Office furniture abstract
A chair, or other office furniture device, includes a first and
second support member. The first support member has a longitudinal
extent and a fluid passageway formed within at least a portion thereof.
A first piston, having a first and second end, is moveably disposed
in the fluid passageway. The second support member is coupled to
the first end of the first piston. A fluid supply is disposed in
the fluid passageway and communicates with the second end of the
first piston. A pressure is applied to the fluid supply. A fluid
flow controller controls a flow of the fluid supply and is operable
between at least an open and closed position, wherein the fluid
supply is allowed to flow when the controller is in the open position
and wherein the fluid supply is not allowed to flow when the controller
is in the closed position. In one preferred embodiment, the fluid
supply comprises a magneto-rheological fluid, and the controller
comprises a magnet moveable between at least a first and second
position, wherein the magnet applies a magnetic field to the fluid
supply when in the first position. In an alternative preferred embodiment,
the fluid supply comprises a hydraulic fluid, and the controller
comprises a valve moveable to an open position to allow the fluid
supply to flow between the first and second positions. A method
for moving a chair component is provided, along with a method for
moving a support member on an office furniture device.
Office furniture claims
What is claimed is:
1. A chair comprising: a first and second support member, said
first support member having a fluid passageway formed within at
least a portion thereof; a first piston moveably disposed in said
fluid passageway, said first piston having a first and second end,
wherein said second support member is coupled to said first end
of said first piston; a fluid supply disposed in said fluid passageway
and communicating with said second end of said first piston; a second
piston having a first end and a second end, wherein said second
end communicates with said fluid supply; a force applying element
biasing said first end of said second piston; and a fluid flow controller
controlling a flow of said fluid supply at a location between said
first and second pistons, wherein said controller is operable between
at least an open and closed position, wherein said fluid supply
is allowed to flow between said first and second pistons when said
controller is in the open position and wherein said fluid supply
is prevented from flowing between said first and second pistons
when said controller is in the closed position.
2. The invention of claim 1 wherein said fluid supply comprises
a magneto-rheological fluid.
3. The invention of claim 2 wherein said controller comprises a
magnet moveable between at least a first and second position corresponding
to said open and closed positions respectively, wherein said magnet
applies a magnetic field to said fluid supply when in said first
position.
4. The invention of claim 3 further comprising an actuator connected
to said magnet, wherein said actuator is operable between at least
a first and second position, wherein said actuator moves said magnet
to said first position when said actuator is in said first position
and wherein said actuator moves said magnet to said second position
when said actuator is in said second position.
5. The invention of claim 4 wherein said magnet is moveable along
a linear path.
6. The invention of claim 5 wherein said magnet moves along a track
between said first and second positions to said first support member.
7. The invention of claim 1 wherein said fluid supply comprises
a hydraulic fluid.
8. The invention of claim 1 wherein said controller comprises a
valve.
9. The invention of claim 1 wherein said fluid passageway is a
first fluid passageway and wherein said first support member further
comprises a second fluid passageway, wherein said second piston
is movably disposed in said second fluid passageway.
10. The invention of claim 9 wherein said first and second fluid
passageways are connected with a third fluid passageway, wherein
said fluid supply flows through said third fluid passageway between
said first and second fluid passageways.
11. The invention of claim 1 wherein said second support member
comprises a chair component.
12. The invention of claim 11 wherein said second support member
is slideably connected to said first support member.
13. The invention of claim 11 wherein said chair component is integrally
formed with said second support member.
14. The invention of claim 11 wherein said chair component comprises
an armrest member.
15. The invention of claim 1 wherein said first support member
comprises a one-piece member having an interior surface defining
said fluid passageway.
16. The invention of claim 1 wherein said force applying element
comprises a spring.
17. The invention of claim 1 wherein said force applying element
comprises a positive pressure.
18. The invention of claim 1 wherein said second piston is slideably
disposed in said fluid passageway, and wherein said fluid supply
is disposed in said fluid passageway between said first and second
pistons.
19. A chair comprising: a support member having a first and second
fluid passageway formed within at least a portion thereof; a first
piston slideably disposed in said first fluid passageway, said first
piston having a first and second end; a second piston slideably
disposed in said second fluid passageway, said second piston having
a first end and a second end; a fluid supply flowing between said
first and second fluid passageways and communicating with said second
ends of said first and second pistons; a fluid flow controller controlling
a flow of said fluid supply.
