RU2832345C1 - Aerosol adhesive composition under pressure in container - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to an adhesive composition capable of further controlled and graduated movement into the environment and is preferably used for construction purposes. Aerosol adhesive composition under pressure in container containing polymeric methylene diphenyl diisocyanate and/or a mixture of mixed isomers of methylene diphenyl diisocyanate and carbodiimide-modified 4,4'-methylene diphenyl diisocyanate with a polyoxypropylene glycol prepolymer; mixture of polyethers, polyesters, antiperene(s), and/or catalyst(s); gas or mixture of gases. Said gas or mixture of gases in adhesive composition under pressure does not foam inside the container, as a result of which the adhesive composition does not have an aerosol structure when it comes out.

EFFECT: providing high strength of connection of wood materials.

3 cl, 4 dwg, 4 tbl

Description

Field of technology

The proposed invention relates to integral packaging, made, for example, in the form of an aerosol tube or can, inside which an adhesive aerosol composition is contained under pressure, capable of subsequently being moved in a controlled and dosed manner into the external environment and primarily used for construction purposes.

State of the art

The prior art discloses an aerosol can containing a composition for an internal coating that stores and doses a pressurized aerosol composition (see RU2710431, class C09D5/03, published on 26.12.2019 [1]).

In terms of design, the known solution [1] relates to aerosol-containing one-piece aerosol tubes/cans, additionally containing a coating composition placed on at least a portion of its internal working surface.

The inner surfaces of the said packages (aerosol tubes/cans) are coated (composition) mostly to protect the can from its contents, which are in many cases chemically aggressive. In addition, such coating should protect the contents from the can material.

Thus, the essence of the solution is mainly aimed at the fact that the contents of the package (can/tube) should not actually be subject to significant changes under the influence of substances that are products of erosion of the package. Accordingly, the composition of the inner coating used for this purpose should resist contact with aggressive chemicals and at the same time minimize the release of substances from the walls of the package or the coating layer into the contents of the can.

The coating composition according to the known solution [1] is capable of withstanding contact with alkaline chemicals, in addition, the coating compositions according to the known solution [1] can be used as a mono-layer or as part of a multi-layer system, the coating compositions can also be used as a primer coating, they can be applied over another layer of paint as part of a multi-layer system.

At the same time, the coating compositions can form an intermediate layer or a top layer, moreover, the coating compositions can be applied once or repeatedly.

Among the disadvantages of the known solution [1] the following should be noted.

The known aerosol packaging in the form of a can or tube is used mainly for household needs and is intended primarily for the storage and metered release of aerosol compositions, which can be foams and mousses for shaving, deodorizing compositions, as well as other care and personal hygiene products in structure and composition, while universality of use and expansion of the area is not provided, since the additional coating composition does not have guaranteed characteristics capable of neutralizing and maintaining a working position, including chemically and physically active substances, such as adhesives of organic or inorganic origin, used in various industries and in household conditions.

An additional disadvantage should be considered the high complexity of production, as well as the unjustified and unconfirmed practicality and efficiency of using known aerosol packages, since the application of an additional coating composition is associated with a number of operational measures, which provide, in particular, for compliance with the technology of application and the use of specialized equipment, which in turn increases the production time and complicates the process, certainly increasing the cost of production of batches of products.

The closest in technical essence to the claimed invention can be considered to be an aqueous adhesive composition applied using an aerosol agent (see RU2723170, class C09D105/00, published on 09.06.2020 [2]).

A known solution [2] relates to an aqueous adhesive composition intended for obtaining a water-based adhesive.

The known adhesive composition contains a number of key (essential) components in a certain amount, which serves as the basis and determines the technical possibility of using it under pressure in an aerosol can for the purpose of obtaining an adhesive used primarily for obtaining high-quality wood material such as plywood, veneer, chipboard, fiberboard, etc.

It should be noted that the above materials are generally produced by applying or spraying an adhesive onto wood raw materials (e.g. different fiber sizes, small pieces and veneers) and then pressing them, if necessary, by increasing pressure and heating.

The known solution [2] is essentially created for the implementation of wood material, which can be obtained using an aqueous adhesive composition, which in turn has high characteristics, such as bending strength, durability, water absorption, etc.

The following disadvantages of the known solution [2] should be highlighted.

