1. Field of the Invention
This invention relates to a system for installing rolled sheet material on a wall and methods for installing a rolled construction material. More specifically, this invention relates to a system for installing rolled waterproofing webbing to a vertical or near vertical wall and methods for installing rolled waterproofing webbing to a vertical or near vertical wall.
2. Description of Related Art
Rolled sheet materials, such as textiles, paper, flexible plastics, roofing materials, waterproofing materials, and the like come in rolls where the thin material is generally rolled around an open core. This rolled configuration allows manufacturers to provide materials that cover a large surface area in a compact form as the rolls can contain hundreds of feet of length of material depending on the thickness and weight of the material. Generally, materials that are relatively flat and flexible are good candidates to be offered in rolled configurations.
Rolled sheeting materials are used extensively in construction projects, and contractors must take the rolled material and unroll it into a flat sheet for installation. Most rolled sheeting materials used for construction are heavy and difficult for workers to handle when installing, especially on a vertical surface. In these instances, the rolled material must be kept level or near-level as it is unrolled and installed to maintain a proper overlap of the layer of material installed below, and sags and wrinkles may distract from the performance of the material. Further, as the layers are installed vertically, the workers must move further up the wall and away from the ground, which makes the process more difficult and dangerous. The prior art fails to provide systems and methods of installation to allow easier and safer use of rolled materials, especially in vertical or near-vertical applications.
It is therefore desirable to have a system and method for installation that enables simpler and safer deployment of sheet material from a rolled state into an unrolled and deployed state on a vertical or near vertical-wall.
The present invention provides for a system and method of installation for installing a rolled sheet material on a vertical or near-vertical surface. Specifically the system and method of installation are useful in the construction industry where heavy rolls of sheet materials must be precisely installed on walls and other vertical surfaces that can be several stories high.
The system includes a rolled material spool holder with mounting hardware to allow mounting of the spool holder to a piece of construction equipment along with a spool director, which is also mounted to the piece of construction equipment. The material spool holder consists of a vertical circular shaft with a rotatable, preferably round base plate near the bottom of the vertical shaft. In use, the vertical circular shaft extends through the round open core of the rolled sheet material and supports the material vertically. The rolled material rests on the base plate, which supports the weight of the roll and also rotates as the rolled material is unwound during installation. The vertical shaft of the spool holder extends through the base plate and is mounted underneath the base plate to a horizontal support element.
The horizontal support element of the rolled material spool holder is connected to an additional vertical support beam, which is spaced apart from the vertical circular shaft due to the length of the horizontal support element. The vertical support beam is connected to a vertical mounting plate by a hinge. The hinge is located on the bottom of the vertical support beam and vertical mounting plate, which allows the vertical support beam and vertical circular shaft to be rotated 90 degrees downward to a horizontal plane. This allows for easier installation of the rolled material onto the vertical shaft of the spool holder, which is in fixed relation to the support beam via the horizontal support element. The vertical support beam additionally includes a threaded bolt extending perpendicularly therefrom which is aligned with a receiving hole in the vertical mounting plate. When the vertical support beam is in its vertical position adjacent to the vertical mounting plate, the threaded bolt extends through the receiving hole in the vertical mounting plate, and the support beam is secured in its vertical orientation via a washer and wing nut.
The vertical mounting plate includes mounting hardware, which allows it to be mounted to a piece of construction equipment. In the preferred embodiment, the spool holder is attached to a piece of construction equipment known as a scissor lift. Because scissor lifts offer forward and backward movement along with vertical movement, attachment to a scissor lift allows the operator to precisely control the height of the roll during installation as well as the unwinding of the roll as the scissor lift moves along beside the wall.
The system also preferably includes a spool director, which consists of a vertical shaft, a horizontal support member and mounting hardware to allow mounting of the spool director to the construction equipment. The function of the spool director is to help control the unwinding of the spool of material and to allow the material to change direction around the corner of the construction equipment if desired. The vertical shaft of the spool director is preferably a narrow steel rod with pins at each end to support a concentric piece of hollow, larger-diameter pipe. In use, the material being unwound contacts the hollow pipe, which is able to rotate freely around the internal steel rod. The steel rod is longer than the hollow external pipe, which allows the horizontal support member to be attached to the top of the steel rod on one end. The other end of the horizontal support member attaches to the construction equipment with the use of mounting hardware.
The method of installation that enables simpler and safer deployment of sheet material from a rolled state into an unrolled and deployed state on a vertical or near-vertical wall incorporates the system described above. In the preferred embodiment, the rolled material spool holder is first mounted to a scissor lift. Next, the vertical support beam and spool holding vertical shaft is rotated down to a horizontal position via the hinge to allow for loading the rolled material onto the holder. Once loaded, the support beam and spool-holding vertical shaft are returned to a vertical orientation and locked in place adjacent to the vertical mounting plate through the use of the threaded bolt and wing nut. A rope attached to the end of the vertical support beam can be used to pull the support beam and spool-holding shaft back to vertical after loading. Once the rolled material is loaded, the scissor lift is positioned along the wall in desired start location and positioned vertically to the desired height. The operator affixes the start of the roll to the wall and then drives the scissor lift along the wall, which causes the roll to unwind due to the movement. In the preferred embodiment, one operator drives the scissor lift, while an additional worker affixes the roll to the wall at the desired intervals. This process continues along the length of the wall. The worker then cuts the roll and raises the scissor lift to the desired height for the next row. This process continues until the wall is covered with the rolled material. If the spool holder is mounted on the end of the scissor lift rather than the side, then the spool director with the rotatable outer pipe would be mounted close to and extending from the corner to allow the rolled material to leave the roll and wrap around the corner. Mounting the spool holder on the end rather than the side of the scissor lift allows the scissor lift to be positioned closer to the wall, which enables the workers to be closer for affixing the rolled material to the wall.
