Composite textile material for the manufacturing of thermoformed products, method and machinery for its manufacturing

Abstract

A composite material developed for manufacturing thermoformed products has applications in furniture making, automotive industry, etc. The composite material for thermoforming is made of a thermoplastic fibrous component consisting of 4-60 mm long and 7-16 DEN polypropylene fibers representing 40% to 50% of the total material weight, and a plant fiber component which can be hemp, jute, sisal, coconut, etc., or a mix of natural fibers which is 70-80 DEN and 5 to 100 mm in length and represents 60% to 50% of the total material weight. Manufacturing the composite material comprises proportioning the components, followed by mixing and coarse defibering, then fine mixing in a four-chamber module which also opens the natural fibers to 70-80 DEN, followed by the consolidation of the fibers and rolling of the resulting fabric in a roll. The machinery for manufacturing the composite material has a modular structure, comprising two modules (1 and 2) for feeding the components, two modules (3 and 4) for weighing and proportioning the components, a primary mixing and coarse defibering module (5), a module (7) for fine mixing and fiber opening, an interlacing module (8), and a module (9) for pulling and rolling the final fabric.

Description

The invention refers to a composite material developed for manufacturing thermoformed products with applications in furniture making, automotive industry, etc., a method and machinery for manufacturing the material in unwoven form.

The majority of upholstered products have a structure in the form of a wood frame. The wood is an excellent material from a functional, ecological and esthetic viewpoint, but the excessive cutting of trees is starting to take its toll on the environment, and so most of the countries now have very strict logging laws. Due to this reason the manufacturers of large series products that contain wood, among which the furniture manufacturers can be found, are looking for solutions to replace wood with other recyclable materials that offer advantages regarding the productivity and the general cost of the product. For this purpose a series of composite materials made of natural and thermoplastic fibers have been developed, materials which can be thermoformed so as to replace products made of wood.

Patent RO 115182 “Nonwoven textile material and process for its manufacturing” shows a nonwoven layered material that is used mainly in the manufacturing of drainage systems. The material is formed of at least three layers which have alternating fiber thicknesses. The odd layers are formed of 4 . . . 10 DEN and 60 . . . 100 mm long polyester fibers, and the even layers are made of monofilament 160 . . . 220 DEN and 80 . . . 100 long polyester fibers. The manufacturing process of the non-woven textile material is done by carding-interlacing of the odd layers, while the even layers are made by forming a fibrous fabric using compressed air. The final assembly is done by interlacing with needles of size 15×18×32×3½″, with an interlacing density of 150 needle stickings/cm² and a depth of travel of 9 mm.

The described composite material does not have thermoforming specific properties and the manufacturing method of carding-interlacing is not efficient for making a composite fabric used in thermoforming.

Patent WO2006052967 “Composite thermoplastic sheets including natural fibers” shows a laminated composite material that is made of a porous core that includes at least one thermoplastic material and natural fibers of jute, linen, hemp, coconut, etc., which make up 80% of the total weight of the porous core. This material is used in numerous products because of its ease of manufacturing through thermoforming. Among the products made so one can find decorative panels for car interiors or public transportation systems and architectural use. The manufacturing method of the composite involves mixing natural fibers with a length of 5 to 50 mm with a thermoplastic resin powder in order to obtain an aqueous foam mix. The natural fibers are set on a wire mesh, then the water is drained and the fibers are heated and compressed to obtain a porous sheet of the desired thickness.

The disadvantage of this method of manufacturing the composite material lies in the difficulty of draining the aqueous solution completely before rolling the material onto rolls. Burning these materials to dispose of them at the end of lifecycle is an impractical solution because they contain fiberglass.