20. The invention of claim 19 wherein said first and second fluid
passageways are parallel.
21. The invention of claim 19 wherein said fluid is a magneto-rheological
fluid.
22. The invention of claim 21 wherein said controller comprises
a magnet moveable between at least a first and second position corresponding
to said open and closed positions respectively, wherein said magnet
applies a magnetic field to said fluid supply when in said first
position.
23. The invention of claim 22 further comprising an actuator connected
to said magnet, wherein said actuator is operable between at least
a first and second position, wherein said actuator moves said magnet
to said first position when said actuator is in said first position
and wherein said actuator moves said magnet to said second position
when said actuator is in said second position.
24. The invention of claim 22 wherein said magnet is moveably disposed
in said support member.
25. The invention of claim 19 wherein said fluid is a hydraulic
fluid.
26. The invention of claim 25 wherein said controller comprises
a valve.
27. The invention of claim 19 further comprising a chair component
connected to and moveable with one of said support member and said
first piston.
28. The invention of claim 27 wherein said support member comprises
a first support member and further comprising a second support member
slideably connected to said first support member, and wherein at
least one of said chair component and said first piston is connected
to said second support member.
29. The invention of claim 19 further comprising a spring biasing
said second piston.
30. The invention of claim 19 wherein said support member comprises
a one:piece member having an interior surface defining said first
and second fluid passageways.
31. An office furniture device comprising: a support member having
a fluid passageway formed within at least a portion thereof; a piston
moveably disposed in said fluid passageway and having a first and
second end; a magneto-rheological fluid disposed in said fluid passageway
and communicating with said second end of said piston; a magnet
moveable between at least a first and second position, wherein said
magnet applies a magnetic field to said magneto-rheological fluid
when in said first position; an actuator connected to said magnet,
wherein said actuator is operable between at least a first and second
position, wherein said actuator moves said magnet to said first
position when said actuator is in said first position and wherein
said actuator moves said magnet to said second position when said
actuator is in said second position.
32. The invention of claim 31 wherein said magnet is moveably disposed
in said support member.
33. The invention of claim 31 wherein said magnet is moveable along
a linear path.
34. The invention of claim 31 further comprising a shuttle member
supporting said magnet, wherein said actuator is connected to said
shuttle member, and wherein said shuttle moves along a track.
35. The invention of claim 31 wherein said actuator comprises a
spring biasing said magnet between said first and second positions.
36. The invention of claim 35 wherein said actuator further comprises
a push rod connected to said magnet.
37. The invention of claim 34 wherein said magnet is disposed in
said shuttle.
38. The invention of claim 31 wherein said magnet is rare earth
magnet.
39. The invention of claim 30 wherein said support member forms
part of an armrest on a chair.
40. A method for operating a chair comprising: providing a first
and second support member, said first support member having a fluid
passageway formed within at least a portion thereof; providing a
first piston moveably disposed in said fluid passageway, said first
piston having a first and second end, wherein said second support
member is coupled to said first end of said first piston; providing
a fluid supply in said fluid passageway, wherein said fluid supply
communicates with said second end of said first piston; providing
a second piston having a first end and a second end, wherein said
second end communicates with said fluid supply; stopping a flow
of said fluid supply at a location between said first and second
pistons with a fluid flow controller; operating said controller
in an open position and thereby allowing said fluid supply to flow
past said location between said first and second pistons; and applying
a force to said first end of said second piston and thereby flowing
said fluid past said location between said first and second pistons.
41. The invention of claim 40 wherein said stopping said flow further
comprising operating said controller in a closed position.
42. The invention of claim 40 further comprising applying a force
to said first end of said first piston.
43. The invention of claim 40 wherein said applying a force to
said first end of said second piston comprises biasing said first
end of said second piston with a spring.
44. The invention of claim 40 wherein said fluid supply comprises
a magneto-rheological fluid.
45. The invention of claim 44 wherein said operating said controller
in said open position comprises moving a magnet adjacent said fluid
supply and thereby applying a magnetic field to said fluid supply.
46. The invention of claim 45 wherein said moving said magnet comprises
moving an actuator connected to said magnet between at least a first
and second position.
47. The invention of claim 40 wherein said fluid supply comprises
a hydraulic fluid, and wherein said operating said controller in
said open position comprises opening a valve to an open position.
48. The invention of claim 40 wherein said fluid passageway is
a first fluid passageway and wherein said first support member further
comprises a second fluid passageway, wherein said second piston
is moveably disposed in said second fluid passageway.
