DE19822431A1 - Infinitely adjustable ball joint for shelves, tables provides height adjustment - Google Patents

Abstract

An infinitely variable-position ball joint (1) for esp. shelves or tables has a connecting rod (10), a connecting rod cover (20), a connecting rod-seat (30), and a slide (40) with a ball cap (45). The structure to which the joint is attached is pushed onto the connecting rod cap (20) and can be swivelled through a range of 8 degrees to 59 degrees above the connecting rod (10). Height adjustment is effected by rotating the connecting rod seat (30) in the slide (40). The connecting rod is made in glass fibre reinforced plastic or metal, while the remainder of the joint is made in plastic.

Description

The invention relates to a joint unit for stepless height and angle adjustment of frame components in relation to a support surface.

It is mainly known in plastics and connection technology to use two-element joint units that have a spherical joint body include, which is in turn stored in a half-shell-shaped joint trough. This enables a multi-dimensional angle adjustment option, however, such joint units are in terms of their load-bearing capacity and load availability and the adjustable angular range is very limited. Because of a Increased material stress and material fatigue result in an inaccurate fit that can even result in a loss of function. Known Plastic plug systems, however, only offer the possibility of angle adjustment frame components opposite their support surface, however, leave a height  disregard adjustment. But especially with table frames, it is often necessary in addition to an angle adjustment or adjustment, a height at the same time ensure adjustment. This can compensate for uneven floors wobble-free stand of the frame.

The object of the invention is to provide an articulated unit which is both for different frame systems, as well as for different table or shelf sizes universally applicable and due to the modular construction easy to manufacture and is applicable and can withstand high loads.

The object is achieved in that the joint unit from one multi-unit height adjustment element and an also multi-unit angle adjusting element is constructed. This results in a multifunctional use Joint unit. The height can be adjusted from the frame components are changed relative to a support surface. The angle adjustment element opens up the functionality associated with the joint unit Frame component, in particular a support tube or a table base, with regard to its To change the angle to the support surface. According to the invention, the Winkelver adjusting element a connecting rod pin, a connecting rod cover and a connecting rod seat, the The connecting rod pin engages positively in the connecting rod cover and around a bearing axis lying parallel to the support surface is pivotally mounted in the connecting rod seat is. The height adjustment element comprises the connecting rod seat and a slider, the Connecting rod height is mounted in the glider.

With the invention, an articulated connecting element is created, which also at increased force on the frame due to cumulative or alternative height and / or Changing the angle enormously increases the variability of the overall frame.

The modular structure of the joint unit according to the invention means that structural adjustment of only one element to the joint unit various existing rack systems applicable.  

For example, if an exact, quick adjustment to the rack location is required can do this by using several multifunctional joint according to the invention units can be achieved.

In a development of the invention, in which all elements of the joint unit are made Are made of plastic, that is related to the connecting rod cover Frame component can be swiveled steplessly in an angular interval of 8 ° to 59 °. Become additional frame components of different lengths, e.g. B. tubular table legs used in a Y-fork, so any table and frame can be create configurations.

If the area of use of the frame requires an increased angle adjustment range of 8 ° up to 64 ° or more, so is in a further embodiment of the invention Connecting rod pin of the joint unit made of aluminum or steel.

Due to the universal applicability of the joint unit according to the invention, this takes place not only for frames that are supported on the floor, but can also for shelving systems that support themselves on the wall or ceiling similar can be used.

In an advantageous embodiment of the invention, the joint unit is as closed system executed so that the adjustment and bearing elements in front pollution from the environment are protected.

