CA2359595A1 - Extruded siderail apparatus - Google Patents

Abstract

A modular siderail (20) for attachment to a bed includes a first end section (38) having a first end (40) and a second end (42). The second end (42) includes a connector joint (44). The modular siderail (20) also includes a second end section (38) substantially identical to the first end section (38).
A connector joint (42) of the second end section (38) and the connector joint (42) of the first end section (38) are configured to mate and together to form a skeletal structure (222).

Description

EXTRUDED S>DERAIL APPARATUS
Back;~round and Summary of the Invention This invention relates to siderails for beds and more particularly to modular siderail systems for forming skeletal structures of differing length siderails for hospital beds using various combinations of only two major skeletal components.
Health care facilities typically provide patients with beds that have siderails to prevent patients from falling out of their beds during sleep or seizures and to provide a convenient location for controls for bed positioning, nurse call buttons, speakers, television, room lighting, etc. Hospital beds are provided with siderails of differing lengths to meet the patient's needs and the hospital's aesthetic preferences.
Therefore, hospital bed suppliers must have access to hospital bed siderails of varying lengths so that they can meet their customers' preferences in filling orders for beds.
Hospital beds typically include siderails on each side of the bed. Often components of left and right siderails are not interchangeable requiring bed suppliers to maintain additional components in their inventories.
Hospital bed suppliers would welcome a modular siderail that includes a skeleton which can be assembled in varying lengths using a minimum number of components designed to be freely interchangeable between left siderails and right siderails.
A bed siderail system in accordance with the present invention includes a first skeletal end section having an exterior end and in interior end with a connector thereon, a second skeletal end section substantially identical to the first skeletal end section, and at least one extender having a first end with a connector thereon and a second end with a connector thereon connectable to the connector of the first and second skeletal end sections. The first and second skeletal end sections can be directly connected through the connectors on their internal ends to form a shorter length siderail, the connector of the first end section can be directly connected to one end of an extender and the connector of the second skeletal end section can be connected to the second end of the extender to form a siderail having a longer length.
Multiple extender sections can be disposed between the first skeletal end section and the second skeletal end section to form even longer bed rails.

It will be appreciated therefore, that the invention is a siderail frame comprising a pair of end sections each having a cross sectional extruded shape providing an exterior and interior end such that the interior ends of the end sections are joinable to form a siderail frame. Extender sections are also provided which are joinable to the end sections to form extended siderail frames.
Features and advantages of the invention will become apparent to those skilled in the art upon consideration of the following detailed description of an illustrated embodiment exemplifying the best mode of carrying out the invention as presently perceived.
Brief Description of the Drawings Fig. 1 is a perspective view of a half-length siderail skeleton in accordance with the present invention showing two identical end sections connected together at connectors on their interior ends to form the half-length siderail skeleton;
Fig. 2 is a plan view of the half-length siderail skeleton of Fig. 1;
Fig. 3 is a perspective view of a three-quarters length siderail skeleton formed from two end sections identical to the end sections shown in Fig. 1 connected to a central extender section to form the three-quarters length siderail skeleton;
Fig. 4 is a plan view of the three-quarter length siderail skeleton of Fig.

3;
Fig. 5 is a perspective view of a full length siderail skeleton formed from two end sections identical to the end sections shown in Fig. 1 joined to two central extender sections identical to the extender section shown in Fig. 3 to form the full length siderail skeleton;
Fig. 6 is a plan view of an end section of a modular siderail skeleton system;
Fig. 7 is a top plan view of the end section of Fig. 6;
Fig. 8 is a perspective view of the end section of Fig. 6;
Fig. 9 is a perspective view of the end section of Fig. 8 rotated 180 degrees about axis 9-9 of Fig. 8;
Fig. 10 is a plan view of an extender designed to be disposed between two end sections to form siderail skeletons of three-quarter or full length;