The novel features and construction of the present invention, as well as additional objects thereof, will be understood more fully from the following description when read in connection with the accompanying drawings.
The improved process of the invention is further described and explained in relation to the following figures of the drawings wherein:
Like reference numerals are used to describe like parts in all figures of the drawings.
Referring to
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Base plate 14 is preferably circular in shape and rests on smaller plate 15, which preferably is also circular and has a smaller diameter than base plate 14. When the rolled sheet material is installed on material spool holder 10, it rests on base plate 14. Smaller base plate 15 is supported vertically on vertical shaft 12 through the use of support 18. In the preferred embodiment, support 18 is comprised of two pieces 52 that are clamped around vertical shaft 12 with threaded bolts 50. Support 18 is stationary on vertical shaft 12 and provides a supportive base for base plate 15 to rest upon. Support 18 could take several different forms including other bolted on or welded brackets, etc. such that support 18 is rigidly mounted to and stationary on vertical shaft 12. The embodiment with two pieces 52 clamped on vertical shaft 12 with threaded bolts 50 is preferred because it allows base plates 14 and 15 to be raised and lowered along vertical shaft 12 depending on the width of the rolled sheet material that is being installed. Base plates 15 provides more support for base plate 14 and allows for heavier rolls of sheet material to be supported, but alternatively, base plate 14 could directly rest on support 18, if support 18 was sized larger to provide more support. Base plates 14 and 15 are free to rotate in relation to vertical shaft 12, which allows the rolled sheet material to unwind as it is being installed. Base plate 14 preferably has a sufficient diameter to support the full thickness of the roll of rolled sheet material being installed.
Horizontal support element 16 connects vertical shaft 12 to vertical support beam 20, which is mounted on the prior art scissor lift through the use of vertical mounting plate 22. Horizontal support element 16 is sized sufficiently to space vertical shaft 12 apart from vertical support beam 20 to allow for the diameter of base plate 14 to rotate freely without interference from vertical support beam 20. In the preferred embodiment, horizontal support element 16 is rigidly attached via welding to vertical support beam 20. Alternatively, horizontal support element 16 could be releasably mounted on vertical support beam 20 through the use of pins with clips, bolts with nuts or the like. Releasable mounting of horizontal support element 16 would allow for removal of horizontal support element 16 and vertical shaft 12 from spool holder 10 when not in use, which would allow vertical support beam 20 and vertical mounting plate 22 to be left mounted on the prior art scissor lift when spool holder 10 is not in use. Releasable mounting of horizontal support element 16 could also allow for adjustable height mounting of horizontal support element 16 (and consequently base plate 14 and vertical shaft 12), which would give the operator greater flexibility depending on the width of the rolled sheet material that is being installed.
Vertical support beam 20 is approximately parallel with vertical shaft 12, and in the preferred embodiment extends below horizontal support element 16 and above the upper end of vertical shaft 12. Vertical support beam 20 is connected to vertical mounting plate 22 via hinge 24 located at the bottom of vertical support beam 20 and the bottom of vertical mounting plate 22. Hinge 24 allows vertical support beam 20 and vertical shaft 12 to rotate 90 degrees downward to a horizontal plane to allow the rolled sheet material to be installed on the spool holder 10 more easily. This will be discussed more fully with regard to
In the preferred embodiment, vertical support beam 20 has threaded bolt 26 extending perpendicularly towards and through a hole in vertical mounting plate 22. Spacers 58 and 60 keep vertical support beam 20 and vertical mounting plate 22 parallel and act as a barrier to prevent over-rotation of vertical support beam towards vertical mounting plate 22. Spacers 58 and 60 serve to ultimately keep vertical shaft 12 vertical, which allows for more uniform unrolling of the rolled sheet material and better installation on vertical surfaces. Vertical support beam 20 is held in place through the use of winged nut 46, which is screwed on threaded bolt 26 when threaded bolt 26 is protruding through the hole in vertical mounting plate 22. Rather than a threaded bolt/wing nut configuration, a steel pin and clip or other similar type configuration could also be used as long as vertical support beam 20 is rigidly held in place against spacers 58 and 60. This connection must provide sufficient support to prevent vertical shaft 12 and base plate 14 from rotation downward due to the weight of the rolled sheet material. Eye bolts 48 are attached to the tops of vertical support beam 20 and vertical mounting plate 22. Rope 40 is connected to each eye bolt to prevent vertical support beam 20 from rotating greater than 90 degrees when hinged downward for rolled sheet material loading and by subsequently pulling the rope, the operator can return vertical support beam 20 to its upright position after loading. This will be discussed more fully with regard to
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Other alterations and modifications of the invention will likewise become apparent to those of ordinary skill in the art upon reading the present disclosure, and it is intended that the scope of the invention disclosed herein be limited only by the broadest interpretation of the appended claims to which the inventors are legally entitled.
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