CA2000203C

CA2000203C - Woven fabric made of shape memory polymer

Info

Publication number: CA2000203C
Application number: CA 2000203
Authority: CA
Inventors: Kazuyuki Kobayashi; Shunichi Hayashi
Original assignee: Mitsubishi Heavy Industries Ltd
Current assignee: Mitsubishi Heavy Industries Ltd
Priority date: 1988-10-17
Filing date: 1989-10-05
Publication date: 1997-03-04
Anticipated expiration: 2009-10-05
Also published as: US5128197A; DE68917410T2; JPH0723572B2; DE68917410D1; EP0364869A2; EP0364869A3; JPH02112433A; KR900006585A; CA2000203A1; EP0364869B1

Abstract

A woven fabric woven from fibers of a shape memory polymer alone or a blend of said fibers and ordinary natural or synthetic fibers. The woven fabric can be produced from long fibers without cutting them into short fibers and so at a lower cost than non-woven fabric made of the shape memory polymer that requires cutting of long fibers. The woven fabric can be used for example as such a clothes portion that is desired to keep its shape without making wrinkles or deforms.

Description

2G(1~3 SPECIFICATION

1. TITLE OF THE INVENTION
WOVEN FABRIC MADE OF SHAPE MEMORY POLYMER

2. FIELD OF THE INVENTION AND RELATED ART STATEMENT
The present inventlon relates to a woven fabrlc woven from fibers of a shape memory polymer alone or a blend of such flbers and ordlnary natural or synthetic flbers.
The conventlonal woven fabrlc ls made of natural or synthetic flbers or a blend of both. These flbers are also used ln comblnatlon wlth an adheslve to produce non-woven fabrlcs. There has recently been proposed a non-woven fabrlc whlch ls composed of flbers of a resln havlng the shape memory property and an adheslve of a resln havlng the shape memory property. (See Japanese Patent Lald-open No. 252353/1986.) Belng made by bondlng short flbers to one another wlth an adheslve, a non-woven fabrlc has the followlng dls-advantages.
(1) It tends to be thlck.
(2) It tends to be uneven ln thlckness and hence ln strength because lt 1B dlfflcult to dlstrlbute the adheslve unlformly.
~3) It ls hlgh ln cost owlng to the expenslve adheslve The foregolng holds true of the non-woven fabrlc made of shape memory resln mentloned above.

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20~0203 Another dlsadvantage of the conventlonal non-woven fabrlc made of shape memory reslns ls a hlgh productlon cost attrlbutable to additlonal processes. For example, where short fibers of a shape memory resln are used ln comblnatlon wlth natural or synthetlc long flbers, lt ls necessary to cut the latter short accordlng to the length of the former. Also, there ls an lnstance where a woven fabrlc of natural or syn-thetlc flbers as to be lamlnated wlth an adhesive to a non-woven fabrlc composed of flbers of a shape memory resln and an adheslve of a shape memory resln. The adheslve for lamlnatlon also adds to the productlon cost.

3. OBJECT AND SUMMARY OF THE INVENTION
The present lnventlon was completed to solve the above-mentloned problem assoclated wlth the conventlonal non-woven fabrlc made of a shape memory resln. Accordlngly, lt ls an ob~ect of the present lnventlon to provlde a woven fabrlc havlng the shape memory property.
The glst of the present lnventlon resldes ln a woven fabrlc of shape memory polymer whlch ls formed by weavlng yarns of shape memory polymer flbers alone or by weavlng such yarns and yarns of ordlnary natural or synthetlc , ~

flbers, and also ln a woven fabrlc of shape memory polymer whlch ls formed by weavlng blended yarns of shape memory polymer flbers and ordlnary natural or synthetlc flbers.
The woven fabrlc of the present lnventlon functlons dlfferently as follows depending on the glass transltion temperature or polnt (Tg for short herelnafter) of the shape memory polymer ln the woven fabrlc and the method of lmpartlng the shape memory property.
Generally, ln the case where the Tg ls lower than normal temperature, the shape memory property ls lmparted at a temperature hlgher than normal temperature.
In the case where the Tg ls lower than normal temperature tsay, about -5C) and the shape memory property ls lmparted at a temperature conslderably hlgher than the Tg (say, a temperature at which the polymer beglns to flow, or lS0C ln the case of polyurethane), the woven fabrlc cut to an adequate slze ls caused to remember lts shape when lt ls deformed as deslred ln a mold, and heated and held ln the mold at a temperature at whlch the polymer beglns to flow, and flnally cooled to normal temperature ln the deformed state.
The woven fabrlc rememberlng the deslred shape glves soft hand llke an ordlnary cloth when lt ls used at normal temperature, whlch ls hlgher than the Tg. It does not wrlnkle and deform even when lt ls washed or stored for a long tlme ln a wardrobe.

