NL1017876C2 - Guide member for receiving between two leg parts of a telescopic leg. - Google Patents

Description

Gel egg member for receiving between two leg parts of a telescopic leg.

DESCRIPTION

The invention relates to a guide member for receiving between two leg parts that can be displaced relative to each other in a shifting direction of a telescopic leg for a piece of furniture or the like, which guide member comprises fixing means for fixing the guide member to one of the two leg parts and a guide part for conducting cooperation with a counter-guide part of the other of the two leg parts, wherein expansion means are provided for expanding the guide part against the counter-guide part, as well as fixing means for fixing a expanded state of the guide member.

Such a guide member is known from the

German utility model DE 298 12 762 UI. A telescopic lifting arm is described herein with a number of sliding shoes between the telescopic parts. Each sliding shoe comprises two shoe parts which are movable relative to each other in the horizontal direction, transversely to the longitudinal direction of the telescopic lifting arm. For this purpose two wedge-shaped parts are provided between the movable shoe parts, which wedge-shaped parts can be moved towards each other or away from each other by means of a set of screws, under the influence of which the shoe parts move relative to each other until suitable abutment within a vertical guide slot of one of the telescopic parts is the case. Adjusting the width of such a guide member is time-consuming. In addition, there is a risk that the settings of the different guide members on the circumference of the telescopic parts are uneven, as a result of which an uneven guide and load can arise. The invention has for its object to provide a guide member which is in particular suitable for use in a telescopic leg for a piece of furniture or the like, wherein the drawbacks associated with the above-described adjustable sliding shoes according to the prior art are not applicable. to be. To this end, the guide member according to the invention is characterized in that the expansion means are active as a result of the leg parts shifting relative to each other. With such an activity, the adjustment of guide members can, as it were, occur autonomously upon assembly of the telescopic leg parts. There is no need for separate manual, time-consuming adjustment of the guide members.

According to a very advantageous preferred embodiment, the guide member comprises two guide elements which are displaceable relative to each other in the shifting direction for achieving the fixed expanded state. The two guide elements which are slidable relative to each other allow a relatively simple construction.

A very compact guide member constructed from a limited number of parts is obtained if the guide part is arranged on at least one of the guide elements.

For further shortening the mounting time of a telescopic leg, the fixation means are preferably effective as a result of the leg parts shifting relative to each other.

A compact and constructive simple preferred embodiment is obtained if the expansion means comprise a first wedge surface on a guide element along which a counter-guide part of the other guide element can guide.

The counter-guiding part is preferably formed by a second wedge surface that is slidable along the first wedge surface, so that an optimum transmission of force and movement can be achieved.

The fixation means preferably comprise engaging sliding teeth. Such teeth can make movement in one direction possible, while movement in the opposite direction is impossible. As a result, as soon as the desired expanded state is reached, this situation can be fixed.

For making the adjustment of the guide members even more autonomous, each guide member is preferably provided with engaging means for activating the expansion of the guide member.

The engaging means are preferably intended for engagement by a leg part, so that separate adjustment of the guide members is not necessary, and simultaneous sliding of the leg parts during assembly can take place.

To this end, the engaging means may preferably comprise a breaking element that is breakable as a result of the movement of the leg parts relative to each other. The breaking force associated with the breaking element determines the effective setting of the guide member.

The same can be achieved if, according to an alternative preferred embodiment, the engaging means are foldable, for example from the path of a leg part that engages the engaging means.

The invention further relates to a telescopic leg provided with at least two leg parts that can be displaced relative to each other in a shifting direction, wherein at least one guide member according to the invention described above is provided between the leg parts.

In addition, the invention relates to a piece of furniture provided with such telescopic legs.

The advantages associated with such a telescopic leg and furniture piece have already been further elucidated on the basis of the description of the guide member according to the invention together with the preferred embodiments.

The invention will be further elucidated with reference to 1817876 4 of the description of two preferred embodiments of guide members according to the invention. For the purpose of illustration, reference will be made to the following figures.