It is particularly advantageous that the individual components of the invention according joint unit are designed so that their assembly is very simplified and can therefore also be carried out by inexperienced personnel, however after functional assembly by special design features, such as in the form of a catch seat, can no longer fall apart. This is a special one relevant advantage in practice, since it is in a conversion, moving or a lifting of the frame is not desired that the components of the joint unit must be reassembled in each case

An embodiment of the invention is shown in the drawing and will described in detail below. Show it:

FIG. 1 is a three dimensional view of a joint assembly having a tubular frame member;

FIG. 2a is a three dimensional view of a Pleuelstiftes;

FIG. 2b shows another three-dimensional view of the Pleuelstiftes;

Fig. 3 is a three dimensional representation of a connecting rod cover;

Fig. 4 is a three dimensional representation of a Pleuelsitzes;

Fig. 5 is an isometric view of a slider;

Fig. 6 is a three-dimensional view of a spherical cap,

Fig. 7 is an isometric partially broken view of the hinge unit to operate according to the assembly consisting of Pleuelstift, connecting rod, Pleuelsitz, slider and ball cover;

Fig. 8 is a side sectional view of the joint unit and

Fig. 9 is a three-dimensional exploded view of the hinge unit.

A joint unit, generally designated 1 , is intended for engagement with a frame component 2 . In overview, FIG. 1 shows the possible angular arrangement of the frame member 2 through the hinge unit 1, which in turn (not shown) on a support surface is supported. In the main area of application of the joint unit 1 according to the invention, this is a floor on which, for example, a table is supported via the frame and via the joint unit 1 . Through the use of several joint units 1 and through the use of different frame components 2 - different especially with regard to their length and their angle to the support surface - a variety of frame and table configurations are possible.

FIGS. 8 and 9 show all the elements of the joint unit 1 of the invention. It consists of a connecting rod pin 10 , a connecting rod cover 20 , a connecting rod seat 30 and a slider 40 . In the embodiment shown in FIG. 8, the joint unit 1 additionally comprises a spherical cover 45 which is placed on the slider 40 and which does not have a supporting function, but serves the optical cover and protects the joint unit from contamination.

The individual elements of the joint unit 1 are described below with reference to the individual figures of the drawing.

FIGS. 2a and 2b show the Pleuelstift 10 in different perspective views. In its asymmetrical shape, it has at its end facing the joint unit 1 a convex bearing area 12 which is laterally delimited by the side walls 16 . Both side walls 16 have cams 15 which protrude laterally and which are basically cylindrical in shape, but are flattened in an area to make assembly easier. The cams 15 are intended to engage portions of the connecting rod seat 30 and prevent the joint from falling apart when the unit is raised. A functional area 13 adjoins the bearing area 12 of the connecting rod pin 10 and , as shown in FIG. 2b, is characterized by a material recess. This is necessary in order to ensure the functional movement of the connecting rod pin 10 within the joint unit 1 - the material cut-out prevents the connecting rod pin 10 from striking the slider 40 in the border area. The functional area 13 is completed by an insertion stop 14 of the connecting rod pin 10 . The insertion stop 14 serves to axially secure the connecting rod cover 20 relative to the connecting rod pin 10 . At its end facing away from the joint unit 1 , the connecting rod pin 10 has a shaft 11 . The shaft 11 has two different sections, the section near the center being essentially in the form of a square with rounded corners and the outer section having a circular cross section, the diameter of which is smaller than an edge of the square section. The section near the center is the positive insertion area of the connecting rod pin 10 for the force-transmitting connection to the connecting rod cover 20 . The outer section has an external thread 19 . The shaft 11 of the connecting rod pin 10 is symmetrical in cross section with respect to both axes.

As can be seen in particular in FIG. 8, the longitudinal center line of the connecting rod pin 10 and the bearing center point have an offset. This offset enables the minimum angle of 8 °.

The connecting rod cover 20 shown in FIG. 3 has a predominantly cylindrical outer contour and continues at its end facing the joint unit 1 into an attachment which forms a cover cap 22 . The cover cap 22 has the shape of a spherical surface. The frame-side, cylindrical section of the connecting rod cover 20 has an outer contour having projections and shoulders in the form of a corrugation 21 , which are used to adapt to pipe tolerances of the frame component 2 . In a second embodiment, the corrugation 21 can be perpendicular to the central axis. The insertion geometry of the connecting rod cover 20 for frame profiles shown here can also be designed as a connecting flange. The connecting rod cover 20 is provided on the inside with a through hole which has a symmetrical square section which merges into a section which is circular in cross section. At the foot of the cylindrical section, the connecting rod cover 20 has an insert pocket 23 for the possible accommodation of one or more shims, not shown. The inner contours of the connecting rod cover 20 are designed in such a way that they can be fitted together with the shaft 11 of the connecting rod pin 10 with a precise fit. In the exemplary embodiment, connecting rod pin 10 and connecting rod cover 20 are designed as two separate components. However, it is also possible to manufacture connecting rod pin 10 and connecting rod cover 20 as one component.

