US20010028127A1

US20010028127A1 - Method for manufacturing a floor covering

Info

Publication number: US20010028127A1
Application number: US09/782,036
Authority: US
Inventors: Terence Hinds; John Geraghty; Rolf Basler
Original assignee: Individual
Current assignee: Individual
Priority date: 1997-08-27
Filing date: 2001-02-14
Publication date: 2001-10-11
Also published as: EP0899372B1; ATE324482T1; EP0899372A2; EP0899372A3; DE69834297D1

Abstract

A method for manufacturing a floor covering involves leading a glass fiber matt 1 from a supply reel 2 onto a conveyor belt 3. At a first scattering station 4, a saturation material is scattered onto the matt 1 to form a scattered layer. The matt 1 is then led between upper and lower heated belts 10, 11 to gel the scattered layer. The belts are then passed between a pair of smoothing/nipping rollers to form a layer of uniform thickness. The belts are then cooled and the matt 1 with saturation layer applied is wound for further processing. In an alternative arrangement a saturation material is scattered directly onto a substrate belt at the first scattering station 4, a glass fiber matt 26, is applied over the scattered material and, at a second scattering station 28, an amount of the saturation material or a different material is scattered onto the matt 26.

Description

INTRODUCTION

The invention relates to a method for manufacturing a floor covering and in particular to a method for manufacturing a polymeric, for example, a vinyl floor covering.

In conventional manufacturing processes for cushion vinyl floor covering, a glassmat tissue or mineral felt is used as the base carrier material. In a first step in the process, the glassmat tissue is saturated with a PVC plastisol material which is applied to the mat using a knife and/or application roller. The plastisol is then gelled on a hot chrome plated drum to provide a smooth solid surface.

A basecoat in the form of a foamable plastisol is applied using a knife or roller to a coating thickness of typically 300 g/m ². This basecoat is also gelled on a hot gel drum to produce a smooth surface which is suitable for printing. A design is then printed on the gelled basecoat, typically using a rotogravure method in which a design/coloration is printed using a sequence of printing cylinders. To provide an embossed finish, one or more of the cylinders applies an inhibitor in a desired pattern. The inhibitor inhibits foam expansion.

A topcoating in the form of a clear PVC plastisol is then coated on top of the print layer and the topcoating is gelled on a hot gel drum. The layered product thus formed is then heated in an oven at typically 190° C. which causes the basecoat foam layer to expand in all areas except where the inhibitor has been applied. The PVC plastisol also fuses at this temperature to give a clear hard resilient surface finish.

A backing layer in the form of a PVC plastisol is coated onto the product. The backing may be of a foamable material. If desired, the surface of the floor covering thus formed may be toughened by applying a crosslinkable polyurethane or acrylic lacquer.

There are a number of problems with such manufacturing techniques. In particular, there is an ever increasing need to minimise production and raw material costs, to minimise use of environmentally unfriendly material while optimising product quality.

There is therefore a need for an improved cost effective method for producing floor covering.

STATEMENTS OF INVENTION

According to the invention, there is provided a method for manufacturing a floor covering comprising the steps of:

scattering powder, granules or pellets of a thermoplastic material onto a substrate to form a coating;

leading the coating between a pair of belts;

applying heat to gel the coating between the belts;

smoothing the gelled coating to provide a layer of desired thickness; and

cooling the layer.

In a particularly preferred embodiment of the invention, the substrate is a fibre matt material, especially a glass fibre matt material. Preferably, the fibre matt has less than 100 g, ideally less than 65 g and most preferably from 30 to 50 g of glass fibre per m ²of material. This material is easily handled in roll form and provides the required reinforcing strength.

In an especially preferred embodiment of the invention, the gelled coating is smoothed by leading the gelled coating between a nipping means.

Ideally, for ease of use the nipping means comprises a pair of nip rollers defining a gap therebetween. Preferably the method includes the step of adjusting the gap between the nip rollers. In this way the process is readily tailored to a desired final product.

In one embodiment of the invention the method comprises the steps of:

scattering powder, granules or pellets of thermoplastic material onto a first substrate to form a first coating;

applying a second substrate over the first coating;

scattering powder, granules or pellets of a thermoplastic material onto the second substrate to form a second coating;

leading the coatings between a pair of belts;

applying heat to gel the coatings between the belts;

smoothing the gelled coatings to provide a layered product of desired thickness; and

cooling the layered product.

In one case the first substrate is defined by a lower of the belts. Alternatively or additionally the second substrate is a fibre matt substrate as defined above.

For some applications the first and second coatings may be the same. For example, the coatings may be of a saturation material to provide a highly efficient saturation layer in which the substrate matt is impregnated from both sides.

Alternatively, the coatings may be of a different material. For example, the first coating may be of a saturation material and the second coating may be of a basecoat material. The advantage of such an arrangement is that two layers may be formed in one pass through the heating section.

