DE1957892A1 - Rubber spring arrangement for a chair adjustment - Google Patents

Description

Rubber spring assembly for a chair regulator The invention relates to generally rubber spring chair regulators and in particular a chair regulator with a rubber spring, which is placed under longitudinal shear stress, and with improved stability and deformation resistance.

Rubber springs, a rotational movement of a holder component in a Resisting stool regulation have been in use for many years. Normally such springs are placed under I) jerk or torsional stress in order to prevent them from tipping to withstand the rotational movement of the holder component. Pressurizing the Rubber leads to aging and consequently to the hardening of the rubber, so that the rubber has a relatively short lifespan. On the other hand, a torsional stress is required of the rubber is a complicated, relatively expensive arrangement in which the larger rubber surface is firmly clamped or fitted into a cylinder-like housing or the like, in order to tension the rubber when the holder component rotates, as a direct connection difficult to maintain between the rubber and metal in such an embodiment.

Furthermore, the person sitting on the chair exercises the known chair regulating rotary movement Forces against a spring, which is arranged so that it Resisting force in a direction perpendicular to the stator axis. This causes Instability and requires relatively heavy or massive parts along with complicated fastening techniques and devices to protect the chair from malfunctions, To secure fracture and instability.

The invention overcomes the above disadvantages. the use of a annular rubber component, the outer surface of which on a cylindrical casing surface adheres or is pressed against this housing, which is axially supported by a stator component is held with the inner surface of the rubber adhered to a tube that moves axially in accordance with the rotational movement of the holder component. The axial Displacement puts the rubber under longitudinal shear stress, causing the Lifespan is extended while the load is over a large adhesive surface is distributed, which allows a simple economical arrangement.

In order to further improve the chair, the rubber component or the Spring arranged generally coaxially with the stator axis, and the rotational movement the chair is moved by a short lever arm in a direction corresponding to the stand axis broadcast. Because the spring at one end by the relatively heavy stand is held and the torque is transferred to the stator, the interconnections become between the various components simplified and the parts reduced in size, while the application of forces through the stator axis and centrally on the Base contributes to the stability of the chair.

Another embodiment of the invention relates to a chair regulator, which uses a rubber spring placed under longitudinal shear stress becomes according to the rotational movement of the chair adjustment holder component.

Yet another embodiment is by creating an economical one Chair regulation characterized by the use of a rubber spring.

Further features, advantages and possible uses of the new invention result from the attached representations of exemplary embodiments and from the following description.

1 shows a side view of a chair according to the invention, FIG. 2 is an isometric view of a chair regulator according to the invention, FIG. 3 is a front view of the rubber spring assembly, FIG. 4 is a view of part of FIG Chair regulation in a partial sectional view, Fig. 5 is a sectional view along the Line 5-5 of Figure 3s, the dashed lines indicating the location of the rubber spring assembly under load or under tension, Fig. 6 a isometric view of a chair regulator according to the invention, which 80 is arranged is that a force is developed along the stator axis to support the rotational movement of the person sitting on the chair, Fig. 7 is a sectional view of the chair regulator, which is shown in FIG. 6, FIG. 8 is a sectional view taken along line 8-8 in FIG Figure 7, and Figure 9 is an isometric view of the tube which is used in the chair regulator, shown in Figure 6 and Figure 7 is used.

In Figure 1, a chair 10 is shown. The chair has a base 12 on swiveling rollers 14. A threaded post 16 extends vertically upwards from the pedestal 12 and carries a handwheel 18 to the conventional Setting the height of a chair regulator 20. The chair regulator 20 enters Pair of L-shaped support arms 22, which with a seat 24 and a backrest 26 are connected.

The chair regulator 20 has an L-shaped support part? 8, with a base web 30 for receiving the upper end of the stand 16 on which the Component 28 is applied. The component 28 has a front wall 32, which upwards between two side plates 34 of a U-shaped holder component 36 extends.

