Double-layered thermal insulation sleeve

Abstract

A double-layered thermal insulation sleeve having a frusto-conical shape is disclosed. The sleeve is used on the outer surface of a cup to maintain a water and heat barrier. The sleeve is comprised of a first thermal insulation layer, a second thermal insulation layer, and longitudinal fold lines. The first thermal insulation layer being a cup facing layer that is constructed from non-woven polyester fiber having a plurality of interior air channels being retaining channels for fluids and heat being released from the cup. The second thermal insulation layer is constructed from embossed paper having outward facing bumps that provide a non-slip and thermally insulative gripping surface and a moisture barrier. The longitudinal fold lines allow the double-layered thermal insulation sleeve to be folded into a flattened configuration and stored for reuse.

Claims

1. A double-layered thermal insulation sleeve having a frusto-conical shape and being used to cover the outer surface of a cup to maintain a water and heat barrier, said sleeve comprising, a. a first thermal insulation layer, a second thermal insulation layer, and longitudinal fold lines, b. said first thermal insulation layer having an upper channel edge and a lower channel edge; c. said second thermal insulation layer having a back side, a non-slip and thermally insulative gripping surface, and an outer layer; d. said first thermal insulation layer being a cup facing layer and being constructed from non-woven polyester fiber, said non-woven polyester fiber having a plurality of interior air channels being disposed on said first thermal insulation layer, said plurality of interior air channels having a plurality of bonding lines for connection to said second thermal insulation layer and forming a bonding site with said second thermal insulation layer, adhesive being used for fixedly attaching said bonding lines of said first thermal insulation layer to said back side of said second thermal insulation layer for permanent connection to said second thermal insulation layer and thereby creating said double-layered thermal insulation sleeve wherein said first thermal insulation layer is a cup facing layer and said second thermal insulation layer is said non-slip and thermally insulative gripping surface, said adhesive being placed between one of said bonding lines and said back side of said second thermal insulation layer in overlapping relationship, said plurality of interior air channels retaining said water and heat that is released from said cup, said fluid and said heat being released in an upward and downward direction in said plurality of interior air channels and from said upper channel edge and said lower channel edge, said upper channel edge and said lower channel edge being release points for said water and said heat from said first thermal insulation layer and thereby directing said heat and said fluids away from the hands of a user; e. said outer layer of said second thermal insulation layer being constructed from embossed paper having outward facing bumps so as to provide said non-slip and thermally insulative gripping surface for said user, said second thermal insulation layer having poly-coating being applied thereon and wherein said poly-coating provides a moisture barrier by strengthening said second thermal insulation layer and prevents said liquid and said heat from permeating said second thermal insulation layer; f. said longitudinal fold lines being arranged on said double-layered thermal insulation sleeve and allowing said double-layered thermal insulation sleeve to be folded into a flattened configuration along said longitudinal folds lines and stored for reuse.

2. The plurality of air channels in claim 1 wherein said plurality of air channels are so spaced on said first thermal insulation layer and said back side of said second thermal insulation layer as to provide sufficient reinforcement for said second thermal insulation layer while minimizing the conduction of heat directly between said first thermal insulation layer and said second thermal insulation layer.

3. The plurality of air channels in claim 1 wherein said plurality of air channels are adhered to said back side of said second thermal insulation layer.

4. The first thermal insulation layer of claim 1 wherein said non-woven polyester fiber is made from 100% post-consumer recyclable plastic.

5. The first thermal insulation layer of claim 1 wherein said non-woven polyester fiber supports said second thermal insulation layer along said back surface of said second thermal insulation layer.

6. The second thermal insulation layer of claim 1 wherein said second thermal insulation layer is a moisture barrier.

7. The second thermal insulation layer of claim 1 wherein said second thermal insulation layer is a heat barrier.

8. The second thermal insulation layer of claim 1 wherein said second thermal insulation layer is adapted to repel stains.

9. The second thermal insulation layer of claim 1 wherein said second thermal insulation layer is selected from the group consisting of printing, embossing, attaching, dying a pattern, cast, compression molded, injection molded, blow molded, extruded, and rotational cast.

10. The second thermal insulation layer of claim 1 wherein said second thermal insulation layer is constructed from materials having thermo-resistant properties.

11. The second thermal insulation layer of claim 1 wherein said outer layer of said second thermal insulation layer has advertisement indicia being placed thereon.

12. The second thermal insulation layer of claim 1 wherein said outer layer of said second thermal insulation layer graphically depicts the outer surface of various types of sporting balls.

13. The second thermal insulation layer of claim 1 wherein said outer layer of said second thermal insulation layer has advertisement indicia being placed thereon.

14. The double-layered thermal insulation sleeve of claim 1 wherein said double-layered thermal insulation sleeve is sized for a variety of cup sizes.

15. The double-layered thermal insulation sleeve of claim 1 wherein said first thermal isolation layer and said second thermal insulation layer are folded over each other in a face to face configuration and joined to form said double-layered insulation sleeve.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of one embodiment of a thermal insulation sleeve being used on a cup.

(2) FIG. 2 is a front view of an unassembled thermal insulation sleeve.

