PL235155B1 - Composition of polyurethane foam with improved mechanical properties - Google Patents

Abstract

The subject of the application is a composition for polyurethane foams with improved mechanical properties, containing a mixture of polyol with auxiliary substances, 4,4'-diphenylmethane diisocyanate and a chain extender. The composition is characterized by the fact that it contains vegetable oil with a long aliphatic chain as a chain extender.

Description

Description of the invention

The present invention relates to a polyurethane foam composition with improved mechanical properties for insulation products used in the construction industry.

Today, polyurethanes are one of the most commonly used plastics in the world. The excellent application properties of this group of materials result primarily from the wide base of raw materials, enabling the production of products with precisely designed properties. Among the numerous groups of polyurethane materials, such as fibers, elastomers and adhesives, the most popular are products with a porous structure, constituting about 90% of the total production.

Polyurethane foams are foamed materials with a segmented structure, consisting of rigid segments (aromatic rings, urethane and urea groups) and flexible (polyester or polyether chains). As with other polyurethane products, foams are obtained by reacting polyols with a di- or triisocyanate. The production of the foam additionally requires the use of a foaming agent, which gives the products a cellular structure. The most important parameter of foamed polyurethane materials is their appropriate cellular structure, which determines the further use of this type of materials. Rigid PUR foams, characterized by a closed-cell structure, are characterized by excellent insulating properties, being used mainly in the construction industry as insulation of buildings, pipes and various types of tanks, protecting elements against loss of cold and heat.

In recent years, pro-ecological activities have been a significant challenge in the development of polyurethane (PUR) technology. The constantly increasing prices of mine raw materials and the vision of their exhaustion resulted in the intensive development of research on the acquisition of new systems, which would not only be characterized by good performance properties, but at the same time would be an ecologically beneficial solution, allowing the management of raw materials of natural origin. Therefore, recently intensive research has been carried out on the development of new composites, not only with improved mechanical properties, but due to the renewable raw materials used in their synthesis, to make them environmentally friendly materials.

One of the methods of modifying foamed polyurethane materials is the addition of compounds acting as chain extenders, connecting the rigid segments with each other, increasing their size, and thus the density of hydrogen bonds and the molecular weight of the polymer. In the synthesis of polyurethane materials, difunctional compounds are used as chain extenders that react with isocyanate groups, causing the polymer to rapidly solidify. Typical chain extenders are glycols (ethylene and butylene) and aromatic diamines (N-phenylenediethanolamine). When choosing the right compound, more and more attention is paid to the harmful effects of the substance used. Currently, more and more emphasis is put on the elimination of aromatic diamines, which have a potential carcinogenic risk.

Unexpectedly, it turned out that the use of vegetable oils composed of molecules with long aliphatic chains and reactive hydroxyl groups in the synthesis of rigid polyurethane foams (SPPUR) as chain extenders allows to obtain an environmentally friendly polyurethane foam composition with improved mechanical properties.

The inventive polyurethane foam composition with improved mechanical properties comprises a polyol mixture with excipients, 4,4'-diphenylmethane diisocyanate and a chain extender. As the chain extender, a vegetable oil with a long aliphatic chain from the group of linseed, palm and castor oil in the amount of 5 to 15 parts is used. wt. for 100 parts wt. polyol. The composition preferably contains auxiliary substances such as a catalyst, anti-pyrene.

The products made from the composition according to the invention are characterized by very good mechanical properties, in particular compressive strength at 10% deformation, as well as high apparent density, low water absorption, good shape stability under elevated temperature conditions and high hardness. Products made of the composition according to the invention can be used mainly in the construction industry as insulating materials for buildings, pipes and tanks, protecting elements against loss of cold and heat. In addition, products made of the composition can be used in the automotive, electronics and electrotechnical industries.

The subject of the invention is illustrated by the following examples with reference to the drawing, in which Fig. 1 shows a diagram showing the mechanical properties (compressive stress at 10% deformation) of foamed polymer composites with the addition of linseed oil, Fig. 2 - diagram illustrating

Mechanical properties (compressive stress at 10% strain) of foamed polymer composites with the addition of castor oil, Fig. 3 - diagram illustrating the mechanical properties (compressive stress at 10% strain) of foamed polymer composites with the addition of palm oil, acting as chain extenders , Fig. 4 is a diagram illustrating the mechanical properties (bending strength) of foamed polymer composites with the addition of linseed oil, Fig. 5 - a diagram illustrating the mechanical properties (bending strength) of foamed polymer composites with the addition of castor oil, Fig. 6 - a diagram illustrating the properties of mechanical (bending strength) of foamed polymer composites with the addition of palm oil, acting as chain extenders.

