DE1283457B - Tilting device for a chair - Google Patents

Description

The invention relates to a tilting device for a chair with a seat member that is freely rotatable about a vertical axis and tiltable to the side and a chair shaft in which a spindle connected to the seat member and a coil spring abutment located on the spindle and with a clamped between the helical spring abutment and the seat member, the spindle surrounding coil spring.

In the known tilting chairs, the adjustment of the tilting movement counteracting spring force with the help of handwheels, wing nuts or wrenches which are usually located at the bottom of the chair shaft. to For this purpose, the chair must be raised to about table height so that the adjustment device can be operated reasonably comfortably.

However, since such a tilting chair has a considerable weight, requires this type of operation requires a relatively large amount of force.

The object of the invention is therefore to provide a tilting device to create that can be adjusted more easily.

This is achieved in that the spindle against rotation by a Locking can be secured and the tension of the helical spring by turning the seat member is adjustable about the vertical axis. This creates one and the same running element, namely the seat member, used to fulfill two different tasks, namely to rotate freely and to change the coil spring preload, without that an additional adjustment element must be installed. The tilt chair needs thus neither lifted up nor removed from the place where it is used when the helical spring influencing the tilting resistance are adjusted should because this can be achieved by simply rotating the seat member.

An embodiment of the subject matter of the invention is shown in the drawing, to which the following description refers, shown schematically.

F i g. 1 is a side elevation of a chair according to the invention; F i g. Fig. 2 is an enlarged axial section of the rocker device; part of the chair and part of the column structure have broken away; F i g. 3 is a broken away view from the underside of the FIG. 2 shown device; F i g. 4 is a broken section taken along a plane taken along line 4-4 of FIG . 2 corresponds to; F i g. 5 is one of the F i g. Fig. 2 is a view similar to Fig. 2 but showing the elements in different positions; F i g. 6 is a broken section taken along the offset plane taken through line 6-6 of FIG . 2 is indicated; F i g. 7 is a section along the plane taken along line 7-7 of FIG . 2 corresponds to; F i g. 8 is a section taken along the offset plane taken through line 8-8 of FIG . 2 is indicated; F i g. 9 is a section taken along a plane corresponding to line 9-9 of FIG . 5 corresponds.

In Fig. 1 , a chair including a seat structure 10 and a column structure 11 is illustrated. The seat 10 can be any designed model. The column 11 contains a support post or stand 12 which is open at the ends and has a series of feet 13 which radiate outward from its lower part. The column 11 also includes an attachment 14 which is carried by the post 12.

The attachment 14 includes a seat receiving portion or flange 15 which is located slightly above the top of the post or stand 12. The flange 15 is annular in outline and widens outwardly and upwardly to form a circular rim portion which contacts the lower surface of a portion of the seat 10 . Appropriate fasteners such as screws 16 go through the rim to attach the seat to the attachment flange 15.

The flange 15 has a lower wall 17 which is located above its bottom and thereby delimits a recess 18 which is open at the bottom.

The lower wall 17 rests on a pressure member 19 which fits into the recess. The wall 17 and the pressure member 19 have flat surfaces which are normally in mutual contact.

The pressure piece 19 in turn is built up on the upper end of the post 12. A sleeve 20 supports the construction of the pressure piece 19.

The HüIse 20 is attached by screwing to a remote extension 21 of the pressure piece 19 and is received for guiding telescopically in the post 12th The sleeve 20, when its axial movement is prevented, restricts the pressure piece to angular movement about the common axis of the sleeve 20 and the post 12. The pressure piece 19 has a downwardly pointing annular shoulder 22 which faces the upper face 23 of the post or stand 12 . A bearing arrangement 24 is inserted between these surfaces, so that the pressure piece 19, the attachment flange 15 and the seat 10 are able to execute a rotary movement without inadmissible friction hindrance.

A thin flange 25, which is made in one piece with the pressure piece 19 , forms a recess in which the bearing is enclosed and hidden. The depending walls which form the recess 18 in the bottom of the flange 15 , in turn, for the most part cover the pressure member 19 and the top of the post 12.

