Arm rail mechanisms for hospital beds

Abstract

A vehicle for use in hospitals, and the like, giving better mobility, steering, braking and passenger handling while providing comfort to the passengers from the time they lay down until they are standing on the side through the rotation and tilting ability of the frame.

Description

FIELD OF THE INVENTION

The present invention relates to beds for use in hospitals, nursing homes or residential homes.

SUMMARY OF EMBODIMENTS OF THE INVENTION

Embodiments of the present invention are directed to beds with rotating sleep surfaces that can be configured to sit into a chair and also may stand a patient up like a lift chair on the side of the bed.

The present invention includes 8″ casters for specific ease of steering.

The present invention includes a braking system operated by hydraulics whereby the casters may be locked and released with one cylinder. Components of the braking system thereof are strategically located inside the bottom frame rails.

The present invention includes a steering system that is spring loaded to the floor and lifted with a hydraulic cylinder.

The present invention includes a twin scissor mechanism actuated by a cylinder with a cylinder extension so that the mechanism may operate at full extension in a confined space.

The present invention includes a rotating sleep surface mounted to the center frame at the top of the scissors allowing operating rotation of 360 degrees.

The present invention includes a mounted platform system attaching to the rotating sleep surface that allows the upper frame to tilt around the four-way platform at optimal degrees of tilt.

The present invention includes arm rails that are mounted to the main frame operated by pin or latch release to allow straight in and out movement. The rail is spring loaded and will automatically release when the pin or latch is activated. The up/down feature will stop at designated points along the back of the rack and is controlled by a rack and pinion guide system.

The present invention includes side egress chair capabilities allowing the entire sleep surface to rotate 360 degrees left or right of center and can transition to a seated position at 90 degrees left or right of center. This side egress chair position is locked at 90 degrees, 180 degrees and 270 degrees.

The present invention includes side egress lift chair allowing the patient to transition from a suspended comfort position to a chair position to a gentle walkout exit position. Walkout exits are obtainable at 90 degrees and 270 degrees.

The present invention allows 30 degree tilt which is easily achieved by main frame proximity to the floor when the scissors are raised to a predetermined height.

The present invention will be described hereafter with reference to the attached drawings that are given as non-limiting examples.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a PCV Braking Mechanism.

FIG. 2 is an exploded side perspective view of a PCV Steering Mechanism.

FIG. 3A is a side view of a Twin Scissor Lift Mechanism in an extended lift configuration.

FIG. 3B is an end perspective view of the Twin Scissor Lift Mechanism shown in FIG. 3A.

FIG. 3C is a side view of the device shown in FIG. 3A, illustrated in a collapsed configuration.

FIG. 4 is an exploded view of a Rotating Surface Mechanism.

FIG. 5A is a top view of a Four Way Equal Platform Tilting Mechanism shown in FIG. 4.

FIG. 5B is a rotated view of the Four Way Equal Platform Tilting Mechanism shown in FIG. 5A (rotated 90 degrees).

FIG. 6 is a top view of the Four Way Equal Platform Tilting Mechanism shown in FIGS. 5A and 5B shown attached to a sleep surface frame.

FIG. 7A is a side view of an Arm Rail Mechanism.

FIG. 7B is a side view of the device shown in FIG. 7A, illustrating the arm rail at first retracted position.

FIG. 7C is a side view of the device shown in FIG. 7A, illustrating the arm rail at a second retracted position below the position shown in FIG. 7B.

FIG. 8 is an end view (looking from the foot end) of a Comfort Side Chair Egress Mechanism.

FIG. 9 is an end view (looking from the foot end) of the device shown in FIG. 8 with the bed translated into a Comfort Side Standing Egress configuration.

FIG. 10 is a side view of a PCV Tilt Mechanism.

FIG. 11 is a top view of a sleep surface with a Manual Retracting/Extending Foot Section Mechanism.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

PCV Braking Mechanism

FIG. 1 illustrates the PCV Braking mechanism is made of 4-8 inch locking casters, 2-hex rods, 1-drive shaft bar, 1-hydraulic cylinder, 2-clevis mounts.

The casters are mounted to the four corners of the bed into square tubes. The tubes are drilled to allow for set screws in each caster and to slide a full length hex rod through the head of the caster to lock the brakes. The hex rod is put through the short 1 by 3 inch frame tube on both ends of the bed. A clevis is mounted to one end of each of the hex rods. The drive shaft bar is mounted to the clevis on each end. The drive shaft bar runs through the long 1 by 3 tube. There is a slot cut into the side of the long tube to connect the hydraulic cylinder to the drive shaft bar. When activated the cylinder rocks the clevis, the clevis rotates the hex rod and locks or unlocks the brakes on all 4 of the casters.