Fig. 11 is a top view of the extender of Fig. 10; and Fig. 12 is an exploded view of a half length siderail having an internal skeleton formed from two end sections around which two shell sections are secured to form a housing in which circuit boards for the controls and speakers may be received.
Detailed Description of the Drawings Referring to Fig. 12, there is illustrated a siderail 20 for attachment to a hospital bed (not shown). Siderail 20 helps to prevent a patient from falling out of the bed and also provides a convenient location for switches, controls, and speakers.
Siderail 20 consists of a skeletal structure or skeleton 22, circuitry and switches on circuit boards 24, speaker 26, and a molded shell 32 which partially encloses skeletal structure 22 and encloses the circuit boards 24 and speaker 26 therein. In the illustrated embodiment of siderail 20, a caregiver-facing shell half 28 and a patient-facing shell half 30 are joined with screws 29 to form exterior shell 32 of siderail 20.
Siderail 20 is attached by screws, bolts, or other fasteners (not specifically shown but represented by lines 85 in Fig. 12) to first end 34 of arm mechanisms 36 which are connected at second end to the frame of the bed.
As can be seen in Fig. 12, illustrative skeleton 22 of siderail 20 is symmetrically formed so that caregiver-facing shell half 28 and patient-facing shell half 30 can be attached in either direction to skeleton 22. Caregiver-facing shell half 28 and patient-facing shell half 30 at first glance appear to be substantial mirror images of each other. In actuality caregiver-facing shell half 28 and patient-facing shell half 30 differ in that patient facing shell half 30 typically includes attachment holes 80 therethrough to allow attachment of siderail 20 to arm mechanisms 36, a speaker grill 31 behind which the diaphragm of speaker 26 is located in the assembled siderail 20, and either more, or fewer, controls. The illustrated structure can be assembled to form a left siderail 20 (from the perspective of the patient lying supine in the bed to which siderail is attached) as shown in Fig. 12. A right siderail 20R (not shown) may be formed by attaching true mirror images 28R, 30R (not shown) of caregiver-facing shell half 28 and patient-facing shell half 30 respectively in the opposite direction from that shown in Fig. 12. Therefore, left and right siderails can be formed from the skeletal structure 22 reducing the need for differently configured parts to form siderails 20 for beds.
Refernng to Figs. 1, 2, and 12, a half length siderail skeleton 222 includes two identical end sections 38 oriented in opposite directions and joined together. Each end section 38 includes an exterior (or first) end 40 and an interior (or second) end 42 with interior end 42 being formed to allow end section 38 to be joined to another end section 38 (or another skeletal component as will be described later).
Because skeletal structure 222 of half length siderail 20 is formed from two identical components, mirror images of a longitudinally divided shell can be attached to keletal structure 222 in opposite orientations to form a left siderail and a right siderail.
Referring now particularly to Figs. 1, 2, and 6-9, the presently preferred embodiment of end section 38 is shown. End section 38 is designed and arranged so that two identically configured end sections 38 may be joined to form a skeleton 222 of a half length siderail. End section 38 has an exterior end 40 and an interior end 42 having connectors 44. Illustratively, end section 38 is formed by extrusion of an aluminum alloy in the shape shown in Fig. 6. End section 38 is sliced, cut or otherwise separated from the end-shaped extrudate to have a first side 46 and a substantially parallel second side 48 defining a thickness 50, as shown for example in Fig. 7.
End section 38 has an upper member 52, a middle member 54, and a lower member 56 with these members 52, 54, 56 being connected at exterior end and being spaced apart at interior end 42 as shown in Fig. 6. Upper support 58 extends substantially vertically between upper member 52 and middle member 54 and lower support 60 extends at an angle from near interior end 42 of middle member 54 to near exterior end 40 of lower member 56 to increase the structural rigidity of end section 38.
