Composite rung for a ladder and method

Abstract

A ladder having a first fiberglass rail. The ladder having a second fiberglass rail. The ladder having a one-piece composite rung which is hollow and made of carbon fiber or glass. The rung has a middle and a first end and a second end. The ladder having rivets that extend through the first end and the second end of the rung to attach the rung to the first rail and the second rail. No portion of the rung penetrates any portion of the first or second rails. A method for producing a ladder. A method for forming a one-piece composite rung for a ladder. A method for using a ladder.

Claims

1. A ladder comprising: a first fiberglass rail having a web with an inner face surface; a second fiberglass rail having a web with an inner face surface; a one-piece composite rung, which is hollow and made of layers of carbon fiber or glass in a matrix of thermoset epoxy, thermoset polyurethane, thermoset polyester or thermoset polymers, that is at least 12 inches long in a longitudinal direction and weighs no more than 0.35 pounds, the rung having a middle and a first end and a second end, each end is non-movably attached to the middle of the rung, each end flares outward from the middle to define a flat face having a shape which corresponds with the web's inner face surface to which the flat face attaches, no portion of the rung penetrating any portion of the first or second rails, the middle has a flat portion; and rivets that extend through the faces and the inner face surface of the web of the rails to attach the rung to the first rail and the second rail, wherein no other part or component is used to attach the rung to the rails other than the rivets, such that the rivets extend in the longitudinal direction through the faces of the inner face surface of the web of the rails.

2. The ladder of claim 1 wherein the first end and second end of the rung has a top and a bottom which extend above and below, respectively, from the middle, and the rivets extend through the top and the bottom of the first and second ends into the first and second rails respectively.

3. The ladder of claim 2 wherein the middle has a rounded portion underneath the flat portion, the flat portion upon which a user places a foot to stand on the rung.

4. The ladder of claim 3 wherein the layers extend between the flat face of each end, inclusive of the flat face of each end.

5. The ladder of claim 4 wherein all layers are 3K (3000 filaments per fiber) 22 twill standard modulus Carbon Fiber pre-impregnated 215 Fahrenheit degree cure.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

(1) In the accompanying drawings, the preferred embodiment of the invention and preferred methods of practicing the invention are illustrated in which:

(2) FIG. 1 is an isometric view of a rung of the present invention.

(3) FIG. 2 shows a logo side view of the rung.

(4) FIG. 3 shows a rounded side view of the rung.

(5) FIG. 4 shows an axial view of the rung.

(6) FIG. 5 is a cross-sectional view of the rung as identified from FIG. 3.

(7) FIG. 6 is a perspective view of a ladder of the present invention.

(8) FIG. 7 shows a logo side of a tool.

(9) FIG. 8 shows a rounded side of the tool.

(10) FIG. 9 shows a representation of the layers of the rung.

DETAILED DESCRIPTION OF THE INVENTION

(11) Referring now to the drawings wherein like reference numerals refer to similar or identical parts throughout the several views, and more specifically to FIGS. 1-6 thereof, there is shown a ladder 10. The ladder 10 comprises a first fiberglass rail having a web 16 with an inner face surface 18. The ladder 10 comprises a second fiberglass rail having a web 16 with an inner face surface 18. The ladder 10 comprises a one-piece composite rung 20 which is hollow and made of carbon fiber or glass that is at least 12 inches long and weighs no more than 0.35 pounds. The rung 20 has a middle 22 and a first end 24 and a second end 26. Each end flares outward from the middle 22 to define a flat face 28 having a shape which corresponds with the web's inner face surface 18 to which the flat face 28 attaches. The ladder 10 comprises rivets 30 that extend through the faces and the inner face surface 18 of the web 16 of the rails to attach the rung 20 to the first rail 12 and the second rail 14. No portion of the rung 20 penetrates any portion of the first or second rails 12, 14.

(12) The first end 24 and second end 26 of the rung 20 may extend perpendicularly from the middle 22. The first end 24 and second end 26 of the rung 20 may have a top 32 and a bottom 34 which extends above and below, respectively, from the middle 22, and the rivets 30 extend through the top 32 and the bottom 34 of the first and second ends 24, 26 into the first and second rails 12, 14, respectively. No other part or component may be used to attach the rung 20 to the rails other than the rivets 30.

(13) The middle 22 may have a flat side 40, also called the logo side 40, and a rounded side 42 underneath the flat 40. The flat side 40 upon which a user places a foot to stand on the rung 20. The rung 20 may have layers 44 of carbon fiber or glass. All layers 44 may be 3K 22 twill standard modulus Carbon Fiber Prepreg 215 degree cure.

