1. Field of the Invention
The present invention relates generally to an adult walker for assisting the disabled or those who have difficulty ambulating and, more specifically, with an adult walker for seated or standing use. Even more specifically, this invention relates to an adult walker with provisions for incontinent persons.
2. Discussion of the Related Art
Adult walkers and wheelchairs are known in the art which assist the mobility of persons, such as the elderly or disabled, who are unable to walk or move around without assistance. These devices have improved the range of activity of such persons under conditions where available assistance by personnel is limited. A person requiring mobility assistance may also be incontinent, dictating a device which both provides mobility and security while accommodating incontinence needs and providing for the comfort of the user.
Wheelchairs are one method of providing mobility, and the prior art includes wheelchair commodes for use by incontinent persons. However, since the wheelchair provides no exercise or movement for legs, these muscles will atrophy more quickly and ultimately diminish the physical strength of the patient.
Various types of adult walkers are commonly used by elderly or disabled persons who have the capability of supporting their weight on their legs and walking, but cannot do so unassisted because of a tendency to stumble or fall. For example, elderly persons who reside in long-term care facilities frequently have a great need to exercise and to convey themselves from one location to another, but are afraid to do so without the assistance of an aid.
A wide variety of adult walkers have been devised for elderly or disabled persons. Adult walkers typically consist of a rigid frame supported on the floor. Numerous frame variations are found in the art. For the more ambulatory, the adult walker legs rest directly on the floor. The person lifts the frame, extends it forward with his arms, and walks for one or more steps before lowering the frame to the floor. Other frame variations incorporate a combination of wheels and legs so that the adult walker may be tilted and rolled forward. For the less ambulatory, the adult walker may be supported solely by three or more wheels, and the person need only apply a lateral force to move the walker. Tipping can be a hazard, especially since the elderly or disabled may have limited balance. Depending on the number and location of wheels and/or legs, the adult walker may fail to provide sufficient lateral support against tipping, especially if the person is overweight.
Most adult walkers are vertically adjustable so that users of different sizes and/or needs can be accommodated. Commonly the adjustment is provided by a type of telescoping leg.
Adult walkers may have an enclosed design with a moveable portion that allows the person to enter or exit when open while providing additional support and security in the closed position. Alternately, the adult walker may have an open front or back that allows for support while providing ease of entry and exit.
Some adult walkers have a seat or sling. This allows the walker to fully support the person in a seated position and may also be used to prevent falls. The support may be integral or removable. Some adult walkers have a strap or multiple straps to assist in securing the person and preventing falls.
Another feature of some adult walkers is a foldable design or a design that allows for easy disassembling. This allows the walker to be more easily transported or stored.
Persons using adult walkers may have need of additional medical equipment while using the walker. Some walkers are equipped with support or attachment devices for medical equipment such as IV bags or medication dispensers. However, walker designs to accommodate incontinence are not found in the prior art, even though persons requiring walker use may be incontinent as well.
Several embodiments of the invention advantageously address the needs above as well as other needs by providing a walker apparatus comprising a U-shaped lower frame comprising a left lower arm and a right lower arm connected by a front lower connector, the lower frame oriented in a horizontal position; a plurality of casters coupled to an underside of the lower frame and supporting the lower frame on a floor and allowing the walker to roll across the floor; a U-shaped upper frame comprising a left upper arm and a right upper arm connected by a front upper connector, the upper frame oriented in a horizontal position generally above the lower frame, whereby the left upper arm is generally above the left lower arm and the right upper arm is generally above the right lower arm, and wherein the lower frame and upper frame are configured to surround a person on three sides; a generally vertical left double scissor mechanism interposed between the left lower arm and the left upper arm; and a generally vertical right double scissor mechanism interposed between the right lower arm and the right upper arm, each double scissor mechanism comprising a top X-shaped scissor pivotally coupled to a bottom X-shaped scissor, wherein a vertical distance between the upper frame and the lower frame can be varied by simultaneously adjusting the left double scissor mechanism and the right double scissor mechanism.
The above and other aspects, features and advantages of several embodiments of the present invention will be more apparent from the following more particular description thereof, presented in conjunction with the following drawings.
Corresponding reference characters indicate corresponding components throughout the several views of the drawings. Skilled artisans will appreciate that elements in the figures are illustrated for simplicity and clarity and have not necessarily been drawn to scale. For example, the dimensions of some of the elements in the figures may be exaggerated relative to other elements to help to improve understanding of various embodiments of the present invention. Also, common but well-understood elements that are useful or necessary in a commercially feasible embodiment are often not depicted in order to facilitate a less obstructed view of these various embodiments of the present invention.
The following description is not to be taken in a limiting sense, but is made merely for the purpose of describing the general principles of exemplary embodiments. The scope of the invention should be determined with reference to the claims.
Reference throughout this specification to “one embodiment,” “an embodiment,” or similar language means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, appearances of the phrases “in one embodiment,” “in an embodiment,” and similar language throughout this specification may, but do not necessarily, all refer to the same embodiment.
Furthermore, the described features, structures, or characteristics of the invention may be combined in any suitable manner in one or more embodiments. In the following description, numerous specific details are provided to provide a thorough understanding of embodiments of the invention. One skilled in the relevant art will recognize, however, that the invention can be practiced without one or more of the specific details, or with other methods, components, materials, and so forth. In other instances, well-known structures, materials, or operations are not shown or described in detail to avoid obscuring aspects of the invention.