The flange 15 can be rocked about a horizontal axis relative to the pressure member 19 . In order to create a suitable hinge connection, cylindrical support dowels 26 ( Figs. 2, 5 and 8) are provided. The support dowels 26 have a snug fit in the opposite ends of an approximately semi-cylindrical recess 27 which is worked into the upper flat surface of the pressure piece 19 . The common axis of the support dowel 26 and the recess 27 is horizontal and is at a distance from the axis of the rotary movement.

The upper surfaces of the support dowels 26 are received in an associated, approximately semi-cylindrical recess 29 which is incorporated in the lower surface of the wall 17 . The recesses 27 and 29 cover separated when the flange 15 is in its normal, horizontal less than 3601. In particular, the ends of the recesses are defined by an angle a (2 g F i.), By the contact between the wall 17 together and the pressure member 19 is certain position. As a result of the angular separation a, the flange 15 can move angularly about the horizontal axis of the dowels into the position shown in FIG . 5 move position shown. In order to prevent separation of the flange 15 and pressure member 19 and to limit their rocking movement, a locking screw 31 is provided. This screw passes through a generally arcuate slot 32 machined into a bead 28. The bead 28 is located on the upper surface of the wall 17 and extends around the recess 29 . The slot 32 divides the semi-cylindrical recess 29 transversely in the middle.

The screw 31 has a cylindrical shaft part 33 which passes between the inner ends of the support dowels 26. The screw 31 has a stepped thread extension 35 which engages in a threaded hole 36 machined in the bottom of the semi-cylindrical recess 27 of the pressure member 19 . The arcuate course of the slot 32 about the axis of 28 is such that the desired degree of rocking movement is possible without interference. The sidewalls of the arcuate slot 32 have a running fit with the cylindrical shaft 33 to prevent relative movement of the parts parallel to the axis of 28 .

In order to keep the wall recess 29 in contact with the support dowels 26 and in order to keep them in contact with the recess 27 of the pressure member 19 , the screw 31 has a head 37. The head overlaps the upwardly pointing shoulders 38, which are attached to an enlarged outer opening of the arcuate Slit are worked. The head has at least 38 free movement with the shoulders.

In the outermost rocking position, the pressure member 19 is essentially hidden by the edge walls which form the recess 18 .

In order to limit the angular rocking movement of the attachment parts 19 and 15 , a stop member 41 (see FIGS. 2, 5 and 6) is provided. The stop member 41 protrudes upward from the pressure member 19 at a point which is opposite the support dowels 26. The stop member 41 passes through a through opening 42 which runs in the wall 17 . The stop member 41 can be designed as a cylindrical shaft screw which is screwed into a hole 44 in the upper surface of the pressure member 19. The upper end of the shank screw 43 carries a transverse pin 45, the ends of which protrude beyond the edges of the through opening 42, that is to say limit the angular movement of the flange 15. The upper edges of the opening 42 are provided on the opposite sides with semi-cylindrical incisions, as at 46, which are suitable for opposing the transverse pin and thus distribute the force exerted on it.

To the flange 15 and the seat 10 in a horizontal normal position as in FIG. 2 to rotate back, a compression spring 47 is provided. The spring ends are not circular, but instead are helical for purposes to be explained immediately. The spring 47 fits within the sleeve 20 and the post or stand 12. The upper end of the coil spring 47 sits as seen partially in FIGS. 7 and 9 can be seen in a contoured groove 48 which is machined into the lower surface of the stepped extension 21 of the pressure member 19. The shape of the groove 48 is such that it forms a stop shoulder 49 ( FIG. 9) which is opposite to the direction in which the helical spring 47 is wound.

The other, lower end of the spring 47 engages in a driving nut 50. The nut 50 is generally cylindrical in shape. Its upper surface is provided with a groove 51 which is so outlined that by fitting in the lower end of the spring 47 it forms a stop shoulder which is opposite to the direction of winding of the spring.