PCV Steering Mechanism

FIG. 2 illustrates the steering mechanism is made of 2 plastic or rubber wheels, springs, hydraulic cylinder, metal rods and square tubes.

The steering mechanism is mounted to the frame with 3 metal square tubes that are welded to the main base frame. There are holes in the cross section of tube to mount the spring loaded rods to and put the threaded hydraulic cylinder through. The spring loaded rods are attached to the bar the casters are mounted to so the springs keep them on the floor. There is a bar that connects above the square tube to the spring loaded bars to make sure they stay straight up and down. It is the same bar that the hydraulic head pushes on to lift the casters off of the ground. This keeps the casters on the floor until the bed needs to be moved side to side when the cylinder will raise them. This mechanism allowed us to push the bed 60 feet in a straight line by itself.

Twin Scissor Lift Mechanism

FIGS. 3A-3C illustrate the twin scissor mechanism is made of custom cut steel bars, steel rods, steel tube, copper or nylon bushings, copper or nylon washers, cylinder extension block 75, nylon blocks and wheels, and can be driven by hydraulics cylinders, air cylinders, air bags, or several electric mechanisms. We chose the hydraulic cylinder because of load we want to lift. We plan to build less expensive models with the other mechanisms in the future.

The scissor mechanism has 8 scissor arms mounted with welds and washers between them to 6 cross structural support rods, 1 cross structural support bar and 1 cross structural support tube. The cross structural support tube has 2 clevis arms 79 welded to it and a custom designed cylinder extension 75 mounted to clevis arms 79 with bushing and washers so the extension 75 will pivot. The bottom of the cylinder is mounted with a screw to the top of the cross structural support bar and the top of the cylinder is attached with threads to the inside of the cylinder extension block 75. This allows a larger cylinder to fit in a smaller space and get full range of motion. The top of the scissor is mounted to the bottom of the main lift surface (50, FIG. 4) and to the top of the metal scissor housing that has a metal mounting bracket that is welded to both the main lift surface and the top of the scissor housing. Inside the metal mounting brackets are nylon blocks with holes in them to lock the cross structural support rods in place and allow them to move very quietly straight up and down on one end of the scissor. The other ends are attached with channel iron. The channel iron is welded to the top of the scissor housing on both sides and the bottom of the main lift surface. The channels act as tracks for the nylon wheels to run in. The wheels move from one end (our foot end) to the other end (our head end) causing the scissors to lift. The purpose of using the scissor is to get very low and very high while having an almost square top to work around to achieve degree of tilt on all 4 sides.

Rotating Surface Mechanism

FIG. 4 illustrates the rotating surface is made of steel angle iron, custom cut 4 piece metal guide, aluminum round plate, aluminum and steel channel, bearings, nuts, bolts, nylon pads.

The main lift surface 50 is made of 4 pieces of angle iron cut on a 45 degree angle and welded together to form four 90 degree angles. This makes the main frame 50 where everything else is attached. The flat side of the frame is on top and the wall side is faced down to the bottom. There are 2 channel tracks mounted with a weld to the bottom of the frame for the 2 scissor lift wheels to run in and 2 brackets welded to the bottom on the opposite side to make the scissor track straight up and down. The top of the surface has a custom cut round aluminum plate 40 mounted to the center. The mounts are made of steel and nylon. The bottom steel mounting brackets are welded to the frame to lock them in place and keep the round plate from moving. There are 4 custom cut nylon pieces that fit on the top and bottom of the round plate 40 inside of metal mounts for the round plate to ride on. There are 4 top metal pieces of the mount that screw into the frame top to lock the metal and nylon in place. These mounts cause the round plate 40 to make a smooth 360 degree movement. The top of the round plate has 2 pieces of channel custom cut and screwed to it to mount 2 bearings 60 and allow the sleep surface to tilt. The bearings are screwed to the top of the channel to mount the main support rod (20, FIG. 6, FIG. 10) for the sleep surface. As shown, the plate 40 includes circumferentially spaced apart apertures 45.

Four Way Equal Platform Tilting Mechanism

FIGS. 5A, 5B and 6 illustrate the Four Way Equal Platform Tilting Mechanism. The way the “Rotating Surface Frame” connects to the “Sleep Surface Frame” and the width of each allows the “Sleep Surface Frame” to fit over or around the “Rotating Surface Frame” on all sides. The “Rotating Surface Frame” has a triangle shaped main structural tilt bar mount that allows the back of the seat section or “Trend Section” to stay at an optimal degree of tilt while the front of that section fits over the “Rotating Surface Frame”. FIG. 6 illustrates the primary support rod 20 attached to bearings 60 above the tilt platform 50 under the back and seat sections 15, 16, respectively, of the patient support surface.

