The present invention relates to a keyboard support attachable to an underside of a workstation work surface and, more particularly, to a keyboard support providing both height and tilt adjustment of a keyboard with respect to the work surface.
Various keyboard support designs have been proposed for movably supporting a computer keyboard which is part of a computer workstation. Generally, the workstation includes a work surface that supports a computer monitor. The keyboard support typically includes a workstation engaging member, a keyboard engaging member, and a mechanical linkage between the workstation engaging member and the keyboard engaging member.
The workstation engaging member is attached to an underside of the work surface and the keyboard engaging member supports a planar keyboard support surface on which the keyboard is disposed. The linkage permits relative movement of the keyboard engaging member with respect to the workstation engaging member.
For ergonomic reasons, it is desirable the keyboard support surface be adjustable both in terms of vertical position or height and orientation or tilt angle with respect to the work surface. Various designs have been proposed for keyboard supports wherein the keyboard support surface has both height and tilt angle adjustability with respect to a work surface. One such design is disclosed in U.S. Pat. No. 6,450,467 to Timm, which is assigned to the assignee of the present invention. The '467 patent is incorporated herein in its entirety by reference. Other examples of keyboard supports include the supports disclosed in U.S. Pat. Nos. 5,145,136 to McConnell and 5,881,984 to Lin.
One area of continuing attention and potential improvement is that of the braking assembly of a keyboard support. The braking assembly of a keyboard support allows a user of the keyboard support to move the keyboard support surface (and thereby the keyboard) to a desired height relative to the work surface and then lock the support at the desired height. The braking assembly may also allow the user to adjust the tilt angle of the keyboard support surface. The braking mechanism must be easy to use allowing a user to easily adjust the keyboard support surface to a desired height and, at the same time, must have a positive locking capability such that once the keyboard support surface is at the desired height and in the locked position, pressure applied to the keyboard during use will not cause the support to move.
Additionally, the braking mechanism must be rugged, since the keyboard support surface extends outwardly and away from the workstation work surface and, therefore, is prone to being hit or bumped by the user or others in the area. Further, the keyboard support must be durable. While a user may expect his or her computer system to be replaced every few years because of technological advances, a user will generally expect a keyboard support to last for many years. Finally, since a keyboard support is an extra cost, add-on feature to most computer workstations, it must be economical and cost-effective to manufacture such that the keyboard support can be competitively priced.
What is needed is a keyboard support that permits vertical height and tilt adjustment of the keyboard support surface. What is also needed is a keyboard support with a braking assembly that provides easy vertical adjustment of the keyboard support surface and positive locking of the support surface once a desired height is ascertained. What is also needed is keyboard support wherein the braking assembly is durable. What is also needed is a keyboard support that is cost efficient to manufacture.
The present invention concerns a keyboard support for movably supporting a keyboard with respect to a work surface of a workstation. In one illustrated embodiment, the keyboard support includes a workstation engaging member adapted to be attached to an underside of the work surface, a keyboard engaging member for supporting a keyboard, a linkage assembly mechanically coupling and providing relative movement between the workstation engaging member and the keyboard engaging member and thereby between the keyboard and the work surface, and a braking assembly adapted to allow relative movement of the keyboard engaging member with respect to the workstation engaging member in an unlocked position and to prevent relative movement of the keyboard engaging member with respect to the workstation engaging member in a locked position.
The keyboard engaging member includes a generally planar keyboard support surface whose position and orientation are controlled to control a position and orientation of the keyboard with respect to the work surface of the workstation. The keyboard engaging member includes two parallel side pieces spaced apart by and extending rearwardly from a center section. Extending above the center section is the keyboard support surface. The side pieces define aligned slots on opposite sides of the center section and aligned holes on opposite sides of the center section wherein the aligned holes are disposed vertically above the aligned slots.
The workstation engaging member is attachable to an underside of the work surface and includes two parallel side pieces spaced apart by a center section.
The linkage assembly includes a first support member having one end rotatably mounted to the workstation engaging member and including a body portion that extends away from the workstation engaging member at a controlled angle. The first support member includes an arcuate slot and a hole spaced from the arcuate slot at an end spaced from the end that is rotatably mounted to the workstation engaging member.
The linkage assembly further includes a second support member having one end rotatably mounted to the workstation engaging member and including a body portion that extends away from the workstation engaging member at a controlled angle. The second support member includes a hole at an end spaced from the end that is rotatably mounted to the workstation engaging member.
The linkage assembly further includes a first connector passing through the arcuate slot in the first support member, the aligned slots of the keyboard engaging member, and the hole passing through the second support member and a second connector passing through the aligned holes of the keyboard engaging member and the hole of the first support member.
