FI119888B - Sleeve connection between outer and inner tube of telescopically adjustable shaft - Google Patents

Description

Sleeve joint between telescopically adjustable shaft outer tube and inner tube

The present invention relates to a sleeve joint between a telescopically adjustable length of the outer tube of an arm 5 and an inner tube having a sleeve-like body portion attached to an end of the outer tube having opposite fastening lugs which is pivotable about a substantially transverse pivot axis 10 with respect to the helical wedge surfaces, and at the end of the pivot axis is formed a limb having tensioning wedges adapted to match the wedge surfaces of the mounting lugs, and a tensioning pivot the clamping forces substantially in the direction of the pivot axis are applied to the blades.

15 Such a sleeve connection is known from Applicant's own patent publication FI 113252. It discloses a sleeve-like body, which also includes opposing fastening lugs. A single longitudinal slit is formed between the mounting lugs on the body, the edges of which are pressed against each other by a form locking mechanism (including a draw bar and a clamping lever) formed on the lugs to lock the inner tube relative to the outer tube. In this way, a relatively good and secure locking is obtained. However, the disadvantage of such a joint is that, in order to obtain sufficient traction between the pipes, a relatively high force must be applied to press the edges of the slit towards each other. This also exposes the form locking mechanism to rapid wear. To compensate for the high force, a relatively long locking lever is required, which makes the joint area clumsy and exposes, for example, to unintentional contact with objects in the environment.

The object of the present invention is to eliminate or at least substantially reduce the above disadvantages.

The aforesaid object of the present invention is achieved in accordance with the present invention by forming flexible protrusions as an axial extension of the run-35 co-element near the opening edge of the body, and by securing the lugs 2 to a clamping sleeve removably secured to the flexible protrusions so that the protrusions are pressed around the inner tube when turning the mounting lever.

This sleeve connection according to the invention achieves the above purpose. In other words, a separate clamping sleeve allows the formation of flexible protrusions. Preferably, the material of the flexible protrusions is more flexible and / or softer than the material of the clamping sleeve. The flexible protrusions are located at regular intervals as an extension of the circumferential wall of the sleeve-like body. The clamping force exerted on the clamping sleeve 10 is then distributed evenly over the circumferential wall and further into the inner tube. Hereby, the forces between the wedge surfaces of the mounting lugs and the clamping wedge surfaces are smaller than those of the prior art for the outer and inner tube for a correspondingly strong joint. As a result, the pivoting force exerted on the clamping lever to secure the clamping sleeve is also smaller compared to prior art. This also has the advantage of less wear on the joint mechanism. In another sense, this allows for a significantly stronger connection between the tubes with the same clamping force compared to the prior art.

The telescopic arm with the sleeve connection according to the invention is suitable for many applications such as tool arms for cleaning, building maintenance and gardening, and masts, columns and furniture and tripod legs and the like.

Preferred embodiments of the present invention are disclosed in the dependent claims.

The invention will now be explained in more detail with reference to the accompanying drawings, in which: Figure 1 shows a partial view of a sleeve joint according to the invention, and Figure 2 shows a sleeve joint according to the invention.

Figures 1 and 2 show a sleeve joint in accordance with the present invention and parts thereof. The sleeve connection includes an outer tube designated 30 and an inner tube 31. In this embodiment, the tubes are circular. The outer diameter of the inner tube 31 is smaller than the inner diameter of the outer tube. A slider fit is provided between the tubes 30 and 31 so that they slide relative to one another. Due to the sliding fitting, the arm remains rigid at the joint, even though it is subjected to lateral forces relative to the arm, thereby preventing, for example, buckling.

Partly around one end of the outer tube 1 is provided a sleeve connection portion comprising a body portion 1, a clamping sleeve 10, a clamping lever 20 and a pull rod 26. The sleeve-like body portion 1 is permanently secured to the outer tube 30. The outer tube 30 is disposed internally preferably over a distance of about half the length of the body portion 1. Thus, the other open end of the body part 1 is an axial extension of the outer tube 30, whereby the inner tube 31 can be pushed from the open end of the body part 1 into the sleeve connecting part and further into the outer tube 30.