The connecting rod seat 30 shown in FIG. 4 has a cylindrical base plate 33 and a structure which extends essentially perpendicular to the base plate 33 . In a preferred embodiment, the structure consists of four spring struts 34 which predominantly have a long leg which opens into a short leg which is bent almost at right angles and has a spherical contour surface which matches the spherical cover 45 . The base plate 33 of the connecting rod seat 30 is provided with an external thread 31 at least in some areas. The structure of the connecting rod seat 30 has a bearing shell 35 in the form of a recess on the bottom, which is delimited laterally by cheeks of two spring struts 34 each. The cheeks secure against rotation during the height adjustment by rotating the slider 40 relative to the connecting rod pin 10 and connecting rod seat 30 . Two spring struts 34 each form an intermediate gap which opens into a circular recess 36 on the bottom side. The diameter of this recess 36 corresponds to the diameter of the cams 15 of the connecting rod pin 10 . The bearing axis 32 , which forms the pivot axis of the joint unit 1 , runs through the center of the recesses 36 and the bearing shell 35 . Correspondingly, the radius of curvature of the bearing shell 35 of the connecting rod seat 30 corresponds to the radius of curvature of the connecting rod pin 10 in the bearing area 12 .

The slider 40 shown in FIG. 5 has a circular cross section. Its outer contour can be subdivided into two sections, the bottom section having a profiled outer contour 42 and the section arranged above it consisting of an unprofiled guide collar 43 . The slider 40 has an internal thread 41 on the inside. In a preferred embodiment, the entire slider 40 is provided with the internal thread 41 in its inner region. Alternatively, the internal thread 41 can only be formed in an upper section of the slider 40 . At least the upper section of the slider 40 is double-walled and has support ribs 44 between the walls.

In a preferred embodiment, the joint unit 1 is additionally provided with a ball cover 45 , which is shown in FIG. 6. The ball cover 45 has a central movement slot 46 , which is intended for receiving the connecting rod pin 10 . The inside of the ball cover 45 is provided with catch ribs 47 which serve as a stop for the spring struts 34 of the connecting rod seat 30 . For this purpose, the short legs of the struts 34 are preferably sharp-edged at their mutually facing edges. The strut stop prevents the struts 34 from being displaced into the movement slot 46 of the ball cover 45 and thus into the movement range of the connecting rod pin 10 .

Fig. 7 shows the joint unit 1 in the assembled state. Here, the profiled outer contour 42 of the slider 40 can be seen, on which the ball cover 45 with the movement slot 46 is seated. In the moving slot 46 of the Pleuelstift 10 engages (partially visible) which will, in turn, is connected to the connecting rod 20th Visible is the corrugation 21 of the connecting rod cover 20 with the cover cap 22 , which can cover the movement slot 46 of the ball cover 45 when the connecting rod pin 10 moves.