The braking assembly includes a wedge and a roller assembly. The wedge is affixed to one side of the keyboard engaging member and includes a slot aligned with one of the arcuate slots of the keyboard engaging member. The wedge includes an inclined surface extending rearwardly from a higher end spaced further outwardly from the keyboard engaging member side to a lower end. The wedge slot extends along the inclined surface from near the higher end towards the lower end.
The roller assembly is carried on the first connector and includes at least one roller. The roller assembly is biased against the wedge for adjusting frictional force between the first and second support members, the further outwardly the roller assembly is urged the greater the pressure applied by the roller assembly against the wedge and the greater the frictional force between the first and second support members.
As the keyboard support surface is pivoted downwardly about the second connector, the wedge moves rearwardly. The roller assembly roller rolls along the inclined planar surface from a first unlocked position to a second locked position. When moving from the first unlocked position to the second locked position, the roller assembly is urged outwardly with respect to keyboard engaging member side, thereby applying increased pressure to the first and second support members to prevent relative movement between the keyboard engaging member and the workstation engaging member.
As the keyboard support surface is pivoted upwardly about the second connector, the wedge moves forwardly. The roller assembly roller rolls along the inclined planar surface from the second locked position to the first unlocked position. When moving from the second locked position to the first unlocked position, the roller assembly moves toward the keyboard engaging member side, thereby reducing pressure applied to the first and second support members and to allow relative movement between the keyboard engaging member and the workstation engaging member.
The roller assembly is biased against the wedge by a spring disposed between the roller assembly and a tilt adjustment knob threaded onto a threaded end of the first connector. To change an orientation or tilt angle of the keyboard support surface when the braking assembly is in the locked position, the keyboard support surface is pivoted slightly upwardly to a position intermediate a position of the keyboard support surface when the braking assembly is in the locked position and a position of the keyboard support surface when the braking assembly is in the unlocked position to slightly reduce the pressure applied by the roller assembly against the wedge. The tilt adjustment knob is then rotated. Rotating the tilt adjustment knob in a counterclockwise direction reduces a pressure of the roller on the wedge thereby tilting the keyboard support surface downwardly. Rotating the tilt adjustment knob in a clockwise direction increases the pressure of the roller on the wedge thereby tilting the keyboard support surface upwardly. The slight upward pivoting of the keyboard support surface reduces the frictional engagement braking forces sufficiently to permit movement of the roller along the wedge.
These and other objects, advantages, and features of the exemplary embodiment of the invention are described in detail in conjunction with the accompanying drawings.
For ease of description, but not by way of limitation, a forward direction will be presumed to be a horizontal direction H toward a user of the keyboard 12, a rearward direction will be opposite the forward direction. Outward to the right will mean a horizontal direction away from a centerline C-C through the support 10 to the user's right (shown as HR in
The keyboard engaging member 20 (best seen in
The workstation engaging member 30 (best seen in
A spin rivet 36 extends through aligned openings in the bracket 32 and an upper planar surface 38 of the bracket 32 to rotatably affix the bracket 32 to the flange 34. This allows the keyboard support 10 to be pivoted about the rivet 36 to either the left or right side of the user, if desired. It should also be noted that instead of the flange 34 being mounted directly to the underside 16 of the desk 14, if desired the flange 34 may be part of a carriage having ball bearing slides which slide within tracks of a housing affixed to the underside 16 of the desk as disclosed in the '467 patent to Timm referenced earlier. Alternately, instead of ball bearing slides, the carriage may utilize polymer slide bearings.
The linkage assembly 60 (best seen in
The linkage assembly 60 includes a lower bracket 62 and a pair of upper supports or arms 64a, 64b all pivotally supported by the downwardly extending supports 48a, 48b of the workstation engaging member 40. The supports 48a, 48b define the engagement between the workstation engaging member 40 and the linkage assembly 60.
At a rearward end, the upper pair of support arms 64a, 64b include aligned openings 68 that accommodate a bearing in the form of a rod 69 that is received in aligned openings 49 of the downwardly extending supports 48a, 48b. The upper support arms 64a, 64b pivot about the rod 69. A spring counterbalance assembly 100 (described below) includes a pair of counterbalance springs 102, 104 (described below) disposed around the rod 69 to assist the user in raising the keyboard engaging member 20. The rod 69 also supports a protective cover 78 that slides along the upper planar cross piece 67a of the lower bracket 62. The cover 78 helps to keep dirt and debris from the counterbalance assembly and also provides a pleasing aesthetic appearance.