The holder component 36 is rotatably mounted on the component 28 through a torsion bar 38 and sockets 40. The bar or pin 38 extends through the lower web 30 of the component and through the upper end of the stand 16 near the longitudinal axis of the stand and perpendicular to this longitudinal axis. The holder component 36 in turn carries support arms 22, each attached to the component by short bolts or rivets 44 are attached, the near opposite of the front and rear ends and are arranged along the top edge of the side panels. It is noted that the axis of rotation can be arranged in other .Stellungen and the stand can be dismantled can be or separable relative to the support part, so that the two for example can be sent separately.

A tab 46 formed between the ends of each side panel 34 is able to communicate with the rear surface of the wall 32 pedal to limit forward or clockwise rotation as can be seen in the drawings. A protrusion 47 near the back of the lower one Web 30 of the support part is suitable with the corresponding rear edge of the side plates 34 to connect to the rotational movement in the reverse or To limit the clockwise direction as shown in the drawings.

The support arms 22 normally support the seat 24 and both, the seat and the backrest 26, rotate as a unit about the axis of the rod 38, so that the chair can be classified in the category which is well known is under the term office chair. It is noted that the backrest alone is used for a rotational movement can be fixed. In this Trap is that Chair commonly known as the secretary chair type. If desired, the seat and backrest can be attached for independent rotation be used to create a steel that is commonly used as a post office chair Is known to employees.

The U-shaped holder component 36 has a rear web 48, the-above the upper edge of the wall 32 is arranged for one-piece connection of the two Side panels 34. A sloping wall 50 is on the rear edge of the Web 48 is provided, and this extends behind the wall 32 for engagement with the rod 52 for controlling a rubber spring arrangement 54. To support the wall 50 bases 46 are provided to withstand bending movements.

The rubber spring assembly 54 comprises an annular rubber spring component 56 on, its outer surface against the inner surface of an annular or cylindrical housing 58 is pressed or adhered to this. The inner surface the spring 56 is pressed or adhered to the outer surface of a tube 60 on this surface.

One end of the housing 58 engages in a recess in the wall 32 and abuts against an end wall 64 of this Buanehmung, so that a movement of the housing to the right, as can be seen in Figures 2 and 4, is prevented. An opening 66 is provided in end wall 64, coaxial with the axis of the rubber spring 56, the housing 58 and the tube 60.

The opening 66 is large enough to allow movement of the tube 60 / in to allow the opening. One end of the rod 52 extends through the opening 66 and a correspondingly oriented opening in the wall 50. On the corresponding end of the rod 52 is a cross head 70 is provided, and the cross head 70 has a pin or pivot edge for meshing with one another. corresponding shaped recess 72 which is arranged in the rear surface of the wall 50 is. This arrangement allows some rotational movement of the rod while a independent axial movement of the rod to the left is prevented, as in Figure 4 can be seen. The other end of the rod 52 is threaded for the purpose of adjustable meshing with a threaded hand wheel 74.

The handwheel 74 is substantially cup-shaped, with its outer Wall 75 is knurled to facilitate the rotary movement, and the end of the Housing 58 overlaps. A raven 76 extends from the rear wall of the cup 74. This is provided with an opening to the end of the rod 52, which is opposite to the head 70. At the appropriate end of the rod 52 and in the Na W opening are threads provided, us an axial adjustment of the handwheel on the rod 52 to enable. A shoulder 78 is between the ends of the hub 76 provided for support against one end of the tube 60, which the reduced end of the raven 76 overlaps. The handwheel 74 can of course in different Can be changed in a way, e.g. instead of a cup-shaped arrangement a T-shaped or other arrangements may be provided.

It is noted that the rubber spring member 56 has an outer diameter about 4.45 em (1-3 / 4 inches) and its outer surface against the inner Surface of the housing 58 is pressed or sticks to this their entire combined length of 5.08 cm (2 inches) of the housing 58. The inner The diameter of the rubber spring is approximately 1.91 cm (3/4 inch), and the inner surface the spring, determined by this diameter, is pressed or stuck against the pipe on the pipe for the length of 5.72 cm (2-i / 4 inches) with the pipe 60 on the left end opposite the end of the housing 58 protrudes. It is noted that changes in dimensions and location can be introduced, depending on the type of chair and the location of the assembly 54. The adherent or bonded surfaces of the pipe and the housing are treated appropriately if necessary.

