DE102012023401A1 - Telescopic part arrangement, for example table leg - Google Patents

Abstract

In the case of a telescopic part arrangement of elongated shape, for example a table leg, with a guide profile (14) and a telescopic profile (19) which is adjustable in the longitudinal direction in the guide profile (14) and which extends out of the guide profile (14) in the direction of extension and into the guide profile in the direction of entry (14) can be moved into it, and with locking means with which the telescopic profile (19) can be locked in position after taking a desired relative position with respect to the guide profile (14), an energy storage device (27) with at least one is in the parts arrangement (11) Integrated energy storage (28), which can be charged with the kinetic energy generated when the telescopic profile (19) is retracted, which energy can be used to generate a subsequent extension movement.

Description

The invention relates to a telescopic part arrangement of elongated shape, for example table leg, with a guide profile and a longitudinally adjustable mounted on the guide profile telescopic profile, which is out in the extension of the guide profile and retractable in the guide profile, and with locking means with which the telescopic profile can be locked in position after taking a desired relative position with respect to the guide profile.

Telescopic parts arrangements of this type can be used in many fields, especially in furniture, when an adjustment of the respective piece of furniture in height is desired.

Height-adjustable furniture parts, especially tables, are increasingly in demand and used, as society is changing to a more sedentary and less mobile community. In particular, the number of office workplaces with seated work on a worktable has increased significantly over the years. The long-sitting activity is known to cause many problems, for example, here are the increase in back problems.

It has long been known to use height-adjustable furniture parts, especially tables, the table top can be adjusted so that the user can switch between sitting and standing activity.

For height-adjustable tables, it is known to accommodate a torsion spring in a arranged between two legs table synchronous rod, which ensures the synchronization in the movement of the movement profiles, which is tensioned during the retraction movement and then provides the stored spring energy when extending available.

However, such tables have a limited field of application, as always a synchronous rod between two legs must be used, in which then an expensive and heavy torsion spring is to be accommodated. Overall, such tables are very bulky and have a significant weight.

The object of the invention is therefore to provide a telescopic part assembly of the type mentioned, which allows for use in a table, a tool or the like a cost-effective, compact and easy to handle height adjustment.

This object is achieved by a telescopic part arrangement with the features of independent claim 1. Further developments of the invention are shown in the subclaims.

The telescopic part arrangement according to the invention is characterized in that in the parts arrangement, an energy storage device is integrated with at least one energy storage, which can be charged by the kinetic energy generated during retraction of the telescopic profile with energy that can be used for the generation of a subsequent extension movement.

The energy storage device is thus integrated into the parts arrangement, whereby a particularly compact design can be achieved. If the telescopic part assembly used for example for a table, so the telescopic part assembly is thus designed as a table leg, offers in comparison to the aforementioned prior art with the clamped between two legs table torsion a broader scope. Here you can also adjust the height of tables or desks with only one table leg. The energy saving device is thus accommodated compactly within the parts arrangement, whereby weight and volume can be saved. Due to the compact design of the telescopic part assembly with energy storage device, for example, transport costs can be saved, which have a significant impact on the price with such telescopic parts arrangements equipped furniture parts, equipment, etc.

By the energy storage device with at least one energy storage, which provides the energy stored during retraction energy when extending again, it is possible that the telescope part with the coupled component, such as a tabletop, automatically or almost automatically with low support of the user extends. In this case, the storage capacity of the energy store can be individually adapted to the coupled to the telescope profile component, for example, to the weight of a table top. Furthermore, expected loads of such a table top can also be taken into account, so that even a relatively heavily loaded table top can be automatically or almost automatically adjusted to a higher position. Such a weight adjustment is useful, for example, in children's desks, so that the height adjustment can also be performed by the child himself and even with a loaded desk in a simple manner.

The locks ensure that the telescopic profile can be locked at the desired height. The telescopic profile is expediently guided on the base profile in such a way that it can be adjusted steplessly or with a slender grid leaves and therefore can be locked in the desired altitude. This, in turn, makes sense in children's / student's desks, as children are still in a growth phase and consequently, optimal seating and standing positions change.

In a development of the invention, the energy store is a mechanical energy store.

In a particularly preferred manner, the mechanical energy storage at least one spring element, whereby the kinetic energy can be stored in the form of spring energy. The mechanical energy storage could therefore also be referred to as spring storage. As spring element, all known types of springs can be used, but the use of a coil spring is preferred.

