DE3125230A1 - Device for adjusting the height of a working surface - Google Patents

Abstract

A device for changing the height of a working surface with two essentially rectangular telescopic tubes guided inside one another, has a horizontal support at the upper end of the inner telescopic tube and, on the bottom plate of the outer telescopic tube, a rotary actuator which sets a vertical spindle within the inner telescopic tube in rotation. Engaging in the spindle is a spindle nut which is held in a rotationally fixed manner and is seated on the lower end of a thrust sleeve fixedly connected to the inner telescopic tube. Rotary actuator and spindle are connected to one another by a ratchet drive with torque limitation. The supporting and guiding of the inner telescopic tube in the outer telescopic tube takes place via stabiliser roller arrangements on the inner telescopic tube which are displaceably guided and spring-loaded in obliquely running slots in bearing blocks in such a manner that they brace the inner telescopic tube in a frictional manner with respect to the outer when the rotary actuator is at a standstill. This bracing is released by the adjustment force, transmitted by the rotary actuator to the thrust sleeve, for the adjusting process and automatically comes into effect again at the end of the adjusting process.

Description

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35 125

MAYLINE COMPANY, INC.
Sheboygan, Wis./USA

Device for adjusting the height of a work surface

The invention relates generally to tables and supports and in particular relates to a telescopic column for adjusting the height of a work surface.

Telescopic columns for supporting and adjusting the height of a table are described in US Pat. Nos. 3,707,930 and
3,888,444, for example. Egg; However, there is the possibility with this work surface support that the
Work surface wobbles. The bearing strips can only move in one direction, ie outwards. Also must be
move each bearing strip as a whole in order to limit the lateral movement of the telescopic inner tube towards the outside
Compensate outer tube. In the invention, however, each individual stabilizing role is able to act independently
Adjust distance changes between the telescopic tubes.

Unlike the bearing strips of the known device, the stabilizing rollers in the invention are also able to roll along the inner wall of the outer tube, which facilitates a desired displacement movement while
to overcome the friction between the bearing strips of the

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known device and the outer tube an additional axial force is required. Furthermore, in the known The device has not taken any precautions to reduce resistance to desired vertical movement, which occurs when the bearing strips come into contact with the outer tube. In the invention, however, the stabilizing rollers retract independently if there is an axial force intended to raise or lower the work surface, applied by the motor and the vertically moving ball bearing nut and support sleeve assembly driven by it will.

In addition, the freely rotating ball bearing nut in the invention enables the ball bearing spindle to move as desired can continue to rotate when the inner telescopic tube has reached the highest extended position or the strongest shortened position, so that the motor or the power transmission mechanism cannot be destroyed.

The invention is illustrated below with reference to the drawing of exemplary embodiments explained. Show it:

Fig. 1 is a sectional front view of the device / allows insight into the inner telescopic tube, which is fitted into the outer telescopic tube and a horizontal one at the top Has carrier and inside the height adjustment device and drawn with dashed lines Is equipped with pinch rollers;

2 shows an upright sectional view of the telescopic column from the side with the adjusting spindle mechanism and dashed stabilization

sier- and pinch rollers, with the inner tube once fully retracted and once shown in the fully extended position;

Fig. 3 shows a horizontal 'section through' inner and Outer tube of the telescopic column, from which the arrangement of the stabilizing and clamping rollers can be seen, while the adjustment mechanism is omitted;

Pig. 4 is a partially broken away side view of the

inner telescopic tube with cross member attached at the top, two of the stabilizing roller assemblies, a connecting spring and the guide slots;

FIG. 5 shows a more detailed illustration of the lower section of the inner telescopic tube shown in FIG. 4; and

6 shows a section through the bearing arrangement of a stabilizing and clamping roller according to line 6-6 in Fig. 5.