Either during or after the separation of end section 38 from the end-shaped extrudate, shoulders 66 and cheeks 64 of lap scarf end joints 62 are milled, machined, or otherwise formed adjacent to interior end 42 of upper member 52, middle member 54, and lower member 56 of end section 38. Cheeks 64 extend from interior end 42 substantially parallel to sides 46, 48 of each of upper member 52, middle member 54, and lower member 56 of end section 38 to shoulder 66.
Shoulder 66 extends substantially perpendicular from cheek 64 and first side 46 of each of upper member 52, middle member 54, and lower member 56 of end section 38 as shown, for example in Fig. 7. Cheek 64 has a width 68, so shoulder 66 is displaced from interior end 42 by displacement 68. Shoulder 66 has a depth 70, so cheek 64 is displaced from first side 46 of end section 38 by a known displacement 70 equal to one-half of thickness 50 and is thus also displaced by displacement 71 equal to displacement 70 from second side 48 of end section 38.
Lap scarf joints 62 facilitate the joining of one end section 38 to another end section 38, as shown, for example, in Fig. 12, or to another skeletal component as is described hereinafter. Since depth 70 of shoulder 66 is one-half thickness 50 of end section 38, two end sections 38, or an end section 38 and another skeletal component, can be joined cheek 64 to cheek 64 to form a unit having a width 74 which is the same as thickness 50 of end section 38. Extending substantially perpendicular through cheek 64 and second side 48 is a connection hole 76.
Connection hole 76 is preferably formed during the extrusion of end-shaped extrudate but may be drilled through end section 38 after separation from end-shaped extrudate.
Center 77 of connection hole 76 is displaced from interior end 42 by a displacement 180 equal to one half width 68 of cheek 64 and is also displaced from shoulder 66 by displacement 182 equal to one-half width 68 of cheek 64.
Referring to Figs. 8 and 9, when end section 38 is rotated 180 degrees about axis 9-9, cheek 64 and shoulder 66 are positioned to form a lap scarf joint 62 with cheek 64 and shoulder 66 of another non-rotated end section 38. During assembly of half length siderail skeleton 222, two substantially identical end sections 38, one rotated 180 degrees about axis 9-9 relative to the other, are joined together so that cheeks 64 and shoulders 66 on the corresponding upper members 52, middle members 54, and lower members 56 form three lap scarf joints 62 as shown in Figs. 1 and 12. When the corresponding interior ends of each of the members 52, 54, 56 of each end section 38 abut shoulders 66 of the corresponding members 52, 54, 56 of the other end section 38, the three connection holes 76 in each end section 38 are aligned with the corresponding connection holes 76 in the other end section 38. A
screw, bolt, dowel, rivet, or other fastener 72 extends through connection holes 76 of oppositely oriented end sections 38 to form half length siderail skeleton 222, as shown, for example, in Figs. 1 and 12.
Also located on lower member 56 of end section 38 is attachment structure 78 for attaching siderail 20 to arm mechanisms 36 of a bed. As shown, for example, in Fig. 12, patient-facing shell half 30 of plastic shell 32 is formed with holes 80 therethrough so that connectors (not specifically shown but indicated by lines 85 in Fig. 12) can pass through plastic shell 32 and through attachment holes formed in attachment structure 78 in skeletal structure 22 of siderail 20. In the illustrated embodiment, a fastener such as a screw, rivet, bolt, dowel or other device (not specifically shown but indicated by lines 85 in Fig: 12) is assumed to extend from central axes 84 of arm mechanisms 36 through holes 80 in plastic shell 32 and attachment holes 82 in attachment structure 78. Center 81 of attachment hole 82 is displaced from center 77 of connection hole 76 on lower member 56 of end section 38 by a distance 86. Distance 86 is one-half the displacement 88 between central axes 84 of arm mechanisms 36. Thus, when two end sections 38 are joined to each other center 81 of attachment hole 82 of each end section 38 is separated from center 81 of attachment hole 82 of the joined end section 38 by a distance 90 equal to displacement 88 between central axes 84 of arm mechanisms 36 to facilitate attachment of siderail to arm mechanisms 36 with fasteners (not specifically shown).
As shown in Figs. 3, 4, 5, skeletons for siderails having lengths greater 20 than half length siderail skeleton 222 can be formed by joining two oppositely oriented end sections 38 to one or more centrally located extender sections 92. The presently preferred embodiment of extender section 92 is illustrated in Figs.