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The top horseshoe 102 in one embodiment of the invention is made of ¼ inch solid aluminum rods which form a top inner horseshoe rail 174 and top outer horseshoe rail 176. Each horseshoe rail 174, 176 is formed in a horseshoe shape, with the top horseshoe rails 174, 176 running parallel with an approximately 2 inches clear distance between the rails. The top horseshoe rails 174, 176 are joined at the horseshoe shape ends so that the top horseshoe rails 174, 176 are continuous. The top horseshoe rails 174, 176 at the horseshoe shape ends form an arc. The front of the adult walker 100 is designated as the location of the midpoint of the horseshoe shape, and the rear of the adult walker 100 is designated as the location of the horseshoe ends. The length of the top horseshoe 102 in this embodiment is approximately 36″ measured along the line of symmetry of the top horseshoe 102. The top front plate 104 in a pointed oval shape is coupled to the underside of the front portion of the top horseshoe 102. The top front plate 104 is made of aluminum or other suitable material. The top front plate 104 is oriented so that the front curved edge of the top front plate 104 aligns with the front edge of the top horseshoe 102. The left top front plate 114 approximately 2.5 inches×2.5 inches is coupled to the underside of the top horseshoe 102 at approximately a one-third point along the left side of the top horseshoe 102, starting at the front of the top horseshoe 102. The right top front plate 118 approximately 2.5 inches×2.5 inches is coupled to the underside of the top horseshoe 102 at approximately a one-third point along the right side of the top horseshoe 102, starting at the front of the top horseshoe 102. The left and right top front plates 114, 118 are made of aluminum or other suitable material. The left top rear plate 116 approximately 2.5 inches×2.5 inches is coupled to the underside of the top horseshoe 102 so that one side of the plate aligns with the left end of the top horseshoe 102. The right top rear plate 120 approximately 2.5 inches×2.5 inches is coupled to the underside of the top horseshoe 102 so that one side of the plate aligns with the right edge of the top horseshoe 102. The left and right top rear plates 116, 120 are made of aluminum or other suitable material. The left top rear pivot attachment 106 is shown on the left side of the top horseshoe 102 near the top horseshoe's left end. The left top front pivot attachment 108 is shown on the left side of the top horseshoe 102 near the left edge of the top front plate 104. The left top pivot attachments 106, 108 span horizontally between the parallel top horseshoe rails 174, 176. The right top rear pivot attachment 110 is shown on the right side of the top horseshoe 102 near the horseshoe's right end. A right top front pivot attachment 112 is shown on the right side of the top horseshoe 102 near the right edge of the top front plate 104. The right top pivot attachments 110, 112 span horizontally between the parallel top horseshoe rails 174, 176. The pivot attachments 106, 108, 110, 112 are described in more detail below.
The bottom horseshoe 122 in one embodiment of the invention is made of ¼ inch solid aluminum rods which form the bottom inner horseshoe rail 178 and bottom outer horseshoe rail 180. Each horseshoe rail 178, 180 is formed in a horseshoe shape, with the bottom horseshoe rails 178, 180 running parallel with an approximately 2 inch clear distance between the rails. The bottom horseshoe rails 178, 180 are joined at the horseshoe shape ends so that the bottom horseshoe rails 178, 180 are continuous. The bottom horseshoe rails 178, 180 at the horseshoe shape ends form an arc. The length of the bottom horseshoe 122 in this embodiment is approximately 36 inches measured along the line of symmetry of the bottom horseshoe 122. The bottom front plate 124 in a pointed oval shape is coupled to the underside of the front portion of the bottom horseshoe 122. The bottom front plate 124 is made of aluminum or other suitable material. The bottom front plate 124 is oriented so that the front curved edge of the bottom front plate 124 aligns with the front edge of the bottom horseshoe 122. The left bottom rear pivot attachment 126 is shown on the left side of the bottom horseshoe 122 near the horseshoe's left end. The left bottom front pivot attachment 128 is shown on the left side of the bottom horseshoe 122 near the left edge of the bottom front plate 124. The left bottom pivot attachments 126, 128 span horizontally between the bottom horseshoe rails 178, 180. The right bottom rear pivot attachment 130 is shown on the right side of the bottom horseshoe 122 near the horseshoe's right end. The right bottom front pivot attachment 132 is shown on the right side of the bottom horseshoe 122 near the right edge of the bottom front plate 124. The right bottom pivot attachments 130, 132 span horizontally between the bottom horseshoe rails 178, 180. The six bottom plates 134, 136, 138, 140, 142, 144 are shown coupled to the underside of the bottom horseshoe 122. The bottom plates 134, 136, 138, 140, 142, 144 are made of aluminum or other suitable material and are sized to provide secure attachment to the underside of the bottom horseshoe rails 178, 180 and also to provide sufficient area for wheel attachment. The left and right bottom rear plates 136, 140 are located at the left and right ends of the bottom horseshoe 122, respectively. The left and right bottom middle plates 142, 144 are located approximately halfway between the front and rear of the walker frame. The left and right bottom front plates 134, 136 are approximately equidistant from the middle wheel, with sufficient clearance given for the adjacent front pivot attachment.
