JPH0431212Y2 - - Google Patents

Description

[Detailed description of the invention] [Industrial field of application] This invention has excellent characteristics of high moisture permeability and low swelling that provide a comfortable feeling when worn as gloves or finger pads, and is suitable for workability. This invention relates to a thin film protective device for hands and fingers that has modulus properties.

[Conventional technology]

Conventionally, hand and finger protectors include gloves and finger pads molded from compounded rubber, gloves and finger pads molded from rubber latex, and polyethylene gloves or stretched highly crystalline tetrafluoride resin. Films and urethane resin wet films that utilize microporosity, as well as other nonporous films that utilize the moisture permeability of amino acid resins, are well known, but these conventional products do not have the characteristics necessary for practical use. This is something that is lacking.

In other words, there are products with high moisture permeability, low swelling properties, and appropriate properties that are necessary for thin film protectors such as gloves and finger pads, such as those with insufficient moisture permeability, high swelling properties, poor flexibility, and insufficient strength. It lacks the combined performance of appropriate characteristic values such as modulus.

[Problem that the invention attempts to solve]

Conventional gloves and finger pads are made of rubber,
Polyethylene and the like are used, but they have extremely poor moisture permeability and trap sweat and hot air when worn, and in the case of thin films, rubber has insufficient strength and modulus for elongation. That is, when the elongation is large, the modulus tends to be low, and if the film is thin and has a low modulus, when working while wearing gloves made of this thin film, the grip on the palm is poor, resulting in poor stability and poor workability. In addition, polyethylene has low strength, high bending rigidity, and low contact with the palm of the hand, so it similarly has the drawbacks of poor workability, poor toughness, and easy breakage. Moreover, these poor gripability and crimpability further deteriorate workability due to sweating due to poor moisture permeability. In addition, if the swelling ratio is large, the physical properties and moisture permeability will deteriorate, making it impossible to withstand long-term use. Furthermore, microporous materials can provide sufficient moisture permeability, but cannot provide practical strength and elasticity.

Therefore, thin film protectors used for gloves and finger pads should overcome the above defects and have high moisture permeability and low swelling properties, as well as sufficient strength and appropriate elongation with appropriate properties such as modulus. It is necessary to use a polymer that has Therefore, we aim to solve this problem with polymers.

[Means for solving problems]

In order to solve the above problems, we have developed a polyurethane polymer elastomer that has high moisture permeability and low swelling properties, which can provide a large toughness index (TOUGHNESS INDEX) in both strength and elongation, and can freely obtain large modulus properties. The most appropriate means is to select a polymer that has appropriate properties such as modulus and to produce a thin film protector. This elastomer polyurethane polymer can have the above three properties in a well-balanced manner, and as a result of research, when producing thin-film gloves, we found that a non-porous polyurethane polymer has the practically necessary property values. , it has been clarified that good results can be obtained if the moisture permeability is 1500g/ ^m2・24hr./20μ or more, the swelling rate is 10% or less, and the M ₁₀₀ (100% modulus) is 30Kg/ ^cm2 or more. It is.

The composition of this polyurethane polymer is an ether-type polyurethane polymer developed by the same applicant, and is composed of "polyethylene glycol with an average molecular weight of 200 to 600 and a C=3 or higher polyalkyl ether with an average molecular weight of 500 to 3000. A polyol is used as a base polymer, and a polyisocyanate is reacted with the polyethylene glycol content of the base polymer in the range of 20 to 100%, and a chain extender is used as necessary, so that the ethylene oxide content of the obtained polymer is A non-porous polyurethane polymer with a composition ranging from 15 to 60%.

In other words, the moisture permeability of this nonporous polyurethane polymer is 1500g/ ^m2・24hr./20μ or more, and the swelling rate is
This idea was devised based on the knowledge that thin film materials with characteristics of 10% or less and M ₁₀₀ of 30 Kg/cm ² or more are most suitable as thin film protectors for hands and fingers. It is possible to obtain a suitable thin-film glove and finger pad that eliminate the problems of the conventional ones.

The moisture permeability was measured according to the method of JIS Z0208, and the swelling rate was measured at a thickness of 20μ x width of 30
Insert marked lines at 100 mm intervals on a film of mm x length 150 mm, immerse it in water at room temperature for 24 hours, take it out of the water, and immediately measure the marked line interval l, swelling rate (%) = l - 100 / 100 x 100 was calculated.

The thin film protector for hands and fingers of this invention is mainly manufactured and used in the form of a thin film.
It is also suitable as a glove coated with a film or coating of the polyurethane polymer on a heat insulating material as a cold-proof glove to prevent wetting.

[Effect]

As mentioned above, the thin film protector for hands and fingers of this invention uses a thin film of polyurethane polymer elastomer having a specific high moisture permeability, low swelling property, and appropriate modulus value, so it can be used with gloves and finger pads. In addition to providing excellent moisture permeability, the low swelling property prevents deterioration in permeability. In addition, when wearing it while working, it prevents the slipping effect caused by sweating, and since it has appropriate elasticity and modulus as an elastomer, the thin film provides good grip on the palm and provides a stable state with less shaking. Workability can be obtained.
In addition, as cold protection gloves, suitable heat retention and a comfortable wearing feeling can be obtained.