Alternatively or additionally, it is possible for the energy store to be a non-mechanical energy store, for example a fluidic or electrical energy store. In the case of an electrical energy storage, it would be conceivable that a battery is charged by means of the kinetic energy generated when retracting the telescopic profile, the stored electrical energy is then provided to an electric motor, which takes over or supports the extension movement of the telescopic profile.

In a development of the invention, the energy storage device has motion conversion means for implementing the movement of the linear retraction movement of the telescopic profile into a movement for charging the energy store. In the case of a mechanical energy storage with spring element, the linear retraction of the telescopic profile can thus be converted into a movement for tensioning the spring element. In the case of a spiral spring, the movement for tensioning the spring element may, for example, be a rotational movement over which the spiral spring can be tensioned.

In a particularly preferred manner, the movement conversion means comprise a transfer gear, with gear parts, of which at least one of the base profile and at least one of the telescopic profile is assigned. The base profile side gear parts can thus be fixedly secured to the base profile, while the telescopic profile side gear parts with the movement of the telescopic profile are movable.

The transfer gear is particularly preferably a gear transmission, wherein preferably one of the gear parts is designed as a pinion and one of the gear parts as a rack interacting with the pinion. However, it is also possible to use other types of transfer gears, such as belt transmissions or the like.

It is possible that the pinion on the telescopic profile and the rack are arranged on the guide profile.

In a particularly preferred manner, the pinion is rotatably mounted by means of bearing means on the telescopic profile and is in the linear movement of the telescopic part on the engagement in the rack in rotation or rotational movement displaceable. In the case of a spring element designed as a spiral spring, it is thus possible that it is tensioned due to the rotational movement generated by the rack / pinion combination during retraction of the telescopic tube.

It is possible that the bearing means a pinion shaft which is rotatably connected to the pinion detachably connectable and a non-rotatably mounted on the telescopic profile bearing sleeve in which the pinion shaft is rotatably mounted, have. The pinion shaft is therefore rotatable with the pinion, while the bearing sleeve is fixed non-rotatably on the telescopic profile. It is possible that the pinion shaft is inserted through the bearing sleeve and in the transverse direction through the telescopic profile.

In a further development of the invention, the telescopic profile is designed as a hollow profile with a hollow chamber. Conveniently, this is a profile of metal material, for example light metal material, in particular aluminum. The telescopic profile may be formed, for example, as an extruded aluminum profile. The combination of hollow section and light metal gives a particularly low weight of the telescopic profile. A low weight of the telescopic profile is important because in the design of the energy storage, the weight of the telescopic profile must also be taken into account.

It is possible that the base profile is designed as a TI profile. In this case, the telescopic profile is thus displaceably mounted in the U-profile-like base profile.

In order to ensure smooth insertion and removal of the telescopic profile from the base profile, it is expedient to use guide means which act between the telescopic profile and the base profile. For this purpose, for example, rolling elements, in particular guide rollers which are rotatably mounted in particular on the telescopic profile and roll on a guide rail formed on the base profile during the movement of the telescopic profile.

In a further development of the invention, the energy storage is arranged in the hollow chamber of the hollow profile, wherein preferably the Energy storage, in particular the spring element, is accommodated in a particular can-like storage housing, which is arranged in the hollow chamber of the hollow profile.

The storage housing is suitably rotatably connected to the pinion and is rotated during the rotation of the pinion with.

In the case of a spring element in the form of a spiral spring, it is therefore possible to store these on the one hand on the rotatable storage housing and on the other hand on the non-rotatable bearing sleeve to clamp this by means of the rotational movement of the storage housing generated via the retraction movement of the telescopic profile.

In a development of the invention, the rack is detachably fastened or secured in a receiving groove extending in the longitudinal direction of the base profile, wherein preferably the rack is fastened in different mounting positions within the receiving groove, so that it protrudes more or less far out of the receiving groove and thereby with pinions can be combined with different diameters. The combination of pinion size and position of the rack in the receiving groove and the associated spring element, the storage capacity of the energy storage device to different weights of the telescopic profile to be coupled component, such as table top, adjustable. In the case of a trained as a spiral spring energy storage, the storage capacity or the maximum storable spring energy can also be adjusted by the width, height and / or length of the coil spring forming the spring band and / or by the strength of the spring band. When using round spring wire, the storage capacity can be adjusted by varying the wire diameter and the length of the round spring wire Furthermore, the spring band by appropriate choice of the pinion coil material of the coil spring also different compact wrap, which then different spring energy can be stored.