49. The invention of claim 40 wherein said second support member
comprises a chair component.
50. The invention of claim 49 wherein said chair component comprises
an armrest member.
51. The invention of claim 50 wherein said fluid passageway is
extruded in said first support member
52. A method for operating an office furniture device comprising:
providing a support member having a fluid passageway formed within
at least a portion thereof; providing a piston moveably disposed
in said fluid passageway and having a first and second end; providing
a magneto-rheological fluid disposed in said fluid passageway and
communicating with said second end of said piston; moving a magnet
between at least a first and second position; and applying a magnetic
field with said magnet to said magneto-rheological fluid when said
magnet is in said first position.
53. The invention of claim 52 wherein said moving said magnet comprises
moving an actuator connected to said magnet.
54. The invention of claim 52 wherein said moving said magnet comprises
moving said magnet along a linear path between said first and second
positions.
55. The invention of claim 53 wherein said actuator comprises a
spring, and wherein said moving said magnet comprises biasing said
magnet with said spring.
56. The invention of claim 55 wherein said actuator further comprises
a rod connected to said magnet, and wherein said moving said magnet
comprises moving said rod in opposition to said biasing of said
spring.
57. The invention of claim 54 wherein said support member forms
part of an armrest on a chair.
58. A chair comprising: a first support member comprising a one-piece
member having at least one interior passageway running through a
portion thereof, wherein said interior passageway is defined by
an interior surface of said one-piece member; a piston slideably
disposed in said at least one interior passageway, said first piston
having a first and second end; a second support member coupled to
said first end of said first piston; a fluid supply disposed in
said interior passageway and communicating with said second end
of said first piston; and a pressure applied to said fluid supply.
59. The invention of claim 58 wherein said first support member
has a groove formed along at least a portion thereof, and wherein
said second support member slideably engages said groove.
60. The invention of claim 58 wherein said second support member
comprises an armrest member.
61. The invention of claim 58 wherein said piston comprises a first
piston and wherein said pressure comprises a second piston having
a first end and a second end, wherein said second end acts against
said fluid supply and wherein a force applying element acts against
said first end.
62. The invention of claim 58 further comprising a control system
operably connected to said fluid supply and operable between at
least an open and closed position, wherein said fluid supply is
allowed to flow when said control system is in the open position
and wherein said fluid supply is not allowed to flow when said control
system is in the closed position.
63. The invention of claim 58 wherein at least a portion of said
first support member is exposed to a user.
64. The invention of claim 58 wherein said first support member
with said passageway is formed as an extrusion.
65. A chair comprising: a support member having at least one interior
passageway running through a portion thereof, wherein said interior
passageway is defined by an interior surface of said support member,
said support member further comprising a groove formed along at
least a portion thereof; a piston slideably disposed in said at
least one interior passageway, said first piston having a first
and second end; a second support member coupled to said first end
of said first piston, wherein said second support member slideably
engages said first support member; a fluid supply disposed in said
interior passageway and communicating with said second end of said
first piston; and a pressure applied to said fluid supply.
66. The invention of claim 65 wherein said second support member
comprises a slide member slideably engaging said first support member
and a cover member connected to said slide member.
67. The invention of claim 65 wherein said second support member
comprises an armrest support.
Office furniture description
BACKGROUND
[0001] The present invention relates generally to a fluid control
system, and in particular, to a fluid control system for various
office furniture devices, including various chair components.
[0002] Typically, various office furniture devices, including for
example, chairs and worksurface members, are configured with moveable
support members. For example, office chairs generally can be configured
with moveable support arms, support columns, backrests and seats.
Likewise, worksurface members or assemblies often are configured
with moveable support legs and the like.
[0003] Often, the movement of such support members is controlled
with mechanical systems, including for example various ratchet mechanisms,
gear trains and the like. Typically, support members controlled
by such devices have some play in them due to the tolerance buildup
between the interconnected parts, such that the support members,
or components connected thereto, may feel loose to the user. Moreover,
many such devices have a limited number of adjustable positions,
and therefore are not infinitely adjustable. In addition, such systems
are passive, meaning that they typically require the user to move
the support member, or component supported thereon, between one
or more positions. Alternatively, when electromechanical devices,
including for example various screw devices, are used, a power source,
which can be expensive and bulky, must be provided.