The driving nut 50 represents an extension of the flange 15 insofar as a downward force exerted on the nut 50 is transmitted to the flange 15 and tends to move the flange into the normal position of FIG . 2 to turn back. A rod 52 connects the nut to the flange 15. The rod 52 extends generally along the axis of the post 12 and sleeve 20 and through the spring 47. The lower end of the rod 52 is threaded for installation in the drive nut 50. The upper end of the rod passes through the central opening 53 in the pressure member and through a through or play opening 54 in the central wall 17. A large transverse pin 55 is used to articulate the rod 52 and the flange 15 together and allow the rocking movement therebetween.

The cross pin 55 is seated, as can be seen in FIGS. 4 and 7 sees, in a semi-cylindrical recess 56 of the wall 17, which is pierced in its center by the through opening 54. The axis of the groove 56 runs parallel to the axis of the support groove 29. The rod 52 goes with running play through a transverse hole 57 in the transverse pin. A nut 58 placed on the upper threaded end of the rod 52 faces a flat 59 which is milled into the transverse pin 55. A tracking bearing 60 is interposed between the flat 59 and the nut 58 to allow the rod 52 to rotate about its own axis with the least amount of friction for purposes described below. The downward pressure of the spring 47 is transmitted to the flange 15 through the driving nut 50, the rod 52, the nut 58, the track bearing 60 and the transverse pin 55 .

When the flange 15 angularly moves about the support dowels 26 , the rod 52 is levered up and slightly to the side, as shown in FIG. 5 is indicated. A corresponding widening of the openings 53 and 54 allows the lateral movement of the rod 52.

By rotating the rod 52 about its own axis with the drive nut 50 being appropriately secured against rotation, the latter is raised or lowered and the pressure level of the spring 47 is changed, whereby the restoring force on the flange 15 also changes. In order to rotate the rod, i.e. to make it act as a lead screw, a handle arrangement 63 is provided. It includes a nut screwed onto the rod end, and thereto coupled by a threaded pin 65 collar 64. A hand strap 66 is housed in an arcuate circumferential groove 67 at the outer end of the collar 64 and so articulated by pivot pins that it can rotate outwardly. Typically, a ball detent (not shown) can hold the handlebar in the arcuate groove 67 . When the handlebar 66 is rotated outward, the rod 52 can be rotated easily. Upon rotation of the rod or lead screw 52 in one direction, the driving nut 50 is committed to migrate so that its end shoulder firmly rests against the end of the spring 47th The spring resists this torsional movement and accordingly the rod 52 rotates while the drive nut 50 is restrained from rotation by the spring 47. The spring 47, in turn, is held back against angular rotation with the aid of the engagement of its other end in the end shoulder 49. The pressure member 19 in turn, in which the end shoulder 49 is incorporated, is prevented from moving by a retaining fit. This direction of movement of the lead screw 52 causes the drive nut 50 to compress the spring, and this movement of the handle 63 is preferably clockwise, viewed from below, in accordance with the conventional convention that tightening is accomplished by a clockwise movement. The threads of the nut 50 and the rod 52 must be left-hand threads in this case.

When the rod 52 is rotated in the opposite direction, the inclined surface of the guide nut 50 tends to push the helical spring upwards, that is to say in the direction of increasing spring force. Of course there is resistance to this; therefore, in this direction of rotation, the thrust cam action secures the drive nut 50 against rotation, so that it accordingly migrates downwards along the threaded end of the rod 52.

The tension is thus set by the relative movement between the seat and the pressure member 19 on the one hand and the handle or collar 64 on the other hand. Instead of holding the seat and rotating the collar 64, the latter can also be held and the seat can be rotated with the pressure member 19. For this purpose, the collar 64 has a slot 68 ( FIG. 3) which can be brought into alignment with the slot 69 which is machined into the bottom of the post 12 and the adjoining part of one of the feet 13. Insertion of a key or other flat piece of metal into slots 68 and 69 will retain the collar. The angular movement can then be transmitted to the pressure member 19 and the spring 47 only by rotating the seat. When the desired setting has been made, the piece inserted in the slot 68 and 69 is removed again.