The invention further comprises a table, in particular a desk, with a height-adjustable table top and at least one table leg connected to the table leg, which is characterized in that the table leg is formed as a telescopic part arrangement according to one of claims 1 to 15.

A preferred embodiment of the invention is illustrated in the drawing and will be explained in more detail below. In the drawing show:

1 A preferred embodiment of the part assembly according to the invention when used as a table leg of a table, wherein the table top is shown in different height positions,

2 a longitudinal section through the part arrangement according to the invention of 1 in the field of energy storage device and

3 a cross section through the parts arrangement of 1 in the field of energy storage device.

The 1 to 3 show a preferred embodiment of the invention telescopic part assembly 11 , here exemplified trained as a table leg as part of a height-adjustable table 12 is shown.

As in particular in 1 shown, the table owns 12 a height-adjustable table top 13 made of wood or metal material, which is supported on two table legs and is supported by them.

Both table legs are as a telescopic part arrangement 11 educated.

As in particular in the 2 and 3 shown comprises the parts arrangement 11 a leadership profile 14 , which is U-shaped and in the present case one of the feet of the table 11 forms. The leadership profile 14 has in the example a side wall 15 and two from the side wall approximately at right angles projecting leg 16a . 16b , The insides of the thighs 16a . 16b run in the longitudinal direction 17 of the guide profile parallel to each other. The leadership profile 14 consists of metal material, in particular aluminum. Conveniently, it is designed as an aluminum extruded profile. The side wall 15 and the two thighs 16a . 16b define a receiving space open to the inside 18 in which a telescope profile 19 is received and there by means of guidance in the longitudinal direction 17 of the guide profile is guided. The telescope profile 19 is in the leadership profile 14 adjustable.

An identical embodiment of the telescopic part assembly is also found on the other table leg. To the two telescope profiles 19 is the tabletop 13 attached, which thus when retracting or extending the telescopic profiles 19 is height adjustable.

The telescope profiles 19 , of which only one example will be described below, is designed as a hollow profile and has a hollow chamber 20 , As profile material for the telescope profile 19 is also metal, especially aluminum used. Conveniently, the telescopic profile 19 also designed as an aluminum extruded profile.

The telescope profile 19 can be locked by means of locking means (not shown) at any height along its extension path, whereby the tabletop 13 can be adjusted continuously to the desired height.

As in particular in 3 are shown, guide means for guiding the telescopic profile 19 on the guide profile 14 used. As a guide, leadership roles 21 used, by means of bearing means rotatable on the telescopic profile 19 are stored. The bearing means include a bearing axle 22 on the one hand on a front wall 23 and on the other hand on a back wall 24 of the telescope profile 19 is rotatably mounted. The leadership 21 is designed for example as a rolling bearing and rotatable on the bearing axis 22 stored.

As in particular in 3 shown are located on both opposite side walls 25a . 25b of the telescope profile 19 guide rollers 21 , In particular, each leg are 16a . 16b of the leadership profile 14 at least two guide rollers 21 assigned, so that a synchronization is guaranteed. The leadership roles 21 each protrude over a slot through the associated side wall 25a . 25b through and dive into one in each leg 16a . 16b of the leadership profile 14 longitudinal guide track 26a . 26b and are led there. The leadership roles 21 Furthermore, sit relatively close to the side wall 15 of the leadership profile 14 , which also leads to an exact run of the telescope profile 19 within the leadership profile 14 leads.

In the table leg, so in the telescopic part arrangement 11 , is an energy storage device 27 integrated, the at least one energy storage 28 which, by the retraction of the telescopic profile 19 generated kinetic energy can be charged with energy, which is usable for the generation of a subsequent extension movement.

In the example, a mechanical energy storage 28 provided in the form of a spring element. The spring element is configured in the example as a spiral spring, which is a spirally extending spring band 29 having. The parts layout 11 or the table leg also has movement-Umsetzmittel 30 for the motion conversion of the linear retraction movement of the telescopic profile 19 in a movement to charge the coil spring. The motion conversion means 30 comprise a transfer gear in the form of a gear transmission 31 , The gear transmission 31 has a pinion 32 in the manner described in more detail below rotatable on the telescopic profile 19 is stored and one with the pinion 32 interacting rack 33 ,

As in particular in 3 shown is the rack 33 in a longitudinal direction of the guide profile 14 extending receiving groove 34 added. The rack 33 possesses, as the name already suggests, on its active side a multiplicity of teeth arranged longitudinally behind one another ( 2 ). Furthermore, the rack has 33 at its two opposite, substantially perpendicular projecting from the active side long sides 35a . 35b gearing 36 , which with at the corresponding inner walls of the receiving groove 34 trained counter-teeth 37 interact. Due to the interacting teeth is the rack 33 secured in groove depth direction. Furthermore, this embodiment allows the insertion of the rack 33 in different positions, so that the action side more or less far from the receiving groove 34 protrudes. This makes it possible for the rack 33 can be combined with pinions of different diameters.

