The invention relates to support mechanisms for hospital bed siderails. In one of its aspects, the invention relates to a four-bar link for a support mechanism with an anti-binding feature. In another of its aspects, the invention relates to a siderail support mechanism with an under-bed retracting feature.
Four-bar link mechanisms require careful dimensional control to avoid binding as the mechanism traverses through a full range of motion. As the four-bar link is required to pass a “zero” point wherein the arms are required to change relative position, this is especially important.
Hospital bed siderails are used in an upright position, but when in a stowed position that is in the same plane as the upright position, the siderail can interfere with access by a health care provider. Known hospital bed siderails further require a two-handed operation to raise to a deployed position or to lower to a stowed position.
It would be advantageous to provide a siderail locking mechanism that securely locks the siderail in the upright deployed position, but that is also capable of being unlocked and rotated to a stowed position using a one-handed operation and without binding, and that is further capable of being moved completely out of the way when in the stowed position, such as in a retracted position underneath the bed.
A siderail support mechanism comprises a bottom cross-member having a first lower pivot and a second lower pivot, a first support arm and a second support arm. The first support arm includes a first upper pivot shaft and a first lower pivot shaft, the first upper pivot shaft being configured to pivotally attach to the siderail at a first upper pivot and the first lower pivot shaft configured to pivotally attach to the first lower pivot of the bottom cross-member. The first upper pivot includes an oblong slot. The second support arm includes a second upper pivot shaft and a second lower pivot shaft, the second upper pivot shaft being configured to pivotally attach to the siderail at a second upper pivot and the second lower pivot shaft configured to pivotally attach to the second lower pivot of the bottom cross-member.
In a further embodiment, the siderail support mechanism includes a locking arm pivotally mounted to the siderail at a first end and having a locking tooth at a second end, the locking arm being biased downwardly by a spring for the locking tooth to engage a locking cog mounted on the second upper pivot shaft when the siderail is in an upright, deployed position.
In a further embodiment, the siderail support mechanism includes a locking mechanism and a lock release mechanism including a handle positioned at the center of gravity of the siderail. The handle is configured for one-handed operation of the lock release and lowering of the siderail to a stowed position.
In a further embodiment, the bottom cross-member includes a retraction mechanism. The retraction mechanism includes a pair of mounting brackets for attachment to a bed frame. A pair of retracting arms are pivotally attached between the mounting brackets and the bottom cross-member to form a four-bar link.
Certain terminology will be used in the following description for convenience in reference only and will not be limiting. The words “up”, “down”, “right” and left” will designate directions in the drawings to which reference is made. The words “in” and “out” will refer to directions toward and away from, respectively, the geometric center of the device and designated parts thereof. The words “head” and “foot” will refer to the respective ends of a hospital bed, and the word longitudinal refers to an orientation parallel to a line running from the head to the foot of the bed. Such terminology will include derivatives and words of similar import.
Referring to
The synchronizing link 65 is connected to the bottom cross-member 40 by a load spring 80 connected to the synchronizing link 65 at a fastener 85 and to the bottom cross-member 40 at spring anchor 90. The synchronizing link 65 is further connected to the bottom cross-member 40 by a gas cylinder 95 secured to the synchronizing link 65 at a fastener 100 and to the bottom cross-member 40 at a gas cylinder anchor 105.
The siderail 15 includes an oblong slot or aperture 110 for receiving the first upper pivot shaft 25. The oblong aperture 110 has a minor vertical axis with a diameter substantially equivalent to the diameter of the first upper pivot shaft 25 and a major horizontal axis having a diameter greater than the diameter of the minor axis and defined by a left extent 112 and a right extent 114. The major axis of the oblong aperture 110 is substantially parallel to a line drawn between the centers of the first and second upper pivot shafts 25, 35. The siderail 15 further includes a regular aperture (not shown) for closely receiving the second upper pivot shaft 35. A wheel cog 115 is mounted on the second upper pivot shaft 35 and includes a radially projecting locking cog 120. The wheel cog 115 is affixed to the second upper pivot shaft 35 in a manner to be rotatably fixed with respect to the second support arm 30.
The siderail 15 further includes a pivotally connected locking arm 125. The locking arm 125 pivots on a pivot pin 130 at a first end thereof and includes a locking tooth 135 at a second end thereof. The locking arm 125 is biased downwardly by a spring 140. The siderail 15 further includes a lock release handle 145 pivotally connected to the siderail 15 by a pivot pin 150. The lock release handle 145 includes a contact pad 155 adapted for grasping by an operator and a locking arm engaging projection 157 configured to engage the underside of the locking arm 125.
The lock release handle 145 and contact pad 155 are configured so that as the operator grasps the contact pad 155, the operator is applying the force in a centered position between the upper pivot shafts 25, 35 and coinciding with the center of gravity of the siderail 15. The operator is thus able to grasp and support the siderail 15 in a balanced fashion, disengage the locking arm 125, and lower the siderail 15, in a one-handed operation.
Referring specifically to
The siderail 15 includes an integrally molded stop 122 adjacent to the locking cog 120 of the wheel cog 115 to prevent further clockwise rotation of the wheel cog 115 from the position shown in
The siderail 15 is prevented from rotating to a lower position due to the action of the locking tooth 135 of the locking arm 125 with the locking cog 120 of the wheel cog 115. As shown in
As the support arms 20, 30 rotate counterclockwise about the first and second lower pivot shafts 45, 50, the first upper pivot shaft 25 shifts laterally within the oblong slot 110.
As the siderail mechanism 10 is further rotated counterclockwise to the zero point shown in
As the siderail 15 is lowered, the load spring 80 reduces the apparent load or weight of the siderail 15 to the operator. The gas cylinder 95 acts as a damper to soften the drop of the siderail 15. In concert, the load spring 80 and gas cylinder 95 can lower the siderail 15 in a controlled fashion upon release by the operator.
Referring now to
A sequence of movement of the first upper pivot shaft 25 within the oblong slot 110 is illustrated in
In order to raise the siderail 15, an operator can grasp the siderail 15 at any convenient location. As shown in
Referring now to
The first mounting bracket 165 includes a horizontally oriented base plate 175 and an upstanding edge wall 180. In the plan view of
A retracting arm 210 is pivotally mounted to the base plate 175 within the cavity 185 by a pivot pin 215 passing through a base end 220 of the retracting arm 210. The retracting arm 210 is pivotally mounted centered within the cavity 185 proximate the bight portion 187 of the wall 180, and extends between the legs 190, 195 to a free end 225 extending beyond the base plate 175. The retracting arm 210 is free to pivot through a range defined by a pair of stops 230, 235 formed at the end of each respective leg 190, 195 of the wall 180.
The free end 225 further includes a depending portion 240 (
In the upright, deployed position of
While the invention has been described in the specification and illustrated in the drawings with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention as defined in the claims. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment illustrated by the drawings and described in the specification as the best mode presently contemplated for carrying out this invention, but that the invention will include any embodiments falling within the scope of the appended claims.
Number | Name | Date | Kind |
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6751815 | Heimbrock et al. | Jun 2004 | B1 |
6938289 | Morin | Sep 2005 | B1 |
Number | Date | Country | |
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20060090259 A1 | May 2006 | US |