When the flange 15 rocks, the collar 64 is lifted with the rod 52 upwards. Appropriate clearance is provided between the collar and the lower end of the sleeve 20.

As the flange 15 rocks, the lower end of the rod 52 is held generally in the center of the sleeve 20 by virtue of the somewhat mating fit between the cylindrical periphery of the drive nut 50 and the sleeve.

A threaded pin 70 passing through the post or stand 12 engages an annular groove 71 in the sleeve 20 to normally prevent it from separating from the post or stand 12 should the seat be raised to move the chair.

The length of the spring 47 changes only slightly during the rocking movement of the flange 15. This means that the restoring force remains essentially the same in all rocker positions. This contributes to the convenience of use.

Claims (2)

Claims: 1. Tilting device for a chair with a seat member freely rotatable about a vertical axis and laterally tiltable and a chair shaft in which a spindle connected to the seat member and a helical spring abutment movable on the spindle are located and with one between the helical spring abutment and the seat member clamped helical spring surrounding the spindle, characterized in that the spindle (52) can be secured against rotation by locking (68, 69) and the tension of the helical spring (47) can be adjusted when the spindle is locked by rotating the seat member (15) about the vertical axis is. In that the seat member (15) comprises second tilting device according to claim 1, characterized in that on a plate (19) about a substantially horizontal axis, which was a waste of the vertical axis, is mounted tiltably. 3. Tilting device according to claim 2, characterized in that the plate (19) can be screwed to a sleeve (20) which is telescopically guided in the stand (12) so that it is rotatable about the vertical axis of the stand (12) . 4. Tilting device according to claims 2 and 3, characterized in that an operating device (63) is attached to the lower end of the spindle and accessible at the lower end of the sleeve (20) and the stand (12) with which the spindle (52) is rotatable against the helical spring abutment in order to change the tension exerted by the helical spring (47) by raising and lowering the nut (50). 5. Tilting device according to claim 4, characterized in that the operating device (63) has a handle (66) sunk into the stand (12) for rotating the spindle (52) . 6. Tilting device according to claim 4 or 5, characterized in that the operating device (63) is provided with a part (64) which is coupled to the spindle and in which there is a slot (68) which, together with one in the stand (12 ) existing slot (69) forms a recess which releasably receives a locking device between the part (64) and the stand (12). 7. Tilting device according to one of claims 4 to 6, characterized in that the nut (50) against rotation relative to the sleeve (20) in one direction by the torsional resistance of the helical spring (47) and in the other direction by the overrun effect between the Top of the nut (50) and the underside of the plate (19) on the one hand and the helically wound ends of the spring on the other hand is secured. 8. Tilting device according to one or more of claims 1 to 7, characterized in that the upper end of the spindle (52) through the bottom of a recess (56) formed in the top of a wall (17) of the seat member (15 ) and by a in an opening (57 ) located in the recess (56) protrudes through an opening (57) located in the recess (56) and can be rotated therein, so that the spindle (52) with a nut (58 ) resting against the edges of the opening (57) of the transverse bolt (55) ) , with a bearing (60) being provided between the nut (58) and the transverse bolt (55) to reduce the friction of the spindle (52) when it moves about its own axis. 9. Tilting device according to one or more of claims 1 to 8, characterized in that the seat member (15) and the plate (19) are provided with opposite, substantially semi-cylindrical recesses (27, 29) in which cylindrical bodies (26) sit, which form the tilt axis between the plate (19) and the seat member (15) . 10. Tilting device according to claim 9, characterized in that transversely between the cylindrical bodies (26) a screw (31) runs through which is connected to the plate (19) , that the semi-cylindrical recess (29) has a curved recess (32) cuts, which guides the shaft (33) of the screw (31) , and that the screw (31) is provided with a head (37) . 11. Tilting device according to one or more of claims 2 to 10, characterized in that a thrust bearing (24) is arranged between the plate (19) and the upper end (23) of the stand (12) for receiving the weight of the seat (10) is. 12. Tilting device according to one or more of claims 1 to 11, characterized in that a stop body (11) for limiting the tilting movement of the seat member (15) is present.