As follows from the description of the known technical solution [2], the resulting wood material has high properties (ultimate bending strength, ultimate peel strength, water absorption capabilities, etc.), however, from the level of technology, it is still known to a specialist that the parameters of water-based adhesives are very often unstable and unsatisfactory, thus there is reason to assume that the specified improved parameters of wood material are not stable in the long term and can lose their useful properties over time, especially when exposed to atmospheric factors and phenomena such as solar radiation, precipitation, wind, humidity, temperature, etc.

As was indicated above, the essence of the known solution [2] relates to the production of various types of wood material and this is actually the limitation of the concept and technical capabilities, which in a certain aspect can be perceived in the construction segment as an advantage and specificity of processing lumber, however, in the conditions of active market competition and taking into account the high cost of wood raw materials, this narrow focus may not meet market expectations and not find a mass consumer response, both wholesale and retail, which will not contribute to the development and strengthening of the corresponding production capacities, thus an additional disadvantage should be considered the limited area of effective application.

Disclosure of invention

The technical problem of the proposed invention is the creation of an adhesive composition placed in a container under pressure that has high technical and operational characteristics.

The technical result of the proposed invention is the implementation of the purpose of obtaining an adhesive composition in the form of a gel or paste, emerging from an aerosol package, which has increased strength of the connection of wood materials.

The specified technical result and the specified technical problem are achieved as a result of the adhesive composition being under pressure in the container, is characterized by the fact that when exiting the aerosol container it has the consistency of a gel or paste and by the fact that it has a shear strength limit, measured in accordance with the standard “ASTM D905-08 (Reapproved 2021), Standard Test Method for Strength Properties of Adhesive Bonds in Shear by Compression Loading” of 80 psi and higher, when the adhesive composition is applied to hard maple.

The consistency of the gel or paste that comes out of the aerosol can is made up of a polyurethane base.

In a particular embodiment, the adhesive under pressure has a shear strength measured in accordance with ASTM D905-08 (Reapproved 2021) of 90 psi or greater when applied to hard maple.

In a particular embodiment, the adhesive under pressure has a shear strength measured in accordance with ASTM D905-08 (Reapproved 2021) of 100 psi or greater when applied to hard maple.

In a particular embodiment, the adhesive under pressure has a shear strength measured in accordance with ASTM D905-08 (Reapproved 2021) of 110 psi or greater when applied to hard maple.

In a particular embodiment, the adhesive under pressure has a shear strength measured in accordance with ASTM D905-08 (Reapproved 2021) of 120 psi or greater when applied to hard maple.

In a particular embodiment, the adhesive under pressure has a shear strength measured in accordance with ASTM D905-08 (Reapproved 2021) of 130 psi or greater when applied to hard maple.

In a particular embodiment, the adhesive under pressure has a shear strength measured in accordance with ASTM D905-08 (Reapproved 2021) of 140 psi or greater when applied to hard maple.

In a particular embodiment, the adhesive under pressure has a shear strength measured in accordance with ASTM D905-08 (Reapproved 2021) of 150 psi or greater when applied to hard maple.

When released from the aerosol can, the adhesive has the consistency of a gel or paste, and according to “ASTM D905-08 (Reapproved 2021), Standard Test Method for Strength Properties of Adhesive Bonds in Shear by Compression Loading,” the gel or paste has a shear strength of 80 to 150 psi or greater when applied to hard maple.

In the process of implementing the proposed product, it was unexpectedly discovered that the characteristic, in accordance with the concept of the invention, technical features of the adhesive composition do not foam the chemical adhesive composition inside the aerosol can when releasing the adhesive composition to the outside; when releasing to the outside from the aerosol can, the chemical adhesive composition comes out in the form of an adhesive gel or adhesive paste, and the gases used in the aerosol container can be any gases, as well as mixtures of gases in different proportions.

The use of adhesive in an aerosol container is due to improved ergonomics, since at any time it is possible to stop pressing on the dosing element of the container under pressure and the dosing stops, while excess product does not come out or drip, which protects surfaces.

If the task is to apply bulk adhesive layers, then when the adhesive release is stopped, the outlet is completely blocked and there is no leakage of the adhesive composition.