As already mentioned, the pinion is 32 By means of bearing means rotatable on the telescopic profile 19 stored. The bearing means includes a pinion shaft 38 , which rotatably with the pinion 32 is connected, wherein the pinion 32 on the pinion shaft 38 attached and releasably secured there, so it optionally against a pinion 32 smaller or larger diameter can be replaced. The pinion shaft 38 in turn is in the transverse direction through the telescopic profile 19 inserted through, with this on both the front wall 23 as well as on the back wall 24 Through openings are formed.

The bearing means also includes a bearing sleeve 39 that are inside the hollow chamber 20 of the telescope profile 19 is arranged and through which the pinion shaft 38 also sticks out. The bearing sleeve 39 is by means of fasteners on the front wall 23 of the telescope profile 19 attached. The bearing sleeve 39 is thus fixed against rotation.

As in particular in 3 Shown is the coil spring in the hollow chamber 20 of the telescope profile 19 arranged and that is in a can-like storage enclosure 40 accommodated. The storage enclosure 40 has a housing cover 41 , which rotates with the pinion 32 connected is. To this end, for example, driving pins protrude 42 in this provided holes on the housing cover 41 into it. The housing cover 41 closes a housing base part 43 , which in turn receives the coil spring. The housing cover 41 is with the housing base part 43 rotatably connected, for example by fixing screws 44 , Both housing cover 41 as well as housing base part 43 be both from the bearing sleeve 39 as well as from the pinion shaft 38 interspersed.

As in particular in 3 represented sitting on the lateral surface of the bearing sleeve 39 an outwardly projecting hanging nose 45 for hanging the spring band end of the spring band 29 the spiral spring. The other end of the spring band 29 is, however, by means of suitable fastening means on the housing base part 43 fixed. The coil spring is thus between the non-rotatable bearing sleeve 39 and the rotatable housing base 43 clamped.

As in particular in 1 shown, the table top can 13 with the help of the telescopic part arrangement 11 be adjusted between different altitudes. Should the table top 13 shifted down, so it is first necessary to release the locking means. The locking means may comprise, for example, a Bowden train, which at the bottom of the table top 13 is arranged and can be conveniently operated by the user. The Bowden train is based on a shortening of a piece of wire, whereby a bolt can be solved, then the retraction or extension of the telescopic profile 19 into or out of the leadership profile 14 allows. The latch may have a rack segment, which by spring force of a pressure spring in the teeth of the rack 33 engages and thus the retraction or extension of the telescopic profile 19 blocked. By operating the Bowden cable, the rack segment becomes out of engagement with the rack against the spring force of the pressure spring 33 moved, causing the retraction and extension of the telescopic profile 19 is possible. When retracting the tabletop is 13 So together with the telescope profile 19 moved down, with the pinion 32 at the rack 33 unrolls and is offset by this in rotation. The rotating pinion 32 thereby also drives the pinion shaft 38 and both the housing cover 41 as well as the thus rotatably connected housing base part 43 rotationally. By this rotational movement of the can-like storage housing 40 the coil spring is wound together, as they at the other end of the non-rotatable bearing sleeve 39 is clamped. This rotational movement of the storage enclosure 40 together with the spiral spring leads to the tensioning of the spiral spring, that is, to store spring energy obtained from the kinetic energy. If the lower position is reached, the locking means are activated again, whereby the table top is fixed in a fixed position in the set lower altitude. The energy storage device 27 can be accommodated in one of the two table legs or in both legs of the table. Between the two telescopic profiles 19 The table legs extend a synchronous rod, which ensures the synchronization during extension and retraction of the telescopic parts.

Should the table top 13 then be adjusted back up, the stored during retraction spring energy is used for the extension. In this case, the locking is first released again, whereby the telescopic profile 19 can be moved with the help of the stored spring energy automatically or with little support of the user in the higher position. The storage capacity of the coil spring can be adjusted to the weight of the table top 13 and on an expected loading of the tabletop 13 be set so that even a loaded table top 13 can be moved smoothly automatically or with little support of the user using the stored spring energy in a higher position.

