1. Field of the Invention
The present invention relates to a method of making a flexible sheet heater for use in waist pads, waist bandages, and clothes and more particularly, to a method of making a flexible sheet heater by using an electrically conductive fabric.
2. Description of the Related Art
Flexible, electrically conductive sheet heaters are intensively used in clothes, kneepads, gloves, shoe pads, ear covers, waist pads, and etc. to keep the user warm.
A conventional flexible, electrically conductive sheet heater is known comprising two flexible heat-resistant insulative sheets, a metal loop formed of a thin metal sheet member by chemical etching or stamping and sandwiched in between the two flexible heat-resistant insulative sheets, and two electrical terminals respectively connected to the two distal ends of the metal loop and extending out of the two flexible heat-resistant insulative sheets for enabling an electric current to be transmitted through the metal loop to generate heat. There is known another conventional structure of flexible, electrically conductive sheet heater, which comprises a first flexible heat-resistant insulative sheet, a carbon loop printed on the first flexible heat-resistant insulative sheet, a second flexible heat-resistant insulative sheet bonded to the first flexible heat-resistant insulative sheet to have the carbon loop be sandwiched in between the two flexible heat-resistant insulative sheets, and two electrical terminals respectively connected to the two distal ends of the carbon loop and extending out of the two flexible heat-resistant insulative sheets.
The aforesaid two different electrically conductive sheet heaters have light and thin characteristics and can be slightly curved; however, they cannot be folded up. Because the aforesaid two different electrically conductive heater systems are not foldable, their application is limited.
There is also known a flexible, electrically conductive sheet heater, which has an electrically conductive fabric, for example a carbon fiber fabric, sandwiched in between two flexible heat-resistant insulative coverings and provided with a power input structure. This design of flexible, electrically conductive sheet heaters has light and thin characteristics and is foldable for different applications. Exemplars of these electrically conductive fabric-based heater designs are seen in Taiwan Patent Publication No. 374,539, U.S. Pat. No. 6,172,344, and U.S. Pat. No. 6,483,087.
According to Taiwan Patent Publication No. 374,539, the heater comprises an electrically conductive rectangular carbon fiber fabric, two elongated conductive copper strips respectively affixed to two sides of the carbon fiber fabric, two electric wires respectively connected to the copper strips, and two plastic cover films respectively covered on the top and bottom sides of the carbon fiber fabric and the copper strips. According to this design, the conductivity of the copper strips is superior to the carbon fiber fabric, resulting in a high contact resistance between the two copper strips and the carbon fiber fabric. Further, because the surface of the carbon fiber fabric is not a smooth surface such that the whole surface of each copper strip is not fully kept in contact with the carbon fiber fabric, an excessive high temperature may be produced between the copper strips and the carbon fiber fabric. Taiwan Patent Publication No. 374,539 does no provide any measures to eliminate the aforesaid problems.
U.S. Pat. No. 6,172,344 discloses continuous and batch-based conductive element fabrication methods by sandwiching a carbonized fabric with electrical terminals between layers of plastic insulating material. However, U.S. Pat. No. 6,172,344 does not teach the way of keeping the carbonized fabric between the two layers of plastic insulating material in a smooth manner.
U.S. Pat. No. 6,483,087 discloses a process of making a heater by: combining a layer of electrically conductive fabric with two metal foil bus bars, securing the bus bars to the conductive fabric, drawing the conductive fabric layer containing bus bars between two layers of thermoplastic film forming a sandwich structure, feeding the sandwich structure through a pinch roller preheated at a predetermined temperature and thickness to cause gelling of the thermoplastic layers, and consolidating the conductive fiber layer to form a single sheet heater. According to this method, it is difficult to cut the layer of electrically conductive fabric into the desired curved shape. When cutting the layer of electrically conductive fabric, the carbonized fiber structure of the layer of electrically conductive fabric tends to be stretched and damaged, and the layer of electrically conductive fabric may be deformed easily when pulled toward the layers of thermoplastic film.
The present invention has been accomplished under the circumstances in view. It is therefore one object of the present invention to provide a method of making a flexible sheet heater, which enables an electrically conductive fabric to be rapidly and smoothly sandwiched in between two protective sheet members.
To achieve this object of the present invention, the method of making a flexible sheet heater comprises the steps of: a) preparing an electrically conductive fabric; b) preparing a support member having a PET (polyethylene terephthalate) film and a layer of acrylic glue covered on one side of the PET film; c) joining the electrically conductive fabric and the support member together by adhering the layer of acrylic glue to one side of the electrically conductive fabric through a pressing process; d) cutting the electrically conductive fabric to form a heating element having a predetermined loop pattern by a stamping process; e) applying a conducting glue to each of two distal ends of the heating element and fixedly bonding a respective electrical terminal to the conducting glue at each of the two distal ends of the heating element; f) bonding a first flexible protective sheet member to one side of the heating element opposite to the PET film through a hot press; g) removing the PET film from the heating element; and h) bonding a second flexible protective sheet member to one side of the heating element opposite to the first flexible protective sheet member such that the heating element is sandwiched between the first and second flexible protective sheet members.
Referring to
a) Prepare an electrically conductive fabric 10. As shown in
b) Prepare a support member 20. As shown in
c) Join the electrically conductive fabric 10 and the support member 20 together. As shown in
d) Stamp the electrically conductive fabric 10a of the substrate 30a subject to a predetermined loop pattern, thereby forming a heating element 10b on the support member 20a of the substrate 30a. As shown in
e) Apply a conducting glue 40 to each of the two distal ends of the heating element 10b and fixedly bond a respective electrical terminal 50 to the conducting glue 40 at each of the two distal ends of the heating element 10b as shown in
f) Bond a first flexible protective sheet member 60 to one side of the heating element 10b opposite to the PET film 21a. The first flexible protective sheet member 60 is formed of a waterproof fabric layer 61 and a thermoplastic layer 62 bonded to one side of the heating element 10b opposite to the PET film 21a by a hot press, as shown in
g) Remove the PET film 21a from the heating element 10b as shown in
h) Bond a second flexible protective sheet member 70 to the other side of the heating element 10b opposite to the first flexible protective sheet member 60. As shown in
Because the invention uses the support member 20a to support the electrically conductive fabric 10a for processing, the interlacing fiber structure of the electrically conductive fabric 10a does not disperse and the loop pattern of the heating element 10b is well kept in shape when the electrically conductive fabric 10a is cut and stretched by the cutter during the stamping operation. More particularly, the support member 20a of the invention uses the PET film 21a and the acrylic glue 22a as elements thereof, no residual acrylic glue will be left on the heating element 10b after removing of the PET film 21a from the heating element 10b.
Further, by means of the support of the support member 20a, the heating element 10b can be smoothly adhered to and supported on the first flexible protective sheet member 60 so that the heating element 10b can further be smoothly sandwiched in between the first flexible protective sheet member 60 and the second flexible protective sheet member 70.
Number | Name | Date | Kind |
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6172344 | Gordon et al. | Jan 2001 | B1 |
6483087 | Gardner et al. | Nov 2002 | B2 |
Number | Date | Country |
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374539 | Nov 1999 | TW |