The first component is mixed in a separate metal or plastic reactor, according to the specified quantitative and qualitative composition, using an anchor, blade or any other mixer. After mixing, the prepared mixture (prepolymer) is fed through a dispenser into an aerosol container. Then, through a separate dispenser, the second component is fed in the form of polymeric methylene diphenyl diisocyanate, polymeric diphenylmethane diisocyanate, 4,4'-diphenylmethane diisocyanates, polymethylene polyphenylene polyisocyanates, polymeric MDI, polymethylene polyphenylene isocyanate ester, a mixture of mixed isomers of methylene diphenyl diisocyanate and carbodiimide-modified 4,4'-methylene diphenyl diisocyanate with a prepolymer based on polyoxypropylene glycol, or a mixture of any of these components.

After this, a valve is rolled onto the aerosol can.

The next step is to dose the gas or gas mixture into the aerosol can through the installed valve.

During the experimental work it was established that the components of the adhesive composition used (specified above) form a high-quality adhesive structure with consistently reliable and high strength indicators for the connection of wood materials.

Thus, the features of the parts and the characteristics of the adhesive components placed in a container under pressure predetermine the essential features necessary and sufficient to achieve the specified technical result, which consists in implementing the purpose of obtaining, coming out of an aerosol package, an adhesive gel or adhesive paste composition with increased strength of the connection of wood materials, which actually implements the solution to the designated technical problem of creating an adhesive composition placed in a container under pressure, which has high technical and operational indicators.

Brief description of the drawings

Fig. 1 shows an image of aerosol cans with the proposed adhesive composition inside under pressure;

Fig. 2 shows an image of two hard maple samples joined together using adhesive;

Fig. 3 shows a general view of the setup for performing a standard shear test under load;

Fig. 4 shows a fragment of Fig. 3 with the section with the test samples highlighted.

Implementation of the invention

In Fig. 1 - 4 the following parts and elements used in the implementation of the proposed pressurized aerosol adhesive composition are designated:

1 - pressurized containers (aerosol cans);

2 - samples of wood material (wood blanks made of hard maple);

3 - standard installation for conducting shear tests under load;

symbol D - adhesive composition No. 1 (a composition known from the prior art);

symbol M - adhesive composition No. 2 (a composition known from the prior art);

Symbol I - adhesive composition No. 3 (the claimed product).

The proposed pressurized product (aerosol adhesive composition) can be obtained using the generally accepted manufacturing method presented below, and the possibility of implementing the designated purpose and achieving the technical result together with solving the current technical problem is further confirmed not by the only possible, but by reliable examples of implementation with the necessary supporting experimental data.

One of the components, namely polymeric methylene diphenyl diisocyanate, polymeric diphenylmethane diisocyanate, 4,4'-diphenylmethane diisocyanates, polymethylene polyphenylene polyisocyanates, polymeric MDI, polymethylene polyphenylene isocyanate ester, a mixture of mixed isomers of methylene diphenyl diisocyanate and carbodiimide-modified 4,4'-methylene diphenyl diisocyanate with a prepolymer based on polyoxypropylene glycol, or a mixture of any of these components, as well as another component, namely polyethers, polyesters, fire retardants, a catalyst, or a mixture of any of these components are mixed in a given qualitative and quantitative composition in a metal or plastic reactor using an anchor, paddle or any other stirrer.

When mixing, the prepared mixture (prepolymer) is fed into an aerosol can.

Next, polymeric methylene diphenyl diisocyanate, polymeric diphenylmethane diisocyanate, 4,4'-diphenylmethane diisocyanates, polymethylene polyphenylene polyisocyanates, polymeric MDI, polymethylene polyphenylene isocyanate ester, a mixture of mixed isomers of methylene diphenyl diisocyanate and carbodiimide-modified 4,4'-methylene diphenyl diisocyanate with a prepolymer based on polyoxypropylene glycol, or a mixture of any of these components are fed through a separate dispenser.

After this, a valve is rolled onto the aerosol can. The next step is dosing the gas or gas mixture into the aerosol can through the installed valve.

Composition of the laboratory tests performed

Tests were conducted on three versions of the adhesive composition (two compositions known from the prior art (product D, product M) and the claimed composition (product I), each of which is in its own container under pressure, i.e. in an aerosol can 1 (see Fig. 1).

The specified compressive shear tests on aerosol formulations were conducted in accordance with ASTM D905 (Reapproved 2021), “Standard Test Method for Strength Properties of Adhesive Bonds in Shear by Compression Loading”. Hard maple was used as the substrate in all product tests.