The top horseshoe 102 and the bottom horseshoe 122 are connected vertically on each side by a series of adjustment rods 148, 150, 152, 154, 160, 162, 164, 168. These rods 148, 150, 152, 154, 160, 162, 164, 168 provide vertical support of the top horseshoe 102 and vertical adjustment of the height of the top horseshoe 102. On each side of the walker 100, the adjustment rods 148, 150, 152, 154, 160, 162, 164, 168 form a vertical double-X shape, with one X on top of the other X. The double-X, also referred to as a scissor mechanism, extends on the left side from the left side of the top horseshoe 102 to the left side of the bottom horseshoe 122. The left top X is formed by the left top outer rod 148 and the left top inner rod 150. The top end of the left top outer rod 148 is coupled to the left top front pivot attachment 108 so that the left top outer rod 148 may pivot or rotate in a vertical plane. The left top outer rod 148 extends diagonally downward and to the rear. The top end of the left top inner rod 150 is coupled to the left top rear pivot attachment 106 so that the left top inner rod 150 may pivot or rotate in a vertical plane. The left top inner rod 150 extends diagonally downward and to the front. The left bottom X is formed by the left bottom outer rod 152 and the left bottom inner rod 154. The bottom end of the left top outer rod 148 is coupled to the top end of the left bottom outer rod 152 so that the outer rods 148, 152 may rotate in the same plane. The bottom end of the left bottom outer rod 152 is coupled to the left bottom front pivot attachment 128 so that the left bottom outer rod 152 may rotate or pivot in a vertical plane. The bottom end of the left top inner rod 150 is coupled to the top end of the left bottom inner rod 154 so that the left bottom inner rods 150, 154 may rotate in the same plane. The bottom end of the left bottom inner rod 154 is coupled to the left bottom rear pivot attachment 126 so that the left bottom inner rod 154 may rotate or pivot in a vertical plane. Where the top X connects to the bottom X, a left horizontal telescoping adjustment tube 182 joins the front side of the X to the rear side of the X. The left telescoping adjustment tube 182 is comprised of the two left outer tubes 156 and the left inner tube 158. One left outer tube 156 is located at each end of the left inner tube 158 so that the outer tubes 156 may slide over the ends of the inner tube 158, lengthening or shortening the left telescoping adjustment tube 182. The left telescoping adjustment tube 182 is connected to a plurality of rod pivot points 184 so that the inner and outer rods 148, 150, 152, 154 may rotate or pivot relative to the left telescoping adjustment tube 182. The rotation of the inner and outer rods 148, 150, 152, 154 raises and lowers the top horseshoe 102. The left telescoping adjustment tube 182 provides additional stability to the vertical adjustment and locks the top horseshoe 102 height in place. The operation of the vertical adjustment is described in more detail below. The vertical adjustment system as previously described is repeated on the right hand side of the adult walker 100.
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The lower frame 1218 is a general U-shape, oriented in a horizontal position, i.e. the U-shape is parallel to the ground. The lower frame 1218 is supported on the floor by the plurality of front casters 1220 coupled to a front portion of the lower frame 1218 and the plurality of rear wheels 1226 coupled to a rear portion of the lower frame 1218. The general U-shape of the present embodiment includes generally perpendicular corners, i.e. the lower frame 1218 includes the left lower arm 1228, the right lower arm 1230 parallel to the left lower arm 1228, and the lower front connector 1232 rigidly coupled to a front end of the left lower arm 1228 at a generally 90 degree angle, and rigidly coupled to a front end of the right lower arm 1230 at a generally 90 degree angle, whereby the rectilinear U-shaped lower frame 1218 is formed. In the embodiment shown in
The left lower arm 1228 and the right lower arm 1230 comprise a rectangular hollow tube-shaped housing. A scissor lift assembly 1618 is housed in each lower arm, as described further below. In lieu of the rectangular hollow tube shape, the lower arms 1228, 1230 may be any hollow shape suitable for housing the scissor lift assembly 1618. Each lower arm includes the horizontal slot 1244 in each vertical side of the housing. The horizontal slots 1244 are in a horizontal plane and located proximate to the front end. A length of the horizontal slots 1244 is configured to allow a connection to a front lower end of each bottom scissor 1212, 1214 to slide within the horizontal slots 1244 in the proximate lower arm, whereby each double scissor mechanism 1240, 1242 is enabled to move between the raised position of
At least two casters 1220 are coupled to an underside of the lower frame 1218. In the present embodiment the casters 1220 are located at the front corners of the lower frame 1218, i.e. one caster 1220 at each intersection of one lower arm 1228, 1230 and the lower front connector 1232.
One motor assembly 1224 is coupled to the rear end of each lower arm. One rear wheel is coupled to each lateral (i.e. left and right) side of each motor assembly 1224, for a total of four rear wheels 1226. Each motor assembly 1224 includes a motor housing 1616 rigidly coupled to the rear end of each lower arm and the lift motor coupled to and supported by the motor housing 1616, as described further below in
The scissor motors 1600 in one embodiment are commercially available DC motors capable of operating at 12V-130V, and 1/7-½ HP.