[0004] Alternatively, the movement of the various support members
or components can be controlled with various pneumatic or gas spring
devices. Although such systems are active, meaning that they typically
are capable of moving the support member or component in at least
one direction without the assistance of the user, they generally
exert large amounts of pressure, which must be countered by the
user to move the support member or component in the opposite direction.
Moreover, such devices typically move rather quickly and the adjustment
thereof can feel erratic to the user.
[0005] In other alternatives, the movement is controlled with various
hydraulic devices. Often, office furniture devices employing hydraulic
devices are relatively heavy, and may require various power sources
for pumps and the like, both of which limit the portability of the
devices. In addition, such devices often include numerous lines,
seals and other parts, which can significantly add to the cost of
the device and which may require frequent, periodic maintenance.
SUMMARY
[0006] Briefly stated, in one aspect of the invention, a chair
includes a first and second support member. The first support member
has a fluid passageway formed within at least a portion thereof.
A first piston, having a first and second end, is moveably disposed
in the fluid passageway. The second support member is coupled to
the first end of the first piston. A fluid supply is disposed in
the fluid passageway and communicates with the second end of the
first piston. A second piston has a first end and a second end,
wherein the second end communicates with the fluid supply. A force
applying element biases the first end of the second piston. A fluid
flow controller controls a flow of the fluid supply and is operable
between at least an open and closed position, wherein the fluid
supply is allowed to flow between the first and second pistons when
the controller is in the open position and wherein the fluid supply
is not allowed to flow between the first and second pistons when
the controller is in the closed position.
[0007] In one preferred embodiment, the fluid supply comprises
a magneto-rheological fluid, and the controller comprises a magnet.
The magnet is moveable between a first and second position, wherein
the magnet applies a magnetic field to the fluid supply when in
the first position.
[0008] In an alternative preferred embodiment, the fluid supply
comprises a hydraulic fluid, and the controller comprises a valve.
The valve is moveable to an open position to allow the fluid supply
to flow between the first and second positions.
[0009] In a preferred embodiment, the support member comprises
a one-piece member having an interior surface defining the fluid
passageway. Also in a preferred embodiment, a second fluid passageway
is formed in the support member, and the second piston member is
slidably disposed in the second fluid passageway.
[0010] Preferably, one of the support members comprises a chair
component. For example, in one embodiment, the second support member
comprises an armrest member.
[0011] In another aspect of the invention, an office furniture
device comprises a support member having a fluid passageway formed
within at least a portion thereof and a piston slideably disposed
in said fluid passageway and having a first and second end. A magneto-rheological
fluid is disposed in the fluid passageway and communicates with
the second end of the piston. A magnet is moveable between at least
a first and second position, wherein the magnet applies a magnetic
field to said magneto-rheological fluid when in said first position.
An actuator is connected to said magnet and is operable between
at least a first and second position, wherein the actuator moves
the magnet to the first position when the actuator is in the first
position and wherein the actuator moves the magnet to the second
position when the actuator is in the second position.
[0012] In other aspects of the invention, a method for operating
a chair is provided, along with a method for operating an office
furniture device.
[0013] The present inventions provide significant advantages over
other office furniture devices and their respective control systems.
For example, by providing a support member having a fluid passageway
formed therein, the system can be greatly simplified. Moreover,
in a preferred embodiment, wherein the fluid passageway and controller,
or control system, are locally contained within or adjacent the
support member, various extraneous parts, such as conduit lines,
are avoided, thereby reducing the cost of the device and the expense
of maintaining it. Moreover, by using a simple force applying member,
the additional cost and weight associated with using various pumps
and electromechanical devices is avoided, thereby making the office
furniture component portable. In addition, such a mechanical system
avoids any interference with electrical devices such as computers.
At the same time, the use of a fluid control system, with a controller,
provides infinite adjustment of the device and a rigid feel when
in the closed position.
[0014] The use of a magneto-rheological fluid, together with a
moveable magnet, also provides significant advantages. For example,
the simple movement of the magnet between the first and second positions
can be used to apply a magnetic field to the magneto-rheological
fluid, which provides a very rigid feel to the device. In this way,
the use of various electrical circuits to create the magnetic field
is avoided, which in turn simplifies the device and eliminates the
need for a power source, which can interfere with the operation
of various office equipment, such as computers.
[0015] The present invention, together with further objects and
advantages, will be best understood by reference to the following
detailed description taken in conjunction with the accompanying
drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0016] FIG. 1 is an exploded perspective view of one embodiment
of an armrest assembly for a chair.