Conventionally, the first sample under study, namely adhesive composition No. 1, is called “product D”, adhesive composition No. 2 is called “product M”, and adhesive composition No. 3 (the claimed product) is called “product I”.

Composition No. 3, namely “product I” (the claimed product) contains:

- (first component) polyethers, polyesters, flame retardants, catalysts, or a mixture of any of these components;

- (second component) polymeric methylene diphenyl diisocyanate, polymeric diphenylmethane diisocyanate, 4,4'-diphenylmethane diisocyanates, polymethylene polyphenylene polyisocyanates, polymeric MDI, polymethylene polyphenylene isocyanate ester, a mixture of mixed isomers of methylene diphenyl diisocyanate and carbodiimide-modified 4,4'-methylene diphenyl diisocyanate with a polyoxypropylene glycol-based prepolymer, or a mixture of any of these components;

- gas or gas mixture.

Test results for composition No. 1 (product D), No. 2 (product M) and No. 3 (claimed product I)

1. Test Results Report

table [1]

PROPERTY PRODUCT AVERAGE RESULTS ASTM D905-08, (Reapproved 2021), Shear Strength D (state of the art) 59.3 psi M (state of the art) 63.0 psi I (claimed product) 157 psi

2. Test method

The evaluation of the samples (known product D, known product M and claimed product I) was, as already indicated, carried out in accordance with the international standard ASTM D905-08, (Reapproved 2021) (Standard Test Method for Compressive Shear Test of Adhesive Joints).

3. Origin of the research material

Three samples were examined and studied:

- first sample (aerosol can with known product D);

- the second sample (aerosol can with a known product M);

- the third sample (aerosol can with the declared product I).

Images of the test samples are shown in Fig. 1. The product tests were conducted as shown, including sample preparation by spraying the starting material onto wooden substrates. Hard maple was used as the substrate in all product tests.

4. Test structure

All conditions of the tests carried out and the condition of the samples under study correspond to standard laboratory conditions; Fig. 3 and 4 show standard setup 3 for carrying out shear tests under load.

The shear strength of the adhesive bonded timber blanks 2 was determined using a standard setup, namely, a SATEC UTM (ICN: Y002011) setup 3 equipped with a 5000 lbf load cell (ICN: INT02615) and operating at a crosshead speed of 0.20 in/min. Compressive shear load was applied to the surface of the timber blanks using a press structure until signs of failure appeared. The dimensions of the timber blanks were measured using a digital caliper (ICN: INT01066).

5. Test results

5. 1 Shear strength of joint under compressive load (known product D)

table [2]

Ordinal
sample number Width (inches) Length (inches) Peak Load (lbf) Shear Strength (lbs/ ⁱⁿ² ) Product type 1 1.988 1.503 228 76.3 Adhesive composition 2 2.024 1.499 169 55.6 Adhesive composition 3 2.002 1.488 226 75.9 Adhesive composition 4 1.980 1.513 156 52.1 Adhesive composition 5 1.990 1.491 171 57.5 Adhesive composition 6 2.017 1.498 159 52.5 Adhesive composition 7 2.020 1.513 182 59.4 Adhesive composition 8 2.018 1.509 197 64.7 Adhesive composition 9 2.010 1.485 137 46.0 Adhesive composition 10 2.012 1.499 141 46.8 Adhesive composition 11 2.024 1.485 127 42.1 Adhesive composition 12 2.009 1.491 248 82.7 Adhesive composition 13 2.005 1.498 199 66.2 Adhesive composition 14 2.005 1.492 140 46.7 Adhesive composition 15 2.002 1.489 162 54.4 Adhesive composition 16 2.018 1.484 178 59.6 Adhesive composition 17 2.014 1.498 167 55.2 Adhesive composition 18 2.010 1.479 179 60.2 Adhesive composition 19 2.003 1.493 185 61.7 Adhesive composition 20 2.006 1.490 208 69.5 Adhesive composition Average 2.008 1.495 178 59.3 Standard
deviation 0.012 0.009 32.4 10.9

5.2. Shear strength of a joint under compressive load (known product M)

table [3]