10 and 11. Extender section 92 has an upper arm 94, a middle arm 96, and a lower arm bidirectionally extending from a strut 100 centrally connecting upper arm 94, lower arm 98, and middle arm 96. Extender section 92 has a height 102 from the bottom 104 of lower arm 98 to the top 106 of upper arm 94 which is equal to height (Fig. 6) between top 110 of upper member 52 and bottom 112 of lower member 56 of end section 38 at interior end 42. Middle arm 96 is displaced from upper arm 94 by displacement 114 which is equal to displacement 116 (Fig. 6) between middle member 54 and upper member 52 of end section 38 at interior end 42. Middle arm is displaced from lower arm 98 by displacement 118 which is equal to displacement 120 (Fig. 6) between middle member 54 and lower member 56 of end section 38 at WO 00/53059 PC'r/US00/05940 interior end 42. The equivalence of height 102 and height 108, displacement 114 and 116, and displacement 118 and displacement 120 respectively facilitates the joining of end section 38 to extender section 92.
Extender section 92 is also preferably formed by extrusion of aluminum alloy. Extender section 92 is separated from extender-shaped extrudate to have a first side 122 and a second side 124 defining a thickness 126 equal to thickness 50 of end section 38. During or after separation of extender section 92 from extender-shaped extrudate, shoulders 130 and cheeks 128 are cut, milled, machined, or otherwise formed at first end 132 of each arm 94, 96, 98 of extender section 92 and shoulders 136 and cheeks 134 are cut, milled, machined, or otherwise formed at second end 138 of each arm 94, 96, 98 of extender section 92. Cheeks 128 and shoulders 130 on first end 132 of each arm 94, 96, 98 are formed by removing material from first side 122 of extender section 92 while cheeks 134 and shoulders 136 on second end 138 of each arm 94, 96, 98 are formed by removing material from second side 124 of extender section 92, as shown, for example, in Fig. 11.
Cheeks 128 extend from first end 132 substantially parallel to sides 122, 124 of each of upper arm 94, middle arm 96, and lower arm 98 of extender section 92 to shoulders 130. Shoulders 130 extend substantially perpendicular from cheeks 128 to first side 122 of each of upper arm 94, middle arm 96, and lower arm 98 of extender section 92. Cheeks 128 have a width 140, so shoulders 130 are displaced from first end 132 by displacement 140. Shoulders 130 have a depth 142, so cheeks 128 are displaced from first side 122 of extender section 92 by a known displacement 142 equal to one-half of thickness 126. Cheeks 128 are also displaced by displacement 143 equal to displacement 142 from second side 124 of extender section 92.
Similarly cheeks 134 extend from second end 138 substantially parallel to sides 122, 124 of each of upper arm 94, middle arm 96, and lower arm 98 of extender section 92 to shoulders 136. Shoulders 136 extend substantially perpendicular from cheeks 134 to second side 138 of each of upper arm 94, middle arm 96, and lower arm 98 of extender section 92. Cheeks 134 have a width 144, so shoulders 136 are displaced from second end 138 by displacement 144. Shoulders 136 have a depth 146, so cheeks 134 are displaced from second side 124 of extender _g_ section 92 by a known displacement 146 equal to one-half of thickness 126.
Cheeks 134 are also displaced by displacement 147 equal to displacement 146 from first side 122 of extender section 92.
Widths 68, 140, 144 of cheeks 64, 128, 134 respectively are equal as are depths 70, 142, 146 of shoulders 66, 130, 136 to facilitate joining extender sections 92 with other extender sections 92 or end sections 38 using lap scarf joints 62. Since depth 70 of shoulder 66 is one-half thickness 50 of end section 38 and depths 142, 146 of shoulders 130, 136 are one-half thickness 126 and thickness 50 is equivalent to thickness 126, an end section 38 and another skeletal component, can be joined cheek 64 to cheek 128, 134 to form a unit having a width 148 which is the same as thickness 50 of end section 38 and thickness 126 of extender section 92.
Likewise two extender sections 38 can be joined cheek 128 to cheek 134 to form a unit having a width 148 which is the same as thickness 50 of end section 38 and thickness 126 of extender section 92.
Extending substantially perpendicular through cheeks 128 and first side 122 and through cheeks 134 and second side 124 are connection holes 150.