The functional interaction of the elements of the joint unit 1 is visible in FIG. 8. The connecting rod cover 20 is intended for engagement with a frame component. The corrugation 21 of the connecting rod cover 20 should compensate for any pipe tolerances within the frame system. Due to the adapted to the outer contour of the connecting rod cover 20 Pleuelstiftes 10 Innenkonturierung of registration with a seat of the connecting rod cover 20 is enabled in the Pleuelstift 10th A washer 17 is pushed over the external thread 19 of the shaft 11 and a nut 18 is screwed onto the connecting rod pin 10 for fastening the connecting rod cover 20 . The insertion stop 14 of the connecting rod pin 10 serves to limit the axial movement of the connecting rod cover 20 . After the connecting rod pin 10 is pressed into the connecting rod seat 30 , an articulated connection with a degree of freedom is created. The bearing area 12 of the connecting rod pin 10 engages in the bearing shell 35 of the connecting rod seat 30 formed in the base plate 33 . In order to facilitate the assembly of the connecting rod pin 10 in the connecting rod seat 30 , the cams 15 are formed with a mounting surface - as shown in FIGS. 2a and 2b - which guide the connecting rod pin 10 in the mounting position within the gap formed between the spring struts 34 , that Reduce expansion or spreading of the struts 4 and allow the cams 15 to snap into the recesses 36 . In the angular range of the working position, the surfaces of the cams 15 are without function, since the round contour of the cams 15 is now guided in the diameter of the recesses 36 of the connecting rod seat and thus connecting rod pin 10 and connecting rod seat 30 hold together. In the assembled state, the cams 15 engage in the circular recesses 36 formed between the spring struts 34 and together form a catch seat which prevents the joint unit 1 from falling apart, for example when it is lifted. After assembly, the ball cover 45 is under tension by the spring force exerted by the spring struts 34 and presses it against a spherical counter bearing in the connecting rod cover 20 . From Fig. 8 it can be seen that the diameter of the guide collar 43 of the slider 40 corresponds to the diameter of the ball cover 45 in its bottom engagement area with the slider 40 with little guide play. This allows guidance between the ball cover 45 and slider 40 in the height adjustment. A bottom-side slipping of the ball cover 45 on the slider 40 is prevented by the profiled outer contour 42 serving as a stop. The height adjustment of the bearing area 12 and thus of the connecting rod pin 10 is made possible by turning the external thread 31 with the internal thread 41 .

The profiled outer contour 42 of the slider 40 serves to facilitate manual operation of the height adjustment element. In the preferred embodiment of the invention, the height adjustment covers an adjustment range of 12 to 14 mm.

In the preferred embodiment, the frames have round tubes with a diameter of between 23 and 40 mm. Alternatively, it is possible to apply the joint unit 1 to rectangular tubes, oval tubes or triangular tubes by adapting the outer contour of the connecting rod cover 20 . In a further embodiment, the insertion geometry of the connecting rod cover 20 can also be designed as a connecting flange for solid frames.

Reference list

1

Joint unit

2nd

Frame component

10th

Connecting rod

11

shaft

12th

storage area

13

Functional area

14

Insert stop

15

cam

16

Sidewalls

17th

Washer

18th

mother

19th

External thread

20th

Connecting rod cover

21

Corrugation

22

Cover cap

23

Insert pocket

30th

Connecting rod seat

31

External thread

32

Bearing axis

33

Base plate

34

Struts

35

Bearing shell

36

Recess

40

Glider

41

inner thread

42

profile. Outer contour

43

Leadership association

44

Support ribs

45

Ball cover

46

Movement slot

47

Ribs

Claims (23)