The upper frame 1206 is a rectilinear U-shape of similar dimensions and orientation to the lower frame 1218 and located above and parallel to the lower frame 1218 such that the lower frame 1218 and upper frame 1206 align vertically. The upper frame 1206 is comprised of a hollow rectilinear tube section, although other suitable geometries may be used, for example a solid rectilinear section or a round tube section. The upper frame 1206 comprises the left upper arm 1234 and the right upper arm 1236 rigidly coupled to each end of the upper front connector 1238 at a normal angle. The upper frame 1206 may include attachment points for a harness, for example hooks. The upper frame 1206 is of a suitably rigid and strong material, for example, aluminum, steel, or stainless steel. As the upper frame 1206 does not require as much structural strength as the lower frame 1218, carbon fiber may also be used.
The left double scissor mechanism 1242 is juxtaposed between the left upper arm 1234 and the left lower arm 1228. The right double scissor mechanism 1240 is juxtaposed between the right upper arm 1236 and the right lower arm 1230. Each generally vertical double scissor mechanism 1240, 1242 includes the X-shaped top scissor 1208, 1210 stacked above and pivotally coupled to the corresponding X-shaped bottom scissor 1212, 1214, such that each double scissor mechanism 1240, 1242 may be extended upward vertically to the raised position of
Each double scissor mechanism 1240, 1242 is pivotally coupled at an intersection of a lower rear end of the bottom scissor 1212, 1214 and the rear portion of the corresponding lower arm 1228, 1230. Each double scissor mechanism 1240, 1242 is also pivotally coupled at an intersection of the lower front end of the bottom scissor 1212, 1214 and a front portion of the corresponding lower arm 1228, 1230. The coupling to the front portion of the corresponding lower arm 1228, 1230 also includes the horizontal sliding of the lower front end of the bottom scissor 1212, 1214 along the horizontal slot 1244, as previously described.
Similarly, each double scissor mechanism 1240, 1242 is pivotally coupled at the intersection of an upper rear end of each top scissor 1208, 1210 and a rear portion of the corresponding upper arm 1234, 1236. Each double scissor mechanism 1240, 1242 is also pivotally coupled at an intersection of an upper front end of the top scissor 1208, 1210 and a front portion of the corresponding upper arm 1234, 1236. Similar to the bottom scissors 1212, 1214, the coupling of the upper front end of the top scissor 1208, 1210 to the front portion of the corresponding upper arm 1234, 1236 also includes horizontal sliding of each upper front end of the top scissor 1208, 1210 along at least one horizontal slot 1244 of each upper arm 1234, 1236. In the embodiment shown, the at least one horizontal slot 1244 is located in an underside of each upper arm 1234, 1236.
In the current embodiment, each scissor leg 1246 is comprised of parallel bars rigidly coupled together by intermediate stitch plates. The distance between the bars is configured to allow the bars to couple to lateral sides of the upper arms 1234, 1236 and the lower arms 1228, 1230. In other embodiment the scissor legs 1246 may comprise a single member. The scissor legs 1246 may comprise carbon composite, carbon fiber, aluminum, titanium, stainless steel, steel, or other suitable material. In the embodiment shown, the pivotal-only connections are shoulder bolts 1900 sitting in a sleeve bearing/bushing to allow smooth operation of the scissor mechanism, as shown below in
Each horizontally-oriented gas spring 1216 is juxtaposed between the scissor leg pivotal connections connecting each top scissor 1208, 1210 to the corresponding bottom scissor below 1212, 1214. The gas spring 1216 provides a linear horizontal contracting force between the scissor legs 1246 to aid in the raising of the upper frame 1206. The gas spring 1216 is described in more detail below in
The top horseshoe frame 1202 above the upper frame 1206 and in a plane parallel to the upper frame 1206 is removably coupled to the upper frame 1206 via the plurality of vertical connectors 1204 coupled to a top face of the upper frame 1206. In one embodiment, a plurality of sockets 1248 are coupled to the top face of the upper frame 1206 and each vertical connector 1204 slides within one socket 1248 and is held in place using an automatically locking “pull-to-unlock” ball spring plunger. The vertical connectors 1204 are configured for adjustable height.
The top horseshoe frame 1202 has a horseshoe-like shape, with the legs of the horseshoe parallel, i.e. a conventional U-shape. A front end of the top horseshoe frame 1202 is set back from a front end of the upper frame 1206, and a rear end of the top horseshoe frame 1202 extends generally to a rear extent of the motor assemblies 1224 below, although it will be understood that other configurations of the top horseshoe frame 1202 may be suitable. In general, the horizontal components of the walker apparatus 1200, the upper frame 1206, the lower frame 1218, and the top horseshoe frame 1202 are configured to minimize the footprint of the walker 1200. The top horseshoe frame 1202 may comprise stainless steel, carbon fiber, or other material of suitable strength. A padding or cover may be coupled to the top horseshoe frame 1202. The top horseshoe frame 1202 includes the plurality of attachment points 1250 coupled to the underside of the top horseshoe frame 1202 and configured to attach to and support a seat, harness or other accessory.