The device shown in Fig. 1 for changing a work table height consists of an inner telescopic tube 12 which is inserted into an outer telescopic tube 11 and of this is kept at a distance by stabilizing and clamping roller devices 14a, 14c, 14e and 14g indicated by dashed lines will. In this embodiment there is a second group of stabilizing roller assemblies 14e to 14h, those vertically above the stabilizing roller assemblies 14a

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to 14d, which according to Figures 3 and 5 are each in the same horizontal plane. Of course they are different Arrangements of the stabilizing rollers possible, depending on the dimensions of the telescopic tubes or the size of the required Holding forces. An adjusting motor arrangement 25 is fastened on a base plate 29. With her is a longitudinal transmission device 30 with ball-bearing spindle and spindle nut assembly 26, push sleeve 27 and fastening clip 28 connected. A ball bearing spindle 26a, on which a spindle nut extends, extends from the transmission of the drive motor 25 26b, which is firmly connected to the push sleeve 27. Both the push sleeve 27 and the spindle nut 26b are through the fastening clamp 28 to the inner telescopic tube 12 firmly connected and can therefore not twist in relation to this.

According to FIG. 2, the inner telescopic tube 12 is located in the outer telescopic tube 12, namely two positions are shown, namely the outermost extended position of the telescopic support and their extreme foreshortening position. One of ball bearing spindle and nut assembly 26, thrust sleeve 27 and mounting bracket 28 existing longitudinal force transmission device 30 connects the rotary motor drive 25 with the inner one Telescopic tube 12, which can be adjusted with respect to the outer telescopic tube 11 in this way. Stabilizing roller assemblies 14b, 14d, 14f and 14h are hinted at the inner telescopic tube 12 shown and touch with their ümfangsflachen the inner wall of the outer telescopic tube 11.

The fastening clip 28 serves to secure the spindle nut 26b and the push sleeve 27 firmly connected to it on the inner telescopic tube 12 so that it faces this

about not being able to twist. So when the rotary motor drive 25 sets the ball bearing spindle 26a in rotation, then the push sleeve 27, the spindle nut 26b and thus the inner telescopic tube 12 as a unit along the spindle 26a postponed. As will be described later, the stabilizing roller assemblies 14b, 14d, 14f and 14h the effect, the inner telescopic tube 12 opposite the outer telescopic tube 11 so long in a fixed height position to hold until a force for lifting or lowering via the longitudinal movement transmission device by rotating the drive motor 30 is transferred to the inner telescopic tube 12. By the occurrence of such an increaseor Lowering force and the subsequent movement of the inner telescopic tube 12 relative to the outer telescopic tube 11 roll the stabilizing roller assemblies 14a to h, which are connected to the inner telescopic tube 12, along the inner wall of the outer telescopic tube 11.

When, as shown in Fig. 2, the outer telescopic tube 12 is extended to its extreme position, then rotates the ball bearing spindle 26a within the spindle nut 26b continues as long as there is a threat from the rotary drive 25, so that neither the rotary drive nor the longitudinal force transmission device 30 are damaged.

Reversing the direction of rotation of the rotary drive 25 leads to a downward shift, the spindle nut 26b with the push sleeve 27 and the inner telescopic tube 12 as a unit on the Ball bearing spindle 26a. Again, the stabilizing roller arrangements 14a-h ensure a separation of the inner telescopic tube 12 from the outer telescopic tube 11, so that the inner telescopic tube can slide along the outer. Will then reached the fully retracted position, then

the ball bearing spindle 26a rotates again freely in the spindle nut 26b until the rotary drive 25 is stopped, so that neither the rotary drive nor the longitudinal force transmission mechanism 30 take damage.

3 gives a view of the outer telescopic tube 11 surrounded inner telescopic tube 12 from above again. Stabilizing roller arrangements are located between these two telescopic tubes 11 and 12 14a to d. These are mounted near the corners of the inner telescopic tube 12 so that the axis the stabilizing roller 13a is perpendicular to the axes of the adjacent stabilizing rollers 13b and 13d. With their circumferential surfaces 23a to h, the stabilizing rollers 13a to h also touch the inner wall of the outer telescopic tube 11, while their end faces 24 a to h rest against the adjoining inner wall of the outer telescopic tube 11. In Fig. 3 the longitudinal force transmission mechanism 30 and the rotary drive 25 are omitted.

A partially cut-away side view of the inner telescopic tube 12 with a horizontal support beam 19 is shown in FIG. 4. In the lower area of the inner telescopic tube 12 there are stabilizing roller arrangements 14a, 14e, 14b and 14f, which are slidable in inclined slots 15a, 15e, 15b and 15f are led.