Figure 1 shows a perspective view of a first preferred embodiment of a guide member according to the invention during assembly of a telescopic leg; Figure 2 shows in front view the fixed guide element of the guide member according to Figure 1; Figure 3 shows in front view the slidable guide element of the guide member according to Figure 1; Fig. 4 shows in perspective front view the guide member according to Fig. 1; Figure 5 shows a perspective rear view of the guide member according to Figure 1; Figure 6 shows a perspective view of a second preferred embodiment of a guide member according to the invention during assembly of a telescopic leg; Figure 7 is a perspective rear view of the fixed guide element of the guide member according to Figure 6; Figure 8 shows in side view the fixed guide element according to figure 6; Figure 9 shows a perspective front view of the sliding guide element of the guide member according to Figure 6; Figure 10 shows in perspective rear view the guide member according to figure 6; Figure 11 shows the guide member according to Figure 10 in the open position.

Figure 1 shows a telescopic leg 1 during assembly. The telescopic leg 1 has a lower leg part 2, within which an upper leg part 3 can be slid. The leg parts 2 1 0 1 7 8 7 6 5 and 3 are extruded aluminum profiles with a substantially rectangular cross section. Slots 4 extending in the longitudinal direction are provided on the outer sides of the upper leg part 3. Two guide members 5 are included in each longitudinal slot 4. The guide members 5 will be further elucidated with reference to Figures 2 to 5. Guide members 5 are intended for cooperation with ridges 6, which extend centrally on the inner sides of the lower leg part 2 in the longitudinal direction thereof. In the state shown in Figure 1, the underside of the upper leg part 3 is at the same vertical level as the top of the lower leg part 2.

Guide member 5 consists of a fixed guide element 7 (Figure 2) and a slidable guide element 8 (Figure 3). Both guide elements 7 and 8 are plastic-sprayed products. The fixed guide element 7 is provided at its rear with two connecting elements 9 and 10 (Figure 5). Each connecting element 9, 10 is formed by two opposite semicircular stubs 11, 12 and 13, 14 with two elastic latching hooks 15, 16 and 17, 18 respectively. Each connecting element 9, 10 has an outer circumference in the form of a stretched circle. This shape corresponds to the shape of holes in the inner wall of longitudinal slots 4, as a result of which the connecting elements 9, 10 can be received in these holes, whereby the fixed guide element 7 is fixedly connected to it because of the effectiveness of latching hooks 15 to 18. upper leg part 3.

Connecting elements 9 and 10 form the connection between longitudinally extending guide parts 29, 30, whereby the fixed guide element 7 has a substantially U-shaped cross-section in top or bottom view, the legs being formed by guide parts 29 and 30. The space between the guide parts 29 and 30 is intended for receiving grooves 6 of the lower leg part 2. The sides of guide parts 29 and 30 which face towards each other form sliding surfaces 31, 32. For this purpose sliding surfaces 31, 32. On the outer sides of the The fixed guide element 7 is provided with conically tapered guide surfaces 19, 20 with guides 21, 22. These guide surfaces 19, 20 extend over the entire length of the fixed guide element 7. In the middle of the guide surfaces 19, 20, upwardly oriented teeth 23, 24 are arranged between front retaining surfaces 25, 26 and rear retaining surfaces 27, 28.

The slidable guide element 8 consists of two expansion parts 33, 34 which are connected at the top by a U-shaped break cord 35. The expansion parts 33 and 34 are provided with upper guide blocks 36, 37 on their upper sides and lower guide blocks on their lower sides 38, 39. On the opposite sides of the upper guide blocks 36 and 37, these are provided with grooves 40, 41. The bottoms of these grooves form the ends of guide surfaces 42, 43. These guide surfaces 42, 43 are tapered towards each other downwards over the entire length of expansion parts 33, 34 and are intended for conductive cooperation with tapered guide surfaces 19, 20 of the fixed guide element 7. In the middle 20 of the guide surfaces 42, 43 are inwardly directed sliding teeth 44, 45 applied. These sliding teeth 44, 45 are intended for cooperation with teeth 23, 24, whereby due to the downward direction of teeth 44, 45 and the upward direction of teeth 23, 24 shifting of the slidable guide element 8 in the direction according to arrow 46 does occur. is possible, but a return shift is not. On their outer sides, the upper guide blocks 36, 37 and the lower guide blocks 38, 39 are provided with abutment surfaces 47, 48 and 49, 50 respectively, which surfaces are parallel to the longitudinal direction of the slidable guide element 8. The abutment surfaces 47, 48, 49 50 are intended for abutment against the edges of longitudinal slot 4.

