GUIDE/DAMPING UNIT AND PISTON HOUSING UNIT

Abstract

A piston housing unit comprises a housing with a longitudinal axis, a piston rod that is displaceable, in particular along the and/or around the longitudinal axis, a guide/damping unit for guiding and damping the displacement of the piston rod.

Claims

1. A guide/damping unit for guiding and damping a piston rod in a piston housing unit, wherein the guide/damping unit has a guide element and at least one damping element.

2. A guide/damping element according to claim 1, wherein the guide element has two half-shells.

3. A guide/damping element according to claim 1, wherein the guide element has two identically designed half-shells.

4. A guide/damping unit according to claim 1, wherein the guide element has at least one linear guide section.

5. A guide/damping unit according to claim 1, wherein the guide element has two linear guide sections spaced a distance from each other along the longitudinal axis.

6. A guide/damping unit according to claim 1, wherein the damping element encloses the piston rod.

7. A guide/damping unit according to claim 6, wherein the damping element has a damping ring or at least one damping strip.

8. A guide/damping unit according to claim 1, wherein the damping element is arranged in a damping element recess of the guide element.

9. A guide/damping unit according to claim 8, wherein the damping element recess is designed as an inner groove.

10. A guide/damping unit according to claim 1, further comprising at least one grease pocket.

11. A guide/damping unit according to claim 10, wherein the grease pocket is arranged in a half-shell of the guide element.

12. A guide/damping unit according to claim 10, wherein the grease pocket is designed as an indentation in an inner surface of the inner groove.

13. A guide/damping unit according to claim 1, wherein the damping effect can be set.

14. A guide/damping unit according to claim 1, wherein the damping effect can be set by means of a pre-tensioning force, with which a damping strip is arranged in the guide/damping unit.

15. A piston housing unit, comprising a housing having a longitudinal axis, a displaceable piston rod, a guide/damping unit for guiding and damping the displacement of the piston rod.

16. A piston housing unit according to claim 15, wherein the guide/damping unit is fitted in a housing.

17. A piston housing unit according to claim 15, wherein the guide/damping unit is integrated into a housing.

18. A piston housing unit according to claim 15, wherein the housing is designed tubular.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] FIG. 1 shows a perspective illustration of a piston housing unit according to the invention,

[0024] FIG. 2 shows a longitudinal section along section line II-II in FIG. 1,

[0025] FIG. 3 shows an illustration of the piston housing unit according to FIG. 1 in an exploded illustration,

[0026] FIG. 4 shows an enlarged illustration of the guide/damping unit of the piston housing unit according to FIG. 1,

[0027] FIG. 5 shows an illustration of the guide/damping unit according to FIG. 4 in an exploded illustration,

[0028] FIG. 6 shows a perspective illustration of a half-shell of a guide element of the guide/damping unit,

[0029] FIG. 7 shows an illustration of a second embodiment example of a piston housing unit according to FIGS. 2, and 10

[0030] FIG. 8 shows an illustration of a third embodiment example of a piston housing unit according to FIG. 2.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0031] A piston housing unit 1 has a hollow cylinder housing 2 with a longitudinal axis 3. The housing 2 of the piston housing unit 1 is closed by means of a closure cap 4 at a first end, illustrated on the right in FIG. 1. The closure cap 4 has a fitting lug 5 arranged concentric to the longitudinal axis 3, shaped of a single piece on a cover plate 6. The cover plate 6 is oriented vertical to the longitudinal axis 3. The lug is arranged on an outside of the cover plate 6 facing away from the housing 2. The closure cap has an insertion collar 7 on an inside facing the housing 2, with which the closure cap 4 can be inserted into the first end of the housing 2. The insertion collar 7 can be positively, and in particular non-disconnectably connected with the housing 2. For this several, in particular six indentations 8 can be envisaged along the outer circumference of the housing 2, which engage corresponding counter-indentations 9 in a radial direction in relation to the longitudinal axis 3. The closure cap 4 is held securely on the housing 2 axially as well as radially in relation to the longitudinal axis 3.

[0032] A guide/damping unit 10 is arranged on the housing 2 at a second end opposite the closure cap 4. The guide/damping unit 10 is inserted into the facing open end of the housing 2 much like the closure cap 4 and is positively fixed there by means of indentations 8 and counter-indentations 9.