In both cases, if required, the or each coating may be pre-heated by means of an infra red heater or the like.

The material may be scattered to form, on heating, a basecoat layer. The basecoat is preferably a foamable layer, typically formed using a blowing agent mix of azodicarbonamide and zinc oxide.

Preferably, the basecoat is formed by a method including the steps of:

scattering a foamable basecoat-forming material onto the saturation layer of the substrate;

leading the substrate between a pair of belts; and

applying heat to the belts to form a basecoat layer on the saturation layer.

In one embodiment of the invention, a substrate is defined by one of especially the lower of the belts.

Preferably, the method includes the steps of:

scattering a first thermoplastics material onto a first belt;

applying a substrate over the first thermoplastics material;

scattering a second thermoplastics material onto the substrate;

leading the substrate with the first and second thermoplastics materials under a second belt; and

applying heat to the belts to gel the thermoplastics material to form a backing layer on one face of the substrate and a saturation or basecoat layer on the other face of the substrate.

In one embodiment of the invention, the second layer is a saturation layer and the method includes the steps of:

scattering a third thermoplastics material over the saturation layer;

leading the substrate between a pair of belts; and

applying heat to the belts to gel the third thermoplastics material to form a basecoat layer on the saturation layer.

Preferably, after heating, the substrate is led over a smoothing roller prior to cooling. Ideally, one of the belts as it is led over the smoothing roller.

In one embodiment of the invention, the method includes the step of heating and/or cooling the substrate as it is led over the smoothing roller.

Preferably, the substrate is heated or cooled by heating or cooling the smoothing roller.

In a preferred arrangement, the substrate is led over an infeed roller to the smoothing roller. Preferably, the substrate is led over an outfeed roller from the smoothing roller.

In one embodiment of the invention, the substrate is heated or cooled as it is led over the infeed and/or outfeed rollers.

Preferably, the substrate is cooled after gelling by leading the pair of belts through a cooling station.

In another embodiment of the invention, the substrate is a mineral felt. In this case, a saturation layer is typically not required and a basecoat material is applied directly to the substrate.

In this specification basecoat layer refers to the layer which is subsequently printed. The basecoat is preferably of a foamable material.

The invention also provides a floor covering whenever manufactured by the method of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be more clearly understood from the following description thereof, given by way of example only, with reference to the accompanying drawings, in which: [0054]
FIG. 1 is a diagrammatic side elevational view of apparatus used in the method of the invention. [0055]
FIG. 2 is a diagrammatic side elevational view of an apparatus of FIG. 1 used in a method for manufacturing a floor covering according to the invention in one arrangement of use; [0056]
FIGS. [0057] 3 to 5 are cross sectional views of a layered floor covering product at various stages in the method of FIG. 2;
FIG. 6 is a diagrammatic side elevational view of the apparatus of FIG. 1 in another arrangement of use; [0058]
FIGS. [0059] 7 to 9 are cross sectional views of a layered floor covering product at various stages in the method of FIG. 6;
FIG. 10 is a perspective view of part of the apparatus of FIG. 1; [0060]
FIG. 11 is a side elevational view of the apparatus of FIG. 10; [0061]
FIG. 12 is a perspective view of another part of the apparatus of FIG. 1; [0062]
FIG. 13 is a side elevational view of the apparatus of FIG. 12; [0063]
FIG. 14 is a perspective view of a smoothing roller part of an alternative apparatus; and [0064]
FIG. 15 is a plan view of the apparatus of FIG. 14.[0065]

