3-fabric layer insulation material and a method and an arrangement for producing the same

Abstract

This invention describes a 3-layer insulation material (10) comprising a first fabric layer (12), a second fabric layer (14) and a third fluted intermediate fabric layer (16) between the first and the second fabric layers (12, 14), the fluted intermediate fabric layer (16) being attached alternately to the first and the second fabric layer (12, 14) with longitudinal seams (18a-18n) forming longitudinal channels (20a-20n) for the insulation material (22) having individual insulation material (22) bundle in-side each longitudinal channel (20a-20n). Also disclosed are a method and an arrangement for producing the same.

Claims

1. An arrangement for producing a 3-layer insulation material, the arrangement comprising an upper guide element for a first fabric layer, a lower guide element for a second fabric layer and means for guiding and fluting an intermediate fabric layer to a point where the first and second fabric layers are attached by attaching means, the first fabric layer to a first side of the fluted intermediate layer and the second fabric layer to a second side of the fluted intermediate layer, to form longitudinal bundle channels, wherein a multiplicity of guiding means is installed for introducing an insulation material separately to each longitudinal bundle channel and the attaching means are situated on both an upper and a lower side of the 3-layer insulation material, and wherein the said multiplicity of guiding means is installed at the attachment point for introducing the insulation material inside the longitudinal bundle channels simultaneously with attaching of said layers.

2. The arrangement for producing a 3-layer insulation material of claim 1, wherein the attaching means are stitching means.

3. The arrangement for producing a 3-layer insulation material of claim 1, wherein the attaching means are laser welding means.

4. The arrangement for producing a 3-layer insulation material of claim 1, wherein the attaching means are ultra sound welding means.

5. The arrangement for producing a 3-layer insulation material of claim 1, wherein the attaching means are adhesive bonding means.

Description

(1) In the following the invention is discussed more precisely referring to drawings where,

(2) FIG. 1 shows a cross sectional view of the 3-layer insulation with corrugated middle layer,

(3) FIG. 2 shows a cross sectional view of a laser welding machine being able to make corrugated insulation,

(4) FIG. 3 shows a cross sectional view of a laser welding machine in open position,

(5) FIG. 4 shows a side elevational view of the laser welding machine and the material flow in the machine,

(6) FIG. 5 shows a perspective view of a laser welded seam, and

(7) FIG. 6 shows a garment and the placement of a piece of insulation material as part of garment.

(8) FIG. 1 shows a cross sectional view of a 3-fabric layer corrugated insulation material 10 with a first fabric layer 12, second fabric layer 14 and fluted third intermediate fabric layer 16 joined together longitudinally by multiplicity of lengthwise welded seams 18a-18n. First fabric layer 12 and third intermediate fabric layer 16, and respectively on reverse side second fabric layer 14 and said third intermediate fabric layer 16 form a plurality of bundle channels 20 which are individually filled with insulation material 22. The fabric layers 12, 14 and 16 can be different type of textile material, e.g. woven, knitted, warp knitted, felt, or nonwoven material.

(9) FIG. 2 shows a laser welding machine 24, which is able to make insulation material 10 (FIG. 1). The machine 24 has an upper frame 26, which houses an upper fabric guide 30 guiding the first fabric layer 12 and a lower frame 28 housing a lower fabric guide 32 guiding the second fabric layer 14. Third fabric layer 16 is directed between upper fluting folder 34 which is attached to said upper frame 26 and a lower fluting folder 36, which is attached to said lower frame 28. Multiplicity of laser sources 38 are attached to said upper frame 26 above multiplicity of welding stations 24a-24n and a multiplicity of laser sources 38 are attached to said lower frame 28 below multiplicity of welding stations 24a-24n.

(10) The multiplicity of said laser sources 38 are shown only symbolically. The function and design of laser welding have already been disclosed in a variety of publications with respect to the laser transmission welding method, which is therefore common knowledge to a person skilled in the art, such that they need not be described in more detail here. Therefore the depiction of the laser light source from which the laser light 38 originates has been omitted.