Patent KR970008215 “Thermoplastic composite material reinforced with hemp fibers” refers to a composite material made of a thermoplastic reinforced with hemp fibers and filler represented by wood. The wood filler can be particles, powder or chips and is dispersed homogenously throughout the thermoplastic matrix. The thermoplastic can be polypropylene, polyethylene, a copolymer of ethylene and polypropylene, a copolymer of acrylonitrile-butadiene-styrene or simply nylon. The thermoplastic material may contain anorganic filler such as talcum or plastifiers/lubricants depending on the desired properties. The composite is manufactured as sheets used in die-cutting or pellets used in injection molding.

Patent FR2781492 “Composite thermoplastic material for use in production of various molded articles, includes hemp fibers of specified dimensions and humidity” refers to a thermoplastic composite which includes hemp fibers of sizes and humidity fit for molded products. The composite material is formed of a thermoplastic with a maximum melting point of 200° C. and hemp fibers shorter than 2 mm and with a diameter smaller than or equal to 0.2 mm. The hemp fibers' humidity is maximum 4% of the fibers' mass. The patent describes a method of manufacturing the material that consists of melting the thermoplastic and mixing hemp fibers into it.

The disadvantage of the material obtained by the patented method consists of the fact that it has small strength due to the short fibers and is recommended to be used in injection molding and less for thermoforming.

Patent DE19950744 “Production of a thermoplastic composite material involves mixing and compressing starch-based polymers with shavings of natural plant fibers, followed by melting, homogenization and granulation” refers to the fabrication of a composite thermoplastic material through the mixing and compressing of starch-based polymers with natural fibers, followed by melting, homogenization and granulation of the obtained material. The novelty consists of using a plant derived polymer which together with the natural fibers produces a biodegradable material. The composite material is fabricated by heating the thermoplastic to 120° C. between the laminating rollers, followed by the mixing of natural fibers and homogenization between another set of rollers and the granulation of the material through cooling at the end.

The disadvantages of the known materials consist either in the weak mechanical properties or in the specific weight and specific strength.

The problem solved by the present invention is the manufacturing of a composite material suited for making thermoformed articles, the material being low-cost, 100% recyclable, needing a low content of synthetic materials derived from hydrocarbons and having the advantage of being made primarily out of a fast growing natural resource.

The composite material for thermoforming is made of a thermoplastic fibrous component consisting of 4-60 mm long and 7-16 DEN fine polypropylene fibers representing 40% to 50% of the total material weight and a plant fiber component which can be hemp, jute, sisal, coconut, etc., or a mix of natural fibers which is 70-80 DEN fine and 5 to 100 mm in length and represents 60% to 50% of the total material weight.

The manufacturing process of the composite material consists of the following operations:

a. taking the plant fibers from the bale and cutting them to lengths between 5 and 100 mm, using a rotating blade chopping machine

b. simultaneous weighing of the plant fibers resulted from the previous phase and polypropylene fibers with a length of 60 mm and 7-16 DEN fine using two scales, opening the chutes and periodically releasing a quantity between 0.5 and 2 kg on a conveyor belt in order to obtain a mix for the composite material of which the plant fibers represent 50-60% of the total mass

c. coarse mixing of the plant and polypropylene fibers and defibering them with the help of a fiber opener with nails, then transferring the material to a mixer with four vertical chambers

d. mixing and finely shredding the materials which is carried out at first in the chambers of the four chamber mixer where the material is fed by compressed air in order to obtain the mixing of the two components, then comes the second phase, where the fibrous material from each of the chambers is shred with the help of the nail rollers which feed fibrous layers onto a conveyor belt where four overlaid layers are made, one from each chamber of the mixer, this allowing an optimum homogenization of the two components, then the obtained material is sent to another feeder which transfers the material with the help of compressed air to the surface of two perforated rollers which rotate in opposite directions and create a blanket that is homogenous in terms of weight/surface unit

e. interlacing the material with the help of barbed needle machines which consolidate the fibrous layer by routing the upper layer fibers to the lower layer and the fibers in the lower layer to the upper layer, increasing the strength of the fibrous material and implicitly reducing its thickness by a factor of 4 to 5

f. pulling and rolling the material with the help of two rollers in order to make a fabric with consolidated fibers (by interlacing) and packaged as a roll

The machinery for producing the composite material consists of at least two feeding modules, one for the thermoplastic fibers and the other for the plant fibers, one module which weighs and feeds correct proportions of each type of fiber, one module for the primary mixing and the coarse defibering, one module for the fine mixing and defibering, one module for interlacing and one module for pulling and rolling the material.