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Several elements of the walker 1200 design prevent tipping of the walker 1200 when used by the user. The location of the motor assemblies 1224, the battery pack 1222, and a scissor lift assembly 1618 housed in each lower arm 1228, 1230 lower a center of gravity of the walker 1200 which provides a greater resistance to tipping. The swiveling front casters 1220 are located at the intersections of the lower arms 1228, 130 and the lower front connector 1232, increasing the side-to-side separation between the front casters 1220, increasing the lateral tipping moment resistance of the walker 1200. The frontmost location of the front casters 1220 increases the front-to-back tipping resistance of the walker 1200. The rear wheels 1226 are located at the rear end of the motor assemblies 1224 to provide the maximum distance from the front casters 1220, again increasing the front-to-back tipping resistance of the walker 1200. Additionally, two rear wheels 1226 are provided for each motor assembly 1224, one rear wheel 1226 on each side of each motor assembly 1224, providing additional stability and front-to-back and lateral tipping moment resistance. In the embodiment shown, each set of rear wheels 1226 coupled to the motor assembly 1224 are separated by 3 inches. Additionally, the rear wheels 1226 do not swivel, providing greater stability.
The lower frame 1218 clears the floor by a maximum of approximately ½″, which also lowers the center of gravity of the walker 1200, and also prevents tipping by contacting the floor upon a small degree of rotation of the walker 1200 due to the closeness of the lower frame 1218 to the floor. The contact of the walker 1200 with the floor prevents the walker 1200 from rotating further and tipping.
These improvements increase the safety of the user by making the walker 1200 tip-proof under normal use, increasing the protection of the user against injury from falls due to tipping of the walker 1200.
In some embodiments, the coupling of the top horseshoe frame 1202 to upper frame 1206 includes connecting of an electrical circuit such that the walker 1200 is not powered unless the top horseshoe frame 1202 is coupled to the upper frame 1206. This allows the top horseshoe frame 1202 to be removed for transport while preventing powered use of the walker 1200 without the top horseshoe frame 1202.
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As previously described, the walker 1200 folds down into the lowered position for storage or transport in response to the movement of the double scissor mechanisms 1240, 1242. The top horseshoe frame 1202 and the vertical connectors 1204 have been removed in the embodiment shown, illustrating the minimum height of the walker 1200 in the folded position. The top horseshoe frame 1202 and the vertical connectors 1204 may be left on in the folded position, although it will increase the height of the folded walker 1200 apparatus.
As previously described, the walker apparatus 1200 is moved from the raised to the lowered position (and vice versa) by simultaneous horizontal moving of the lower front end of each bottom scissor 1212, 1214, resulting in the raising of the double scissor mechanisms 1240, 1242 (if the lower front end of each bottom scissor 1212, 1214 is moved rearward) or the lowering of the double scissor mechanism 1240, 1242 (if the lower front end of each bottom scissor 1212, 1214 is moved frontward). The lower front end of each bottom scissor 1212, 1214 is connected to one motor assembly 1224, as described further below in
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While only the scissor lift assembly 1618 inside the left lower arm 1228 is shown, it will be understood that a corresponding scissor lift assembly 1618 is housed within the right lower arm 1230 and functions in the same way.
One scissor lift assembly 1618 is housed within each lower arm 1228, 1230. An output shaft (not shown) of the scissor motor 1600 is aligned axially with and coupled to the non-threaded motor shaft 1620 via the first coupler 1604, whereby rotation of the output shaft is transferred to the motor shaft 1620.
The motor shaft 1620 passes through a hole in the first bearing block 1606. The first bearing block 1606 is juxtaposed between the first coupler 1604 and the second coupler 1608, and is configured to provide radial support to the motor shaft 1620 and provide the pivotal coupling to the lower scissor leg end proximate to the rear of the corresponding lower arm 1228, 1230. In one embodiment, the first bearing block 1606 comprises a steel block with a press fit iolite flange bushing or sleeve bearing. The first bearing block 1606 provides radial (i.e. vertical and horizontal) bearing support to the threaded rod 1602 but not axial bearing support. One first bearing block 1606 is coupled to each lower arm 1228, 1230 with hardened screws or bolts.
The motor shaft 1620 and the threaded rod 1602 are axially aligned and coupled together with the second coupler 1608, whereby the rotation of the motor shaft 1620 is transferred to the threaded rod 1602. In other embodiments a continuous length of threaded rod 1602 may be used, or other numbers of splices and/or splice locations may be used, as compatible with the rest of the assembly 1618. In the embodiment shown in
The threaded rod 1602 passes through a hole in the second bearing block 1610. The second bearing block 1610 is juxtaposed between the second coupler 1608 and the sliding block 1612. The second bearing block 1610 is configured to provide both radial and axial support to the threaded rod 1602 as the threaded rod 1602 passes through the second bearing block 1610. In the present embodiment, the second bearing block 1610 includes annular thrust bearings on the front and rear sides of the second bearing block 1610, with the threaded rod 1602 passing through the thrust bearings. The second bearing block 1610 also includes a non-threaded sleeve bearing for radial support. The threaded rod 1602 is held in place with a threaded-bore clamp-on shaft collars. The combination of the thrust bearings and the sleeve bearing allows the threaded rod 1602 to rotate with low friction, and holds the threaded rod 1602 in place axially. The second bearing block 1610 also enables axial load to be transferred from the threaded rod 1602 to the second bearing block 1610 to the corresponding lower arm 1228, 1230.
