NO132298B - - Google Patents

Description

The present invention relates to a device for height regula-

lering the seat of a swivel chair attached to a tubular column inserted into a carrier tube mounted on a foot, with the column rotating

bar relative to the support tube, comprising a vertical, threaded spindle mounted rotatably in the support tube and engaged with a nut rigidly connected to the column, a locking device-

ning which serves to prevent rotation of the spindle in relation to the foot and where a number of thread turns on the spindle have at least one notch.

Swivel chairs, for example office chairs, which have a foot and an upward-protruding column on which a swiveling chair seat is mounted,

includes, if desired, a height adjustment mechanism, so that the seat height can be adjusted by the person using the chair. Common height adjustment mechanisms include exposed parts, such as a common threaded spindle, which are unsightly to look at and which also

comes forward and can soil the clothes of the person using the chair. Occasionally, the chair must be placed on its side when the height is to be adjusted,

and in other cases, the user of the chair must bend or stoop to be able to operate the adjustment handwheel. In recent times, cra-

tendency to design from the commercial market has gone in the direction of demanding chairs whose appearance is not encumbered with such ugly

ge presichtenkende mechanical parts. It is therefore desirable to have a height adjustment mechanism for swivel chairs, where all mechanical parts are hidden within the normal contours of the chair and where the adjustment of the chair height can also be carried out without the user of the chair having to bend or lean and while the chair is in the normal upright position.

The purpose of this invention is to provide a height adjustment mechanism which can be easily operated by anyone, but which is at the same time simple, has a sensible mechanical construction and operation, or in other words a height adjustment mechanism which, when properly adjusted, holds the chair seat at the desired height regardless of the rotation of the seat.

In connection with devices of the type mentioned at the outset, the known technique is considered to be represented by Norwegian patent 42,269 as well as US patents 1,582,530 and 2,255,649.

The new and distinctive feature of the device according to the invention compared to the previously known consists primarily in the fact that the nut is designed with at least one downward-pointing projection in the direction of the spindle axis towards the foot, which projection is arranged to be held in a notch when the seat is loaded and to be released from the incision by turning the seat in the position of the locking device where the spindle is held against turning in relation to the foot.

The invention as well as further features and advantages of it will now be described with reference to the drawings, where: Figure 1 is an elevation of a chair foot which includes a device

according to the invention.

Figure 2 is a section on a larger scale taken along the line 2-2

on Figure 1 and shows details of the device.

Figure 3 is a perspective view of the single threaded nut which

is shown in section in Figure 2.

Figure 4 is a section along line 4-4 in Figure 2.

Figure 5 is a section along line 5-5 in Figure 2.

Figure 6 is a section along the line 6-6 in Figure 2, and Figure 7 is a partial section corresponding to that in Figure 2,

but shows a position of the control elements during a height control.

Reference will now be made to the figures where a chair seat 1 (part of which is shown in figure 1) is rotatably mounted on a chair base. A height deregulation mechanism 7 is placed between the chair seat 1 and the chair foot 2, under a tubular column 8 which is connected to the chair seat 1 and lies essentially completely inside a tubular hub 9 which is connected to the chair foot 2. The turning connection is provided between the telescopically arranged, tubular parts 8 and 9, respectively, which are connected to the chair seat 1 and the chair foot 2, respectively. The height adjustment mechanism 7 holds the column 8 in a desired fixed position and prevents axial displacement, but allows rotation when turning the chair seat 1 in relation to the hub 9 or causes the column 8 is moved axially upwards or downwards by rotation in relation to the hub 9 by changing the height of the chair seat 1 in relation to the chair foot 2.

The chair seat 1 can be fixedly connected to the column 8, but a chair regulation mechanism 3 is preferably partly attached to the chair seat 1 and partly to the column 8 to enable a tilting movement of the chair seat 1 in relation to the column 8 and the chair foot 2. The chair regulation mechanism 3 comprises a plate bracket 5a which by means of a suitable device, for example screws 6, is attached to the plate 5 which can be a chair seat, but which often forms support for padding or the like, so that the chair seat 1 is generally shown to include the plate 5 and accessories for the seat . The seat adjustment mechanism 3 provides a yielding resistance to tilting movement of the seat 1

in relation to the column 8 and includes a handwheel 4 for adjusting the original yielding resistance to the rocking movement.

Figure 1 clearly shows how compact the height adjustment mechanism based on the device according to the invention is, and how harmonious it is together with the chair seat 1 and the chair foot 2. It is also clear that the components in this mechanism are necessary to provide good function and to provide the desired turning movement and height adjustment option. They are also essentially enclosed and hardly visible, so that the mechanism is fully suitable for use with any chair construction without spoiling its appearance.