[0033] A piston rod 11 is guided from the housing 2 through the guide/damping unit 10 along the axial alignment of the longitudinal axis 3. The piston rod 11 is arranged outside of the housing 2 with a first, free end 12. An opposing, second end 13 is arranged inside the housing 2. A piston 14, designed as an annular disc 27 according to the embodiment example shown, is fitted on the second end 13 of the piston rod 11 and is held on the piston rod 11 by means of a fitting nut 15. The piston 14 according to the first embodiment example is a collar-out protection. The piston 14 prevents the piston rod 11 being pulled out of the housing accidentally. The annular disc 27 has an outer diameter that is greater than an inner diameter of a through opening of the guide/damping unit 10. The annular disc 27 serves as a stop element on the guide/damping unit 10.

[0034] The guide/damping unit 10 will now be explained in more detail with reference to FIGS. 3 to 6. The guide/damping unit 10 has a stop collar 25 on a facing side that faces away from the housing 2. The stop collar 25 projects further than the guide/damping unit 10 in a radial direction in relation to the longitudinal axis 3. The stop collar 25 delimits a maximum insertion depth of the guide/damping unit 10. The guide/damping unit 10 can be arranged directly in, and defined in relation to the axial position of the housing 2. The assembly of the piston housing unit 1 is simplified.

[0035] The guide/damping unit 10 has a guide element 16 and a damping element 17. The guide element 16 and the damping element 17 are integrated in the guide/damping unit.

[0036] The guide element 16 is of a sleeve-shaped design with a through opening along the longitudinal axis 3, through which the piston rod 11 is guided. The guide element 16 has two linear guide sections 18 arranged at distances from each other along the longitudinal axis 3. The linear guide sections 18 each extend from a facing end of the guide/damping unit 10. The linear guide sections 18 are designed as through channels with an inner contour shaped as hollow cylinders, which approximately equal the outer contour of the piston rod 11 at a level vertical to the longitudinal axis 3.

[0037] A damping element recess 19, into which the damping element 17 can be inserted, is envisaged along the longitudinal axis 3 between the linear guide sections 18. The damping element recess 19 is delimited by each of the neighbouring linear guide sections 18 in an axial direction in relation to the longitudinal axis 3. The damping element recess 19 is designed as an inner groove and has a groove depth that is deeper than the linear guide section 18. An axial abutment shoulder 20 is formed between the damping element recess 19 and each of the neighbouring linear guide section 18.

[0038] The guide/damping unit 10, in particular the guide element 16, has two grease pockets 21, which each serve as a grease reservoir for the damping element 17. The grease pockets 21 are each arranged on an inside of the inner groove, i.e. on an inside of the damping element recess 19. Grease can be supplied from the grease pockets 21 directly to the damping element 17.

[0039] The guide element 16 consists of several parts, in particular in the form of two identically designed half-shells 22. The half-shells 22 can be separated from each other along a separation level that includes the longitudinal axis 3. The half-shells 22 have connection elements 23 and connection counter-elements 24 corresponding with the same. The connection elements 23 are designed as spigots according to embodiment example shown, which can engage corresponding spigot recesses. The half-shells 22 are designed as identical components. The manufacturing effort for the guide/damping unit 10 is reduced. The connection elements 23 and the connection counter-elements 24 guarantee that the half-shells 22 are arranged to define each other. A loosening of the connection is ruled out once the guide/damping unit 10 has been pushed into the housing 2. Connecting the half-shells 22 guarantees a secure and undetachable holding of the guide/damping unit 10 in the housing 2 of the piston housing unit 1.

[0040] It is also feasible that the guide element is designed as one part or with more than two half-shells. It is of advantage if the individual parts from which the guide element 16 is formed are designed as identical parts. It is for example also possible to envisage quarter-shell elements.

[0041] The damping element 17 is designed in the form of two identically designed damping strips 26. The damping strips 26 are flat, in particular level, in their starting condition, i.e. before they have been inserted into the damping element recess 19 of the guide element 16. Inserting the damping strips 26 into the guide/damping unit 10 deforms the damping strips 26, in particular bends them into a cylinder half-shell shape. The damping strips 26 are made from an elastic damping material, in particular from foamed plastic, in particular foam material.

[0042] The inherent rigidity of the damping material for the damping strips 26 is in particular at least so great that a returning force is provided, which effects that the damping strips 26 aim to independently transform themselves into the flat starting condition. The damping strips 26 thus apply a compression force to the piston rod 11.

[0043] The damping strips 26 have a strip width oriented along the longitudinal axis 3. The strip width of the damping strip 26 equals the width of the damping element recess 19.