(14) The present invention pertains to a method for producing a ladder 10. The method comprises the steps of riveting with steel rivets 30 that extend through a flat face 28 of a first end 24 of a composite rung 20 and an inner face surface 18 of a web 16 of a first rail 12 to attach the first end 24 of the rung 20 to the first rail 12; and the second rail 14. There is the step of riveting with steel rivets 30 that extend through a flat face 28 of a second end 26 of the composite rung 20 and an inner face surface 18 of a web 16 of a second rail 14 to attach the second end 26 of the rung 20 to the second rail 14. The composite rung 20 being one piece which is hollow and made of carbon fiber or glass that is at least 12 inches long and weighs no more than 0.35 pounds. The rung 20 having a middle 22 and the first end 24 and the second end 26. Each end flares outward from the middle 22 to define the flat face 28 of the first end 24 and the flat face 28 of the second end 26. The flat face 28 of the first end 24 and the flat face 28 of the second end 26 having a shape which corresponds with the first rail 12 web's inner face surface 18 and the second rail 14 web's inner face surface 18, respectively, to which the flat face 28 of the first rail 12 and the second rail 14, respectively, attaches. No portion of the rung 20 penetrating any portion of the first or second rails 12, 14.

(15) The present invention pertains to a method for using a ladder 10. The method comprises the steps of moving the ladder 10 to a desired location. The ladder 10 having a composite rung 20 that is riveted to a first rail 12 of the ladder 10 and a second rail 14 of the ladder 10 opposing the first rail 12 of the ladder 10 with no portion of the rung 20 penetrating any portion of the first or second rails 12, 14. There is the step of placing the ladder 10 into a desired position to be climbed.

(16) The present invention pertains to a method for forming a one-piece composite rung 20 for a ladder 10. The method comprises the steps of placing carbon fibers in a logo side 40 of a tool 48 shown in FIG. 7. The logo side 40 has a flat portion upon which a user places his foot. There is the step of placing carbon fibers in a rounded side 42 of the tool 48 shown in FIG. 8. There is the step of putting the logo side 40 with the carbon fibers and the rounded side 42 with the carbon side of the tool 48 together. There is the step of autoclaving the tool 48 with the logo and rounded sides 40, 42 together to form the rung 20 with a first side having a flat face 28 and a second side having a flat face 28.

(17) With reference to FIGS. 7-9, the composite rung 20 is formed as follows using standard autoclave techniques with molds 46 where FIG. 7 shows the logo side 40 of the mold 46, FIG. 8 shows the rounded side 42 of the mold and FIG. 9 shows a schematic representation of the layers 44 which form the composite rung 20. The tool 48 is formed from the molds 46 for the rung 20.

(18) 1. All six layers 44 from the Logo side 40 of the tool 48 are cut net (after being cut).

(19) 2. Remaining pieces of Carbon Fiber from Logo side 40 are then used on rounded side 42.

(20) 3. Layup of rounded side 42 starts net on one side of the tool 48 allowing an overlap to hang on the opposite side.

(21) 4. The second layer on the rounded side 42 starts from the opposing side from the first layer, allowing an overlap on the opposite side of the first layers 44 overlap.

(22) 5. After the 2 overlaps have been mad; 1 more layer is added in the center, allowing overlaps on either side.

(23) 6. The overlaps on the sides are cut and folded onto the support sides 50 of the rung 20, then 3 layers 44 of Carbon Fiber are laid up on each side. These layers 44 have a hole cut in them to allow the 4 layers 44 of the rung 20 to go through the hole and be folded back onto the support side.

(24) 7. All layers 44 after the first 3 layers 44 on the rung 20 on each side are staggered down from the edge of the overlaps, while alternating the start point to leave staggered layers 44 on both sides.

(25) 8. After all layers 44 are laid up peel six layer on logo side 40 and place on rounded side 42 and close tool 48.

(26) The vertical portions 45 of the layers 44 that extend along the length of the rung 20 alternate or interleave with the strictly vertical layers 44.

(27) All layers 44 are 3K (3000 filaments per fiber) 22 twill standard modulus Carbon Fiber Prepreg (pre-impregnated) 215 degree Fahrenheit cure.

(28) The composite rung integrates rung plates and rung in one complete part. It is comprised of, but not limited to, fabric and/or unidirectional materials such as glass, carbon fiber, and aramid or a combination thereof. The matrix will be comprised of, but not limited to, thermoset Epoxy, thermoset polyurethane, thermoset polyester and thermoplastic polymers.

(29) Present advantages: This design allows for the use of material other than aluminum to be used for rungs. More specifically allows for use of glass, aramid and carbon fiber thus utilizing each material's advantages over aluminum. Kevlar has high abrasion resistance; carbon fiber has a high strength-to-weight ratio and various glasses with high modulus and/or tensile strength are appealing for electrical resistance and high heat applications.

(30) The rung targets a lightweight solution for end users requiring lighter extension ladders. The average weight savings can be about 50% of the total rung weight depending on material used. This can conform to other extension ladder applications, including, but not limited to, high chemical resistance, high electrical resistance, high heat resistance, high abrasion resistance, and high strength/modulus.

(31) Although the invention has been described in detail in the foregoing embodiments for the purpose of illustration, it is to be understood that such detail is solely for that purpose and that variations can be made therein by those skilled in the art without departing from the spirit and scope of the invention except as it may be described by the following claims.