The present invention relates to systems and methods for supporting an operator from a structure and, more specifically to structure support systems and methods that allow the operator to traverse the exterior of a structure for the purpose of cleaning or maintaining building components in the structure.
The maintenance of components of an exterior wall of a structure such as a multi-story building often requires one or more workers to be elevated above the ground. Ladders, scissor lifts, scaffolding, and other ground support systems and methods may be used if access to the exterior wall from the ground is available and/or convenient.
For certain exterior walls, the use of ground support system may not be feasible or otherwise desirable. Accordingly, certain support systems for allowing a worker access to the exterior wall of a structure are supported (e.g., suspended) from the structure itself.
The present invention relates to improved systems and methods for supporting an operator from a structure. The present invention is of particular significance when used to allow a worker to clean the exterior surface of elevated windows of a building, and that example of the present invention will be described herein in further detail. The present invention may, however, be used to allow a worker to perform other tasks related to a structure such as painting, repairing, and the like.
The present invention may be embodied as a suspension system for supporting an operator from a parapet of a building comprising first and second support assemblies adapted to engage the parapet, a first support line extending from the first support assembly to the first operator, and a second support line extending from the second support assembly to the first operator. At least one of the first and second support assemblies engages the parapet to support the operator relative to building. To allow the operator to move relative to the building, the weight of the operator is supported by one of the first and second support assemblies while the other of the first and second support assemblies is moved.
The present invention may also be embodied as a method of supporting a first operator from a parapet of a building comprising the following steps. First and second support assemblies are provided. First and second support lines are supported from the first and second support assemblies, respectively. The first support assembly is arranged to engage the parapet such that the first operator is suspended from the parapet by the first support assembly through the first support line. The second support assembly is supported relative to the first support assembly at a location spaced from the first support assembly and arranged to engage the parapet. The second support line is engaged to displace the first operator laterally in a desired lateral direction of travel.
The present invention may also be embodied as a support assembly for supporting an operator from a parapet of a building comprising a first portion adapted to engage a front surface of the parapet and a second portion adapted to engage a rear surface of the parapet. At least one of the first portion and the second portion is arranged to engage an upper surface of the parapet. The first portion is arranged to engage the front surface of the parapet. The second portion is displaced relative to the first portion to apply a force against the rear surface of the parapet such that the support assembly is clamped onto the parapet.
Referring initially to
The example structure 24 is or may be conventional and will be described herein only to that extent necessary for a complete understanding of the construction and operation of the first example building support system 20. The example structure 24 is a building that defines an exterior wall 30 in which windows 32 are formed. As is conventional, the exterior wall 30 defines a parapet 34 that extends above a roof 38 of the structure 24.
The example parapet 34 is representative of typical building construction techniques, and the first example building support system 20 is configured to accommodate parapets of different sizes, shapes, and construction. In that context, the example parapet 34 is described herein by way of example only, and the example building support system 20 may be used on parapets having different thickness dimensions, different flashing construction and dimensions, and the like. The term “parapet” is also intended to include building components such as walls, barriers, rails, or the like at the edge of a balcony, roof, bridge, or the like. The first example building support system 20 is adapted to accommodate different parapets and different types of structures 24 as will be apparent from the following discussion.
The example user support system 68 further comprises rope, cable, and/or hardware such as sliding couplings, shackles, carabiners, assisted braking belay device, ascender, or the like capable of performing the functionality as described herein. In particular, the first and second user support lines 64 and 66 are not secured together at the user support system 68 but are supported adjacent to each other for relative movement by the first and second operators 22 and 26 described herein. In addition, the first and second support lines 64 and 66 each define an effective length between the first and second support assemblies 60 and 62 and the user support system 68, respectively. The example user support system 68 is configured such that the first operator 22 alters the effective lengths of the first and second support lines 64 and 66 during use of the first example building support system 20.
The descender 80 allows the first operator 22 to set the elevation of the seat assembly 82 at or near the desired work level. The ascender 90 allows the first operator to raise and lower the level of the foot loop 92 relative to the second support line 66. The ability to move the foot loop 92 relative to the second support line 66 simplifies the process of swinging the user support system 68 laterally relative to the structure 24 as will be described in further detail below.
The example first and second support assemblies 60 and 62 are adapted to engage the parapet 34 as will be described in further detail below. The example first support lines 64 extends between the first support assembly 60 and the first user support 70 of the user support system 68. The example second support line 66 extends between the support assemblies 62 and the second user support 72 of the user support system 68.
