Patent Application
20090026193
The present invention relates generally to an improved method of assembling a floor cover heating system where the floor cover is flexible in nature, such as a carpet or rug, in particular the invention provides an improved method of reducing the wear of under floor heating mats from abrasion. The invention also provides a floor cover heating system including a flexible floor cover layer, an under floor cover heating mat, and a slip layer positioned between the heating mat and the flexible floor cover.
Under carpet heating systems have been used for sometime in New Zealand and Australia, South Africa and other countries. Under carpet heating systems consist of an under carpet heating mat which is encapsulated in a reinforced high temperature foil, or the like for added protection and heat transfer. The heating mat sits between the carpet layer and the carpet underlay layer. These heating mats can quickly heat up a room and can be automatically thermostatically controlled to suit temperature changes and life style options.
One of the difficulties with this system is that the under carpet heating mats have occasionally worn on the top side of the mat, that is the side of the mat that butts up against the underside of the carpet layer. It has generally been recognised that this has been caused by the abrasiveness of the under side of the carpet rubbing against the under carpet heating mat. The problem has been more pronounced in areas where the carpet is exposed to frequent use such as hall ways, corridors or commercial applications such as show rooms where heavy foot traffic is experienced.
It is an object of the present invention to over-come these difficulties and to provide the consumer with a longer wear under carpet heating system, or to at least provide the public with a useful choice.
In a first aspect the present invention provides a method of installing a floor cover heating system over a floor surface, including the steps of
Preferably the method includes the step of locating under the heating mat an underlay layer.
Preferably, the flexible floor cover layer is a carpet layer or a rug layer that does not include an insulative backing layer.
Preferably, the slip layer will be of a size substantially equivalent to the dimensions of the under carpet heating mat.
Preferably, the slip layer is a synthetic material.
Preferably, the slip layer is a synthetic material, such as polypropylene or nylon. More preferably, the slip material is polypropylene 100 gsm spun bound.
Preferably the thickness of the slip layer is between 0.1-2.0 mm. More preferably, the thickness of the slip layer is between 0.4-0.8 mm.
In a second aspect the present invention provides an under floor heating system including:
Preferably, the flexible floor cover layer is a carpet layer or a rug layer that does not include an insulative backing layer.
Preferably, an underlay layer is located underneath the heating mat.
Preferably, the slip layer will be of a size substantially equivalent to the dimensions of the under carpet heating mat.
Preferably, the slip layer is a synthetic material, such as polypropylene or nylon.
Preferably, the slip layer is poly propylene 100 gsm spun bound.
Preferably the thickness of the slip layer is between 0.1-2.0 mm. More preferably, the thickness of the slip layer is between 0.4-0.8 mm.
In a third aspect there is provided a method of reducing abrasion between a flexible floor cover layer and a heating mat positioned over a floor surface including the steps of
Preferably the method includes the step of locating under the heating mat an underlay layer.
Preferably, the flexible floor cover layer is a carpet layer or a rug layer that does not include an insulative backing layer.
Preferably, the slip layer will be of a size substantially equivalent to the dimensions of the under carpet heating mat.
Preferably, the slip layer is a synthetic material.
Preferably, the slip layer is a synthetic material, such as polypropylene or nylon. More preferably, the slip material is polypropylene 100 gsm spun bound.
Preferably the thickness of the slip layer is between 0.1-2.0 mm. More preferably, the thickness of the slip layer is between 0.4-0.8 mm.
The term slip layer includes any layer, synthetic or non-synthetic, that has the ability to reduce abrasion between the floor covering layer and the heating mat and/or to assist in the dispersion of heat from the heating mat.
Further aspects of the present invention will become apparent with reference to the following description and figures in which;
A conventional under carpet heating system 1 is shown in
A heating system 6 of the present invention is illustrated in
The inventor has surprisingly found that despite being such a thin layer of slip material, the layer has the ability to dampen the abrasion effect experienced in the conventional system. The inventor has also found that the slip layer does not in fact interfere with the heating ability of the heating mat, nor does it restrict or limit the heat transfer or cause a localised build up of heat in places where the heating mat and carpet are brought under pressure.
When assembling the heating system, the ground surface 2 is prepared and should be clean, dry and level. The ground surface or substrate may be wooden, wood fibre composite or concrete.