[0017] FIG. 2 is an exploded perspective view of an alternative
embodiment of an armrest assembly for a chair.
[0018] FIG. 3 is a front schematic view of the armrest assembly
shown in FIG. 2.
[0019] FIG. 4 is a perspective view of a control system assembly.
[0020] FIG. 5 is a perspective view of an upper portion of a base
member with a fluid conduit formed therein.
[0021] FIG. 6 is a top plan view of the base member shown in FIG.
5.
[0022] FIG. 7 is a top end view of a riser.
[0023] FIG. 8 is a top plan view of a housing.
[0024] FIG. 9 is a cross-sectional view of the housing taken along
line 9-9 in FIG. 8.
DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EMBODIMENTS
[0025] Referring to FIG. 1 an armrest assembly 100 is shown as
including a first and second longitudinally and vertically extending
support member 102 130. The term "longitudinal" means
of or relating to length or the lengthwise direction. The first,
or inner, support member includes a riser 3 and a base member 104.
The riser 3 is preferably an aluminum extrusion having a first and
second fluid passageway 106 108 formed therethrough. The first
and second fluid passageways 106 108 are preferably formed in the
riser along parallel paths, and are preferably cylindrical, although
they may be configured with alternative cross-sectional areas. Preferably,
the riser is a one-piece member having an interior surface defining
the fluid passageways 106 108 such that the interior surface is
in direct contact with a fluid supply, thereby avoiding the use
of liners, cylinders, etc. in the riser. Preferably, the diameter
of the second fluid passageway 108 is about twice that of the first
fluid passageway 106. In one embodiment, the diameters of the first
and second fluid passageways are about 0.25 inches and 0.50 inches
respectively. Preferably, the riser, with its fluid passageways,
is extruded, although it should be understood that the passageways
could be drilled or bored out. A recess 110 is formed on the bottom
end of the first support member at the entryway to the first fluid
passageway 106. The recess 110 is shaped to receive a seal member
4 e.g. an o-ring, which seals the interface between the riser 3
and the base member 104.
[0026] In the embodiment shown in FIGS. 1 and 7 the exterior profile
of the riser is generally elliptically shaped, and is preferably
configured with opposite convex outer side surfaces 112 and concave
outer end surfaces 114 which form grooves along the end of the
riser. After assembly, at least a portion of the riser is visible
to the user. In this way, the riser provides an aesthetically pleasing
structural support for the armrest, which is capable of handling
significant structural loading due to its extruded profile, and
which at the same time provides a passageway for various fluids.
[0027] A pair of openings 116 are formed in the top end of the
riser and are generally aligned with the first and second fluid
passageways 106 108 along the elongated dimension of the riser.
A pair of openings 118 also formed in the bottom end of the riser
opposite a central opening 121 and are aligned along an axis lying
substantially perpendicular to the elongated dimension. The central
opening 121 can be used as an alternative fluid passageway having
an alternative cross-sectional flow area.
[0028] Referring to FIGS. 1 and 4-6 the bottom end 120 of the
riser abuts the top surface 122 of an upper portion 4 of the base
member, which is preferably made of plastic. The upper portion 4
of the base member has a first opening 124 or passageway formed
therein that is aligned and communicates with the first fluid passageway
106 with the seal member 27 forming a seal between the riser 3
and the base member. The upper portion 4 of the base member further
includes a cylindrical boss member 126 extending upwardly from the
upper surface of the upper portion. A seal member 26 preferably
an o-ring, is disposed circumferentially around the boss member.
The boss member, with its seal member, is inserted into the second
fluid passageway 108 at the bottom end of the riser, such that the
seal member 26 engages the interior surface of the fluid passageway
and forms a seal therewith. An opening 128 or passageway formed
in the boss member communicates with the second fluid passageway
108.
[0029] As shown in FIGS. 5 and 6 a fluid conduit 130 or passageway
extends between and connects the passageways 124 128 formed in
the base member so as to form a continuous fluid passageway allowing
the fluid supply to flow between the first and second fluid passageways
106 108. An end of the conduit is plugged with plug 132 to prevent
fluid from escaping the system. A pair of fasteners 134 are used
to secure the base member to the riser 3 as they engage the openings
118 which are preferably threaded, formed in the bottom end of
the riser. It should be understood that the base member forms part
of the support member, and can be formed integrally with the riser
as a single unit. In such an embodiment, the fluid passageway is
simply formed as a continuous fluid passageway therein.
