NO771220L - TISSUE STRUCTURES. - Google Patents

Description

The present invention relates to grid-shaped net structures of thermoplastic material which are soft and which have high strength and a method for their production. More specifically, the invention relates to grid-shaped structures of thermoplastic material of a uniform thickness across the web, consisting of a first set of oriented substantially parallel flat threads running in the machine direction and crossing a second set of oriented substantially parallel flat threads running across the machine direction , where the said threads all have a largely rectangular cross-section and where the width of the threads is at least 1.5 times the thickness and where the nodes in the threads are biaxially oriented and have a thickness that corresponds to the thickness of the threads and the first set of threads is vertical on the other hand, as well as methods for producing such nets.

The term "oriented" or "orientation" as used in the specification and claims means "molecularly oriented" or "molecular orientation".

Network structures of this type are known from prior art. E.g. describes the U.S. patent 3,386,876 a rectangular mesh of thermoplastic material having round or oval threads and having unoriented thread junctions which are much thicker than the threads themselves. Due to the non-uniform thickness over the mesh structure and due to its low strength, due to unoriented thick nodes, this mesh is not applicable to reinforce e.g. paper,

Another type of web structure of thermoplastic material is described in U.S. Pat. patent 3,666,609. This structure differs from the structure according to the present invention mainly in that it has threads that have round or oval cross-sections. The round or oval cross-sections of the threads give an undesirable stiffness, which gives the structures a stiffer guide than the structure according to the invention.

Another type of net of thermoplastic material is described

in the U.S. Patent No. 3,365,352. This structure differs from the structure according to the invention in particular in that the threads intersect each other diagonally and where both the nodes and the threads are biaxially oriented. Due to the diagonal cutting of the threads and the low strength, the net is not applicable in reinforcement.

The relative stiffness or softness (which is sometimes referred to as 'soft guide') of a checkered net structure is mainly the result of the cross-section of the threads. For a given basis weight and a given distance between the threads, the softness of a given checkered net of thermoplastic material can be judged from the bending modulus of the threads, the softer the net, the smaller the bending modulus. Bending modulus (D) in a rectangular wire can be expressed by the following formula:

where w is the width of the wire, t is the thickness and E is the tensile modulus of the material. The above formula clearly indicates that thread thickness has a stronger influence on softness than thread width. A net with a rectangular cross-section in the threads with width greater than the thickness will be softer than a thread with a circular or square cross-section of the threads with the same polymer material and wdkt.

It is an object of the invention to provide a grid-shaped net structure of a thermoplastic polymer material with soft guidance and a high ratio between strength and weight.

According to the invention, a web structure of a thermoplastic polymer material of uniform thickness is provided which comprises a first set of generally parallel threads running in the machine direction and which are crossed at right angles by a second set of generally parallel threads running across the machine direction , where both threads are oriented when pulled in both of the indicated directions, where the net structure is characterized by the width of the threads being at least 1.5 times the thickness, so that the threads all have a flat, mostly rectangular cross-section after pulling, and where the threads' nodes are biaxial oriented and the net structure has a uniform thickness.

Likewise, according to the invention, a method is provided for producing a grid-shaped net structure of thermoplastic material with a first set of oriented largely parallel threads that run in the machine direction and which are cut at right angles by a second set of oriented, largely parallel threads that run across the machine direction , where the polymer film is subtracted from approx. 3 to 6 times both in the machine direction and across it, characterized by the fact that the film before drawing has a thickness of from approx. 0.075 mm to 0.625 mm and a pattern of round discontinuous op-

nings which are uniformly oriented longitudinally and transversely in a square pattern, and the film is heated to obtain an orientation of the strands along their longest axes and in both directions at the junctions during the drawing operation,

so that the round discontinuous openings in the film are placed so that the distance between the circumference of any opening and the circumference of any neighboring opening of

the narrowest point is at least 1.5 times the thickness of the film and the ratio between and the distance between the circumference of any opening and the circumference of any neighboring opening at the narrowest point and the diameter of the opening

the ratios are from 1.4 to 1.5 to 1.

The temperature at which the perforated film should be drawn

with to provide the desired orientation will de-

depend on the special polymer from which the film is made.