Claims (16)

Telescopic part arrangement of elongate shape, for example table leg, with a guide profile ( 14 ) and a longitudinally adjustable on the guide profile ( 14 ) mounted telescopic profile ( 19 ), which in the extension direction from the guide profile ( 14 ) in and out in the guide profile ( 14 ) and with locking means, with which the telescope profile ( 19 ) after taking a desired relative position with respect to the guide profile ( 14 ) positionally locked, characterized in that in the parts arrangement ( 11 ) an energy storage device ( 27 ) with at least one energy store ( 28 ), which by the retraction of the telescopic profile ( 19 ) kinetic energy is charged with energy, which is usable for the generation of a subsequent extension movement. Part arrangement according to claim 1, characterized in that it is in the energy storage ( 28 ) to a mechanical energy store ( 28 ). Parts arrangement according to claim 1 or 2, characterized in that the mechanical energy storage has at least one spring element and the kinetic energy can be stored in the form of spring energy, wherein it is preferably in the spring element is a coil spring. Parts arrangement according to one of the preceding claims, characterized in that the energy storage device ( 27 ) Motion conversion means ( 30 ) for the movement conversion of the linear retraction movement of the telescopic profile ( 19 ) in a movement for charging the energy store ( 28 ) having. Parts arrangement according to claim 4, characterized in that the movement conversion means ( 30 ) comprise a transfer gear, with gear parts, of which at least one of the guide profile ( 14 ) and at least one telescope profile ( 19 ) assigned. Parts arrangement according to claim 5, characterized in that it is in the transfer gear to a gear transmission ( 31 ), wherein preferably one of the gear parts as a pinion ( 32 ) and one of the gear parts as with the pinion ( 32 ) cooperating rack ( 33 ) is trained. Parts assembly according to claim 6, characterized in that the pinion ( 32 ) on the telescope profile ( 19 ) and the rack ( 33 ) on the management profile ( 14 ) is arranged. Parts arrangement according to claim 6 or 7, characterized in that the pinion ( 32 ) by means of bearing means rotatable on the telescopic profile ( 19 ) and in the linear movement of the telescopic profile ( 19 ) about the engagement in the rack ( 33 ) is displaceable in rotational movement. Part assembly according to claim 8, characterized in that the bearing means a pinion shaft ( 38 ), which rotatably with the pinion ( 32 ) is detachably connectable and one on the telescopic profile ( 19 ) non-rotatably mounted bearing sleeve ( 39 ), in which the pinion shaft ( 32 ) is rotatably mounted, have. Parts arrangement according to one of the preceding claims, characterized in that the telescopic profile ( 19 ) is designed as a hollow profile with a hollow chamber. Parts arrangement according to one of the preceding claims, characterized in that the guide profile ( 14 ) is designed as a U-profile. Parts arrangement according to claim 10 or 11, characterized in that the energy store ( 28 ) in the hollow chamber ( 20 ) of the telescopic profile ( 19 ), wherein preferably the energy store ( 28 ), in particular the spring element in a particular can-like storage housing ( 40 ) received in the hollow chamber ( 20 ) of the telescopic profile ( 19 ) is arranged. Parts arrangement according to claim 12, characterized in that the storage housing ( 40 ) rotatably with the pinion ( 32 ) and during the rotation of the pinion ( 32 ) is also twisted with. Part arrangement according to claim 12 or 13, characterized in that in the case of a spring element in the form of a spiral spring, these on the one hand on the rotatable storage housing ( 40 ) and on the other hand on the non-rotatable bearing sleeve ( 39 ) is mounted and by means of the retraction of the telescopic profile ( 19 ) generated rotational movement of the storage housing ( 40 ) is tensionable. Parts arrangement according to one of claims 6 to 14, characterized in that the rack ( 33 ) in a longitudinal direction of the guide profile ( 14 ) extending receiving groove ( 34 ) is releasably fastened or fastened, wherein preferably the rack ( 33 ) in different attachment positions within the receiving groove ( 34 ) is fastened so that it more or less far from the receiving groove ( 34 protruding) and thereby with pinions ( 32 ) can interact with different diameters. Table, especially desk, with a height-adjustable table top ( 13 ) and at least one with the tabletop ( 13 ) connected table leg, characterized in that the table leg as a telescopic part assembly ( 11 ) is designed according to one of claims 1 to 15.

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