(11) When the first fabric layer 12, the second fabric layer 14 and the third fabric layer 16 are pulled, rolled or otherwise moved forward, the first layer of fabric and said intermediate layer and on reverse side said second layer of fabric and said intermediate layer are longitudinally melted together on a molecular level by laser sources 38 along seams 18a-18n (FIG. 1). A multiplicity of hollow conduits 42 are installed in front of the folders 34 and 36. Insulation material 22 is simultaneously with welding introduced inside the bundle channels 20 through the conduits 42. Even if the hollow conduit 42 is preferred embodiment also other means can be used to guide insulation tow to cavities/bundle channels 20. Guiding means like rings, channels, ducts and tubes can be used. These all among others are widely used in textile industry and are common knowledge to the person skilled in the art.

(12) FIG. 3 shows a laser welding machine 24 in open position. In this position, the machine can be cleaned and served and the third layer of fabric 16 can be inserted between the upper fluting folder 34 and the lower fluting folder 36.

(13) FIG. 4 shows a side elevational view of the welding machine 40 and the material flow in welding machine. The first fabric layer 12 is introduced to welding machine 40 from roll 48, the second fabric layer 14 is introduced to the machine from roll 50 and the third intermediate layer of fabric 16 is introduced to machine from roll 52. The power source (not shown) is connected to roll 46 and is pulling the insulation material 10 through the machine and storing the insulation material 10 on roll 46. Alternatively other fabric moving methods can be used, including pressure rolls connected to a motor or fabric pullers behind welding frames.

(14) Simultaneously when fabric is moved through the machine, the plurality of bundle channels 20 (FIG. 1) are individually filled with insulation material 22a-22n, introduced through said multiplicity of conduits 42a-42n. The first fabric 12 from roll 48 and the second fabric 14 and the third fabric from roll 52 are introduced between folders 34 and 36, and are welded together longitudinally by a multiplicity of welding stations 24a-24n.

(15) In order to absorb IR-light optimal energy, a laser absorber 54a and 54b can be introduced to fabric in a joint before welding fabric. The absorber can be e.g. sprayed on a weldable part of the fabric layer through nozzles 56 and 58. Commercial IR-absorbers are made by, for example, Centex Corporation under the Clearweld name. An IR absorber can alternatively be included to a polymer solution before extrusion, printed, coated, or otherwise applied on the fabric.

(16) In an embodiment where heat adhesive is used to join the fabric layers the adhesive can be sprayed or other way conducted to the joint area through the nozzles. Adhesive can be in liquid form or it can be applied as continuous filament.

(17) It is also possible to use different laser welding methods for alternative embodiments of the invention. In laser welding, instead of using multiple laser heads to perform multiple contour welded seams there is an option to use only one laser head to produce all the seams simultaneously. There are three main techniques know in industry which could be utilized with current invention:

(18) Diffractive Welding

(19) Diffractive optical element (DOEs) shape and split laser beams in an energy-efficient manner. Diffractive beam splitter, included to the laser source is a single optical element that divides an input beam into N output beams 29. Output beams can be pointed to predetermined positions. The light laser beam 29 is split and simultaneously directed to joint fusion areas 18a-18n with minimal light loss.

(20) Scanner Welding

(21) In scanner welding the beam guidance is performed by using mobile mirrors included to laser source 38. The beam 29 is directed by changing the angles of the mirrors. The beam continuously scans the welding areas 18a-18n at very high speed. The fabrics passing through the welding areas will be melted and fused from the joint areas quasi-simultaneously manner.

(22) Mask Welding

(23) Mask welding method utilizes wide beams that moves over the entire surface being welded. Mask shields are protecting areas where welding is not desired. Predetermined welding seam areas 18a-18n will be melted and fused.

(24) The function, design, use and mode of operation of mask welding, diffractive welding and scanner welding have already been disclosed in a variety of publications of the prior art with respect to the laser transmission welding method, which is known per se, and are therefore common knowledge to the person skilled in the art, such they need not be described in more detail here.