The custom sliding block 1612 encircles the threaded rod 1602 and is configured snugly fit within and to slide within the lower arm 1228. The custom sliding block 1612 is coupled to the front lower end of the proximate bottom scissor 1212, 1214 through the horizontal slots 1244 in the lateral sides of the lower arm 1228, thus confining horizontal movement of the sliding block 1612 to the extent of the horizontal slot 1244. Additionally, the pivotal coupling of the sliding block 1612 to the scissor leg 1246 moves the scissor leg end as the sliding block 1612 moves horizontally in the corresponding lower arm 1228, 1230.
The custom sliding block 1612 includes a threaded hole to receive the threaded rod 1602, whereby when the threaded rod 1602 is rotated by the scissor motor 1600, the sliding block 1612, being restrained against rotation by the lower arm 1228, moves horizontally along the threaded rod 1602, moving the sliding block 1612 within the horizontal slot 1244, whereby the double scissor mechanism 1240, 1242 is raised or lowered.
The threaded rod 1602 continues in the corresponding lower arm 1228, 1230 until it terminates at the third bearing block 1614 proximate to the front end of the corresponding lower arm 1228, 1230. The third bearing block 1614 is configured to provide both radial and axial support to the threaded rod 1602. In the present embodiment, the third bearing block 1614 includes thrust bearings on the front and rear sides of the third bearing block 1614. The threaded rod 1602 is held in place by the third bearing block 1614 by threaded bore clamp-on collars. As with the second bearing block 1610, the third bearing block 1614 allows the threaded rod 1602 to rotate with low friction, and holds the threaded rod 1602 in place axially. The second bearing block 1610 also enables axial load to be transferred from the threaded rod 1602 to the third bearing block 1614 to the corresponding lower arm 1228, 1230.
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Although only the sliding block 1612 inside the left lower arm 1228 is shown, it will be understood that a similar scissor lift assembly 1618 including the sliding block 1612 is also located within the right lower arm 1230. The sliding block 1612 includes the threaded center square nut 1702. The threaded rod 1602 is screwed through the center square nut 1702, whereby the rotational movement of the threaded rod 1602 is translated into horizontal movement of the center square nut 1702. The center square nut 1702 is encased in the center block 1704, which includes axially aligned front and rear holes to allow the threaded rod 1602 to pass though the center block 1704. The center square nut 1702 and the center block 1704 comprise steel, aluminum or other suitable material. The first outer casing 1706 fits over a top portion of the center block 1704, and the second outer casing 1708 fits over a bottom portion of the center block 1704, forming a general cube shape, with front and back notches to allow the threaded rod 1602 to pass by the first outer casing 1706 and the second outer casing 1708. The first outer casing 1706 and the second outer casing 1708 comprise PTFE (e.g. Teflon™), acetal resin (e.g. Delrin®) or other lubricant material. The lubricant material provides a lower coefficient of friction, allowing the sliding block 1612 to slide freely within one lower arm 1228, 1230. The lubricant material also prevents galling.
Each tee-shaped side yoke 1710 is coupled to a side of the center block 1704 through the horizontal slot 1244, such that the tee-flange portion of each side yoke 1710 is outside the lower arm 1228. The tee stem of each side yoke 1710 passes through the horizontal slot 1244 and is coupled to a side of the center block 1704. In the present embodiment the connection comprises three screws 1712 for each side yoke 1710, with each side yoke 1710 including two threaded screw through holes. Each side yoke 1710 is also pivotally coupled to the proximate bar of the scissor leg 1246. The side yokes 1710 comprise steel, aluminum or other suitable material.
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Each side yoke 1710 is coupled to a side of the center block 1704 by the threaded screws 1712 threaded into the threaded holes 1802 and screwed into corresponding threaded holes in each side of the center block 1704. The side yokes 1710 are oriented with the tee-flange in a vertical orientation, and the tee-stem oriented horizontally.
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With the exception of the added drive wheel 1500, the scissor motor assembly 1224 of
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For the drive wheel embodiment, at least one accelerometer and/or other motion sensor is coupled to the main controller 2104 to sense when the walker 1200 is being pushed forward by the user. In response to detecting forward motion of the walker 1200, the main controller 2104 would direct drive motors 2114 to power the drive wheels 1500, providing additional forward motion, assisting the user in moving the walker 1200 forward, for example when going up a ramp. When used on a level surface, the drive wheels 1500 reduce the force needed to move the walker 1200 forward, aiding the user with limited pushing ability. The controller may also provide a rearward motion to provide a braking force when the walker 1200 is going down a ramp.
In some embodiments when one harness configured to support the user in a seated position is coupled to the walker 1200, the walker 1200 may be used as a short distance low speed scooter or wheelchair. In one embodiment only the drive motors 2114 are used to propel the walker 1200 forward, with no assistance from the user. In another embodiment, the user provides some forward propulsion by pedaling forward with one or both feet while seated in the harness. In yet another embodiment, a caretaker pushes the walker 1200 forward while the user is seated in the harness while the drive motors 2114 are used to propel the walker 1200 forward, providing a more rapid movement than by using the drive motors 2114 alone.