Arm Rail Mechanism

FIGS. 7A-7C illustrate the arm rail mechanism. The arm rails are made of steel, nylon, plastic gears, copper or nylon bushings, steel rods, custom cut metal blocks, snap rings, washers, rack and pinion, screws, springs, 1 latch or detent for the up-down feature and 1 latch or detent to release the rail from under the sleep surface.

The 2 frame rods are mounted through 2 holes in the sleep surface frame. The housing made of custom bent steel is mounted with screws or welded on the inside of the rail with 2 holes to house the gears and be the second guide for the 2 frame rods with bushings or washers on both sides. The frame rods are keyed to make the gears stay with the frame rods and spring loaded to push them out when they are released with the latch or manually pulled out. The custom made steel swing arms that move the rails low to high are welded to the frame rods on the outside of the bed. The glide mount rods are welded to the swing arms where there is a bushing inserted over the glide rods. The custom made glide blocks are mounted on top of the bushings with a washer on the inside and held on by snap rings on the outside. There are 2 holes in the glide blocks to mount the 2 glide slide rods though. A rack rod is mounted with the teeth facing up to the right guide block and a rack rod is mounted with the teeth facing down to the left guide block. The pinion gear is mounted in the center of the slide rods with the racks keyed into it to make sure the glide blocks move evenly in and out which causes the arm rail to travel straight up and down. The pinion is held in the center of the glide rods by a nylon mounting bracket that is screwed to the glide rods. The latch that holds the rail in any position is mounted through the top of the nylon mounting bracket stops the rails motion by hitting detent slots in the top of the upper rack.

DRAWING LEGEND

• 1. Rack
• 2. Pinion
• 4. Glide Slide Rods
• 7. Steel Swing Arms
• 9. Detent Bar
• 10. Release Latch

Comfort Side Chair Egress Mechanism

FIG. 8 illustrates the Comfort Side Chair Egress Mechanism. The comfort side chair egress is possible by attaching the Sleep Surface Seat Frame to the main structural tilt bar mount that sits on the rotating round aluminum plate 40. The main structural tilt bar mount 30 allows the Sleep Surface Seat Frame to be stopped in a flat position. When the sleep surface frame is rotated 90 degrees to either side of the main structural base frame, the scissors are raised high enough, the foot section 17 is 90 degrees vertically to main structural base frame and the seat 16 is flat or parallel to the main structural base frame, the bed can be manually positioned by the care giver into a chair perpendicular to the main structural base frame.

Comfort Side Standing Egress Mechanism

FIG. 9 illustrates the Comfort Side Standing Egress Mechanism. The comfort side standing egress is possible by attaching the Sleep Surface Seat Frame to the main structural tilt bar mount 30 that sits on the rotating round aluminum plate 40. The height of the main structural tilt bar mount allows the Sleep Surface Seat Frame to tilt 30 degrees down at the foot end. When the sleep surface frame is rotated 90 degrees to either side of the main structural base frame, the scissors are raised high enough, the foot section is kept perpendicular to the main structural base frame and a 30 degree tilt is applied to the seat, the bed will stand the patient up on the side of the bed.

PCV Tilt Mechanism

FIG. 10 illustrates a PCV Tilt Mechanism. The triangle shaped main structural tilt bar mount 30 that allows the main support rod 20 for the sleep surface to stay high or lower than the foot section 17. If the main support rod 20 for the sleep surface remains higher than the front of the seat section 16 it allows for a 30 degree tilt forward. If it remains lower it allows for a 30 degree tilt backwards. The full range of motion is 60 degrees.

Manual Retracting and Extending Foot Section Mechanism

FIG. 11 illustrates a sleep surface support with a Manual Retracting and Extending Foot Section Mechanism. The Manual Retracting and Extending Foot Section Mechanism located inside the “Sleep Surface Foot Frame” is made of one piece of channel iron welded to each side of the sleep surface foot frame to create a track to slide the extension in and out. There are manual stops going in and set pins on the outside to release it out. It is spring loaded to push out when the pin is released and will retract with pressure until it locks itself going in.

Claims

1. A hospital bed with arm rail mechanisms, comprising: a pair of arm rail mechanisms, one attached to each side of a hospital bed, the arm rail mechanisms respectively comprising: a latch that releasably locks a corresponding arm rail in position;at least one horizontally extending rack with gear teeth in communication with the latch; anda pinion gear in communication with the gear teeth of the at least one rack, wherein the rack and pinion gears allow the corresponding arm rail to raise and lower vertically straight up and down,wherein the latch is a vertically extending latch with a top portion thereof extending above the rack and pinion gears.