15

At the open end of the body part 1, an axial extension is formed by elongate protrusions 3 separated by slits 3a. The material of the protrusions is chosen to bend in the radial direction of the body 1 when subjected to a radial or at least substantially radial force 20. The material may be, for example, plastic suitable for injection molding. Preferably there are 2 to 10 protrusions, for example four, as can be seen in the figures.

The outer surface of the projections 3 is shaped to receive a clamping sleeve 10. The clamping sleeve 25 is preferably made of a metal, such as aluminum, which due to its lightness is well suited as a sleeve material. The clamping sleeve 10 is introduced axially around the protrusions 3. Two separate parallel mounting lugs 12 are formed on the outer surface of the clamping sleeve 10, the outwardly facing surfaces of which are formed by helical wedge surfaces 13. The clamping wedge surfaces 30 are otherwise similar in shape, but are mirror images of the longitudinal axis L of the body 1. An example of the structure of the clamping wedge surfaces is disclosed in the applicant's patent publication FI 113252 in connection with the counter wedge surfaces of the fixing lugs formed in the joint sleeve. There is no need to introduce the structure further here. A longitudinal slit 14 is formed in the clamping sleeve 10 between the clamping lugs 12 and extending 4 in the longitudinal direction through the entire sleeve 10. Preferably, the width of the slit is substantially the same as the distance between the lugs and each other. The width of the slit may, of course, differ from this.

The sleeve joint also includes a separate securing lever 20 having a first end formed by two arms 22. At the ends of the arms 22 there are clamping rings whose main tongues form opposing clamping wedges 23. The clamping wedges 23 are substantially similar in shape to the wedge surfaces 13. The clamping lever 20 is preferably made of a wear-resistant material such as metal, for example aluminum.

Attachment of the clamping lever 20 to the clamping sleeve 10 is effected by being pushed onto the clamping lugs 12 of the sleeve 10 such that the clamping wedge faces 23 of the lever 20 rotate about the x-axis against the wedge surfaces 13. Advantageously, the clamping lever 20 is secured in position 15 by pulling the arms 22 apart and pushing the clamping lugs against each other. In this case, they can be easily positioned in the correct position relative to the x axis. When the thrust is released, the pressed wedge faces and the clamping wedge faces are released against each other.

The attachment of the draw bar 26 may be formed as illustrated in FI 113252. An opening 27 through the clamping ring is formed in the center of the first clamping wedge surface 23, and an opening (not shown) is formed in the middle of the second clamping wedge surface 23 (not shown) with threads formed on the inner surface of the opening. Alternatively, the threads formed in the clamping ring may be replaced by a 25-clamped nut.

When the clamping lever 20 is mounted on the clamping sleeve 10, the openings 27 of the clamping lever 20 (as well as the screw threaded opening not shown) and the openings 15 of the clamping lugs are aligned. Thus, the screw-threaded drawbar 26 may be positioned 30 by inserting the drawbar 26 through the opening 27 and the apertures 15 of the retaining lugs and tightening it in place to the second inner thread of the clamping ring. The longitudinal axis of the drawbar 26 (axis of rotation of the clamping lever) is transverse to the longitudinal axis of the body 1. What happens between the wedge surfaces 13 and the clamping wedge surfaces 23 when the clamping lever 20 is rotated is described in more detail in Applicant's Patent Publication FI 133252.