In use, the first support assembly 60 is supported on the parapet 34 at a first primary support location above a first desired window 32a to be washed. Next, the first operator 22 rappels down the exterior wall 30 by playing out a first primary length of the first support line 64 until the first user support 70 is supported at a first desired work location at a first desired work level defined by the vertical elevation of first window 32a. The first user support 70 is configured to releasably hold the first support line 64 in the first primary length. The second support assembly 62 is initially supported by the parapet 34 at a first secondary location spaced from the first primary location, and the second support line 66 defines a first secondary length. The second user support 72 is configured to releasably hold the second support line 66 in the first secondary length. At this point, the first operator 22 sits on the first user support 70 and washes the first window 32a.
When the first window 32a is washed, the first operator 22 transfers the first operator's weight to the second user support 72 such that the first operator's weight is supported by the second support line 66 and is removed from the first user support 70 and first support line 64. By this action, the first operator 22 takes up slack in the second support line 66 to define a second secondary length as shown by a comparison of
At this point, with the first operator's weight removed from the first user support 70, the first user support line 64 is slack. Removing the first operator's weight from the first user support 70 provides enough slack on the first support line 64 to allow the first operator 22 to move from the first desired location to the second desired location without increasing the effective length of the first support line 64. For larger distances, the effective length of the first support line 64 may be increased and an effective length of the second support line 66 may be decreased while the first operator 22 moves from the first desired location to the second desired location.
With the weight of the first operator 22 still supported by the second user support 72, the second operator 26 may then displace the first support assembly 60 from the first primary support location to a second primary support location adjacent to the first secondary support location as shown in
When an entire row of the windows 32 is washed, the first operator 22 may move to another row above or below (typically below) the initial row by playing out a second primary length of the first support line 64 until the first user support 70 is supported at a second desired work level defined by the vertical elevation of second row of windows. The operators 22 and 26 may also change the direction of travel by reversing the process described above to move back along the structure 24. Repositioning the second support assembly 62 from one side to the other side of the first support assembly 60 may facilitate the changing of the direction of travel relative to the structure 24 but is not necessary.
In the example depicted in
The example first and second support lines 64 and 66 are secured at an upper end to the example first and second support assemblies 60 and 62, respectively. The example first support line 64 is connected to the first user support 70 by hardware capable of allowing the first operator to alter an effective length of the first support line 64 and to fix the effective length of the first support line 64 at a desired effective length. The example second support line 66 is connected to the foot line 72 by hardware capable of allowing the first operator to alter an effective length of the second support line 66 and to fix the effective length of the first support line 64 at a desired effective length. The hardware and configurations used to connect the first and second support lines 64 and 66 to the first and second support assemblies 60 and 62 and to the first user support 70 and the second user support 72, respectively, are or may be conventional and need not be described herein in detail.
Turning now to
The example first support assembly 60 comprises a first frame assembly 120, a second frame assembly 122, and one or more connecting bolt assemblies 124. At least one upper engaging surface 130 is formed on one or both of the first and second frame assemblies 120 and 122 and is configured to engage the flashing upper portion 50 such that downward loads on the example support assembly 60 are transferred to the upper surface 40 of the parapet 34. At least one first stabilizing surface 132 is defined by the example first frame assembly 120 and at least one second stabilizing surface 134 is defined by the example second frame assembly 122. The first and second stabilizing surfaces 132 and 134 oppose each other and, during normal use of the example support assembly 60, engage the front and rear surfaces 42 and 44, respectively, of the parapet 34.
In addition, the first and second frame assemblies 120 and 122 are adjustable to allow a distance between the first and second stabilizing surfaces 132 and 134 to be altered to conform to the thickness dimension 46 defined by the parapet 34. The example support assembly 60 thus can be adjusted to accommodate parapets having different thickness dimensions.
The example first frame assembly 120 comprises a frame member 140, a bearing member 142, and a first stabilizing member 144. The example bearing member 142 defines a first upper engaging surface 130b. In one example, each of the bearing member 142 and the first stabilizing member 144 is a removable component that is compressible and has a low coefficient of friction. In addition, the bearing member 142 and the first stabilizing member 144 are removably attached (e.g., by screws) to allow replacement when worn. The bearing member 142 and first stabilizing member 144 are may also be removably attached to increase the spacing distance between the example frame member 140 and the surface of the parapet 34 and thereby avoid contacting delicate parapet features such as the flashing front edge 56. As an example of a delicate parapet feature to be avoided, the flashing front edge 56 is designed to drip water away from the parapet front surface 42. The flashing front edge 56 is not structural and can be easily bent such that the aesthetic and functional properties of the parapet 34 are adversely affected.