In the section in Figure 2, only a lower part of the column 8 is shown, which is formed by a hollow sleeve 60. A pair of axially separated annular indentations 50 and 53 are formed in the column 8, the indentation 50 being preferably formed axially some distance inside the column and the press-in 53 are formed at the lower end of the column 8. Annular bushings 54 and 55 are accommodated in the press-ins 50 and 53 respectively and serve as radial bearings to keep the column 8 axially aligned in the hub 9, but allow rotation and axial displacement

ning of these in relation to each other.

A spindle 61 is rotatably mounted in the hub 9. The spindle 61 comprises an upper part with a screw thread 70, a shaft pin 62 with a reduced diameter and a projection 63 with flat side surfaces, the shaft pin 62 and the projection 63 projecting axially downwards from the spindle 61. A foot plate 64 is received at the bottom edge of the tubular hub 9

and is attached to this preferably by welding, as indicated at 65. The foot plate 64 comprises a central opening in which is arranged

a bearing 67 which comprises a thin-walled, cylindrical part 67a which passes through the opening 66, and a thicker-walled, ring-shaped flange part 67b which rests against the upper surface of the base plate 64. A planar ring disc 68 is preferably placed on the upper surface of the flange part 67b. The spindle 61 is arranged so that the lower threaded part rests on the ring 68, and the shaft pin 62 extends

through the opening in the bearing 67 and the projection 63 protrudes below the lower surface of the foot plate 64.

The threads 70 are cut in the outer surface of the spindle 61 and extend from the hub 62 in a helical spiral up to the part 70a near the top of the spindle 61. At the part 70a, the thread extends vertically to the top of the spindle 61. The part 70a has two functions. First, it forms a stop for a nut 75 when setting up the seat 1. Second, it allows the seat 1 with the column 8 and the nut 75 to be easily removed (or re-attached) by raising the seat 1 until the portion 70a butts against the nut 75 and then lift (or lower when fitted) the seat 1 with the column 8 up or down on the spindle 61 and the foot 2. A pair of grooves or incisions 72 are cut through the threads 70, preferably running axially on diametrically opposite sides of the spindle 61 and ninety degrees offset from the threaded part 70a. The incisions 72 extend through the entire radial depth of the thread 70 and partially in the cylindrical surface of the spindle 61. In reality, the incisions 72 represent incisions in successive windings in the spindle thread 70. While it is preferred that these incisions are complete openings in the thread 70 and furthermore that these openings are arranged in line with each other, they can also be incisions instead of openings and they do not have to be arranged in line with each other from turn to turn.

The single threaded nut 75 is welded to the bottom edge of the column 8 as indicated at 76 and is screwed onto the thread 70 of the spindle 61 to support the column 8 on the spindle 61. The nut 75 is best shown in the perspective view of figure 3 and can usually be extruded from a steel disc with an annular design. The inner part of the annular disk is cut out at 77 and is bent so that it forms a normal, single screw thread 78 which has the same pitch as the screw thread 70 on the spindle 61. On diametrically opposite parts of the nut thread 78, projections 79 are formed. Both nut protrusions protrude downwards, i.e. downwards and parallel to the nut thread axis. The downward projections produce an auxiliary locking effect when the seat is loaded. The total thickness of the nut 75 including the depth of each nut projection 79 is slightly smaller than the axial distance between the upper surface of one turn and the lower surface of the adjacent turn of the screw thread 70 of the spindle 61, and the width of each nut projection 79 is slightly smaller than the width of the incisions 72 through the thread 70. As shown in Figures 2 and 4, the protrusions 79 can be accommodated in the incision 72 between the adjacent ends of each winding part of the thread 70 which is separated by the incision, the remainder of the generally helical portion of the thread 78 on the nut 75 rests on a turn in the screw thread 70 on the spindle 61.

A locking device is arranged to be able to lock the spindle 61 to the hub 9 if desired to prevent relative rotation between them. The lock 80 comprises a locking plate 81 which, while simultaneously referring to figures 2 and 5, comprises a generally rectangular, centrally arranged opening 82. The projection 63 on the spindle 61 can be slidably accommodated in this opening 82. The locking plate 81 comprises a number of projections 85 which are arranged at the same angular distance from each other at the same radius on the upper flat surface. In the embodiment shown, the projections 85 consist of round-headed, cylindrical pins. A stop ring .83 is received in a groove 84 which is taken out on opposite sides of the protruding pin 63, and holds the locking plate 81 firmly on the pin 63.

It will now be shown at the same time to figures 2 and 6 where the foot plate 64 comprises a number of holes 86 which are arranged at the same angular distance and on the same radius as the projections 85. Each of the holes 86 is large enough to accommodate one of the corresponding projections 85, as that the locking plate 81 is effectively locked against rotation in relation to the foot plate 64.

Alternatively, the projections 85 and the holes 86 can be interchanged in whole or in part so that the locking plate 81 comprises openings 86 and the foot plate 64 has projections 85 which extend downwards. Yet another alternative is that a single eccentric projection and a single eccentric opening are used instead of the large number of projections 85 and holes 86 respectively to provide locking between the locking plate

81 and the foot plate 64.