(3) FIG. 3 is a perspective view of an assembled thermal insulation sleeve folded into a frusto-conical shape.

(4) FIG. 4 is a top planar view of an assembled thermal insulation sleeve folded into a frusto-conical shape.

(5) FIG. 5 is a back view of an unassembled thermal insulation sleeve.

(6) FIG. 6 is a cross-sectional view of a double-layered thermal insulation sleeve being folded into a frusto-conical shape.

(7) FIG. 7 is a cross-sectional view of a double-layered thermal insulation sleeve.

DETAILED DESCRIPTION OF THE INVENTION

(8) The detailed description is for illustrative purposes and does not limit the scope of the present invention. The embodiments described below provide sufficient information to enable a person having ordinary skill in the art to practice the invention. It should be understood that other embodiments can be practiced with multiple variations without departing from the scope of the invention.

(9) Referring now to the drawings, FIG. 1 is an exemplary drawing of the preferred embodiment showing an assembled sleeve on a cup 12. The double-layered thermal insulation sleeve 10 has a frusto-conical shape and is used to cover the outer surface of a cup 12. The sleeve comprises a 14 thermal insulation layer, a second thermal insulation layer 16, and longitudinal fold lines 18. The first thermal insulation layer 14 is a cup facing layer and is constructed from non-woven polyester fiber. The non-woven polyester fiber has a plurality of interior air channels 22 being disposed on the first thermal insulation layer 14 in a multidirectional format. Bonding lines 24 are connected to the first thermal insulation layer 14 and forming a bonding site 26 with the second thermal insulation layer 16. An adhesive is used to fixedly attach the bonding lines 24 of the first thermal insulation layer 14 to the back side 28 of the second thermal insulation layer 16 for permanent connection to the second thermal insulation layer 16 and thereby creating a double-layered thermal insulation sleeve 10 wherein. The first thermal insulation layer 14 operates as a cup facing layer and the second thermal insulation layer 16 operates as a non-slip and thermally insulative gripping surface 32. The adhesive is placed between one of the bonding lines 24 and the respective back side of the second thermal insulation layer 16 in an overlapping relationship. The plurality of interior air channels 22 are retaining channels for fluids and heat being released from the cup 12. The fluid and heat are released in an upward and downward direction in the plurality of interior air channels 22 and from the upper channel edge 34 and the lower channel edge 36. The upper channel edge 34 and the lower channel edge 36 are release points for the heat from said first thermal insulation layer 14 and thereby directing the heat and fluids away from the hands of a user.

(10) FIG. 2 shows a front a view of an unassembled sleeve. The outer layer 42 of the second thermal insulation layer 16 is constructed from embossed paper and has outward facing bumps 44 so as to provide a non-slip and thermally insulative gripping surface 32 for a user. The second thermal insulation layer 16 has poly-coating being applied thereon which provides a moisture barrier and additional strengthening. The second thermal insulation layer 16 prevents water and heat from permeating the second thermal insulation layer 16.

(11) The plurality of longitudinal fold lines 18 can be seen in FIGS. 1-4. The lines are arranged on the double-layered thermal insulation sleeve 10 and allow the double-layered thermal insulation sleeve 10 to be folded into a flattened configuration and stored for reuse.

(12) FIG. 4 shows a top planar view of an assembled sleeve that is folded into a frusto-conical shape and further illustrates the interior channels 22, upper channel edge 34, and the non-slip and thermally insulative gripping surface 32 of the second thermal insulation layer 16. The second thermal insulation layer 16 can be made of paper that is printed and embossed to simulate the bumpy texture inherent of an actual ball with the real leather feel of a football, basketball, baseball or soccer ball. This layer may also be personalized with advertising indicia.

(13) FIG. 5 shows a back view of the first thermal insulation layer 14. This layer supports the second thermal insulation layer 16 and houses a plurality of interior air channels 22 which are disposed on the first thermal insulation layer 14 in a multidirectional format.

(14) FIGS. 6 and 7 are cross sectional views of the double-layered thermal insulation sleeve 10. The first thermal insulation layer 14 is fixedly connected to the second thermal insulation layer 16. The non-woven polyester fiber features plurality of interior air channels 22 having a plurality of bonding lines 24 for connection to the back side of second thermal insulation 16. The plurality of air channels 22 are so spaced on the first thermal insulation layer 14 and the back side of the second thermal insulation layer 16 as to provide sufficient reinforcement for the second thermal insulation layer 16 while minimizing the conduction of heat directly between the first thermal insulation layer 14 and the second thermal insulation layer 16. The plurality of air channels 22 are randomly arranged and adhered to the back side of the second thermal insulation layer 16. The first thermal insulation layer 14 is sufficiently rigid to support the second thermal insulation layer 16 along the back surface of the second thermal insulation layer 16 while said double-layered thermal insulation sleeve 10 is being used. The second thermal insulation layer 16 may be formed from the group comprising: printing embossing, attaching, dying a pattern, cast, compression molded, injection molded, blow molded, extruded, and rotational cast and can have advertisement indicia being placed thereon.