[0030] Referring to FIG. 1 the second support member includes
a slide member 5 that is slideably disposed on the outside of the
riser and has an interior opening 136 shaped to receive the riser,
including rib portions that engage the grooves formed in the riser.
The slide member includes a circumferential rib or raised portion
138 formed around a periphery thereof The slide member is preferably
made of a material having a low coefficient of friction and high
lubricity, such as Delrin. Other materials, including Ultra High
Molecular Weight Polyethylenes (UHMWPE) or other viscous plastics
would also work.
[0031] The second support member 130 further comprises a pair of
outer cover members 13 and a top plate 18 which forms part of an
armrest member. The cover members 13 are secured to one another
on opposite sides of the riser 3 and slide member 5 with fasteners
33 and clamp the slide member therebetween. The cover members 13
form a recess 140 that is shaped to receive the raised portion 138
of the slide member 5 such that the cover members are secured to
the slide member. The cover members are preferably made of aluminum,
although other metals or plastics, such as abs also could be used.
The top plate 18 is secured to the top of the cover members with
fasteners 9 that threadably engage holes 142 formed in the ends
of the covers. The top plate is preferably made of aluminum, although
other metals or plastics, such as ABS also could be used. It should
be understood that the cover members could be made as a single integral
member that directly slideably engages the riser, or alternatively,
that the cover members and the top plate can be integrally formed
as a single member.
[0032] Referring to FIG. 1 a piston 6 is slideably disposed in
the first fluid passageway 106 and includes a first end 144 and
a second end 146 with the first end 144 extending from the top
of the riser. The second end of the piston includes one or more
seals, preferably o-rings, disposed thereabout and which sealably
engage the interior surface of the fluid passageway. The first end
144 is secured to the cover members 13 of the second support member
with a pin 8. It should be understood that the piston 6 could be
secured to the second support member in alternative ways, such as
by directly securing the piston to the plate member, or by forming
the piston integrally with the second support member.
[0033] A second piston 30 is slideably disposed in the second fluid
passageway 108 and includes a first end 146 and a second end. A
seal member 7 is disposed around the piston and engages the interior
surface of the fluid passageway 108. A spring 29 is inserted in
the fluid passageway 108 on top of the second piston 30 and engages
the first end 146 thereof A retainer member 31 is then secured to
the riser in the end of the fluid passageway 108 to provide a backstop
for the spring 29 as it biases the second piston 30 downwardly in
the second fluid passageway 108.
[0034] A fluid supply is disposed in the continuous fluid passageway
formed by the passageways 106 108 130. A stop 16 is secured to
the top of the riser with a fastener 32. The stop 16 extends beyond
the profile of the riser 3 and engages the top of the slide member
5 so as to limit the upward travel of the second support member
relative to the first support member.
[0035] Referring to FIGS. 1 and 4 a fluid flow controller, or
control system 150 is operable between at least an open and closed
position, wherein the fluid supply is allowed to flow in the continuous
fluid passageway 106 108 130. A lower portion 17 of the base member,
which is preferably U-shaped, forms a passageway 148 or track in
the base member between the upper and lower portions 17 4. The
lower portion is preferably made of a material having a low coefficient
of friction and high lubricity, such as Delrin. Other materials,
including Ultra High Molecular Weight Polyethylenes (UHMWPE) or
other viscous plastics would also work.
[0036] In one preferred embodiment, the controller, or control
system, includes a shuttle member 19 that is dimensioned to be moveably
received in the passageway 148. The shuttle member 19 includes a
bore 152 formed in the upper surface 154 thereof. A magnet 10 preferably
cylindrical, is inserted into the bore, with a top surface 162 of
the magnet lying substantially flush with the upper surface 154
of the shuttle member 19. The magnet 10 is preferably a Rare Earth
magnet, which is a type of commercial permanent magnet.
[0037] Rare Earth magnets are composed of, for example, Samarium
Cobalt (SmCo) and Neodymium Iron Boron (NdFeB). SmCo magnets are
available in a number of different grades that span a wide range
of properties and application requirements. Ferrite magnets, which
are sintered permanent magnets composed of Barium or Strontium Ferrite,
also can be used. Alnico materials, composed primarily of alloys
of Aluminum, Nickel, and Cobalt also can be used. Typically, Alnico
magnets are manufactured by way of either a casting or a sintering
process. Cast magnets may be manufactured in complex shapes, e.g.,
horseshoe shapes, which may not be obtainable by other processes.