The following presents an example of such a machinery with the help of FIGS. 1 and 2 which represent:

FIG. 1 represents the modular structure of the machinery for the manufacturing of the composite material

FIG. 2 represents the technological schematic of the machinery for the manufacturing of the composite material.

The machinery for the manufacturing of the composite textile material is made of the following modules:

• • module 1, which takes the plant fibers from the bale, chops them to the predetermined length and feeds them to the next module;
  • module 2, which feeds the thermoplastic fibers to the next module;
  • module 3, for weighing and periodical feeding of the plant fibers on a conveyor belt 5a of module 5, for primary homogenization;
  • module 4, for weighing and periodical feeding of the thermoplastic fibers on a conveyor belt 5a of module 5;
  • module 5, for the homogenization and primary opening of the textile fibers;
  • module 6, for the homogenization and fine defibering to a value of 70-80 DEN;
  • module 7 for the compressing and forming of the composite fabric;
  • module 8, for the interlacing;
  • module 9, for the rolling of the obtained fabric.

Module 1 consists of a conveyor belt 1a that has a roller 1b at one end, which feeds the plant fibers FV to a chopper 1c, with rotating blades 1d. Chopper 1c cuts the plant fibers FB to a length between 5 and 100 mm. The length of the fibers is set by tuning the speed of the conveyor belt 1a with the speed of the rotating blades 1d. The shortened plant fibers FV go through a pressing device 1e and are then transferred on a horizontal conveyor belt 1f, then onto an inclined conveyor belt 1g. Conveyor belt 1g has nails which prevent the material from sliding on it. This way conveyor belt 1g takes a great part of the fiber quantity and the formed fibrous layer will be equalized by the equalizing roller 1h that rotates opposite to the travel direction of the inclined conveyor belt, and the excess material will fall onto conveyor belt 1g which will homogenize the fibrous material.

Plant fibers FV are transferred in the direction of arrows A1 and B1 of module 3 at a constant flow.

Module 2, for the feeding of the thermoplastic fibers FT is composed of a conveyor belt 2a and a conveyor belt 2b, that is inclined and has nails. The thermoplastic fibers FT are transferred in the direction of arrows A2 and B2 towards module 4 at a constant flow that is tuned by the equalizing roller 2c.

Module 3 consists of a decompressing roller 3a, which takes plant fibers FV from conveyor belt 1g, and a weigh hopper 3b. Weigh hopper 3b weighs and releases equal quantities of plant fiber FV onto conveyor belt 5a.

Weigh hoppers 3b and 4b open periodically and empty onto conveyor belt 5a the necessary quantity of each component of the composite in order to obtain the right mix percentages.

Module 5, used for the homogenization and primary opening of the textile fibers, takes quantities of each material component from conveyor belt 5a periodically and, with the help of roller 5b which is a nail decompressor, the material is transferred into compressor 5c. The material passes between two feeding rollers 5d to fiber opener 5e, and then together with two other feeding rollers 5f goes to a horizontal fiber opener 5g. The horizontal opener ensures that the fibers get opened up to 150-200 DEN fine.

A pressure switch 5h controls the feeding of condenser 5c depending on the value of the pressure inside it.

The mix is sent from the horizontal opener 5g through tubing 5i to module 6 for homogenization and fine defibering.