1017876 7

The operation of the guide member 5 during assembly of the telescopic leg is as follows. From the condition as shown in Figure 1, the inner leg part 3 is slid into the lower leg part 2, grooves 6 being received in the space 5 between sliding surfaces 31 and 32 of the fixed guide element 7. Continuation of this downward movement will occur at a given moment cause the upper edge of groove 6 to prevent continuation of the downward movement of the slidable guide element 8 because the upper side of groove 6 comes to abut against the inside of the U-10-shaped shear cord 35. Further continuation of the downward movement of the upper leg part 3 will cause the fixed guide element 7 together with leg part 3 to move downwards, while the slidable guide element 8 remains spatially in the same position. This has the consequence that on the one hand the abutment surfaces 47, 48, 49 and 50 will slide along the edges of longitudinal slots 4, and on the other hand the guide surfaces 19 and 20 of the fixed guide element 7 will slide along the guide surfaces 42 and 43 of the slidable guide element 8. Because of the conical orientation of the said guide surfaces, during this relative movement of the slidable guide element 8 relative to the fixed guide element 7, on the one hand the guide parts 29 and 30 will be moved towards each other, whereby the sliding surfaces 31 and 32 with an increased contact pressure grooves 6 come to abut, while on the other hand the upper guide blocks 36 and 37 and the lower guide blocks 38 and 39 will move outwards, as a result of which the contact surfaces 47, 48, 49 and 50 contact the edges of longitudinal slots 4 with an increased contact pressure to lay down. At the same time, the teeth 44, 45 of the sliding guide element 8 will slide down along the teeth 23, 24 of the fixed guide element 7. To this end, the middle regions 51, 52 of expansion parts 33, 34 are relatively thinly shaped, so that elastic deformations of expansion parts 33 , 34 at the location of teeth 44, 45 1017 ?? 8 are possible. As the relative displacement between the fixed guide element 7 and the slidable guide element 8 increases, the frictional force that acts between the slidable guide element 8 and the edges of grooves 4 on the one hand and between the slidable guide element 8 and the fixed guide element will also increase due to the increased contact pressure. 7 on the other hand. This will result in the break cord 35 breaking at a given moment when the breaking stress is reached, as a result of which groove 6 can slide further without interference between the sliding surfaces 31 and 32. There will be no further relative displacement between the fixed guide element 7 and the slidable guide element. 8 more, also in view of the locking cooperation between the teeth 44, 45 and 23, 24. An optimum functionality of guide member 5 within telescopic leg 1 can now be obtained by adapting the breaking tension of break cord 35 to this optimum situation. A separate manual adjustment or determination of the adjustable sliding member 5 is superfluous, which can considerably speed up the assembly of the telescopic leg 1 compared to the prior art.

Figure 6 shows a telescopic leg 101 with lower leg part 102 and upper leg part 103. The two leg parts 102 and 103 are extruded aluminum profiles with a square cross section. In the middle of the sides of the upper leg part 103, on the outside, two guide members 104 according to a second preferred embodiment are arranged above each other on the outside. It is already noted that instead of one guide member 104 it is also possible to place two guide members 104 next to each other near the edges between the sides of the upper leg part 103, whereby an increased torsional and bending stiffness is obtained.

Guide members 104 consist of a fixed guide element 105 (Figures 7 and 8) and a slidable guide element 106 (Figure 9). The fixed guide element 105 is connected to the upper leg part 103 by means of connecting 1017876> 9 elements 107, 108 with elastically movable half disks 109, 110 and 111, 112 respectively. For this purpose leg part 103 is provided with holes whose shape corresponds to that of the connecting elements 107, 108. On the front side the fixed guide element 105 is provided with a sliding surface 113 for sliding cooperation with the inside of the side of the lower leg part 102 opposite the guide member 104. At the rear side of the fixed guide element 105 a gel surface plane 114 which tapers downwardly to sliding surface 113. Upwardly oriented teeth 115, 116 are arranged on either side of the fixed guide element 105. Near teeth 115, 116, slotted holes 117, 118 are provided in the fixed guide element 105 which allow the teeth 115 and 116 to deviate laterally inwards.

The slidable guide element 106 (Fig. 9) has a substantially U-shape in bottom view. On the legs of the U-shape are toothed teeth 119, 120 directed downwards on the inside over the entire length of the slidable guide element 106. In the body of the U-shape there is a longitudinally extending central slot hole 121 through which the connecting elements 107 and 108 extend in assembled condition. The rear side 122 abuts the associated outside of the upper leg part 103. The inside side 123 of the body tapers slightly upwards towards the rear side 122 with the same taperedness as that of guide surface 114 of the fixed guide element 105.