Connection holes 150 are preferably formed during the extrusion of extender-shaped extrudate but may be drilled through extender section 92 after separation from extender-shaped extrudate. Centers 152 of connection holes 150 are displaced from first and second ends 132, 138 respectively by a displacement 154 equal to one half of widths 140, 144 of cheeks 128, 134 respectively. Centers 152 of connection holes 150 are also displaced from shoulders 130, 136 respectively by displacement equal to one-half of widths 140, 144 of cheeks 128, 134 respectively. Since displacements 154, 156, 180, and 182 are all equal, connection holes 150, 76 align when lap scarf joints 62 are formed during connection of extender sections 92 and end sections 38.
As a result of the configuration of end section 38 and extender section 92, extender section 92 can be connected to two oppositely facing end sections 38 or to one end section 38 and another extender section 92 to form skeletal structures of varying lengths. For example, Fig. 3 illustrates a three-quarters length siderail skeleton 322 formed from two end sections 38 with an extender section 92 disposed therebetween while Fig. 5 illustrates a full length siderail skeleton 422 formed from two end sections 38 with two extender sections 92 disposed therebetween.
Lower arm 98 also includes an attachment structure 158 to facilitate attaching a skeletal structure including at least one extender section 92 and two end sections 38 to arm mechanisms 36 of a bed. In the illustrated embodiment, attachment structure 158 is formed to include an attachment hole 160 extending substantially perpendicularly through extender section 92 between first side 122 and second side 124. Center 161 of attachment hole 160 is displaced from centers 152 of connection holes 150 by a displacement 162 which is the same as displacement 86 of attachment hole 82 of end section 38 from connection hole 76 of end section 38.
Thus, when extender section 92 is connected to end section 38 the displacement between center 81 of attachment hole 82 of end section 38 and center 161 of attachment hole 160 of extender section 92 is equal to the displacement 88 between central axes 84 of arm mechanisms 36. Likewise when two extender sections 92 are connected together, the displacement 166 between center 161 of attachment hole in first extender section 92 and center 161 of attachment hole 160 in second extender section 92 is equal to displacement 88 between central axes 84 of arm mechanisms 36.
Thus, siderails 20 made with the disclosed modular skeletal structure are appropriately adapted for attachment to arm mechanisms 36 regardless of the number of components forming, and overall length of, the siderail because attachment holes 82, 160 are always equally spaced apart with a displacement 90, 164, 166 equal to the displacement 88 between central axes 84 of arm mechanisms 36.
While in the illustrated and described embodiments, end section 38 and extender section 92 have been referred to as being formed from an aluminum alloy, it is to be understood that these components 38, 92 may be formed from other metal alloys, composite materials, thermal plastics or other materials within the scope of the invention. Likewise, while extrusion is the preferred method of forming these components 38, 92, components 38, 92 which have been molded, stamped, or otherwise formed or assembled are within the teaching of the invention.
While the illustrated embodiments of the components 38, 92 are formed to create lap scarf joints 62 when assembled, other joint configurations and connectors which minimize the number of skeletal components 38, 92 are within the teaching of the invention, such as scarf joints, splayed lap scarf joints, and other symmetrical joints and connectors. Symmetrical joints and connectors need not be included when end sections and extender sections are formed from materials such as thermal plastics or the like that are conducive to joining using butt to butt using welding, glues or adhesives.
While the invention has been described as being used with a housing which is attached thereto to form a siderail, it is within the teaching of the invention for the siderail skeleton alone to form the siderail. It is also within the teaching of the invention for the assembled siderail skeleton to be dipped in vinyl or some other molten material to form a coating on siderail skeleton and for the coated siderail skeleton to serve as siderail.
Although the invention has been described in detail with reference to a certain illustrated embodiment, variations and modifications exist within the scope and spirit of the invention as described and defined in the following claims.