Module 6 is fed with a mix of fibers through the upper part of the four vertical chambers 6a, 6b, 6c and 6d. Each vertical chamber 6a, 6b, 6c and 6d is fitted with two feeder rollers 6e and fiber opener roller 6f.

For a better homogenization of the textile fibers with the thermoplastic fibers, conveyor belt 6g periodically releases approximately equal quantities of mixed material from each of the chambers 6a, 6b, 6c, 6d by controlling the timing of the feeder rollers 6e of the chambers using photocells 6h.

From conveyor belt 6g the fibrous material mix goes to fiber opener 6i which opens the material to 70-80 DEN, and from here, through tubing 6j, the material goes to compression module 7.

Compression module 7 contains compressor 7a. The fibrous material is detached from condenser 7a and falls into the aspiration bunker that controls the flow using photocell 7b, and is then taken by the feeding rollers 7c and opened by the fiber opener roller 7d.

A rigid gasket with saw like teeth sends fiber packages to the surfaces of the two perforated rollers 7e which rotate opposite to one another (arrows 7g) thus obtaining a uniform thickness of the fabric which is then detached by a deflecting shield. Thus, the fabric is lead onto conveyor belt 7h and from here on to module 8, for the interlacing.

Module 8 contains 3 interlacing machines 8a, 8b and 8c. Each machine has a set of barbed needles that pass the fibers from the upper layer to the lower layer and vice-versa, thus obtaining a consolidation of the fibrous material through the interlacing of the fibers.

Next the consolidated material is taken up by a rolling module 9 with the help of rollers 9a and lead to the rolling system that consists of two lower rollers 9b which rotate in the same direction and package the composite material in the form of roll 9c.

The main differences in the proposed technological process as compared to the known solutions are presented in table 1.

TABLE 1
Operation	Existing solution	Proposed solution
Component fiber opening	uses a double card which subjects	uses a nail fiber opener with
	the fibers to stress and results	a rigid gasket that protects the
	in fibers of different lengths	fibers' characteristics
	fibers with a high wood content	a large array of fibers can
	cannot be opened	be used, including plants
		with more than 20% plant
		fiber content
Machinery cost	more expensive and higher maintenance	shorter workflow
	machinery	easier maintenance
	limited carding capability	2-3 times higher capacity
	high energy consumption	60% of the energy consumption
		of the existing processes
Component mixing	double card	four chamber mixing
	around 30-40% waste results from	module
	the opening and mixing stage	waste is under 10%
Fibrous layer making	the forming is done by plying the	the forming of the fibrous layer
	fibrous layer that exits the card	makes fibers with multiple orientations
	limited capacity due to the chopping	2 to 3 times greater processing capacity
	speed of the plyer

The textile material can be used for various applications:

• • automotive industry: dashboards, front bumpers, door interiors, consoles, trunks, etc.
  • furniture industry: sofas, tables, furniture, hangers, mirror frames, chairs, drawers
  • products for home use: trays, dishes, etc.By applying the invention the following advantages are obtained:
  • obtaining recyclable materials, that do not contain toxic compounds, with multiple applications (automotive industry, furniture industry, home goods, etc.)
  • rapid growth raw materials are used which can grow anywhere on earth
  • reduced dependency on hydrocarbons
  • reduced water consumption in both the production of the raw material as well as in manufacturing
  • reduced electric energy consumption/kg of material
  • low workforce needed and fast productivity growth
  • the manufacturing process uses machinery specific to plant fibers which is easy to build and run
  • the technology doesn't pollute because the waste can be reused in the manufacturing of new material and doesn't give off toxic gases into the atmosphere.

Claims

1. A manufacturing process for the production of a composite fabric material comprising a) 40-50 wt % of a 1st component made of thermoplastic fibers (FT) with a length of 4 to 60 mm and a denier of 7-16 DEN; andb) 50-60 wt % of a 2nd component made of plant fibers (FV) with a denier of 70-80 DEN and a fiber length of 5 to 100 mm;