The rubber spring member is inwardly between at opposite ends the tube and housing recessed as indicated by lines 80 and 82, shown in Figures 4 and 5. The inward depression near the end the rubber spring on the protruding end of tube 60 is approximately 1.91 cm (3/4 in inch) from the adjacent end of the housing 58 and approximately 0.64 cm (1/4 inch) deep at the opposite end.

When assembling the rubber spring assembly with the chair, the tube 60 simply slid over the threaded end of rod 52 while the outer housing 58 abuts against the wall 64. The threaded one Hand wheel 74 engages the threaded end of rod 52, and while the wheel 74 is screwed onto the rod, the shoulder 78 abuts the tube 60 to apply an axial force to the tube 60. Since the tube 60 with the rubber spring 56 is connected, which in turn with the case 58 is connected and the housing is held by the wall 64, this pulls Force the rod 52 to the left and rotate the side plates 34, support arms 22 and the backrest 26 in a clockwise direction about the axis of the rod 38.

This force is used to adjust the backrest and the seat, what is usually called biasing the chair to hold the backrest in place in a substantially upright position. This force acts on the weight of the seat and the backrest, which goes through the center of mass on the right side the axis of the rod 38 acts. Essentially, screwing in the handwheel turns 74 the backrest and the seat counterclockwise until the nose 46 the Wall 32 touches and thereby a movement of the holder component 36 in the corresponding Direction prevented. The 'force that the backrest has in the upright position holds, is stored in the spring 46 by a certain movement of the tube 60 to the right relative to the housing 58, as can be seen in Figures 4 and 5, by one to generate longitudinal shear stress in the rubber.

A person sitting on the chair exerts a force against it when leaning back the backrest 26 and the underside of the seat 24 off, causing a rotational movement of side plates 34 is generated clockwise about the axis of rod 38, such as can be seen in FIG. This force pulls the bolt head 70 and the rod 52 afterwards right, pulling handwheel 74 and tube 60 in the same direction will. Since the outer housing 58 is held by the stator member and cannot move, an additional force is applied to the biasing force Rubber applied to resist tipping or rotating, as indicated by arrows 84 and 86 is displayed in FIG.

It is noted that the tube 60 and the rubber spring 56 are during the rotational movement of the holder member 36, for example, to a position such as by the dashed lines 88 and 80 are indicated in Figure 5, the recessed Outline at one end becomes even deeper in relation to the corresponding end of the Housing 58 as indicated by line 88 and the other contour being relative becomes straighter as shown by line 90. It's a force of 180 pounds (pounds) required to axially deflect pipe 0.32 cm (1/8 inch) or to move so that forces of 800 to 1000 pounds, e.g. near the axis of rotation exerted by the chair back, the tube 60 approximately 2.54 cm (1 inch) deflect. Full deflection of tube 60 causes the recessed ends 80 and 82 of the rubber spring 56 assume the outlines generally indicated by the dashed lines Lines 88 and 90 are shown.

The deflection force creates a longitudinal shear stress in generated by the rubber spring, but there the shear stress over the large in the same plane lying cylindrical contact surfaces between the rubber spring 56 and the housing 58 and distributed between the spring 56 and the tube 60, the load is per Unit area is relatively small, and the adhesion can be easily maintained will. The longitudinal shear stress allows an extremely long life of the Rubbers to, while the recessed or concave surfaces 80 and -82 to the corresponding Ends of the rubber spring 56 displacements of the rubber according to an axial movement of the tube 60 and absorb the effect of any small compressive force exerted on the rubber can be exerted between the tube and the housing, weaken.

When relieving the backward turning force, which is caused by the Sedentary is caused, the rubber spring component 56 is in its original Position reset, causing tube 60, handwheel 74, and rod 52 to the left be pulled to the holder member 36, the seat 24 and the backrest 26 in their normal position to rotate.