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As previously described, each scissor leg 1246 comprises two longitudinal parallel bars coupled together at intermediate intervals by stitch plates. At the pivotal connection between one top scissor 1208, 1210 and one bottom scissor 1212, 1214, a lower end of each bar of the top scissor leg 1246 overlaps an upper end of the proximate bar of the bottom scissor leg 1246. The pivotal connection is made by the high strength shoulder bolt 1900 passing through a hole in an end of each bar. The bolt also is pivotally connected to an end of the gas spring 1216, with the connection occurring between the parallel bars.
The gas spring 1216 is a standard contraction gas spring, with an extension ranging between 5 and 10 inches. In the present embodiment, an overall length of the gas spring 1216 is 12 inches when fully compressed and 22 inches when fully extended. As described previously, the gas spring 1216 provides the contractive force on the scissor leg connection, aiding in the raising of the double scissor mechanism 1240, 1242 and allowing the size of the scissor motor 1600 to be reduced.
Referring next to
The battery pack 1222 is comprised of the plurality of rechargeable batteries 2000, for example lithium ion. The batteries 2000 are arranged in a 7S configuration with the number of cells required to provide the necessary voltage to the scissor motors 1600 and other components receiving power from the battery pack 1222. In the present embodiment, the battery pack 1222 comprises a 24-48V battery with a capacity of 5-30 Ah. The batteries 2000 are arranged in a low rectangular shape to fit on top of the lower front connector 1232. A plurality of conductive shims 2002 connect each battery 2000 in the battery pack 1222 and provide attachment for charging. The battery pack 1222 is removably housed within a battery housing coupled to the lower frame 1218, and the connection of the battery pack 1222 to the other components is designed to allow for hot swapping. The battery pack 1222 is configured for balanced charging and to prevent thermal runaway. In some embodiments each drive motor/controller 2112 is mounted to the lower front connector 1232 proximate to the battery pack 1222, although the drive motor/controllers 2112 may be mounted at other locations on the lower frame 1218.
Referring next to
The battery pack 1222, as previously described, provides power to the various components, including the main controller 2104, the scissor motor driver/controller 2106, the scissor motors 1600, the optional drive controller 2112, and the optional drive motors 2114. In some embodiments back-up batteries may additionally be coupled to one or more of the components, such as a 9V DC cell for backup for the main controller 2104.
The main controller 2104 is comprised of a computing device including a processor, non-transitory memory coupled to the processor, and software stored on the non-transitory memory and configured to run on the processor. In one embodiment the main controller 2104 is configured to allow for additional non-transitory memory to be coupled to the main controller 2104. The software includes programming that monitors motor parameters control the movement of the double scissor mechanisms 1240, 1242 based on input from the user controls 2110 communicatively coupled to the main controller 2104. The software is also configured to receive input from the rotary encoder/position sensor 2100 to monitor the motor parameters (e.g.) speed. The rotary encoder/position sensor 2100 may be built in to the scissor motor 1600 or may be a custom-made encoder. The custom-made encoder may comprise either a Hall effect sensor and gear, or an optical sensor and gear. The software includes a control algorithm to control the speed of the motors, sending signals to the motor driver/controller 2106 communicatively coupled to main controller 2104, whereby the speed of the motor is regulated. The main controller 2104 includes power isolation or power condition so that in rush motor current draw does not power off the main controller 2104.
The scissor motor driver/controller 2106 is configured to control the scissor motor 1600 coupled to the scissor motor driver/controller 2106 in response to receiving signals from the main controller 2104. Each scissor motor driver/controller 2106 is mounted on the lower frame 1218 to enable heat dissipation. The scissor motor driver/controller 2106 may be a commercially available product or may be custom made. In one embodiment the scissor motor driver/controller 2106 is a dual 25 A motor driver with 25 A continuous current capacity and a peak current capacity of 50 A. In the embodiment shown, the scissor motor driver/controller 2106 is configured for motors with a 6-30V nominal voltage range, but in other embodiments the range may vary between 12-96V.
The software may be configured to store at least one intermediate walker setting so that the walker 1200 may be automatically adjusted to one or more pre-set heights. The intermediate walker settings would be set and accessed via the user controls 2110. The main controller 2104 may also be configured for communication with an outside network, for example, to send an alert if a stop control button 2208 is pressed.
Referring next to
The user control panel 2200 includes the up control button 2202, which when pressed by the user causes the walker 1200 to rise by simultaneously activating the double scissor mechanisms 1240, 1242 upwardly. Similarly, the down control button 2204 when pressed by the user causes the walker 1200 to lower by simultaneously activating the double scissor mechanisms 1240, 1242 downwardly. The control buttons 2202, 2204 may require a single press to start the activation, or the walker 1200 may only move when the control button 2202, 2204 is being continuously pressed.
The stop control button 2208 when pressed stops the movement of the double scissor mechanism 1240, 1242. The stop control button 2208 may also be used as a master reset button. In another embodiment pressing of the stop control button 2208 sends an alert to a device in communication with the walker 1200, for example a computing device at a nurse's station. In another embodiment, separate stop and emergency stop control buttons may be included in the user control panel, where the emergency stop button sends the alert in addition to stopping the movement of the walker 1200. The status indicator 2206 displays a current status of the walker 1200, including battery life remaining, as shown in
Referring next to
The left double scissor mechanism cover 2300 is shown transparent to illustrate the relative location of the left double scissor mechanism 1242, but it will be understood that the covers 2300, 2302 may be transparent or opaque.