At the top of the slidable guide element 106 a stop element 123 is provided which, prior to assembly of telescopic leg 101, extends horizontally above the sides of the lower leg part 102. The stop element is connected to the rest of the slidable guide element 106 by means of a bending hinge 124 .

On the inside of the stop element 123, teeth 125, 126 1017876 10 are provided which engage in the teeth 120, 119 in a closed state according to Figure 9.

The operation of the guide member 104 during assembly is as follows. Starting from the situation in figure 6 in which the upper leg part 103 is partly slid into the lower leg part 102, this downward shift is continued until the upper edge of the sides of the lower leg part 102 comes into contact with stop element 123 of the slidable guide element 106. A continuing downward movement of the upper leg part 103 causes the slidable guide element 106 to slide upwards relative to the fixed guide element 105 between the fixed guide element 105 and the respective outside of the upper leg part 103. Due to the tapered orientation of the cooperating guide surfaces 114 and 123, this relative shift will cause the fixed guide element 105 to be pushed outwards against an inner side of the lower leg part 102. At the same time, the teeth 115, 116 and 119, 120 will slide past each other. By expanding the fixed guide element 105 outwardly, on the one hand an increased contact pressure between sliding surface 113 and an inner side of the lower leg part 102 will be obtained, while on the other hand there will also be an increased contact pressure between guide surfaces 114 and 123. This brings additional frictional forces with join in. As the relative shift progresses between the fixed guide element 105 and the slidable guide element 106, the load on the connection between teeth 125, 126 on the one hand and teeth 119, 120 on the other hand will increase and upon passing a limit load these connections will break as the stop element 123 folds open about bending hinge 124 to a vertical orientation. This situation is shown in Figure 11. Once the stop element 123 has been opened, further sliding of the upper leg part 103 into the lower leg part 102 will not result in a further relative shift between the two guide elements 105 and 106 to 1017876 # 11. Due to the shape of the teeth 119, 120 of the slidable guide element 106 and teeth 115 of the fixed guide element 105, the mutual position of the fixed guide element 105 and the slidable guide element 106 will not change during the telescopic adjustment of leg 101 in use thereof.

1017876

Claims (13)

1. Guide member for receiving between two leg parts that can be displaced relative to each other in a shifting direction of a telescopic leg for a piece of furniture or the like, which guide member comprises fixing means for attaching the guide member to one of the two leg parts as well as a guide part for conducting cooperation with a counter-guiding part of the other of the two leg parts, wherein expanding means are provided for expanding the guiding part against the counter-guiding part, and fixing means for fixing an expanded state of the guiding member, characterized in that the expanding means are operative as a result of shifting the leg parts relative to each other. 2. A guide member according to claim 1, characterized in that the guide member comprises two guide elements displaceable relative to each other in the shifting direction for achieving the fixed expanded state. 3. Guide element according to claim 2, characterized in that the guide part is arranged on at least one of the guide elements. 4. Guide member as claimed in claim 1, 2 or 3, characterized in that the fixing means are operative as a result of the leg parts shifting relative to each other. 5. Guiding member according to claim 2, 3 or 4, characterized in that the expansion means comprise a first wedge surface on a guide element along which a counter-guide part of the other guide element can guide. 6. Guiding member according to claim 5, characterized in that the counter-guiding part is formed by a second wedge surface that is slidable along the first wedge surface. 7. Guiding element as claimed in any of the foregoing claims, characterized in that the fixation means comprise engaging sliding teeth. 8. Guiding element according to one of the preceding claims, characterized in that the guiding element is provided with engaging means for activating the expansion of the guiding element. 9. Guiding member as claimed in claim 8, characterized in that the engaging means are intended for engaging by a leg part. 10. Guiding member according to claim 8 or 9, characterized in that the engaging means comprise a breaking element that is breakable as a result of the movement of the leg parts relative to each other. A guide member according to claim 8 or 9, characterized in that the engaging means are foldable. 12. Telescopic leg provided with at least two leg parts that can be displaced relative to each other in a shifting direction, characterized in that at least one guide member according to one of the preceding claims is included between the leg parts. 13. Piece of furniture, characterized in that the piece of furniture is provided with telescopic legs according to claim 10. 1017876