In Figures 6 and 7, another embodiment 100 is one Stool regulation according to the invention shown. Parts of Figures 6 and 7, which are in substantially similar to those parts shown in Figures 1-5 marked by corresponding reference numerals.

The chair regulator 100 has a U-shaped component or a holder body 102 on with substantially vertical side webs 104, which are approximately in the distance 2 inches and a horizontal rear wall 106. One Rubber spring assembly 54 is attached to rear wall 106 and falls off this off, this arrangement being an annular outer housing or wall 108, an annular rubber spring 56 pressed against the inner surface of the housing 108, and an inner tube 60 pressed against the inner surface of the spring 56.

The housing 108 is with its upper end on the lower surface of the Wall 106 is attached, e.g., by a weld joint, and is substantially the same as housing 58 with the exception of an annular projection 110 at its lower end with a slightly smaller radius than the housing 108, to form a small shoulder 112 for the lower edge of the outer surface of the Rubber spring 56. The approach 110 ends in a radial wall 114, to which an annular stand receiving member 116 is connected to the stand 16 to record. The stand 16 and the component 116 can have corresponding Morse tapers to create a backup fit between them, and will for example carried by a pedestal 12.

The upper end of the tube 60, as seen in Figures 6 and 7, extends through an opening 118 in wall 106 with a diameter which is slightly smaller than that of the housing 108, and is connected with a knurled Nut or handwheel 120 which is pushed up by normal tension the rubber spring 56 which is held between the housing 108 and the tube 60. A stud screw 122 screwed through the nut 120 is therefore also after pressed up. The. Stud 122 has a ring at its upper end, rotatable connected with a bolt 124.

The bolt 124 is through gaps 126 of a bow or crank arm 128 having an annular portion 130 surrounding a retainer component or tube 132, guided. A set screw 134 which extends through the annular part 130 extends, attaches the crank arm 128 to the tube 132 so that the crank arm 128 Exerts pressure on the stud 122, corresponding to the rotation of the tube 132, with the stud bolt no less than 1.81 cm (1 1/2 inches) backward from the pipe axis is arranged.

The tube 132 becomes rotatable through openings in the vertical webs 104 of the component 102 passed through and is provided with recesses 136 on the opposite Provided ends. The tube ends in collision with the support arms 22, which approximately 8.57 3 3/8 inches (cm) apart, with recesses 136 engage in corresponding lugs 138 on the vertical webs of the support arms are provided. The support arms 22 in turn carry the seat and the backrest. A bolt 140 with a head at one end is inserted through openings in both support arms 22 between the corresponding lugs 138 and through the tube 132. A mother 142, which is attached to the stud end opposite the head end, attached the support arms 22 to the tube 132 so that movement of the support arms through the lugs 138 and corresponding recesses 136 onto the tube 132 and through the Set screw 134 on crank arm 128 is transferred to the stud screw 122 to move about the axis of stud 140. One sitting on the chair leaning backwards or in a clockwise direction, as in Figures 6 and 7 7, the support arms 22, tube 132 and crank arm 128 rotates about the Axis of the stud screw 140 to move the bolt 124 downwards together with the stud bolt 122, which in turn pushes the nut 120 down against the pipe 60 presses to apply longitudinal shear stress to the rubber, as explained above. The backward rotary movement is continued until the support arms abut the upper rear surfaces 142 of the webs 140, which act as a stop serve for the support arms 22. In the case of the backward rotary movement, it is noted that the torque on a vertical axis, substantially coincident with that Stand axis, is transferred, so that the advantage of the relatively heavy stand is used to withstand the tipping force and that the chair is stabilized against tilting of the pedestal.

When the backward tilting force is canceled, the rubber spring takes 56 returns to its normal position, forcing the nut 120 and stud bolt 122 up to rotate the support arms forwards or counterclockwise, as seen in Figures 6 and 7, until the support arms hit the front upper surfaces 144 of the webs 104 abut to limit further forward tilting.