200Q;~03 Therefore, the woven fabric having a low Tg can be favorably applied to the creases of slacks and the pleats of skirts if it is caused to remember the shape at a high temperature.
In the case where the Tg is higher than normal tem-perature (say, about 40 C) and the shape memory property is imparted at a temperature (say, 150C) at which the polymer begins to flow, the woven fabric gives hard hand at normal temperature. Even if it wrinkles or deforms after washing or storage for a long time in a wardrobe, it easily returns to its original shape it remembers when it is heated above the Tg.
Therefore, the woven fabric having a high Tg can be favorably applied to the collars, cuffs, and shoulder pads of utility shirts.
In the case where the Tg is higher than normal tem-perature (say, about 40C) as mentioned above and the shape memory property is imparted in the softened state at a temperature (say, 90C) slightly higher than the Tg (in-stead of the above-mentioned high temperature at which the poiymer begins to flow) and then the woven fabric is cooled below the Tg, the woven fabric is set in the deformed shape which has been given when softened and remembers this shape.

2000;~03 In this case, the woven fabric gives hard hand when used at normal temperature, which is lower than the Tg, as with the above-mentioned case. Even if it wrinkles or deforms after washing or storage for a long time in a wardrobe, it easily returns to its original shape it remembers when it is heated above the Tg.
Therefore, in this case, too, the woven fabric can be favorably applied to the collars, cuffs, and shoulder pads of utility shirts.
Incidentally, in the case where the Tg is lower than normal temperature (say, about -5C) and the shape memory property is imparted in the softened state at a tempera-ture slightly higher than the Tg as mentioned above, the woven fabric cannot be used in the shape it remembers because the normal use temperature is higher than the Tg.
This is not the case, however, if the woven fabric is used at low temperatures below -5C. In other words, the woven fabric can be used in the shape it remembers only in special districts under special conditions.
The above-mentioned shape memory function can be freely controlled by many factors in the following manner.
(1) In the case where the woven fabric is composed of yarns of shape memory polymer alone, the ability of the woven fabric to retain the shape depends on the fineness of the yarn and the set of the cloth.

2Q00~03 (2) In the case where the woven fabric is composed of yarns of the shape memory polymer fibers and yarns of ordinary natural or synthetic fibers, whether the woven fabric has hand similar to or different from that of the woven fabric of natural or synthetic fibers depends on the blending ratio and fineness of the polymer yarns.
(3) In the case where the woven fabric is composed of blended yarns of shape memory polymer fibers and ordinary natural or synthetic fibers, the ability to retain the shape and the hand of the woven fabric depends on the amount, the fineness and cross-section of the blended yarns, and the set of the woven cloth.
In the case where the woven fabric is composed of blended yarns, the woven fabric exhibits the shape memory function easier or harder as the amount of the shape memory polymer increases or decreases, respectively.
Therefore, the amount of the shape memory polymer should preferably be 10 to 96 wt~ in the blended yarns.
As the shape memory polymer that can be used in the present invention may be cited urethane polymers, styrene-butadiene polymers, crystalline diene polymers, and nor-bornane polymers. Their Tg can be freely controlled by properly selecting the kind of the raw materials (mono-mers, chain extender, etc.) and their mixing ratio.

ZOOQ~03 -The woven fabric of the present invention has an advantage inherént in woven fabrics. That is, the fibers (or yarns) of the shape memory polymer can be easily blended with ordinary natural or synthetic fibers (or yarns thereof). Unlike the conventional nonwoven fabric mentioned above, there is no need for cutting long fibers short, or laminating with an adhesive nonwoven fabrics separately prepared from shape memory polymer fibers and natural~or synthetic fibers.

4. DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
The present invention will be described in more detail with reference to the following examples which are not intended to restrict the scope of the invention.
[1] Preparation of shape memory polymer Polyurethane elastomers as the shape memory polymers were prepared by prepolymer process in the following manner according to the formulation shown in Table 1.
First, the diisocyanate and polyol were reacted in a spe-cific molar ratio of [NCO]/[OH] to give a prepolymer.
When the reaction was complete, the chain extender was added in an amount sufficient to establish a desired molar ratio of [chain extender]/[prepolymer]. After defoaming, the resulting mixture was cured for crosslinking reaction 2QOQ;~03 at 80C for one or two days in a constant temperature dryer. This process may be carried out with or without solvent.
The polyurethane elastomer produced as mentioned above will have a Tg and other physical properties as desired, if the following six factors are properly selected. (1) the kind of the isocyanate, (2) the kind of the polyol, (3) the kind of the chain extender, (4) the [NCO]/[OH] molar ratio, (5) the [chain extender]/[prepo-lymer] molar ratio, and (6) the curing condition.
In Table 1, the crystallinity (wt%) was measured by X-ray diffractometry.

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(panu!tuoa) ~ alqe ~ 2Q00;~03 [2] Weaving of shape memory polyurethane Example (1) A cloth was woven only from yarns spun from the shape memory polyurethane, sample No. 2 in Table 1. The Tg of this cloth was -10C.
Example (2) A cloth was woven from the yarns of the shape memory polyurethane in Example (1) as warps and ordinary cotton yarns as wefts. The Tg of this cloth was - 1 0 C .
Example (3) A cloth was woven from a S0:50 blended yarns of fibers of the shape memory polyurethane, sample No. 2 in Table 1, and ordinary cotton fibers. The Tg of this cloth was -10C.
Example (4) A cloth was woven only from the yarns spun from the shape memory polyurethane, sample No. 39 in Table 1. The Tg of this cloth was 40C.
Example (5) A cloth was woven from the yarns of the shape memory polyurethane in Example (4) as warps and ordinary cotton yarns as wefts. The Tg of this cloth was 40C.
Example (5) A cloth was woven from a 50:50 blended yarns of fibers of the shape memory polyurethane, sample No. 39 in Table 1, and ordinary cotton fibers. The Tg of this cloth was 40C.

2QOal~03 [3] Use of the shape memory woven cloth Example (A) Each of the cloths prepared in Examples (1) to (3) was folded over and heated in a trouser press at a temperature at which the polyurethane, sample No. 2, begins to flow. After being kept at this temperature for 5 minutes, the cloth was cooled to normal temperature, so that the crease was set (or the cloth was caused to remem-ber the crease).
These cloths gave exactly the same hand as the cloths of ordinary natural or synthetic fibers.
When they were washed for 1 hour using a washing machine and then dried, they did not wrinkle.
Example (B) Each of the cloths prepared in Examples (~) to (6) was heated in a shoulder pad press at a temper-ature at which the polyurethane, sample No. 39, begins to flow. After being kept at this temperature for 5 minutes, the cloth was cooled to normal temperature, so that the shape of shoulder pad was set (or the cloth was caused to remember the shape of shoulder pad).
These cloths gave hard hand at normal temperature, but they are not so hard as plastic plate. They gave the hand of cloth and did not give unpleasant feeling when kept in contact with the human skin for a long time.

2Q00~03 The cloths in the shape of shoulder pad were washed in a washing machine for 1 hour and then dried. They slightly wrinkled and deformed; but they restored their original shape when heated with a hair drier at a tempera-ture higher than the Tg. They retained their shape evenwhen they were cooled below the Tg.
Incidentally, when the wrinkled and deformed cloths were heated by bringing them into contact with the human arm instead of using a hair drier, they restored their original shape in 20 seconds to 1 minute.
Example (C) Each of the cloths prepared in Examples (4) to (6) was softened at 50C (higher than the Tg) and folded over and pressed between two flat plates under a pressure of 0.5-2.0 kgf/mm2. Then, it was cooled to a tem-perature lower than the Tg in the folded state so that the- folded state was set.
These cloths gave hard hand at normal temperature as in Example (B), but they are not so hard as plastic plate.
They gave the hand of cloth and did not give unpleasant feeling when kept in contact with the human skin for a long time.
The cloths in the folded shape were washed in a washing machine for 1 hour and then dried. They slightly wrinkled and deformed as in Example (B); but they restored 2Qoo~o~

their original shape when heated with a hair drier at a temperature higher than the Tg. They retained their shape even when they were cooled below the Tg.
Incidentally, when the wrinkled and deformed cloths were heated by bringing them into contact with the human arm instead of using a hair drier, they restored their original shape in 20 seconds to 1 minute.
As mentioned in detail above, the woven cloth of the present invention offers the following advantages inherent in woven cloth.
(1) The thickness of the woven fabric can be easily controlled by properly selecting the fineness of yarns.
(2) The woven fabric does not need any adhesive.
Therefore, unlike the conventional nonwoven fabric which absolutely needs an adhesive, the woven fabric has no fear of becoming uneven in thickness and strength due to the uneven distribution of adhesive.
(3) The woven fabric is low in production cost because it needs no adhesive.
(4) The woven fabric can be woven from a blend com-posed of the fibers (or yarns) of the shape memory polymer and ordinary natural or synthetic fibers (or yarns thereof). The blend may be in the form of blended yarn or different yarns.