This section is shown enlarged in FIG. It can be seen that the stabilizing roller assemblies 14a, 14b, 14e and 14f at an angle into the walls of the inner telescopic tube 12 incorporated slots are slidably supported. Each sloping slot has a first end 2Ta, 21b, 21e and 21f closer to the edge of the inner telescopic tube 12 than with its second end 22a, 22b, 22e and 22f. the

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Stabilizing roller assemblies 14a-h can be installed in the slots 15a to h slide between the two ends. If the Stabilizing roller assemblies 14a to h slide towards the first end 21a to h of the slots 15a to h, then the Roll over the respective edge of the telescopic tube 12 in front. On the other hand, slide them diagonally to the second end 22a to h extending slots 15a to h, then the rollers are withdrawn behind the edges of the inner telescopic tube 12.

An individual illustration of a typical stabilizing roller arrangement 14 is shown in section in FIG. 6 in its holder in FIG Slot 15 shown. The illustration corresponds to view 6-6 in FIG. 5. The stabilizing roller can be placed on a bearing disk 18 13 turn. The bearing washer 18 is with a Screw 20 is attached to a bearing block 17 penetrating the slot 15 in the inner telescopic tube 12.

By means of a tension spring 16a, two are arranged one above the other Stabilizing roller assemblies 14a and 14e on the first end 21a, 21e of their inclined slots 15a, 15e pulled there. As a result, the rollers 13a, 13e come with their Circumferential running surfaces 23a, 23e over the edge of the telescopic tube 12 and come into contact with the outer telescopic tube 11.

The spring 16 and not shown further springs 16b and 16c ensure that the remaining pairs of roller assemblies 14b and 14f, 14c and 14g, 14d and 14h protrude over the edges of the inner telescopic tube 12 and with their circumferential running surfaces against the inner walls of the outer telescopic tube 11.

When the circumferential running surfaces 23a and 23e of the stabilizing rollers against the inner walls of the outer telescopic tube 11 press, the end faces 24b and 24f are also the horizontally next adjacent stabilizing rollers - in this case the rollers 14b and 14f, against the opposite one Inner wall of the outer telescopic tube 11 pressed. Characterized in that the running surfaces 23a to h and the end faces 24a to h of the stabilizing roller arrangements 14a to h against the inner walls of the outer telescopic tube 11 press, the inner telescopic tube 12 is held in the outer in the desired height position.

If the drive spindle 26a is then set in rotation by the rotary drive 25, the spindle nut 26b becomes the thrust sleeve 27 and inner telescopic tube 12 moved as a unit, as through this pushing force overcomes the holding force of the stabilizing roller arrangements 14a to h with respect to the outer telescopic tube 11 will. The lower roller assemblies 14a-d in Fig. 5 move by this movement to the second ends 22a to d of the inclined slots 15a to d when the Displacement of the spindle nut 26b takes place upwards, whereby the movement resisting inhibition of the inner Telescopic tube 12 is reduced. The stabilizing rollers. 13a to h then roll along the inner walls of the outer Telescopic tube 12 until the desired height position is reached and the rotary drive 25 is stopped.

If the spindle 26a supplied rotation the other way around, so that the nut 26b, the thrust sleeve 27 and the inner Move the telescopic tube 12 down as a unit, then the holding force of the stabilizing roller assemblies is again 14a to h in the outer telescopic tube 11 overcome. The upper roller assemblies 14e to h in Fig. 5 are then the

second ends 22e to h of the slots 15e to h and retreat onto the edge of the inner telescopic tube 12, thereby resisting vertical displacement of the tube 12 becomes smaller. The stabilizing rollers 13a to h then roll on the inner wall of the outer telescopic tube 11 downwards until the rotation of the drive 25 stops and the new height is reached.

The springs 16, 16a, 16b, 16c pull the stabilizing rollers 14a to_h then again against the first ends 21a to h of inclined slots 15a to h, whereby the full height of the holding force for the inner telescopic tube 12 is restored and this is kept in a rest position.

The rotary drive for the lifting device can be operated electrically (as described), but also manually.