Ordinal
sample number Width (inches) Length (inches) Peak Load (lbf) Shear Strength (lbs/ ⁱⁿ² ) Product type 1 2.003 1.497 213 71.0 Adhesive composition 2 2.032 1.454 229 77.6 Adhesive composition 3 2.024 1.424 230 79.6 Adhesive composition 4 2.008 1.485 173 58.1 Adhesive composition 5 2.024 1.502 280 92.0 Adhesive composition 6 2.002 1.484 192 64.6 Adhesive composition 7 1.999 1.466 145 49.5 Adhesive composition 8 2.018 1.467 187 63.1 Adhesive composition 9 1.992 1.480 192 65.2 Adhesive composition 10 2.014 1.472 226 76.2 Adhesive composition 11 2.019 1.490 233 77.5 Adhesive composition 12 2.010 1.458 229 78.3 Adhesive composition 13 1.997 1.498 164 54.8 Adhesive composition 14 2.013 1.504 183 60.6 Adhesive composition 15 2.001 1.498 158 52.8 Adhesive composition 16 2.029 1.522 92.7 30.0 Adhesive composition 17 2.007 1.493 183 61.0 Adhesive composition 18 2.010 1.495 191 63.5 Adhesive composition 19 2.015 1.468 152 51.3 Adhesive composition 20 2.020 1.529 102 33.0 Adhesive composition Average 2.012 1.484 188 63.0 Standard
deviation 0.011 0.024 45.4 15.4

5.3 Shear strength of the joint under compressive load (claimed product I)

table [4]

Ordinal
sample number Width (inches) Length (inches) Peak Load (lbf) Shear Strength (lbs/ ⁱⁿ² ) Product type 1 2.006 1.512 193 63.5 Adhesive composition 2 2.009 1.491 590 197 Adhesive composition 3 2.007 1.500 117 38.9 Adhesive composition 4 2.004 1.499 449 150 Adhesive composition 5 2.015 1.483 575 193 Adhesive composition 6 2.004 1.498 549 183 Adhesive composition 7 2.003 1.496 536 179 Adhesive composition 8 2.013 1.493 120 40.1 Adhesive composition 9 2.009 1.486 167 55.8 Adhesive composition 10 2.011 1.491 752 251 Adhesive composition 11 2.022 1.494 543 180 Adhesive composition 12 1.981 1.485 1,530 520 Adhesive composition 13 2.012 1.485 320 107 Adhesive composition 14 2.011 1.500 715 237 Adhesive composition 15 2.006 1.490 777 260 Adhesive composition 16 2.015 1.510 467 154 Adhesive composition 17 2.014 1.502 218 72.1 Adhesive composition 18 2.001 1.500 222 73.8 Adhesive composition 19 2.003 1.497 160 53.3 Adhesive composition 20 2.011 1.492 410 137 Adhesive composition Average 2.008 1.495 470 157 Standard
deviation 0.008 0.008 329 112

In accordance with the obtained experimental data, given in tables [2]-[4] of the corresponding examples of the invention, it has been established that the tested samples (known product D, known product M and the claimed product I) have, according to international standards, high reliability and efficiency of use, however, the claimed product I has improved reliability and efficiency indicators, and the strength indicators of the wood material connection in the claimed product are noticeably higher than in the tested known ones.

In addition, during the experimental work, it was unexpectedly discovered that the gas component used in the claimed adhesive composition does not foam the said adhesive composition inside the container 1, as a result of which, when released outside, the adhesive composition does not have an aerosol structure, but has a paste-like (gel-like) consistency, which allows the product to be used with high precision and ergonomics, in particular, without wasting an excessive amount of glue.

The proposed invention can be successfully and effectively used in the construction industry as a multi-component gel-like or paste-like substance capable of connecting various structures, surfaces, parts, etc.

Claims (7)

1. An aerosol adhesive composition contained under pressure in a container, containing: polymeric methylene diphenyl diisocyanate and/or a mixture of mixed isomers of methylene diphenyl diisocyanate and carbodiimide-modified 4,4'-methylene diphenyl diisocyanate with a polyoxypropylene glycol-based prepolymer; a mixture of polyethers, polyesters, flame retardants, and/or catalysts; gas or mixture of gases, Moreover, the said gas or mixture of gases in the adhesive composition under pressure does not foam the adhesive composition inside the container, as a result of which, when released to the outside, the adhesive composition does not have an aerosol structure. 2. An aerosol adhesive composition under pressure in a container according to paragraph 1, characterized in that when released to the outside it has the consistency of a gel. 3. An aerosol adhesive composition under pressure in a container according to paragraph 2, characterized in that the consistency of the gel is made up of a polyurethane base.