The lower bracket 62 is rectangular in cross section and defines two lower support arms 66a, 66b bridged by top and bottom planar cross pieces 67a, 67b. The lower support arms 66a, 66b of the lower bracket 62 also define openings 70 that accommodate a bearing in the form of a second rod 74 that is also attached to the downwardly extending supports 48a, 48b.
At a forward end of the upper pair of support arms 64a, 64b, the arms include tabs 71 that define arcuate slots 72 and openings 73. A bearing rod or connector 74 extending through the openings 73 of the pair of elongated arms 64a, 64b and the openings 33 in the fingers 31 of the keyboard engaging member 20 to pivotally connect the keyboard engaging member 20 and the upper support arms 64a, 64b to allow relatively unrestricted relative rotation between the keyboard engaging member 20 and the workstation engaging member 40. A threaded bearing rod 75 extends through arcuate slots 32 in fingers 30 of the keyboard engaging member 20 and arcuate slots 72 in tabs 71 of the pair of upper elongated arms or supports 64a, 64b.
The angle between the workstation engaging member 40 and the pair of upper supports 64a, 64b and the pair of lower supports 66a, 66b determines the height of the keyboard 12 in relation to the desk 14. The angle between the workstation engaging member 40 and the upper and lower supports 64a, 64b, 66a, 66b is, in turn, determined by the position of threaded rod 75 along the arcuate slots 72. The workstation engaging member 40 extends away from the desk 14 in a direction generally parallel to the desk top or work surface 16. This corresponds to a maximum keyboard height adjustment for the support 10.
The braking system or assembly 80 provides for a locked condition and an unlocked condition. In the locked condition, the linkage assembly 60 is fixed such that there is no relative movement of the keyboard engaging member 20 with respect to the workstation engaging member 40. In the unlocked condition, the linkage assembly moves or pivots so as to allow relative movement of the keyboard engaging member 20 with respect to the workstation engaging member 40.
As can best be seen in
The roller assembly 83 is slidably mounted on the threaded rod 75 and is biased inwardly to contact the wedge 82 by a bias spring 85 disposed between a flat bearing surface 86 of a tilt adjustment knob 87 and a stepped portion 88 of the hub 89 of the roller assembly 83. The bias spring 85 serves to hold the roller assembly 83 against the wedge 82 when the braking system 80 is in a disengaged or unlocked position. A hex head 76 of the threaded rod 75 bears against the finger 30 of the left hand side piece 28b. The tilt adjustment knob 87 includes internal threads 90 which are threaded onto a threaded distal end 77 of the rod 75. The wedge 82 includes an arcuate opening 91 which is aligned with the arcuate slot 32 in the right side piece finger 30. The wedge 82 increases in thickness moving from back 82a to front 82b. The rollers 84a, 84b are constrained to roll along an outer surface 92 of the wedge 82 and, more specifically, along a path of travel on the outer surface 92 adjacent the arcuate opening 91 of the wedge 82 because the threaded rod 75 extends through the arcuate opening 91.
A position of the rollers 84a, 84b on the outer surface 92 of the wedge 82 determines the force applied by the flat bearing surface 86 of the tilt knob 87 to the roller assembly hub 89 (
The roller position with respect to the wedge 82 can best be seen in the views shown in
In this braking position, the frictional engagement force between the outer surface of forward end portion of the upper elongated support arms 64a, 64b and the inner surface of the pair of fingers 30, 32 extending from the side pieces 28a, 28b of the keyboard engaging member 20 and between the inner surface of the forward end portion of the upper support arms 64a, 64b and the outer surface of a forward end portion the two lower support arms 66a, 66b of the bracket 62 is sufficient to prevent the keyboard engaging member 20 from pivoting with respect to the bearing rod 74. There is also a braking force generated by the contact of the rollers 84a, 84b to the contact surface 93 of the wedge 82 because a contact angle between the rollers 84a, 84b and the wedge 82 functions to oppose relative movement of the rollers 84a, 84b along the wedge 82. Since the upper support arms 64a, 64b and the lower supports arms 66a, 66b cannot move with respect to each other, the keyboard engaging member 20 is locked in position with respect to the workstation engaging member 40, thus, the braking assembly 80 is in the locked condition.