The example stabilizing member 144 defines the example first stabilizing surface 132. The example frame member 140 comprises an upper first frame portion 150 and a lower first frame portion 152. An anchor flange 160 extends from the first frame portion 150. First and second guide flanges 162 and 164 extend from a juncture of the upper first frame portion 150 and the lower first frame portion 152. A guide surface 166 extends between the guide flanges 162 and 164. A guide channel 168 is defined between the guide flanges 162 and 164 and over the guide surface 166. First and second pairs of slots 174 are formed in the example upper first frame portion 150.
The example second frame assembly 122 comprises a frame member 180, an engaging assembly 182, and a lever assembly 184. Operation of the lever assembly 184 reconfigures the engaging assembly 182 between an unclamped configuration (
The example frame member 180 comprises an upper second frame portion 190 and a lower second frame portion 192. The example upper second frame portion 190 defines a second upper engaging surface 130a. At least one brace flange 194 extends from a juncture of the upper second frame portion 190 and the lower second frame portion 192. A support flange 196 extends from the lower second frame portion 192. First and second sets of holes 198 are formed in the upper second frame portion 190.
The example engaging assembly 182 comprises an engaging support 220, an engaging rod 222, and a second stabilizing member 224. The example engaging support 220 is pivotably supported by the support flange 196. The example engaging rod 222 threadingly engages the engaging support 220. The example second stabilizing member 224 is mounted on one end of the engaging rod 222 and defines the example second stabilizing surface 134.
In one example, the second stabilizing member 224 is a removable component having a low coefficient of friction, removably attached to engaging rod 222.
The example lever assembly 184 comprises a lever member 230 and a linkage assembly 232. The example lever member 230 is pivotably supported by the support flange 196. The example linkage assembly 232 is operatively connected between the engaging support 220 and the lever member 230 such that rotation of the lever member 230 between an unclamped position as shown in
The example linkage assembly 232 comprises a link member 240 operatively connected between the engaging support 220 and the lever member 230 such that rotation of the lever member 230 causes rotation of the engaging support 220. In particular, the engaging support 220 is pivotably connected to the support flange 196 by a first pivot member 250. The lever member 230 is pivotably connected to the support flange 196 at a second pivot member 252. The link member 240 is operatively connected to the engaging support 220 by a third pivot member 254 and to the lever member 230 by a fourth pivot member 256.
The pivot members 250, 252, 254, and 256 are offset from each other such that rotation of the lever member 230 from a disengaged position through an angle of approximately 75 degrees to an engaged position causes the engaging support 220 to rotate through an angle of approximately 90 degrees. As the lever member 230 moves from the disengaged position to the engaged position, the engaging support 220.
The fourth pivot member 256 is arranged within a stop notch 260 defined by the support flange 196 when the lever member 230 is in the engaged position. When the fourth pivot member 256 is within the stop notch 260, the linkage assembly 232 is an over-the-center linkage that inhibits movement of the lever member 230 from the engaged position to the disengaged position. However, the application of deliberate manual force to displace of the lever member 230 from the engaged position to the disengaged position allows the engaging support 220 to be moved such that the engaging rod 222 moves from the clamped position back to the unclamped position.
Further, the connecting bolt assemblies 124 may be used to secure the first and second frame assemblies 120 and 122 together in a manner that allows gross adjustment of the distance between the first and second stabilizing surfaces 132 and 134. In particular, the first and second frame assemblies 120 and 122 are arranged such that one or both of the first and second sets of holes 198 are aligned with one or both of the first and second slots 174 and the distance between the first and second stabilizing surfaces 132 and 134 is at a desired distance. Then, at least one of the connecting bolt assemblies 124 is inserted through the aligned slots 174 and holes 198 and tightened to rigidly connect the first and second frame assemblies 120 and 122 together.
The position of the engaging rod 222 relative to the engaging support 220 may also be altered to allow fine adjustment of the distance between the first and second stabilizing surfaces 132 and 134 when the engaging rod 222 is in the engaged position. In particular, axial rotation of the engaging rod 222 moves a position of the second stabilizing surface 134 relative to the engaging support 220. Lock nuts may be used to lock the engaging rod 222 in a desired position relative to the engaging support 220.
Referring now to
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