Sintered Alnico magnets offer slightly lower magnetic properties,
but better mechanical properties than cast Alnico magnets.
[0038] The shuttle member 19 and magnet 10 are moveable between
at least a first and second position. In the first position, the
shuttle 19 is disposed in the passageway 148 such that the magnet
10 lies directly under and adjacent to the fluid passageway. In
this position, the magnet 10 applies a magnetic field to the fluid
supply in the fluid passageway 130.
[0039] Preferably, in one embodiment, the fluid supply is a magneto-rheological
fluid, which essentially is a suspension of micron-sized, magnetizable
particles in oil. An exemplary magneto-rheological fluid is a Rheonetic.TM.
Magnetic Fluid available from the Lord Corporation. When the magnet
10 is in the second position, such that it is moved out of the passageway
148 and does not thereby apply a magnetic field to the fluid supply
in the fluid passageway 130 the magneto-rheological fluid is free-flowing
with a consistency similar to motor oil or hydraulic fluid. Exposure
to the magnetic field, which occurs as the shuttle is moved to the
first position, however, transforms the fluid into a near-solid
in milliseconds, thereby effecting a very large change in viscosity.
The change in the viscosity of the fluid is proportional to the
magnitude of the applied magnetic field. By applying the magnetic
field, the fluid in essence is solidified in the fluid passageway
130 and thereby locks the first and second piston in place, as the
fluid supply is prevented from flowing between the first and second
fluid passageways 106 108.
[0040] Referring to FIG. 1 a housing 2 includes a cavity 170 shaped
to receive a bottom end of the riser and the base member 104 which
is secured to the housing 2. The housing 2 further includes a passageway
172 aligned with the passageway 148 formed in the base member, such
that the shuttle can be moved to a second position out of the base
member passageway 148 and into the housing passageway 172. In this
way, the housing 2 and base member 104 with their perspective passageways
148 172 form a track for the shuttle. Although the movement of
the shuttle and magnet corresponds to a translation of the shuttle
and magnet along a linear path, it should be understood that those
members could also be rotated or pivoted between an open and closed
position.
[0041] The controller, or control system, further includes an actuator
180 that effects the movement of the magnet and shuttle. The actuator
includes a push rod 11 that is attached to one side of the shuttle.
On the opposite side of the shuttle, a spring 20 is disposed between
the shuttle 19 and an end wall 21 or retainer attached to or formed
on the housing 2. For example, fasteners 22 can be used to secure
the end wall 21. The spring 20 acts in opposition, either in compression
or tension, to the movement of the push rod, so as to bias the shuttle
into either a normally open or closed position. It should be understood
that the push rod 11 can be actuated by the user to move the shuttle
19 to the open or closed position, and that the push rod can be
further operably linked or coupled to other levers, buttons, etc.
(not shown), which can be located at a remote location and which
are accessible to the user. The housing can be secured to other
supporting structure 1 with fasteners 28 or can be integrally formed
therewith.
[0042] It should be understood that an electromagnet, such as a
solenoid or a coil that is electrified, can also be used to apply
a magnetic field to the fluid supply. In such a system, a power
supply is required to energize the device and to thereby form the
magnetic field.
[0043] In operation, the user moves the push rod 11 to move the
magnet 10 into the closed position adjacent the fluid supply, or
energizes the electromagnet, so as to create a magnetic field and
thereby magnetize the magneto-rheological fluid. In this position,
the armrest and in particular the second support member 130 is
locked in position. When the user desires to adjust the height of
the armrest, the actuator 180 is manipulated to move the push rod
11 and the connected magnet 10 to the open position. In this position,
the fluid is substantially isolated from the influence of the magnetic
field, such that the viscosity of the fluid allows it to flow in
the fluid passageway. To raise the armrest, the user simply allows
the spring 29 to act on and bias downwardly the second piston 30
which displaces the fluid supply from the second fluid passageway
108 to the first fluid passageway 106 and thereby acts on or raises
the first piston 6 and attached support member. To lower the armrest,
the user simply applies a force to the support member 130 and the
armrest member 18 in particular, which lowers the first piston 6
in the first fluid passageway 106 and displaces the fluid supply,
which acts on or raises the second piston 30 against the biasing
force of the spring 29.