In
It should be noted, however, that an any position of the rollers 84a, 84b along the wedge outer surface 92, including the position shown in
A downward pressure on the keyboard engaging member 20 and specifically the front portion 20a, tends to rotate the keyboard support surfaces 22a, 22b in a counterclockwise direction (shown as CC in
To adjust the height of the keyboard support surfaces 22a, 22b, the user rotates the keyboard engaging member 20 about the rod 74 in an upward direction (clockwise—shown as CW in
Even during the unlocking procedure, the bias spring 85 maintains some pressure on the roller assembly 83 so that the rollers 84a, 84b do not slip off or away from their path of travel along the periphery 93 of the wedge outer surface 92 adjacent the arcuate opening 91. Further, since the roller assembly hub 89 is rotatable coaxially with respect to the threaded rod 75, the rollers 84a, 84b exhibit a swiveling castor effect to insure that the rollers are aligned with respect to the wedge opening 91. When the user releases the keyboard engaging member 20, the rollers 84a, 84b roll forwardly along the wedge 82 providing increased frictional engagement between the upper and lower support arms 64a, 64b, 66a, 66b and the side pieces 28a, 28b of the keyboard engaging member 20 to lock the height of the keyboard engaging member 20. Movement of the rollers 84a, 84b with respect to the surface of the wedge 82 is approximately 0.9 inches laterally along the bearing face 93 of the wedge 82 and less than 0.1 inches axially along the rod 75 in moving between the locking and non-locking positions which is a result of a clearance space between the flat bearing surface 86 of the tilt knob 87 to the roller assembly hub 89 collapsing when going from a unlocked condition to a locked condition.
The tilt adjusting knob 87 (best seen in
As the knob 87 is rotated clockwise as viewed from the right hand side (
By the same token, as the knob 87 is rotated counterclockwise as viewed from the right hand side (
When the braking assembly 80 is in the locked condition, rotation of the tilt knob 87 in the counterclockwise direction (loosening the knob) will result in a positive tilt angle change in keyboard orientation. However, if the braking assembly 80 is in the locked condition, rotation of the tilt knob 87 in the clockwise direction (tightening the knob) will increase the frictional engagement forces of the linkage assembly 60. This will prevent a negative tilt angle change. In order to effect a negative tilt angle change in keyboard orientation, the front of the keyboard engaging member 20 would have to be pivoted upwardly, at least slightly, to somewhat loosen the linkage assembly 60 and thereby permit negative tilt angle change upon clockwise rotation of the knob 87.
It should be noted that the braking assembly 80 includes relative degrees of locking that are intermediate the locked condition and the unlocked condition. Stated another way, the frictional engagement forces of the linkage assembly 60 vary depending on the magnitude of force applied by the flat bearing surface 86 of the tilt knob 87 to the end 94 of the roller assembly hub 89.
One exemplary embodiment of a spring counterbalance assembly 100 (best seen in
The pair of upper support arms 64a, 64b is bridged by a rod 106. One end 102a of the left spring 102 is hooked under the rod 106, while the other end 102b of the left spring 102 bears against a bottom surface 50 of the unshaped clevis bracket 42. The left spring 102 thereby provides for a torsion which tends to raise or upwardly pivot the elongated arms 64a, 64b about the rod 69 and thereby raise the keyboard engaging member 20.
One end 104a of the right spring 104 is also hooked under the rod 106, while the other end 104b defines a loop 104c with a distal end 104d insertable into a selected one of three positions corresponding to the three slotted openings 51a, 51b, 51c in the right side downward support 48a. As seen in
As seen in
Finally, as seen in
Depending upon the size and shape of specific keyboard 12 selected by the user and the seating arrangement used by the user, under certain conditions it may be ergonomically advantageous to prevent too great a positive tilt of the keyboard support surface 22. Additionally, too great a positive tilt may result in the keyboard accidentally sliding off of the keyboard rest 26. Accordingly, a tilt lockout member 120 is provided. As can best be seen in
The lockout member 120 is adapted to be pivoted between a lockout position and a non-lockout position. An opening 122 of the tilt lockout member 120 receives the hex-headed end 76 of the rod 75 and a shoulder 124 of the tilt lockout member prevents the tilt lockout member from falling off the hex-headed end 76. The lockout member 120 includes an inwardly extending arm 126 which is adapted to extend into the arcuate slot 32 of the left side finger 31.