For example, polypropylene film should be drawn at a temperature

on from approx. 100°C to approx. 140°C. The exact temperature required for other polymers will be apparent to those skilled in the art.

The order of drawing is not critical. The machine direction can be carried out before, after or at the same time as the drawing across.' For good reasons in commercial pro-

position, transverse drawing using a stretching frame followed by stretching in the machine direction on a stretching machine with rollers at different speeds will be preferred.

As mentioned above, the shape, size and distance between the openings in the polymer film will be critical in order to obtain a net structure with soft guidance and a high ratio between strength and weight. Consequently, care must be taken when making the openings. There are many ways in which S.lik.e openings can be produced, e.g. by stabbing, drilling, £orm;L,ng<q.>q-.v*. The best method to use in each case will be obvious to those skilled in the art,

The polymer material used to produce the net structure according to the invention can be a

any easily orientable thermoplastic polymer material, §$&<p>HJpoly<g>lefine?:, polyesters, polyamides, ethylene-vinyl-acetate k.QpQrLyme.re<q>,s.,v. The most preferred starting materials are homopolymers and copolymers of olefins, because of their low Pfffca and ease of processing.

The present invention will be understood more easily with reference to the attached drawings.

Fig. 1 is a drawn thermoplastic polymer film viewed from above, which has been perforated in accordance with the invention prior to drawing?

fig; 2 is a cross-section along the line 2-2 i

£igt Ir

fig 3 éb-an isomeric projection of a dfel

The P,V network structure according to the invention.

With reference to fig. 1, a more detailed description can be obtained as this drawing illustrates part of an undrawn film of thermoplastic polymer material (a) which

has a series of round openings (c). The openings are all of the same diameter (d). and have the same distance at the narrowest point between the circumference of neighboring openings (b) and they are evenly spaced along pg on. across in a square pattern.

The cross section of the drawn film in fig. 2 Shows the thickness (t) of the film (a) in relation to the diameter of the openings (d) Qg the distance at the narrowest point between the circumferences of neighboring openings (b).

The perspective sketch of the network structure according to the invention in fig. 3, shows the set of oriented largely

parallel flat threads (f) running in the machine direction and on

across this and intersecting the oriented nodes (i),

with the threads (f) perpendicular to each other and with a largely rectangular cross-section of the threads (f), where the width (w) is at least 1.5 times the thickness (t-^).

Gain reason for the soft guidance and the high

balance between strength and weight, the net structure according to the invention can be used in different ways, such as e.g. to reinforce the paper, film, foam or non-woven fabrics.

The following examples are presented to

illustrate the invention and the method for producing the network structures according to the invention.

Example 1

A 0.025 mm thick film of ethylene-propylene copolymer containing approximately 5% units from ethylene, provided with a uniform quadratic pattern of round holes each having a diameter of 1.125 mm placed so that the distance between the circumference , (ie, the edges! a.V neighboring holes is 0.55 mm and the ratio between width and thickness in the narrowest part between two neighboring holes is 2.2 , stretching on a stretching frame 4.5 times in the direction across the machine in an oven with a temperature of 110°C and is then stretched on a stretcher with several rollers s cm moving at different speeds 4.5 times in the machine direction, while the rollers are heated at a temperature of about 100°C. The resulting checkered net structure has approx. 1.4 threads per

cm in; both directions and one. basic weight of approx. 8.37 g/cm2' The threads are approx. 0.3 mm wide, 0.1 mm thick and have a rectangular cross-section. The resulting structure is flat and has relatively uniform thickness across the mesh. It has a soft guide with a stretching speed of approx. 3.2 kg/cm 2 in the machine direction and 1.1 kg/cm across the machine direction and a tongue effect of approx. 0.45 kg in; both directions, On. due to its softness and high strength-to-weight ratio, the net structure is well suited to reinforce the plastic film.