P r z k ł a d I

A foamed polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Linseed oil - 5 parts by weight

The polyurethane composition was obtained by mixing component A, component B and linseed oil, where component A is a mixture of polyol with tris (2-chloro-1-methylethyl) phosphate and N, N-dimethylcyclohexylamine, component B is polymeric diphenylmethane diisocyanate. Then the composition was foamed and a polyurethane foam was obtained, and then the mechanical properties of the foam were determined - compressive strength at 10% deformation (aio) and bending strength (atm), the Shore 00 hardness (° Sh 00) was also tested, the apparent density was determined of the obtained composition (pp) and the short-term water absorption of the foams by the partial immersion method (Wp).

At the same time, for comparative purposes, a polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Polyurethane foam was obtained from the components and its mechanical properties (aio and afm), Sh 00, pp, ^ Vp were also examined.

P r z x l a d II

A polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Linseed oil - 10 parts by weight

From this composition, a polyurethane foam was prepared according to the method described in Example 1. The following procedure was followed as in Example 1.

P r x l a d III

A foamed polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Linseed oil - 5 parts by weight

From this composition, a polyurethane foam was prepared according to the method described in Example 1. The following procedure was followed as in Example 1.

P r x l a d IV

A polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Palm oil - 5 parts by weight

The polyurethane composition was obtained by mixing component A, component B and palm oil, where component A is a mixture of polyol with tris (2-chloro-i-methylethyl) phosphate and N, N-dimethylcyclohexylamine, component B is polymeric diphenylmethane diisocyanate. Then the composition was foamed and a polyurethane foam was obtained, and the mechanical properties of the foam were determined - compressive strength at 10% deformation (aio) and

Bending (afm), the Shore 00 hardness (° Sh 00) was also tested, the apparent density of the obtained composition (pp) was determined and the short-term water absorption of the foams by the partial immersion method (Wp) was tested.

At the same time, for comparative purposes, a polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Polyurethane foam was obtained from the components and its mechanical properties (gio and afm), Sh 00, pp, ^ Vp were also examined.

P r z k ł a d V

A polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Palm oil - 10 parts by weight

From this composition, a polyurethane foam was prepared according to the method described in Example 4.

The next step was as in Example 4.

P r x l a d VI

A polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Palm oil - 15 parts by weight

From this composition, a polyurethane foam was prepared according to the method described in Example 1.

The next step was as in example 1.

Example VII

A polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Castor oil - 5 parts by weight

The polyurethane composition was obtained by mixing component A, component B and castor oil, where component A is a mixture of polyol with tris (2-chloro-1-methylethyl) phosphate and N, N-dimethylcyclohexylamine, component B is polymeric diphenylmethane diisocyanate. Then the composition was foamed and a polyurethane foam was obtained, and then the mechanical properties of the foam were determined - compressive strength at 10% deformation (qio) and flexural strength (afm), the Shore 00 hardness (° Sh 00) was also tested, the apparent density was determined of the obtained composition (pp) and the short-term water absorption of the foams by the partial immersion method (Wp).

At the same time, for comparative purposes, a polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Polyurethane foam was obtained from the components and its mechanical properties ((hio and afm), Sh 00, pp, ^ Vp were also examined.

P r x l a d VIII

A polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Castor oil - 10 parts by weight

From this composition, a polyurethane foam was prepared according to the method set out in Example 7.

The next step was as in Example VII.

P r x l a d IX

A polyurethane composition was prepared with the composition in parts by weight:

Component A - 100 parts by weight

Component B - 120 parts by weight

Castor oil - 15 parts by weight

PL235 155 Β1

From this composition, a polyurethane foam was prepared according to the method set out in Example 7. The next step was as in Example VII.

Table 1 shows the results of testing processing times (starting time, growth time, gelation time), hardness (° Sh 00), apparent density (p _p ) and short-term water absorption (W _P ) of polyurethane composites obtained in examples Ι-.

Table 1

type of oil oil content [parts by weight / 100 parts polyol by weight] synthesis times Pp [kg / m ³ ] ° Sh 00 Wp [kg / m ² ] start time [s] growth time [s] gel time [s] reference 0 13.4 356 408 51.6 71.4 0.24 linen 5 15.9 409 373 54.6 74.3 0.32 10 16.2 589 341 54.3 69.3 0.28 15 17.7 638 510 52.3 59.8 0.14 palm 5 12.3 524 378 49.1 43.9 0.12 10 15.5 572 368 53.0 51.5 0.14 15 13.0 675 361 56.1 68.3 0.18 castor 5 14.6 385 380 54.2 60.6 0.25 10 17.6 480 419 54.8 70.1 0.28 15 18.3 474 461 60.5 63.8 0.29

Patent claims

Claims (2)

Patent claims 1. Composition for polyurethane foams with improved mechanical properties, containing a mixture of polyol with auxiliary substances, 4,4'-diphenylmethane diisocyanate and a chain extender, characterized in that it contains vegetable oil with a long aliphatic chain from the group consisting of linseed oil, palm oil as the chain extender. castor in an amount of 5 to 15 parts by weight per 100 parts by weight of polyol. 2. A composition according to claim 1 3. The composition of claim 1, characterized in that it contains auxiliary substances such as a catalyst, anti-pyrene.