The left cover 2300 surrounds the left double scissor mechanism 1242, and the right cover 2302 surrounds the right double scissor mechanism 1240. Each cover 2300, 2302 includes vertical accordion folds to accommodate the raising and lowering of the walker 1200. The accordion folds are configured such that each cover 2300, 2302 spans the height of the fully raised double scissor mechanisms 1240, 1242, and each cover 2300, 2302 compresses down to the reduced folded double scissor height when the double scissor mechanisms 1240, 1242 are folded.
The covers 2300, 2302 protect the scissor mechanism components and protects the user from possible pinch points caused by the moving walker 1200 (e.g. scissor mechanism pivot points, the sliding block 1612, etc.). The covers 2300, 2302 also act as cushioning and protection from falls, especially if the covers 2300, 2302 are configured to be inflated with air.
Referring next to
In lieu of the motor assemblies 1224, the walker apparatus 2510 shown in
Each pneumatic actuator assembly 2510 is oriented for vertical movement and mounted to one lower arm 1228, 1230 between the connections of the lower scissor arms 1212, 1214, to the associated lower arm 1228, 1230. From the folded position, as the compressors 2506 actuate the pneumatic actuator assemblies 2510, a top end of the pneumatic actuator assemblies 2510 contacts one of the scissor legs 1246 and pushes the scissor leg 1246 upwards, thus raising the walker 2500. The pneumatic actuator assembly 2510 is also configured to contract, either via a dual-direction actuator or other mechanism such as a spring. The actuator bearing plate 2504 is coupled to a bearing location on each scissor leg 1246 and provides a bearing surface for each pneumatic actuator assembly 2510.
In lieu of the scissor lift assembly 1618 previously described, in the embodiment of
Also included in the walker 2500 embodiment of
In some embodiments the gas springs 1216 are changed to pneumatic actuators and assist in the raising and lowering of the double scissor mechanisms 1240, 1242.
In one embodiment each compressor 2506 is enclosed in a noise-reducing chamber.
Referring next to
In the embodiment of the walker 2600 shown in
Referring next to
The home walker comprises a horizontally-oriented upper U-shaped frame 2800 (shown below in
Referring next to
The upper frame 2800 is of similar configuration to the lower frame 2700, with the exception that the upper frame does not include the tipping-prevention tabs 2704.
In operation, the upper frame legs 2810 and the lower frame legs 2710 are rotated simultaneously using the hinges 2706, allowing the home walker to be opened wider in the rear.
Referring next to
The tipping-prevention tab 2704 is coupled to the lower frame leg 2710 and extends diagonally outward and downward from the lower leg 2710. The tipping-prevention tab 2704 terminates at a small distance from the ground surface 2900, in one example clearing the ground surface 2900 by about ½″. A lower end portion of the tipping-prevention tab 2704 may be parallel to the ground surface 2900.
The tipping-prevention tabs 2704 allow the home walker to roll on the casters, while preventing tipping of the home walker. If the home walker starts to tip to one side, the tipping-prevention tabs 2704 contact the ground surface 2900, preventing further rotation of the home walker and preventing the home walker from tipping over.
Referring next to
The harness 3006 comprises the two harness straps 3008 coupled together at a central portion by the harness seat 3010, similar to the embodiment described in
The harness apparatus 3000 includes two support frames 3002, each in a ladder-like configuration with two “rails” 3012 and the plurality of “rungs” 3014 connecting the two rails 3012. One end of the support frame 3002 is configured for each rail end to slide into one insertion point 3004 and within the harness strap 3008, coupling each support frame 3002 to one end of the harness 3006. The rails 3012 then also rest on and are supported by the harness straps 3008. The addition of the support frames 3002 provide additional security and fall prevention for the user of the harness 3000, and are removable if not required.
Software comprising executable code may, for instance, comprise one or more physical or logical blocks of computer instructions that may, for instance, be organized as an object, procedure, or function. The executables of an identified module of software need not be physically located together, but may comprise disparate instructions stored in different locations which, when joined logically together, comprise the module and achieve the stated purpose for the software code.
Indeed, a module of executable code (software) could be a single instruction, or many instructions, and may even be distributed over several different code segments, among different programs, and across several memory devices. Similarly, operational data may be identified and illustrated herein within modules, and may be embodied in any suitable form and organized within any suitable type of data structure. The operational data may be collected as a single data set, or may be distributed over different locations including over different storage devices, and may exist, at least partially, merely as electronic signals on a system or network.
While the invention herein disclosed has been described by means of specific embodiments, examples and applications thereof, numerous modifications and variations could be made thereto by those skilled in the art without departing from the scope of the invention set forth in the claims.
This application is a continuation-in-part of U.S. application Ser. No. 14/617,872 filed Feb. 9, 2015, entitled WALKER, which is a continuation of U.S. application Ser. No. 13/839,848 filed Mar. 15, 2013, entitled WALKER, now U.S. Pat. No. 8,967,642, both of which are incorporated in their entirety herein by reference.
Number | Date | Country | |
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Parent | 13839848 | Mar 2013 | US |
Child | 14617872 | US |
Number | Date | Country | |
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Parent | 14617872 | Feb 2015 | US |
Child | 15013000 | US |