When carpet is being laid as the floor covering, a carpet underlay layer 3 is next secured to the ground layer by tape or glue or some other non-conductive fastening means.
The area to be heated is calculated and then the heating mat is cut to size and positioned over the underlay in such a manner so that the selected area to be heated is covered.
The slip layer is then positioned over the heating mat and is secured with the likes of glue or tape preferably to the edges of the underlay. The carpet layer can then be rolled out over the slip layer. Preferably the carpet layer is a Hessian backed carpet layer or similar. Rubber backed or foam backed flexible floor covering by virtue of their insulative properties are not suitable to use with the heating mats.
The invention will be further described with reference to the following examples.
On a 19 mm MDF floor a ripple underlay was laid, a 250W undercarpet heating mat was positioned over the underlay. A very coarse 3M® polishing pad, normally used to buff stainless steel and a 6 kg weight were then used in the following tests.
Test 1: The polishing pad was placed on top of the heating mat in position over two wires (covered by foil) from the heating mat. The two wires extended across the width of the heating mat. On top of the polishing pad was placed the 6 kg weight. This 6 kg weight was then dragged along the length of the wires 20 times. At the end, there were visible signs that the foil on the heating mat was starting to wear off. The worn heating mat was replaced and then the polishing pad and 6 kg weight was then dragged across the width of the wires 20 times and again there were visible signs that the foil on the heating mat was starting to wear off.
Test 2: Using the same pad and weight described in Test 1 a piece of polypropylene 100 gsm cloth was placed on top of the foil of the heating mat. The polishing pad and then the 6 kg weight were positioned on top of the heating mat. After 60 times of being repeatedly pulled across the width of the heating mat and 50 times across the length of the heating mat there was no visible sign of wear.
A Zone 1 area was set up on a 19 mm MDF floor. A ripple underlay was laid, a 250W undercarpet heating mat that loomed at 170 Watts per square meter was positioned over the underlay. A slip layer of polypropylene 100 gsm cloth was then positioned over the heating mat and then a wool carpet layer was secured over the slip layer and heating mat. The following heating trials were conducted with an initial air temperature of 17 degrees C.
A Zone 2 area was set up on a 19 mm MDF floor. A ripple underlay was laid, a 250W undercarpet heating mat that loomed at 170 Watts per square meter was positioned over the underlay and then a wool carpet layer was secured over the underlay and heating mat. The following heating trials were conducted with an initial air temperature of 17 degrees C.
In an area of carpet under Zone 1, a plastic lid with a hole drilled through the lid was placed on the carpet surface (Test 1). Through the hole was passed a temperature probe wire and then a 3 inch diameter washer was placed on top to hold the wire and lid in position on the carpet surface. The temperature was monitored over time.
In another test on a Zone 1 area a 25 mm square of copper was used with the temperature probe wire and fastened with a paper clip (Test 2). The plate was placed on the carpet with an eraser as the weight but not totally covering the copper plate. The temperature was monitored with time.
The results are shown in the following tables:
A further test (Test 3) was conducted continuing on with the Test 2 conditions and involved applying a slight weight (approx. 5 gms) pressure to the copper plate. The temperature over time remained at 27 degrees C. for both of the Zones.
Another test (Test 4) was conducted continuing on with the Test 2 conditions but this time involving the placement of the 1.5 kg weight over the copper plate continuously and monitoring the temperature under both Zone 1 and Zone 2 conditions.
The results are shown in the Table below
Other tests were also conducted whereby the probe was positioned in different places between the heating map and the slip cloth, and then orientated in different positions relative to the heating wires in the heating mat. In all such tests there was virtually no difference experienced between the different Zones, strongly suggesting that the slip layer did not interfere or compromise the movement of heat away from the heating mat.
From these examples and tests it can be concluded that the use of a slip layer did not affect the heat transfer from the heating mat through the carpet as shown in the results above. The slip layer is also a very good medium to help protect the outer foil layer surrounding the heating mat from wear.
Wherein the foregoing description reference has been made to integers or components having known equivalents, then such equivalents are herein incorporated as if individually set forth.
Although the invention has been described by way of example and with reference to possible embodiments it is to be appreciated that improvements and/or modifications may be made to these embodiments without departing from the scope of the invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| NZ532691 | Apr 2004 | NZ | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/NZ05/00086 | 4/28/2005 | WO | 00 | 9/27/2007 |