During use, the column 8 is locked to the spindle 61 so that they rotate together in relation to the hub 9 so that the chair seat can be turned at a constant height. As indicated above, the projections 79 on the nut 75 are usually engaged in the vertical slots 72, the weight of the person using the chair being transferred through the column 8 and the nut 75, so that the projections 79 are locked in the slots 72. The nut 75 therefore lies firmly against the spindle 61, and the column 8 and the spindle 61 rotate together in the trust bearing 67 so that the aforementioned turning movement of the chair seat 1 can be produced. The radial bearings 54 and 55 allow this pivoting movement while the column 8 is kept well axially aligned in the hub 9.

When adjusting the chair height, the spindle is locked against rotation

in relation to the hub 9 by influencing the locking mechanism 80. The locking plate 81 can be influenced by lifting it with the tip of the shoe so that the projections 85 fall into the holes 86 in the foot plate 64. This can be done without bending over and it is advantageous, but this however, operation can also be performed by hand if desired. As it can very easily happen that the projections 85 are not immediately aligned in relation to the holes 86 when an upward force is applied to the plate 81, a rotation of the chair seat 1 and thus also a rotation of the projections 85 which will be aligned in relation to and fall into the holes 86, so that the spindle 61 is locked to the hub 9.

When the spindle 61 is locked to the hub 9, a continued rotation will occur

of the chair seat effect a height adjustment. This can happen because a torque occurs between the nut 75 and the spindle

61, which causes the protrusions 79 to be pulled out from the locking position in the notches 72 and onto the spindle thread 70. By simply lifting the locking plate 81 and turning the seat, the nut 75 is pulled onto the thread 70, whereby a loop can be made -ting or lowering the seat 1. The extraction of the protrusions 79 from the incisions 72 can be seen in development in Figure 7. As previously stated, the depth of the protrusions is such that the nut thread 78 and the protrusions 79 can be advanced into the space between the threads 70 on the spindle 61, so that the nut is guided axially along the spindle 61. For every half turn, the protrusions 79 will again enter the notches 72, but if the locking plate 81 is held up, they will again be guided out of the notches by a partial rotation of the chair seat 1. The height adjustments can therefore be made in steps on a half thread pitch. The length of the nut offset is limited by the unthreaded portion 71 at the top of the spindle 61 and the disc 68 at the lower end of the spindle 61.

The use of the locking mechanism 80 is obviously very simple in that it is not even required that the plate 81 be touched by hand. Nevertheless, a secure locking of the spindle 61 to the hub 9 is achieved. The possibility that a height change of the chair seat can simply be made by turning the chair seat while the locking mechanism 80 is engaged is very advantageous, as the dimensions of the chair seat in any case provides a sufficiently long weight arm to turn the nut 75 on the spindle 61 quite easily. It has been found that in offices, especially when the user of the chair is a woman, it is particularly advantageous that the adjustment can be made without bending over and without it being necessary to use the hands on mechanical parts.

The height adjustment mechanism 7 with the specified device according to the invention is a compact, cheap and very effective storage for chairs and is particularly advantageous when used on office chairs. The components in the mechanism are essentially encapsulated and out of sight, which gives a better appearance and ensures that the mechanism does not collect dust and dirt. Avoiding the accumulation of dust and dirt also helps the mechanism work better and that it can be used for longer.

The tubular column 8 which supports the chair seat 1 can rotate freely in the hub 9 during a turning movement and can be freely pushed in and out of the hub 9 during height regulation, without scratching or grinding off its surface. This is very important in terms of appearance, and because the surface does not need lubrication, it can also be better accepted because it does not dirty the clothes of the user of the chair.

Claims (3)

1. Device for height adjustment of the seat on a swivel chair attached to a tubular column inserted in a carrier tube which is mon- tert on one foot, with the column rotatable in relation to the support tube, comprising a vertical, threaded spindle which is rotatably mounted in the support tube and engages with a nut which is rigidly connected to the column, a locking device which serves to prevent rotation of the spindle relative to the foot and wherein a number of threaded turns of the spindle have in it at least one notch, characterized in that the nut (75) is designed with at least one downward-pointing projection (79) in the direction of the spindle axis towards the foot (2), which projection is designed to be held in a notch (72) when the seat is loaded and to be released from the incision (72) by turning the seat in the position of the locking device where the spindle is held against turning in relation to the foot. 2. Device according to claim 1, characterized in that the individual notches (72) in the spindle thread have the same radial direction and that the nut has a downward-pointing projection. 3. Device according to claim 1, characterized in that the incisions in the spindle thread are placed in each of the thread turns so that they form two rows of vertical incisions parallel to the thread axis and situated on diametrically opposite parts of the spindle, and that the nut (75) has a diametrically opposed pair of protrusions (79).