When tilt lockout member 120 is positioned with respect to the rod 75 such that the arm 126 extends into the arcuate slot 32 forwardly (toward the user) of the rod, as seen in
As can be seen in
To move the tilt lockout member 120 from one position to the other, the tilt knob 87 is sufficiently loosened, such that a distance between tilt lockout member 120 and the finger 31 is sufficient to allow the arm 126 of the tilt lockout member 120 clear the arcuate slot 32 which is achieved by pulling on the tilt lockout member 120 outward to the left (shown as HL in
To make it easier for the user to determine whether the tilt lockout member 120 is in the lockout position or the non-lockout position, the tilt lockout member 120 includes a raised peripheral portion 128 with indicia. When the raised peripheral portion 128 is oriented upwardly (
The keyboard support of the present invention includes a tilt gauge assembly 140 which provides the user an easily readable indication of the current tilt angle of the keyboard 12. As can best be seen in
The cover 142 is sized to fit firmly in position over the side pieces 28a, 28b of the keyboard engaging member 20 and includes a pair of forwardly extending ears 146 extending from opposite sides of the cover which fit snugly against the side pieces 28a, 28b and under the rearward portion of the keyboard support surfaces 22a, 22b. A J-shaped hook 148 extends downwardly from an inner surface 150 of a top side 152 the cover 142 and snap fits over the rod 74 to hold the cover in place.
The parallelogram linkage 144 includes a base 154 that is anchored to and extends through a slotted opening 156 in a front side 158 of the cover 142. Extending from the base are spaced apart horizontal beams, a bottom beam 162 and a top beam 164. The bottom beam 162 comprises a lower portion 174 of a stationary member 166 and a lower portion 176 of an offset movable member 168 coupled by a lower pivot member 170. The stationary member 166 is stationary with respect to the base 154, while the movable member 168 is movable with respect to the base 154. The top beam 164 comprises an upper portion 178 of the stationary member 166 and an upper portion 180 of the movable end member 168 coupled by an upper pivot member 172.
The lower pivot member 170 is pivotally connected by a hinge at one end to the lower portion 174 of the stationary member 166 and is pivotally connected by a hinge at an opposite end to the lower portion 176 of the movable end member 168. The upper pivot member 172 is pivotally connected by a hinge at one end to the upper portion 178 of the stationary member 166 and is pivotally connected by a hinge at an opposite end to the upper portion 180 of the movable end member 168.
A rearward face 182 of the movable end member 168 abuts and bears against the threaded rod 75. A biasing spring 184 coupled to a horizontally extending arm 186 of the upper pivot member 172 biases the movable end member 168 rearwardly against the threaded rod. As the planar keyboard support rest 26 of the keyboard engaging member 20 is tilted with respect to the desk 14, the workstation engaging member 40 and the threaded rod 75 remain stationary. Since the stationary member 166 is mounted to the cover 142 and since the cover is mounted to the keyboard engaging member 20, the stationary member 166 pivots with the keyboard engaging member 20 about the rod 74. However, the movable end member 168 abuts the threaded rod 75. The threaded rod 75 does not move when the tilt angle of the keyboard engaging member 20 is changed. The movable end member 168 slides and rotates relative to the threaded rod 75, however, the movable end member 168 remains tangent to the cylindrical outer surface of the threaded rod 75 at all times. Thus, a dynamic line of contact between the movable end member 168 and the threaded rod 75 does not move radially forward or rearward with respect to the rod 75. Accordingly, changing the angle of tilt of the keyboard engaging member 20 causes a distance between the stationary member 166 and the movable end member 168 (along a longitudinal axis L-L of the parallelogram 144) to change. Changing the distance between the stationary member 166 and the movable end member 168 causes the upper and lower pivot members 172, 170 to pivot on their respective hinges.
Extending from the upper pivot member 172 is an upwardly angled arm 188 terminating in a pointer needle 190. The pointer needle 190 extends through a slotted opening 192 in the top side 152 of the cover 142. As the tilt angle of the keyboard engaging member 20 changes, as explained above, due to the geometry of the parallelogram linkage 144, the upper pivot member 172 pivots (as does, of course, the lower pivot member 170). As the upper pivot member 172 pivots, the pointer needle 190 moves along the arcuate slotted opening 192. Tilt angle indicia 194 are printed along an edge of the slotted opening 192 to indicate the angle of tilt. To read the tilt angle, the user merely glances at the position of the pointer needle 190 and reads the value from the indicia 194 that is aligned with the pointer needle 190. The value of indicia aligned with the needle 190 corresponds to the present tilt angle of the keyboard engaging member 20. Basically, the tilt gauge assembly 140 converts the longitudinal movement of the movable end member 168 resulting from contact with the threaded rod 75 as the tilt angle is changed into an angular deflection of the needle 190.
It is appreciated that while a preferred embodiment of the invention has been described, it is the intent that the invention include all modifications and alterations from the disclosed design falling within the spirit or scope of the appended claims.
Number | Date | Country | |
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Parent | 11336737 | Jan 2006 | US |
Child | 12428700 | US |