1. articulation unit ( 1 ) for stepless height and angle adjustment of frame components compared to a support surface with a height adjustment element ( 30 , 40 ) that changes the distance of frame components ( 2 ) from the support surface and an angle adjustment element ( 10 , 20 , 30 ), that changes the angle of the frame ( 2 ) relative to the support surface. 2. Joint unit according to claim 1, characterized in that the angle adjustment element comprises a connecting rod pin ( 10 ), a connecting rod cover ( 20 ) and a connecting rod seat ( 30 ), wherein the connecting rod pin ( 10 ) positively engages in the connecting rod cover ( 20 ) in the assembled state and is pivotally mounted in the connecting rod seat ( 30 ) about a bearing axis ( 32 ) lying parallel to the support surface. 3. Joint unit according to one of claims 1 or 2, characterized in that the height adjustment element comprises the connecting rod seat ( 30 ) and a slider ( 40 ), the connecting rod seat ( 30 ) being mounted adjustable in height in the slider ( 40 ). 4. Joint unit according to one of claims 2 or 3, characterized in that the connecting rod pin ( 10 ), the connecting rod cover ( 20 ), the connecting rod seat ( 30 ) and the slider ( 40 ) are made of plastic. 5. Joint unit according to one of claims 2 to 4, characterized in that the connecting rod pin ( 10 ) in an interval of 8 ° to 59 ° is continuously pivotable about the bearing axis ( 32 ) in the connecting rod seat ( 30 ). 6. Joint unit according to one of claims 2 to 5, characterized in that the connecting rod cover ( 20 ) is intended for axially displaceable engagement with a frame component ( 2 ). 7. Joint unit according to one of claims 2 to 6, characterized in that the connecting rod cover ( 20 ) on its outer contour has a corrugation ( 21 ) extending parallel or perpendicular to the longitudinal axis of the connecting rod cover ( 29 ). 8. Joint unit according to one of claims 2 to 7, characterized in that the connecting rod cover ( 20 ) has a through hole which is intended for positive engagement with a shaft ( 11 ) of the connecting rod pin ( 10 ). 9. Joint unit according to one of claims 2 to 8, characterized in that the connecting rod cover ( 20 ) has at least one cover cap ( 22 ). 10. Joint unit according to claim 9, characterized in that the cover cap ( 22 ) has the shape of a spherical surface. 11. Joint unit according to one of claims 2 to 10, characterized in that the connecting rod pin ( 10 ) has a bearing area ( 12 ), a functional area ( 13 ), an insertion stop ( 14 ), cams ( 15 ) and the shaft ( 11 ). 12. Joint unit according to one of claims 2 to 11, characterized in that the shaft ( 11 ) of the connecting rod pin ( 10 ) is formed from two sections, the section near the center point having a square cross section with rounded corners and the outside section having a circular cross section . 13. Joint unit according to one of claims 11 or 12, characterized in that the bearing area ( 12 ) comprises a convexly curved bearing surface which is delimited by two parallel side cheeks ( 16 ). 14. Joint unit according to one of claims 2 to 13, characterized in that the connecting rod seat ( 30 ) consists of a cylindrical base plate ( 33 ) and a spring leg ( 34 ) having a structure which extends substantially perpendicular to the base plate ( 33 ). 15. Joint unit according to claim 14, characterized in that the base plate ( 33 ) of the connecting rod seat ( 30 ) has an external thread ( 31 ) at least in regions. 16. Joint unit according to one of claims 14 or 15, characterized in that the construction of the connecting rod seat ( 30 ) comprises four struts ( 34 ), each having a long and a short leg, the spring direction of which is different. 17. Joint unit according to one of claims 11 to 16, characterized in that the connecting rod pin ( 10 ) has two cams ( 15 ), each of which forms a catch seat together with the base-side configuration of two spring struts ( 34 ) of the connecting rod seat ( 30 ). 18. Joint unit according to one of claims 3 to 17, characterized in that the slider ( 40 ) is cylindrical and with an inner thread ( 41 ) which at least partially lines the interior and its outer contour has two sections with different diameters, the larger diameter has a profiled outer contour ( 42 ) and the smaller diameter is designed as a guide collar ( 43 ). 19. Joint unit according to claim 18, characterized in that the slider ( 40 ) has an approximately hemispherical ball cover ( 45 ), the diameter of which corresponds to that of the guide collar ( 43 ) plus twice the wall thickness of the ball cover ( 45 ) and the one movement slot ( 46 ) having. 20. Joint unit according to one of claims 18 or 19, characterized in that the slider ( 40 ) in the region of the guide collar ( 43 ) is double-walled with intermediate-walled support ribs ( 44 ). 21. Joint unit according to one of claims 1 to 20, characterized in that the components are made of plastic and the connecting rod pin ( 10 ) is made of a plastic, the 30% glass fiber are added. 22. Joint unit according to one of claims 1 to 20, characterized in that at least the connecting rod pin ( 14 ) of the joint unit ( 10 ) is made of metal. 23. Joint unit according to one of claims 1 to 22, characterized in that the insertion geometry of the connecting rod cover ( 20 ) is designed as a connecting flange.