It is noted that the nut 120 is set on the stud 122 is used to properly preload the chair by applying pressure against the tube 60 will adjust the chair seat and the backrest in the desired horizontal and vertical Position. A hub 148 on nut 120 holds the nut and stud 122 properly centered with respect to tube 60.

Claims (12)

Claims 1. A spring assembly for use in a Chair adjustment suitable to be carried on a stand, and Built with a hold, swiveling by someone sitting in the chair, and with means, which are connected to the holder component, for a longitudinal, substantially linear movement corresponding to a rotary movement of the holder component, characterized by a rubber spring (56), part of which with the means (60) is connected to the means for the longitudinal movement of this connected part (52), and by means (58, 108) suitably fixed in relation to the stand (16) and are connected to the rubber spring (56) are in one layer at a distance from the above connected part, around the rubber spring (56) with a longitudinal To apply shear stress according to the movement in order to counteract this movement. 2. A spring assembly according to claim 1, characterized in that the means (60) associated with the holder member for substantially linear movement are connected in a direction parallel to the stator axis corresponding to the Move the rotational movement of the holder component (32, 22). 3. A spring arrangement according to claims 1 or 2, characterized in that that the rubber spring (56) has an annular shape with inwardly recessed ends. 4. A spring arrangement according to claims 1, 2 or 3, characterized in that that the connected means (60) are a pipe, which one with the inner Surface of the annular rubber spring is connected, and that the fixed means (58, 108) an annular housing (158, 108), which with the outer surface the annular rubber spring is connected. 5. A spring arrangement according to claim 2, characterized in that the movable means (60) is a tube and that the connecting means (60) is a Crank arm (130) connected to the holder component (22, 34) and means (122), rotatable connected to the crank arm (130), which abut one end of the tube (60). 6. A spring assembly according to claim 3, characterized in that the annular rubber spring (56) is recessed inwardly at opposite ends. 7. A spring arrangement according to claims 1 to 6, characterized in that that the movable means (60) comprise a rod (52) one end of which is rotatable is connected to the rotatable holder member (36) to allow axial movement of the To enable rod (52) corresponding to a rotary movement of the holder component (36), and the other end of which is screwed, and means (74, 120) in screwed connection with the opposite rod end to the rubber component between the housing and to apply a shear stress to the pipe, according to either the screw connection This means (74, 120) in a screwed advertising binding on the opposite one Rod end or the rotational movement of the holder component (36). 8. A spring assembly according to claim 5, characterized in that the tube has an outer diameter of 1.91 cm (3/4 inch), the inner surface the annular spring (56) is connected to the outer surface of the tube over a distance of substantially 2 1/4 inches and that the annular Housing (58, 108), which surrounds the rubber spring (56), has a diameter of im Substantially 4.45 cm (1 3/4 inches) and with the outer surface of the Rubber spring (56) is connected a distance of substantially 5.08 cm (2nd inches). 9. A spring arrangement according to claims 1 to 8, characterized in that that a shear stress of substantially 180 pounds (pounds) on the rubber component (56) is applied for every 1/8 inch (0.32 cm) movement of tube (60) relative to the housing (58, 108) in accordance with the rotational movement of the holder component. 10. A spring assembly according to claims 1 to 9 for use in a chair regulation with means for the rotatable support of the support arms the stand, characterized by a pair of spaced apart Struts (34, 104) carried by the stand (16) and rotatable by a tube (132) stored in these webs (34, 104), and by means (136, 138) that attach the pipe to attach the support arms (22). 11. A spring assembly according to claim 10, characterized in that that the support arms (22) are less than 8.89 cm (3 1/2 inches) apart are arranged, and that the webs (104) at a distance of less than 6.35 cm (2nd 1/2 inches) to each other. 12. A spring assembly according to claim 11, characterized in that that the axis of the spring (56) is less than 1.81 cm (1 1/2 inches) backward in the Relation to the rotatably mounted tube (132) is shifted.