The rotational movement of the clamping wedge surfaces 23 of the clamping lever 20 (between the locked and the unlocked position 5) is accomplished by means of a pivotable lever portion 21 or a torque arm extending from the arms 22 of the clamping lever 20. Once the clamping sleeve 10 is inserted around the protrusions 3, the clamping lever 20 can be turned to the closed position (see Fig. 2). Here, a tensile force 26 is applied to the clamping lugs 12 of the clamping sleeve 10 (x-axis force), thereby reducing the width of the slit and thus the diameter of the Kiris-10 socket 10. In this case, the radially extending outer projections 3 are pressed radially towards the central axis of the body part 1 as the inner surface of the clamping sleeve 10 is pressed against the outer surface of the projections 3. In turn, the inner surfaces of the protrusions 3 are pressed through the clamping sleeve 10 and the sleeve-like body part 1 against the outer surface 15 of the smaller tube 31 introduced in part into the larger tube 30.

In particular, Fig. 2 shows that the lever end 21 of the fastening lever 20 remains longitudinally inside the end of the frame part 1 in the longitudinal direction of the body part 1.

To this end, preferably, the body portion 1 is joined to a region of said end by a protrusion 5, 20 which is an extension of the end of the clamping lever 20 in the closed position of the clamping lever 20. The purpose of this is to prevent the penetration of various particles through the end of the clamping lever 20 between the clamping lever 20 and the body part 1 and even to prevent the joint from being opened unintentionally.

25 For opening or facilitating the joint, the edges of the clamping lever 20 have gripping shapes 25. Shaping may be, for example, an edge protrusion as shown in the figures. Further, in the longitudinal direction of the body part, the recess 6 is preferably formed in the base part 2 of the body part 2 with the gripping design 25, but in addition, the recess 6 also forms an advantageous gripping point 30 for opening the joint.

According to a preferred embodiment of the invention, there is provided a non-rotational locking between the clamping sleeve 10 and the frame member 1 which allows the clamping sleeve 10 to be attached to the frame member 1 in only one mutual angle of rotation. For this purpose, a clamping sleeve 10 is formed in the longitudinal direction 6 of the sleeve 10 in the longitudinal direction 15. The protrusion 15 may be inserted into a counter-mold formed in the body, preferably a notch (not shown). This prevents the sleeve 10 from rotating about its longitudinal axis.

The present invention is not limited to the embodiments shown. The invention can be practiced in many ways within the scope of the claims.

Claims (6)

A sleeve connection between a telescopically adjustable arm outer tube (30) and an inner tube (31) having a sleeve-like body portion 5 (1) secured to an end of the outer tube (30) having an opening near the opening edge of the body portion (1). arranged opposite fastening lugs (12) having helical wedge surfaces (13), a latching lever (20) associated with the latching lugs (12) pivotable about the transverse wedge surfaces (13) and facing the pivot axis (x) at the end are formed branches (22) having at their ends tensioning wedge surfaces (23) matched to the wedge surfaces (13) of the fastening lugs (12), 23) upon rotation of the clamping lever (20) to receive substantially the tensioning wedge faces (23) clamping forces in the direction of the axial axis (x), characterized in that elastic protrusions (3) formed as an axial extension of the frame (1) are formed in the body (1) near the opening edge, and that the lugs (12) are arranged in the clamping sleeve (10). , which is removably secured around the flexible protrusions (3), whereby the protrusions (3) are pressed around the inner tube (31) when turning the clamping lever (20). 20 Sleeve joint according to Claim 1, characterized in that the body (1) is joined by a protrusion (5) which extends the end of the clamping lever (20) in the closed position of the clamping lever (20). Sleeve joint according to Claim 1 or 2, characterized in that the clamping lever (20) has gripping shapes (25) at the edges. Sleeve joint according to one of the preceding claims 1 to 3, characterized in that there is an anti-rotation molding (15) between the clamping sleeve (10) and the frame part (1), which allows the clamping sleeve (10) to be attached to the frame part (10). 1) only in one mutual rotation stroke in I ma position. Sleeve joint according to one of the preceding claims 1 to 3, characterized in that there are at least two protrusions (3). 35 5 Sleeve joint according to one of the preceding claims 1 to 4, characterized in that the material of the flexible projections (3) is more flexible and / or softer than the material of the clamping sleeve (10).