2. A hospital bed with arm rail mechanisms, comprising: a pair of arm rail mechanisms, one attached to each side of a hospital bed, the arm rail mechanisms respectively comprising: a latch that releasably locks a corresponding arm rail in position;at least one horizontally extending rack with gear teeth in communication with the latch; anda pinion gear in communication with the gear teeth of the at least one rack, wherein the rack and pinion gears allow the corresponding arm rail to raise and lower vertically straight up and down,wherein the at least one rack is a pair of horizontally extending racks, one of the pair being an upper rack with the gear teeth facing downward, the upper rack residing above and in contact with the pinion gear and the other one being a lower rack with gear teeth facing upward, the lower rack residing below and in contact with the pinion gear.

3. The hospital bed of claim 2, wherein the upper rack has a top surface with spaced apart detent slots, and wherein the latch holds the arm rail in a desired position by engaging a respective detent slot.

4. The hospital bed of claim 2, wherein the arm rail mechanisms further comprise: a pair of horizontal guide slide rods, one residing above the upper rack and one residing below the lower rack with the pinion gear mounted in a center space between the guide slide rods;first and second spaced apart guide blocks slidably mounted to the guide slide rods, one residing on a left side of the pinion gear and one residing on a right side of the pinion gear, the guide blocks configured to translate to move apart and closer together, to lower and raise a respective arm rail; anda pair of swing arms having opposing first and second end portions, the first end portion of one of the swing arms pivotably attached to a first guide block and the first end portion of the other swing arm attached to the second guide block, wherein the second end portion of each swing arm is pivotably attached to the bed frame whereby the swing arms translate the guide blocks horizontally along the glide slide rods to raise the rack and pinion gears and the corresponding arm rail to a vertical uppermost configuration above the bed frame.

5. The hospital bed of claim 4, whereby the swing arms translate the guide blocks closer together and further apart along the guide slide rods to lower the rack and pinion gears to a vertical lowermost configuration.

6. The hospital bed of claim 4, wherein the swing arms have a first angled orientation when an arm rail is in a vertical uppermost position, a second angled orientation that is the mirror image of the first angled orientation in a vertical lowermost position, and a substantially horizontal orientation in an intermediate position between the uppermost and lowermost positions.

7. A hospital bed with arm rail mechanisms, comprising: a pair of arm rail mechanisms, one attached to each side of a hospital bed, the arm rail mechanisms respectively comprising: a latch that releasably locks a corresponding arm rail in position;at least one horizontally extending rack with gear teeth in communication with the latch; anda pinion gear in communication with the gear teeth of the at least one rack, wherein the rack and pinion gears allow the corresponding arm rail to raise and lower vertically straight up and down,wherein the arm rails have an upper portion that is horizontal in a normal bed orientation, and wherein the arm rails are configured to translate with a patient sleep support surface to a side chair egress position whereby the arm rails reside on opposing sides of the patient sleep support surface with the upper portion in the normal bed orientation being an outwardly extending portion with a substantially vertical orientation.

8. The hospital bed of claim 7, further comprising a pair of side rails, one attached to each long side of a foot section of the patient support surface to be able to translate therewith to the side chair egress position and take on a vertical orientation when the patient support surface is in the side egress chair egress position.

9. An arm rail mechanism for a hospital bed, comprising: an arm rail attached to a bed frame, wherein the arm rail comprises an arm rail mechanism with at least one rack gear in communication with a pinion gear, the arm rail mechanism being configured to allow the arm rail to translate vertically up and down to different height positions,wherein the at least one rack gear comprises an upper horizontally extending rack gear and a lower horizontally extending rack gear, the upper rack gear residing above the pinion gear and the lower rack gear residing below the rack gear, each rack gear being in contact with the pinion gear.

10. The arm rail mechanism of claim 9, wherein the upper rack comprises detent slots that cooperate with a latch to lock the arm rail in a desired position.

11. An arm rail mechanism for a hospital bed, comprising: an arm rail attached to a bed frame, wherein the arm rail comprises an arm rail mechanism with at least one rack gear in communication with a pinion gear, the arm rail mechanism being configured to allow the arm rail to translate vertically up and down to different height positions;upper and lower horizontally extending guide slide rods, one positioned above the pinion gear and one positioned below the pinion gear; anda latch in communication with at least one of the slide rods, wherein the guide slide rods and latch translate vertically down to lower the arm rail.

12. The arm rail mechanism of claim 11, further comprising a pair of swing arms attached to the guide slide rods, one on each side of the pinion gear.

13. The arm rail mechanism of claim 12, further comprising a pair of guide blocks in communication with the guide slide rods, one on each side of the pinion gear.