loading force of approximately 3 to 10 kN on the load plate 8. The height of the housing in the loading direction X assumes a specific amount depending on the loading of the pressure plate 8 with a specific loading force. In the embodiment shown in FIG. 1a, the load plate 8 is loaded with a low loading force of approximately 5 kN. Accordingly, the movable housing 3 is spaced relatively far from the stand side A of the housing 2, thus leading to a relatively high height of the housing in the loading direction X.

[0040] For the purpose of illustrating the embodiment of the spring support 1 in accordance with the invention which is shown in FIG. 1a in a full sectional view, the spring support 1 is shown in the same position in FIG. 1b in a semi-sectional view. FIG. 1b clearly shows the two tubular sections of the stand housing 4 and the movable housing 3 which circumferentially enclose the pressure plate 5, the load pipe 6 and the sliding guide 43. It is further shown in FIGS. 1a and 1b that the stand housing 4 comprises two recesses 441 which extend in the loading direction X over a considerable portion of the extension of the stand housing 4 in the loading direction X, which in the present case is more than approximately 80% of said extension. Said recesses 441 are disposed opposite each other and are formed for the purpose that a blocking apparatus 10 can be introduced into the recesses 441 and can be fixed on the second locking projection 32 of the movable housing 3 for the purpose of fixing the relative position of the movable housing 3 and the stand housing 4 with respect to each other. The arrangement and effect of the blocking apparatus 10 is explained in closer detail in FIGS. 3a and 3b. The bead 9 which is comprised by the movable housing 3 can further be recognised from FIG. 1b. As is not shown in FIG. 1b, the bead 9 is arranged in a depression on the pressure plate 5 for fixing the pressure plate in the position shown in FIGS. 1a, 1b and for preventing a relative twisting of the pressure plate 5 in relation to the movable housing 3.

[0041] FIG. 2 shows the spring support 1 according to FIGS. 1a and 1b in a full sectional view in a state in which it is subjected to a high loading force in the loading direction X on the pressure plate 8, which loading force is approximately 9 kN in the illustration of FIG. 2. FIG. 2 shows that the height of the housing in the loading direction X is considerably reduced in comparison with the illustration according to FIGS. 1a and 1b. Accordingly, a pressure spring 7 with a relatively low spring constant can be used in the illustrated embodiment of the spring support 1 in accordance with the invention, which pressure spring ensures a high load capacity for carrying a high loading force in the loading direction X in a low installation height, namely the height of the spring support 1 in the loading direction X. The relative displacement of the pressure plate 5 relative to the stand housing 4 is principally also possible if the movable housing 3 rests on the base plate 45 of the stand housing 4 since the pressure plate 5 is still displaceable relative to the movable housing 3 in the loading direction X. The maximum possible loading of the spring support 1 with a loading force in the loading direction X is predetermined either by the pressure spring 7 or by the limit stop of the load pipe 6 on the base plate 45.

[0042] In FIGS. 3a and 3b, the spring support 1 in accordance with the invention is shown in the position as illustrated in FIGS. 1a and 1b, wherein the relative position of the movable housing 3 and the stand housing 4 with respect to each other is secured by a blocking apparatus 10. The blocking apparatus 10 comprises a bolt 11 and blades 12, wherein the blades 12 are fixed with respect each other by bolting the nuts 13 together with the bolts 11. FIGS. 3a and 3b show that the blades 12 represent a retaining device, which blades extend from the exterior side of the stand housing 4 through the recess 441 in the side wall of the stand housing 4 extending in the loading direction X up to the exterior wall of the movable housing 3, which extends in the loading direction X. The blades 12 arranged at the height of the second locking projection 32 are deflected in comparison with the remaining blades 12 of the blocking apparatus 10, so that a clearance is obtained between said remaining blades 12 in which the second blocking projection 32 is arranged. The relative position of the movable housing 3 relative to the stand housing 4 is secured by the arrangement of the blocking apparatus 10 in the recess 441 and the clamping of the retaining device with the second locking projection 32 which is ensured by the blades 12. For example, the spring support 1 can be placed with the blocking apparatus 10 according to FIGS. 3a and 3b beneath a component, wherein a pretension of the pressure spring 7 in the housing 2 is set by the blocking apparatus 10, which is adjusted to the expected loading force of the component. As soon as the component acts with its loading force on the load plate 8, the blocking apparatus 10 can be released by releasing the nuts 13 from the second locking projection 32 and be removed from the spring support 1 without producing any substantial change in the height of the spring support 1 in the loading direction X.

[0043] The advantageousness of the spring support 1 in accordance with the invention is clearly illustrated to the person skilled in the art from the illustrated embodiment. Since the housing 2 of the spring support 1 is telescopable in the loading direction X, the spring support 1 can be used in a wide load range, wherein a low height of the housing of the spring support 1 is ensured when loading the spring support 1 with a high loading force. The invention can generally relate to spring supports in which the stand housing 4 has an outer diameter perpendicularly to the loading direction X of approximately 100 to 350 mm, especially 120 to 320 mm, and the movable housing 3 has a respective outer diameter of approximately 100 to 300 mm, especially 125 to 290 mm. It can especially be generally advantageous that the movable housing 3 is arranged in a direction perpendicularly to the loading direction X within the stand housing 4, wherein the outer diameter of the movable housing 3 in this direction is approximately 90 to 95% of the respective outer diameter of the stand housing 4. This can ensure a substantially friction-free displacement of the two housing elements with respect to each other on the one hand and an adequate clearance within the movable housing 3 for the pressure spring 7 and the pressure plate 5 as well as the load pipe 6 and the cylindrical guide 43 on the other hand.

LIST OF REFERENCE NUMERALS

[0044] Spring support

[0045] 2 Housing

[0046] 3 Movable housing

[0047] 4 Stand housing

[0048] 5 Pressure plate

[0049] 6 Load pipe

[0050] 7 Pressure spring

[0051] 8 Load plate

[0052] 9 Bead

[0053] 10 Blocking apparatus

[0054] 11 Bolt

[0055] 12 Blade

[0056] 13 Nut

[0057] 31 Retaining projection

[0058] 32 Second locking projection

[0059] 41 First locking projection

[0060] 42 First fixing projection

[0061] 43 Cylindrical guide

[0062] 44 Tubular section

[0063] 45 Base plate

[0064] 46 Hole

[0065] 51 Internal thread

[0066] 52 Centring projection

[0067] 52 Second fixing projection

[0068] 61 External thread

[0069] 62 Borehole

[0070] 441 Recess

[0071] A Stand side

[0072] B Upper side

[0073] X Loading direction