(25) FIG. 5 shows a laser-welded seam, where fabric layer 12 is percolating IR radiation, and where the IR absorbent middle layer of fabric 16 is applied and absorbed with IR radiation 29, then heated, melted and pressed together with pressure 25a and 25b. A controlled amount of heat is applied to the fabric joint. Laser energy passes through the IR percolating fabric layer 12, heats the surface of IR-absorbent fabric layer 16, melts the surface of layer 16, and seals the interface area together under pressure 25, hence forming a welded seam 18, when fabric is moved to direction 27. Pressure is forced between the pressure rollers 23 (FIG. 2 and FIG. 3) and the peaks of the fluting folders 34 and 36 (FIG. 2 and FIG. 3).

(26) In preferred embodiments of the invention the pressure can be applied to the fabric with different methods, such as:

(27) Pressure Plates

(28) In preferred embodiment the fusible fabric layers, 12 and 16 on first side and 14 and 16 on second side, are passing through and pressed between peaks of upper fluting element 34 and IR-transparent pressure plate (not shown) between laser source and first fabric layer on first side and peaks of lower fluting folder 36 and IR-transparent pressure plate (not shown) between laser source and second fabric layer on second side. The guide elements 30 and 32 are located on top of fluting folders and are similar on upper guide elements and lower guide elements. Laser light is applied to the welding positions through the laser light transparent pressure plates.

(29) Pressure Roller

(30) In one embodiment the pressure can be applied by a laser beam transparent glass roller.

(31) Pressure Ball

(32) In one embodiment the pressure can be applied through a laser light transparent sphere which can be supported by air bearing which enables frictionless rotation.

(33) The advantage of employing roller or sphere instead of plate is having less friction and therefore less heat between pressure means and fabric when the fabric is moved thorough the welding station.

(34) Pressure for welding stations can be produced mechanically, or as an alternative, hydrostatically or pneumatically either blowing positive pressure or by suction production procure adhesion and connection of fabrics in welding areas.

(35) The function, design, use and mode of operation of pressure forming, have already been disclosed in a variety of publications of the prior art with respect to the laser transmission welding method, which is known per se, and are therefore common knowledge to the person skilled in the art, such they need not be described in more detail here.

(36) Different pressure sources in context of laser welding are described for example in US patent application US 2014/0363636 A1 for Leister Technologies AG.

(37) FIG. 6 shows a garment 60, and the placement of a piece of insulation material as part of the garment. Insulation material 22 is floating unattached to any of the fabric layers 12, 14 or 16. When the piece of garment is sewn to another piece of garment, like in shoulder seam 62 joining the front part to the back part the insulation material will be secured in its place in the garment making process by a garment maker.

(38) In one embodiment the materials can be selected from groups which are fire retardant. FR-insulation can be used in potential fire hazardous area applications.

(39) In these above embodiments there are described the use of laser-welded seams. It is also possible to use conventional seams which are made by stitching. Also the seams can be ultra sound welded seams or adhesive bonded seams.

(40) Although the invention has been shown and described with respect to certain preferred embodiments, it is obvious that equivalents and modifications may occur to others skilled in the art upon the reading and understanding of these specifications. The present invention includes all such equivalents and modifications, and is limited only by the scope of the following claims.

LIST OF REFERENCE NUMERALS

(41) 10 insulation material 12 first fabric layer 14 second fabric layer 16 third intermediate fabric layer 18a-18n welding seams (lengthwise connections) 20a-20n bundle channels 22 insulation material 23 pressure roller 24a-24n welding stations 25a, 25b pressure 26 upper frame of machine 27 welding direction 28 lower frame 29 laser beam 30 upper guide elements 32 lower guide elements 34 upper fluting folder 36 lower fluting folder 38 laser source 40 welding machine 42a-42n multiplicities of conduits 44 intentionally blank 46 newly made insulation material storage roll 48 fabric storage roll 50 fabric storage roll 52 intermediate fabric storage roll 54 laser absorber 56 nozzles 58 nozzles 60 Garment 62 shoulder seam of garment