〔Example〕

Next, a comparison will be shown between an example of a film-like glove representing an example of this invention and a commercially available polyethylene glove.

Example 1 The composition of the polyurethane polymer in this example is 80 parts of polyethylene glycol with an average molecular weight of 400 and polytetramethylene glycol with an average molecular weight of 2000.
In the base polymer with 20 parts, add 70 parts of isophorone diisocyanate to make the prepolymer,
A chain extender isophorone diamine is added in the presence of N,N-dimethylformaldehyde (DMF) to form a polyurethane polymer solution, and a film-like glove is molded from the solution.

The characteristics of this example are that the ethylene oxide content of the polyurethane polymer is 43%, the 100% modulus (M ₁₀₀ ) is 50 Kg/cm ² , the cutting strength is 450 Kg/cm ² , the elongation at cutting is 500%, the swelling rate is 4%, Moisture permeability per 20μ
4200g/m ²・24hr.

Example 2 The composition of the polyurethane polymer of this example is 100 parts of polyethylene glycol with an average molecular weight of 600, 83.3 parts of pure diphenylmethane diisocyanate.
Chain extender ethylene glycol in the presence of DMF
A polyurethane polymer solution is formed from 10.3 parts to form a film glove. The characteristics of this example are that the ethylene oxide content of the polyurethane polymer is 52%, the M ₁₀₀ is 80Kg/cm ² , and the cutting strength is 400.
Kg/cm ² , elongation at cutting 300%, swelling rate 2%, moisture permeability 2000g/m ² 24hr./20μ.

Example 3 The composition of the polyurethane polymer of this example is as follows: In the base polymer of 80 parts of polyethylene glycol with an average molecular weight of 400, 20 parts of polytetramethylene glycol with an average molecular weight of 2000, and 15 parts of polypropylene ether triol with an average molecular weight of 3000, isophorone 85.91 parts of diisocyanate is added to form a prepolymer, a chain extender isophorone diamine is added in the presence of N,N-dimethylformaldehyde (DMF) to form a polyurethane polymer solution, and a film-like glove is formed from the solution. It is. The properties of this example are that the ethylene oxide content of the polyurethane polymer is 33%, the M ₁₀₀ is 70Kg/cm ² , the cutting strength is 480Kg/cm ² , the elongation at cutting is 450%, and the swelling rate is 2.
%, moisture permeability is 3500g/ ^m2・24hr./20μ.

As described above, gloves as a thin film protective device as shown in the drawings were formed using a polyurethane film made from a polyurethane polymer having each of the characteristic values of Examples 1, 2, and 3, with a thickness of 20μ as a standard. be.

In the figure, FG is a film-like glove, 1 is a polyurethane film, and the periphery of the two films is formed into a glove-like shape by a fused portion 2. It should be noted that it is possible to form a non-slip pattern on the outer surface of the gloves or finger pads, if necessary.

Comparative Example This example is a comparison with commercially available polyethylene gloves (embossed). The thickness of this commercially available polyethylene film is 16 microns.
The film part has a thickness of 4 microns and the embossed part has a thickness of 12 microns, and its moisture permeability is 32.6g/ ^m2・24hr.
The water absorption swelling rate was 0%. In this case, as the thickness of the film increases, the moisture permeability decreases proportionally, and the moisture permeability is extremely low compared to the example.

As mentioned above, there is a large gap between the two in terms of moisture permeability, and as a result of wearing tests between the above examples and the comparative example, unpleasant sweating was observed in the comparative example 30 minutes after wearing. , sweat seeped between the hands and gloves, making them slippery and uncomfortable. In contrast to the polyethylene gloves conventionally available on the market, the gloves of the various embodiments of this invention did not tend to sweat or slip, and were comfortable.

[Effect of idea]

The thin film protector for hands and fingers of this invention has the performance mentioned in the above-mentioned section, so there is no stuffiness caused by sweating, and it is comfortable to wear.
Good moisture dissipation and low swelling properties prevent deterioration of physical properties due to moisture, ensuring good moisture permeability over a long period of time. Furthermore, since the elastomer has strength and appropriate modulus, it can be set in a stable state in the hand, and there is no slipping effect due to perspiration, resulting in good workability and durability over a long period of time.

[Brief explanation of the drawing]

The drawing is a plan view showing an example of this invention. FG...Film glove, 1...Polyurethane film, 2...Fusion part.

Claims (1)

[Scope of utility model registration request] In ether type polyurethane polymer, moisture permeability is 1500g/ ^m2・24hr./20μ or more, swelling rate is 10%
The following is a thin film protector for hands and fingers made from a polyurethane elastomer with a characteristic value of 100% modulus of 30Kg/cm ² or more.