2000;~03 (5) The woven fabric can be produced at a low pro-duction cost for the reasons given in (3) and (4) above.

(6) Owing to its shape memory performance, the woven fabric can be used in various ways depending on the Tg of S the shape memory polymer used in the woven fabric or the way in which the woven fabric was caused to remember the shape. It can be used in various application areas and in various places ranging from cold districts to hot dis-tricts.

Claims

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. A woven fabric of shape memory polymer, which is formed by weaving yarns of fibers of a shape memory polymer, by weaving yarns of fibers of a shape memory polymer and yarns of ordinary natural or synthetic fibers or by weaving blended yarns of fibers of a shape memory polymer and ordinary natural or synthetic fibers and which has been set in a shape, wherein:
(a) when the shape memory polymer has a glass transition point lower than normal temperature, the setting of the shape is performed at a temperature higher than normal temperature, and (b) when the shape memory polymer has a glass transition temperature higher than normal temperature, the setting of the shape is performed at a temperature which is from slightly higher than the glass transition temperature to a temperature at which the shape memory polymer begins to flow.

2. A woven fabric as claimed in Claim 1, wherein the shape memory polymer has a glass transition point lower than normal temperature and the setting of the shape is performed at a temperature higher than normal temperature.

3. A woven fabric as claimed in Claim 2, wherein the setting of the shape is performed at a temperature approximate to the temperature at which the polymer begins to flow.

4. A woven fabric as claimed in Claim 1, wherein the shape memory polymer has a glass transition point higher than normal temperature and the setting of the shape is performed at a temperature approximate to the temperature at which the polymer begins to flow.

5. A woven fabric as claimed in Claim 1, wherein the shape memory polymer has a glass transition point higher than normal temperature and the setting of the shape is performed in a softened state at a temperature slightly above the glass transition point.

6. A woven fabric as claimed in any one of Claims 1 to 5, wherein the yarns of the shape memory polymer fibers and the yarns of natural or synthetic fibers in the weight ratio of 10-95/90-5 are woven together.

7. A woven fabric as claimed in any one of Claims 1 to 5, wherein the blended yarns are composed of the shape memory polymer fibers and natural or synthetic fibers in the weight ratio of 10-95/90-5.

8. A woven fabric which is formed by weaving yarns of long fibers made of a shape memory polymer or by weaving the said yarns and other yarns of long fibers made of a natural or synthetic polymer, wherein:
(1) when the other yarns are included their content is up to 90% by weight;
(2) the shape memory polymer has a glass transition temperature of from about -45°C to about 48°C; and (3) the woven fabric is capable of being imparted a shape memory property by heating the woven fabric in a deformed state at a temperature which is higher than normal temperature and at which the shape memory polymer softens or begins to flow and then cooling the woven fabric to normal temperature in the deformed state, provided that when the shape memory polymer has a glass transition temperature lower than normal temperature, the woven fabric has to be heated at a temperature at which the shape memory polymer begins to flow.

9. The woven fabric as claimed in claim 8, wherein the shape memory polymer is polyurethane.

10. The woven fabric as claimed in claim 8 or 9, wherein the shape memory polymer has a glass transition temperature lower than normal temperature and the shape memory property is imparted at a temperature considerably higher than the glass transition temperature; and the woven fabric has a soft hand at normal temperature.

11. The woven fabric as claimed in claim 8 or 9, wherein the shape memory polymer has a glass transition temperature higher than normal temperature and the shape memory property is imparted at about a temperature at which the shape memory polymer begins to flow; and the woven fabric has a hard hand at normal temperature.

12. The woven fabric as claimed in claim 8 or 9, wherein the shape memory polymer has a glass transition temperature higher than normal temperature and the shape memory property is imparted at a temperature slightly higher than the glass transition temperature; and the woven fabric has a hard hand at normal temperature.