Claims (32)

1. A modular siderail for attachment to a bed comprising:
a first end section having a first end and a second end, the second end including a connector joint, a second end section substantially identical to the first end section, and, wherein the connector joint of the second end section and the connector joint of the first end section are configured to mate together to form a skeletal structure.

2. The apparatus of claim 1 wherein the first and second end section have an identical width and the connector joint is formed to include a shoulder having a depth equal to half the identical width.

3. The apparatus of claim 1 wherein the first and second end sections are configured to form a lap scarf joint when mated.

4. The apparatus of claim 1 wherein the connector joint is formed to include a connection hole and each end section is formed to include an attachment hole configured to receive one of a pair of spaced apart fasteners extending from the bed, the attachment hole being displaced from the connection hole by an on center displacement equal to half of the on center displacement of the two fasteners.

5. The apparatus of claim 1 and further comprising an extender having a first end and a second end, the first and second ends of the extender each including connectors configured to mate with the connectors of the second end suction and the connectors of the first end section to form a skeletal structure.

6. The apparatus of claim 5 wherein the connector of the first end of the extender is configured to mate with the connector of the second end of the extender facilitating formation of varying length skeletal structures.

7. The apparatus of claim 6 wherein a single extender suction is joined at the first end of the extender to the first end suction and at the second end of the extender to the second end section.

8. The apparatus of claim 6 wherein the first extender is joined at its first end to the first end section and at the second end of the first extender to the first end of a second extender section which is joined at its second end to the second end section.

9. A siderail system for a bed comprising:
a first skeletal section having a first end and an second end, the second end having a connector, a second skeletal section substantially identical to the first skeletal section, at least one extender having a first end having a connector and a second end having a connector, wherein the connector of the first skeletal section is directly connectable to the connector of the second skeletal section to form a siderail having a shorter length and the connector of the first skeletal section is directly connectable to the connector of the first end of the extender and the connector of the second end of the extender is connectable to the connector of the second skeletal section to form a siderail having a longer length.

10. The apparatus of claim 9, and further comprising a plurality of extenders each having a first end having a connector and a second end having a connector, and wherein the connector of the first skeletal section is directly connectable to the connector of the first end of one of the plurality of extenders, the connector of the second end of one of the plurality of extenders is connectable to the connector of another of the plurality of extenders, and the connector of the second end of the other of the plurality of extenders is connectable to the connector of the second skeletal section to form a siderail having a longest length.

11. A method of manufacturing the skeletal structure of a bed rail comprising the steps of:
extruding an end-shaped extrudate having a first end and a second end, separating two end sections each having a first end and a second end from the extruded end-shaped extrudate, and, forming connectors on the second end of the separated end sections;

12. The method of claim 11 and further comprising the step of joining the connectors of the two end sections.

13. The method of claim 11 and further comprising the steps of:
extruding an extender-shaped extrudate having a first end and a second end, separating an extender section having a first end and a second end from the extruded extender-shaped extrudate, and, forming connectors on the first end and second end of the separated extender section.

14. The method of claim 13 and further comprising the steps of:
joining the connector of one of the end sections to the connector of the first end of the extender section, and, joining the connector of the other end section to the connector of the second end of the extender section.

15. The method of claim 13 and further comprising the steps of:
separating a second extender section having a first end and a second end from the extruded extender-shaped extrudate, forming connectors on the first end and second end of the second extender section, joining the connector of one of the end sections to the connector on the first end of the first extender section, joining the connector of the second end of the first extender suction to the connector of the first end of the second extender section, and, joining the connector of the other end section to the connector of the second end of the second extender section.

16. A siderail frame comprising a pair of end sections, each having a skeletal structure formed to provide substantially identical coupling regions, said end sections capable of being coupled to one another at their substantially identical coupling regions to provide said frame.

17. The frame of claim 16 wherein the end sections are substantially identical.

18. The frame of claim 16 further comprising an extender section joined between the end sections to provide an elongated frame.

19. The frame of claim 18 wherein the extender section has a skeletal structure.

20. A siderail frame comprising:
a pair of substantially identical end sections, each having a skeletal structure to provide a first end and a second end; and at least one extender section positioned between the end sections to provide a more elongated frame.

21. The siderail frame of claim 16 further comprising a cover coupled to the end sections.

22. The siderail frame of claim 21 wherein the cover includes a plurality of cover sections coupled together to form the cover.

23. The siderail frame of claim 22 wherein the plurality of cover sections are substantially identical.

24. A siderail system comprising:
a plurality of frame sections including end sections and extender sections;
and a plurality of covers, at least two of the plurality of frame sections being coupled together to form a frame, and one of the plurality of covers being coupled to the frame to form a siderail.

25. The siderail system of claim 24 wherein each of the plurality of frame sections has substantially identical coupling regions.

26. The siderail system of claim 24 wherein the plurality of frame sections includes two end sections.

27. The siderail system of claim 26 wherein the plurality of frame sections includes at least one extender section.

28. The siderail system of claim 24 wherein each of the plurality of covers includes a plurality of cover sections coupled together to form each of the plurality of covers.

29. A siderail frame comprising:
a pair of identical end sections, each having a skeletal structure formed to provide a coupling region, said end sections being coupled to one another at their coupling regions.

30. The siderail frame of claim 29 wherein the coupling regions of the end sections are substantially identical.

31. The method of claim 11, wherein the connectors are substantially identical.

32. The method of claim 11, wherein the end sections are identical.