If a side force acts on the inner telescopic tube 12, this way one or more roller arrangements can be created instantaneously 14a to h are separated from the outer telescopic tube 11, but the springs 16, 16a, 16b and 16c provide that the roller assemblies against the first ends 21a to h of the inclined slots 15a to h and thereby the protrusions of the roller assemblies 14a to h Enlarge over the respective edge of the inner telescopic tube 12, so that the contact with the outer telescopic tube 11 again will be produced.

Claims (6)

MAYLINE COMPANY, INC.
SkeLbc-ygän, Wis./USA Device for adjusting the height of a work surface Claims 1.> Device for height adjustment of a work surface, ekenn is characterized by a telescopic column with an inner and an outer telescopic tube (12, 11), which have several flat side surfaces with top and bottom edges that meet along edges, the inner telescopic tube (12) having external cross-sectional dimensions which are sufficiently smaller than the internal cross-sectional dimensions of the outer telescopic tube (11), so that the inner tube (12) is in contact with the outer tube (11) finds, while the telescopic tubes have substantially uniformly rectangular cross-section, means (14) between the telescopic tubes (11, 12) in order to convert them into a selectable To set the extended position to one another, which comprise a bearing block arrangement (17, 18), one rotatable with the Bearing block arrangement (17, 18) connected stabilizing roller (13) which runs freely opposite the bearing block, slots (15) in one of the telescopic tubes (12) in which the bearing block assemblies (14) are slidably mounted so that a stabilizing roller (13) with its bearing block arrangement (14) is movable as a unit in the slot., A spring ' element (16) to each roller assembly (14) that comprises the roller assembly so loaded that it protrudes over the edge of the inner telescopic tube (12), the outward pressed stabilization roller (13) with the other stabilization roller assemblies (14) cooperates in such a way that a holding force occurs against the outer telescopic tube (11), a horizontal cross member (19) fastened to one of the telescopic tubes (12), a rotary drive (25), a Ball bearing spindle and spindle nut arrangement (26, 30), which is connected to the rotary drive (25), a thrust sleeve (27), which surrounds the spindle (26a) and is firmly connected to the spindle nut (26b) and the inner telescopic tube (12) the spindle rotates together with the rotary drive and a displacement of the spindle nut (26b) and the thrust sleeve (27) along the spindle (26a) causes the inner telescopic tube (12) to move in relation to the outer one Telescopic tube (11) moves when the occurring rectilinear Force outweighs the holding force, the lifting means being operatively attached so that the one telescopic tube (12) can be pushed into a desired extended position opposite the other. 2. Apparatus according to claim 1, characterized in that all Stabilisierunqsrollen (13a-h) have a circumferential running surface (23a-h) and an end face (24a-h), both of which are in contact with the second telescopic tube (11) can be brought when the roller assemblies (14a-h) in the direction are shifted to the first end of the slot (21a-h), and that the roller assemblies (14a-h) are arranged in such a way are that the axis of each stabilizing roller (13a-h) is perpendicular to the direction of the axis of the respective adjacent stabilizing roller is. 3. Device according to claim 1, characterized. that the rotary drive (25) has an electrical linear actuator. 4. Apparatus according to claim 1, characterized in that the ball bearing spindle (26a). when rotating the rotary actuator (25) rotates in a first direction, whereby the push sleeve (27) and the spindle nut (26b) along the Move the spindle (26a) and the inner telescopic tube (12) connected to it is opposite the outer telescopic tube (11) with sufficient linear force, through which the holding force of the interacting, outwards against the outer Telescopic tube (11) pressed stabilizing rollers (13) is moved upwards. 5. Apparatus according to claim 4, characterized in that the ball bearing spindle (26a) when the direction of rotation is reversed of the rotary actuator turns in the opposite ■ direction and thereby the spindle nut (26b) and the thrust sleeve (27) and with it the inner telescopic tube (12) opposite the outer one Telescopic tube moves down when the linear force exerted by the spindle is large enough to prevent that from the stabilizing rollers (13) to overcome the holding force exerted on the outer telescopic tube (11). 6. Device according to claim 4, characterized in that that the ball bearing spindle (26a) on reaching the end positions of the spindle nut (26b) is opposite the spindle nut can spin freely.