[0044] According to an embodiment example not shown, the width of the damping element recess 19 can be greater than the strip width of the damping strip 26. The width of the damping element recess 19 is in particular at least 105% of the strip width of the damping strip 26, in particular at least 110%, in particular at least 120%, and in particular at least 125%. With this design the damping strip 26 can be axially displaced along the longitudinal axis 3 in the damping element recess 19. With an axial displacement of the piston rod 11 the damping strip 26 is initially also axially displaced along the longitudinal axis 3 due to static friction until the facing side of the damping strip 26 abuts against the end of the damping element recess 19, in particular against the axial abutment shoulder 20. The axial abutment shoulder 20 prevents a further axial displacement of the damping strip 26. A further displacement of the piston rod 11 causes a relative movement between the piston rod 11 and the damping strip 26. From this point in time a friction force is generated by the abutment of the damping strip 26 against the piston rod 11.

[0045] There is therefore no or only a low damping force at the start of the axial displacement of the piston rod with this embodiment example. Such a piston housing unit enables a so-called soft start characteristic.

[0046] The damping strip 26 is designed with a strip thickness that is greater than the groove depth of the damping element recess 19. This guarantees that a radial pressing of the damping strip 26 against the piston rod is reliably guaranteed. The strip thickness of the damping strip 26 in particular is at least 105% of the groove depth, in particular at least 115%, in particular at least 125%, in particular at least 130%, and in particular at least 135%. The groove depth of the damping element recess 19 can also substantially equal the strip thickness of the damping strip 26.

[0047] The strip length of the damping strips 26 is sized in such a way that a substantially closed damping ring extending along the entire circumference of the damping element recess 19 is formed when the damping strip is inserted. It is also feasible to envisage more than two damping strips 26 or only one damping strip. It is also feasible to use a closed damping ring as a damping element 17.

[0048] The major advantage of the design of the guide/damping unit 10 as illustrated in FIG. 5 is that the unit 10 consists of just two different individual parts, namely the half-shells 22 and the damping strips 26. Manufacture of the guide/damping unit 10 is possible in a cost effective way.

[0049] The assembly of the piston housing unit 1 will be explained in more detail below. The housing 2 is first closed at the first end by means of the closure cap 4. The piston rod 11 is then inserted into the housing 2 with the second end 13. The two half-shells 22 are arranged around the piston rod 11 with an inserted damping strip 26 each in the area of the piston rod 11 that projects from the housing 2 and connected with each other. By connecting the half-shells 22 the damping strips 26 are pressed into the damping element recess 19 and bent into a half-shell shape, and the half-shells 22 connected with each other are then pushed along the piston rod 11 into the housing 2 as a guide/damping unit 10 until the guide/damping unit 10 lies against the housing 2 with the facing side of the abutment collar 25. The guide/damping unit 10 is fitted to the housing 2 above the indentations 8 and the counter-indentations 9.

[0050] A second embodiment example of the invention will be described below with reference to FIG. 7. Components of identical construction are identified with the same reference numbers than for the first embodiment example, to the description of which we herewith refer. Components of different construction, but with an identical function are identified with postposed a.

[0051] The major difference compared to the first embodiment example is that the piston 14a has two discs 27 arranged at a distance from each other long the longitudinal axis 3. The discs 27 are in particular designed identically. The discs 27 have an outer diameter that is smaller than an inner diameter of the cylindrical housing 2. An annular groove 28 is formed between the discs 27. According to the second embodiment example, the piston 14a serves as a plug-out protection.

[0052] The annular groove 28 can in particular be designed as a distancer sleeve arranged between the two annular discs 27. The discs 27 can be riveted to the piston rod 11.

[0053] A third embodiment example of the invention will be described below with reference to FIG. 8. Components of identical construction are identified with the same reference numbers than for the first two embodiment examples, to the descriptions of which we herewith refer. Components of different construction, but with an identical function are identified with postposed b.

[0054] Compared to the second embodiment example the third embodiment example differs in that an additional friction element 29 is arranged in the annular groove 28, and is in particular held there. The additional friction element 29 is designed in such a way that it rubs against an inside of the housing 2. According to this embodiment example the piston 14b fulfills a double function, namely serves as a pull-out protection, and enables additional fiction force to be generated during an axial and/or rotation displacement of the piston rod 11. The friction force that can be generated with the piston housing unit 1b is increased.