DETAILED DESCRIPTION

Referring to FIGS. 1 and 2 of the drawings, there is illustrated an apparatus used in a method for manufacturing a floor covering according to the invention. A [0066] substrate 1, in this case in the form of a glass fibre matt material having 30 to 50 g/m²of glass fibre material is led from a supply reel 2 onto a lower conveyor belt 3. At a first scattering station 4, a material is scattered in a curtain 5 onto the glass fibre matt substrate 1 to form a scattered layer 6.
The [0067] fibre matt substrate 1 with the scattered layer may then be passed without any further layers being applied between an upper belt 10 and a lower belt 11 of a thermofixing oven unit 12. The belt 11 forms a continuation of the belt 3. The oven unit 12 is a heated low pressure double belt press which applies heat to the scattered layer 6 and glass fibre matt 1 to bind the non woven glass matt to the scattered layer 6. In this case the oven unit comprises a number of upper and lower sections 13, 14. The operating temperature of each section or groups of sections 13, 14 may be varied.
After heating, the substrate supported between the upper and [0068] lower belts 10, 11 is led between a pair of nipping rollers 15, 16 to smooth the gelled coating to provide a layer of desired thickness.
The gelled layered substrate is then cooled between the pair of belts at a [0069] cooling station 17. The cooling station 17 comprises a plurality of top and bottom cooling sections 18, 19, the operating temperature of which may be adjusted in groups or individually. The layered substrate 30 may then be wound onto a take-up reel 40.
Further layers may be scattered onto the gelled substrate by leading the substrate through the apparatus again as described above or through another similar apparatus arranged in series. [0070]
Alternatively or additionally, and referring particularly to FIGS. [0071] 6 to 10 at a second substrate applying station 25, a substrate such as a fibre matt 26 may be applied over the first scattered layer either before or after heating. One or more further layers may be formed by scattering a dry blend material onto the second substrate 26 at a second applying station 28 upstream of the heating oven 12. In this way, any desired layer structure may be built up. An infra red heater 27 may be used to heat the first scattered layer and/or substrate in advance of oven heating and second scattering.
In one case, the scattered material forms, on heating, a saturation layer to receive a basecoat material. Alternatively or additionally, the material is scattered to form, on heating, a foamed basecoat layer. [0072]
The basecoat may be formed by scattering a foamable basecoat material onto the saturation layer of the substrate, and heating the dry blend to form a foamed basecoat layer. [0073]
Referring particularly to FIGS. [0074] 6 to 10 the substrate may be defined by one of the heating belts 3, 11. In this case, a first material may be scattered onto the first belt 3, 21 at the first scattering station 4, a substrate 26 applied over the first coating and a second coating applied over the substrate 26 from the second scattering station 28. The substrate with the first and second scattered layers is then led under the second belt 10 and the layered product is heated to gel the coatings. For example, a backing layer may be formed on one face of the substrate and a saturation or basecoat layer on the other face of the substrate.
In another case, the second layer is a saturation layer and the method includes the steps of scattering a further coating over the saturation layer and heating the third coating to form a basecoat layer on the saturation layer. [0075]
The material that is scattered on the substrate may be in any suitable form such as powder, granules or pellets. A blended powder may be extruded to produce a fully fused compound which is then pelletised and in some cases pulverised. Such pellets have the advantage that they are more easy to control and are less adherent to the belts generally than powders. Thus, a more controlled scattering, higher processing speed and a more uniform product may be achieved. Typically the pellets are from 0.5 to 2 mm diameter, preferably about 1 mm, and from 1 to 2 mm long, preferably about 1.5 mm. The pulverised particles are generally in the 100 to 500 micron range. [0076]
Preferably the belts are at least coated with a release material such as a silicone-based material and/or Teflon or the like material. [0077]
In an alternative or additional arrangement illustrated in FIGS. 14 and 15 the gelled coating may be smoothed or further smoothed by leading the substrate supported on the lower belt [0078] 11 over a large diameter smoothing roller 20. To optimise the operation of the smoothing roller 20, the substrate is first led over an infeed roller 21 on the infeed side and is led over an outfeed roller 22 at the outfeed side of the smoothing roller 20.
The substrate may be heated or cooled by circulating a heating or cooling fluid through the smoothing [0079] roller 20. Similarly, a heating or cooling fluid may be circulated through the infeed and/or outfeed rollers 21, 22.

EXAMPLE 1

A glass fibre matt material having 50 g/m[0080] ²of glass fibre material is used as the substrate.
A saturation layer forming dry blend of the following formulation was used. The dry blend may be in the form of a powder or in the form of granules or the like material. [0081]

Parts by Weight

Suspension Grade PVC 100

Di-2-Ethyl Hexyl Phthalate 40-60

Butyl Benzyl Phthalate 10-30

Calcium Carbonate Filler 100-160

Barium/Zinc Stabiliser 2-3
At a first scattering station, an amount of typically 200 g/m[0082] ²of the saturation dry blend is applied on a substrate belt. The glass fibre matt is then applied over the scattered material as described above and at a second scattering station an amount of typically 200 g/m²of the saturation dry blend is scattered on top of the fibre matt. We have found that by splitting the saturation material and applying it top and bottom as described, a matt with a high level of saturation and a smooth surface finish is achieved. Alternatively, an amount of 350 g/m²of the saturation dry blend may be applied to the top of the fibre matt at only one scattering station.
The substrate is then passed between heated belts at a temperature typically in the range of 180° C. to 200° C. at a residence time in heating of typically one minute. [0083]
The heated layered substrate is passed between nip rollers and then cooled by passing between a pair of cooling belts which are maintained at typical process water conditions. The residence time in cooling is typically one minute. [0084]
A glass fibre matt with a smooth surface top and bottom is formed in a highly cost efficient manner which may be processed further using conventional techniques or by passing through the same oven unit or another similar unit arranged in series. [0085]

EXAMPLE 2

A foamed basecoat material may be applied to a saturated substrate using the following basecoat dry blend formulation:



	Parts by Weight

	Suspension Grade PVC	95-100
	Dispersion Grade PVC	0-5
	Di-2-Ethyl Hexyl Phthalate	20-50
	Butyl Benzyl Phthalate	20-50
	Calcium Carbonate Filler	20-80
	Barium/Zinc Stabiliser	1.5-3.5
	Blowing Agent Mixture	2-4
	(Azodicarbonamide/Zinc Oxide)
	Titanium dioxide	6-10

The foamable basecoat material is scattered onto the saturated substrate at a single scattering station at a rate of from 250-450 g/m[0087] ²and further processed as described above in Example 1.
It will be appreciated that the method is applicable to producing non directional homogeneous floor covering materials. [0088]
It will also be appreciated that while the invention has been described particularly in relation to PVC material it may also be applied to any suitable thermoplastics materials which are substantially free of PVC. [0089]
Many variations on the specific embodiments of the invention described will be readily apparent and accordingly the invention is not limited to the embodiments hereinbefore described which may be varied in detail. [0090]

Claims

1. A method for manufacturing a floor covering comprising the steps of:

leading the coating between a pair of belts;

applying heat to gel the coating between the belts;

smoothing the gelled coating to provide a layer of desired thickness; and

cooling the layer.

2. A method as claimed in

claim 1

, wherein the substrate is a fibre matt material, especially a glass fibre matt material.

3. A method as claimed in

claim 2

, wherein the fibre matt has less than 100 g of glass fibre per m²of material.

4. A method as claimed in

claim 3

, wherein the fibre matt has less than 65 g of glass fibre per m²of material.

5. A method as claimed in

claim 4

, wherein the fibre matt has from 30 to 50 g of glass fibre per m²of material.

6. A method as claimed in

claim 1

wherein the gelled coating is smoothed by leading the gelled coating between a nipping means.

7. A method as claimed in

claim 6

wherein the nipping means comprises a pair of nip rollers defining a gap therebetween.

8. A method as claimed in

claim 7

including the step of adjusting the gap between the nip rollers.

9. A method as claimed in

claim 1

comprising the steps of:

applying a second substrate over the first coating;

leading the coatings between a pair of belts;

applying heat to gel the coatings between the belts;

cooling the layered product.

10. A method as claimed in

claim 9

wherein the first substrate is defined by a lower of the conveyor belts.

11. A method as claimed in

claim 9

wherein the second coating is of the same material as the first coating.

12. A method as claimed in

claim 9

wherein the second coating is of a different material to the first coating.

13. A method as claimed in

claim 9

wherein the first coating is of a saturation material to form, on heating, a saturation layer.

14. A method as claimed in

claim 9

wherein the second coating is of a basecoat material to form, on heating, a basecoat layer.

15. A method as claimed in

claim 1

wherein the thermoplastic material is scattered to form, on heating, a saturation layer to receive a basecoat layer.

16. A method as claimed in

claim 1

wherein the thermoplastic material is scattered to form, on heating, a basecoat layer.

17. A method as claimed in

claim 16

wherein the basecoat is formed by a method including the steps of:

scattering a basecoat-forming material onto the saturation layer of the substrate;

leading the substrate between a pair of belts; and

applying heat to the belts to form a basecoat layer on the saturation layer.

18. A method as claimed in

claim 1

wherein a substrate is defined by one of the heating belts.

19. A method as claimed in

claim 1

including the steps of:

scattering a first thermoplastic material onto a first belt;

applying a substrate over the thermoplastic material;

scattering a second thermoplastic material onto the substrate;

leading the substrate with the first and second thermoplastic material under a second belt; and

applying heat to the belts to gel the thermoplastic material to form a backing layer on one face of the substrate and a saturation or basecoat layer on the other face of the substrate.

20. A method as claimed in

claim 19

wherein the second layer is a saturation layer and the method includes the steps of:

scattering a third thermoplastics material over the saturation layer;

leading the substrate between a pair of belts; and

applying heat to the belts to gel the third thermoplastic material to form a basecoat layer on the saturation layer.

21. A method as claimed in

claim 1

including the step, after heating, of leading the substrate over a smoothing roller prior to cooling, preferably the substrate is supported on one of the belts as it is led over the smoothing roller, preferably the method includes the step of heating and/or cooling the substrate as it is led over the smoothing roller, preferably the substrate is heated or cooled by heating or cooling the smoothing roller, preferably the substrate is led over an infeed roller to the smoothing roller, preferably the substrate is led over an outfeed roller from the smoothing roller, preferably the substrate is heated or cooled as it is led over the infeed and/or outfeed rollers.

22. A method as claimed in

claim 1

wherein the substrate is cooled, after gelling, by leading the pair of belts through a cooling station.

23. A method as claimed in

claim 1

wherein the substrate is a mineral felt.

24. A floor covering whenever manufacturing by a method as claimed

claim 1

.