[0044] It should be understood that instead of using a spring as
a force applying member, a positive pressure could be applied to
the first end 146 of the second piston 30 such as by a pump or
other device. In addition, it should be understood that the first
and second fluid passageways do not need to be made parallel, or
even as separate passageways. For example, a single linear passageway
could be configured with pistons disposed in opposite ends thereof
and with a control system regulating the flow of fluid therebetween.
It should also be understood that the position of the fluid passageways,
control system and pistons could be reversed, with the fluid passageways
and control system formed in a moveable second support member, and
with the piston connected to the first support member, which is
preferably stationary. Finally, it should be understood that in
an alternative embodiment, the second piston can be eliminated in
its entirety, wherein a positive pressure is applied directly to
the fluid supply, which acts on the first piston 6.
[0045] Referring to FIGS. 2 and 3 an alternative embodiment of
an armrest assembly is shown. In this embodiment, the riser 303
is secured to a laterally extending base member 304. The second
support member 330 includes an outer slide member having an opening
331 formed therethrough, which is shaped to mate with the exterior
contour of the riser, and an armrest member 332. The slide member
313 includes opposite rib portions 307 that engage grooves formed
along the sides of the riser 303. The armrest member 332 includes
a top plate 318 that is secured to the slide member and a pad 334
secured to the top plate. An actuator lever 336 is pivotally connected
to the armrest member 332.
[0046] In this embodiment, the riser 303 includes a single fluid
passageway 306 formed therethrough. A piston 406 is inserted in
the passageway 306 and includes a pair of seal members 408 that
engage the interior surface of the passageway. A top end 410 of
the piston 406 is connected to the second support member 330. A
conduit member 500 is connected to the bottom of the riser and communicates
with the fluid passageway 106. The conduit member 500 is connected
to a valve 502 which forms part of a fluid controller, or control
system 250. A second conduit member 504 is connected to and communicates
with a piston assembly 506 which includes a cylinder housing 508
and a piston 510 disposed therein. A spring 512 is disposed between
the end 514 of the housing and the piston 510 and biases the piston
510 within the housing 508. A fluid supply flows between the pistons
510 410 in the conduits 504 and fluid passageway 306.
[0047] In operation, the actuator lever 336 is pivoted to operate
the valve 502 between at least an open and closed position. In the
open position, fluid, preferably hydraulic fluid, is allowed to
flow between the pistons 510 410. To raise the armrest member 330
the spring 512 biases the piston 510 which displaces the fluid
and thereby raises the piston 410 in the riser 313. To lower the
armrest member, the user pushes on the armrest 330 to displace the
fluid in the passageway and which thereby moves the piston 510 against
the force of the spring 512. The valve 502 can be actuated by moving
the lever 336 which is operably connected thereto. It should be
understood that a single piston assembly 506 and valve 502 can be
operably connected to a pair of armrests, or to other members, as
shown in FIG. 2 or that individual piston assemblies and valves
can be separately connected to each component.
[0048] It should be understood that the controller, or control
system shown in FIG. 2 which includes a simple valve, could also
be used in the first embodiment. Conversely, the magnet and magneto-rheological
fluid controller shown in the first embodiment could be used in
the embodiment shown in FIG. 2 in place of the valve and hydraulic
fluid.
[0049] In another aspect of the embodiment shown in FIG. 2 the
laterally extending base member 304 which defines a support member,
is slideably disposed on a longitudinally and horizontally extending
support member 500 configured with a fluid passageway 506. The
support member 500 is supported on a supporting structure 520. It
should be understood that the base members 304 can be connected
to pistons (not shown) disposed in the fluid passageway 506 formed
in the support member 500 the lateral movement of which is controlled
by the various control systems herein described so as to provide
laterally adjustable armrests.
[0050] Although the aforedescribed embodiments have been directed
to vertically and laterally adjustable armrests, it should be understood
that the fluid control system, including the fluid passageway(s),
the piston and the control system, could also be used to adjustably
control other chair components or support members, including for
example the height and depth of a seat and the height of a backrest.
In addition, the fluid control system can be used to control the
relative movement between other office furniture support members,
including for example upper and lower support members forming a
support leg for a work surface.
[0051] Although the present invention has been described with reference
to preferred embodiments, those skilled in the art will recognize
that changes may be made in form and detail without departing from
the spirit and scope of the invention. As such, it is intended that
the foregoing detailed description be regarded as illustrative rather
than limiting and that it is the appended claims, including all
equivalents thereof, which are intended to define the scope of the
invention. |