Example 2

A 0.125 mm thick film of ethylene-propylene copolymer containing about 5% units from ethylene produced a uniform square pattern of round holes each having a diameter of 1.125 mm positioned so that the distance between the perimeters (ie the edges) of neighboring holes is 0.55 mm and the ratio between width and thickness of the narrowest part between two neighboring holes is 4.4, is first stretched on a stretcher with several rollers at different speeds, 4.1 times in the machine direction while the rollers are heated to 100°C and then on a stretching frame 5 times in the direction across the machine in a room with a temperature of 110°C. The resulting net structure had about 1.5 threads per cm in the machine direction and 1.2 threads per cm across the machine direction and a basis weight of <» 4^4 g/m 2 . The wires are rectangular in cross-section with a width of 0.3 mm and a thickness of 0.05 mm. The resulting structure is flat and has uniform thickness. It has a soft guide, a tensile strength of 0.59 kg/cm in the machine direction and of Of 61 across the machine direction and a tongue riVA-ing of approx. Q.27 kg in both directions - The structure is well suited to reinforce tissue paper.

Example 3

The network structure described in example 2 is compared with commercial network structures produced from the same copolymer and with the same basis weight. The physical properties a the stiffness (i.e. bending modulus determined by applying the formula as stated above) divided by the Tensile modulus times the number of threads per cm) are reproduced in Table I.

Example 4

A 0.12 mm thick film of ethylene-propylene copolymer described in Example 2, with the same pattern of round holes of the same diameter positioned in the same manner,

with it. the same distance between the edges as described in example 2, is first stretched through a roller stretcher with different speeds on the rollers 4.7 times in the machine direction with the rollers heated to 125°C and then stretched in a stretching frame 5 times across the machine direction in a furnace with 13Quc . The resecting network structure has approx. 1.4 thread there pa?, cm. in both directions and a basis weight of 3.6 8 gr/cm<2>The threads are rectangular in cross-section with a width of 10 3 mm and a thickness of 0.05 mm, The resulting structure is flat and with a thickness of a soft guidance. The provided net with the rectangular configuration of the threads is compared with a net having the same basis weight and largely the same number of threads. size of the openings and shape of the threads, except that the threads run diagonally. Modulus, tensile strength and tensile elongations in the two types of nets are shown in table XX,

Claims (6)

1. Mesh structure of thermoplastic material of uniform thickness, c a u r a c t e r i s e r in that it consists of a first set of oriented and substantially parallel flat threads running in the machine direction and which is intersected by a second set of oriented substantially parallel flat threads running transverse to the machine direction , where the said threads all have a largely rectangular cross-section where the width of the threads is at least 1.5 times the thickness and hvcir the nodes between the strands are biaxially oriented with the strands perpendicular to each other at the node. 2. Grid-shaped net structure of thermoplastic material according to claim 1, characterized in that the thermoplastic is a polyolefin. 3. Checkered net structure according to claim 2, where the polyolefin is an ethylene-propylene copolymer. 4. Procedure for producing a grid-shaped . net structure of thermoplastic material consisting of a first set of oriented substantially parallel flat threads running in the machine direction and supported by a second set of oriented substantially parallel flat threads running at t <y> ers of the machine direction, said threads all Large sets have rectangular cross-sections, in which the width of the threads is at least 1.5 times the thickness, characterized in that a! polymer film of thermoplastic material with a thickness of from about, Q.07 mm to 0.0625 mm and a pattern ay rough discontinuous openings which are placed evenly in length and crosswise, in a square pattern are stretched from 3 to 6 times both , in the machine direction and across the machine direction, while said film is heated to a temperature sufficient to orient the threads along their longest axes and. in both directions at the junctions, where said rough, continuous openings in said film are placed so that the distance between the circumference of any opening and the circumference of any neighboring opening at the narrowest point is at least 1.5 times the thickness of. the film and the forecourt between the distance between the circumference of a. any opening and the distance of any neighboring opening at the narrowest point and the diameter of the opening is from approx. 1 to 4 to approx. 1.5 to 1. 5. Method according to claim 4, characterized in that the polymer film of thermoplastic material is first pulled in the direction across the machine, favoring the use of a stretching frame, to then be pulled in the machine direction using six stretching tools at different speeds. 6. "Procedure according to claim 5, characterized in that the polymer film of thermoplastic material is drawn equally in: both the machine direction and on the other side of the machine direction.