FR2460987A1 - Solid material for absorbing liq. hydrocarbon(s), esp. oil spills - of milled rigid closed cell polyurethane foam - Google Patents

Abstract

Material capable of absorbing liq. hydrocarbons comprises a powder made from a mainly closed cell rigid to semi-rigid polyurethane foam. The powder is pref. obtd. by milling polyurethane foam scrap which is opt. faced e.g. with kraft paper, bituminised paper, polyethylene-coated paper, etc. The foam pref. contains 70-100% closed cells and has a density of 20-150 kg/m3. The milled powder pref. has a particle size of 50 microns-15 mm, esp. 150 microns-10mm. Used for cleaning up oil spills on the surface of water or on the ground, to prevent pollution.

Description

 The subject of the invention is a material capable of absorbing liquid hydrocarbons. It also relates to the application of this material to the absorption of liquid hydrocarbons polluting the surface of various media, in particular the absorption of liquid hydrocarbon layers on the surface of the water and particularly the absorption of liquid hydrocarbons diffused over the surface. ground surface.

 The increasing use of petroleum products, particularly liquid hydrocarbons, leads to more and more handling and transport operations, and as a result, increases the risk of having greater or lesser amounts of liquid hydrocarbons accidentally spread over the and / or the surface of the water during these operations with the result that surface pollution of the medium on which the hydrocarbons were spread. Certain pollutions by liquid hydrocarbons, for example the pollution of the service station areas by the oil of draining, pose daily problems.

 The cleaning of service station areas polluted by accidentally spilled oil is generally done by spreading absorbents such as sawdust or treated leather waste on the surface polluted by the waste oil and then, after sweeping of the oil-impregnated absorbent, washing the surface treated with the absorbent with water containing one or more detergent products. This type of treatment is not very effective, especially when water is present at the same time as the oil on the polluted surface to be treated because, due to their hydrophilic properties, the absorbents used, especially sawdust preferentially absorb water.

 Compared to such absorbents, the material according to the invention has a high absorption capacity with respect to liquid hydrocarbons as well as a good selectivity for liquid hydrocarbons in the presence of water, the absorption of said hydrocarbons being indifferent to the presence of water. In addition, said material has dry detergency properties, that is to say that an oil stain, even partially dried (for example 24 hours after its formation), is completely cleaned by treatment using said material and after absorption. the soil is dry.This property of dry detergency is important because it avoids carrying out a subsequent washing of the surface treated by the absorbent by means of water containing detergents, operation being necessary when using a absorbent of the sawdust or leather waste type.

 Because of these particular properties, the material according to the invention is suitable for replacing absorbents, in particular sawdust or leather waste, used to fight against minor pollution by liquid hydrocarbons on land and possibly on the surface of non-aqueous water. agitated, because it makes it possible to remedy the deficiencies of said absorbents.

 The material according to the invention is characterized in that it consists of a powder obtained from a semi-rigid polyurethane foam with a rigid majority of closed cells, and more particularly from falls of said foam.

 It is known that polyurethane foams have already been proposed for the absorption of liquid hydrocarbons polluting various media, in particular the absorption of oil-floating aquifers, but these foams are generally open-cell flexible foams which, for of the intended application, are specially prepared to increase their absorption capacity for hydrocarbons. On the other hand, the polyurethane foam, which constitutes the material of the material according to the invention, is a semi-rigid rigid-cell foam with essentially closed cells which is intended to provide a thermal insulation function. As a result of the large proportion of cells closed that it contains, such rigid semi-rigid foam is not specifically intended for absorbent use and the effectiveness of the material according to the invention, produced from this foam and more particularly from falls this foam, in the absorption of liquid hydrocarbons and in particular in the cleaning of soil surfaces polluted by said hydrocarbons, is therefore of an unexpected nature.

 The closed-cell rigid to rigid semi-rigid foam, from which or from which the material according to the invention is produced, has at least 50% and in particular 70 to 100% of closed cells and its density is at least 20 kg / m and can reach 150 kg / m.

 Said foam is prepared generally by intimately contacting a polyisocyanate-type isocyanate component with a polyol component in the presence of a swelling agent, a catalyst, and optionally one or more additives.

 The polyisocyanate component is most often a diisocyanate or a polyisocyanate containing more than two isocyanate groups. By way of examples of polyisocyanate components, mention may be made of compounds such as toluene 2,4-diisocyanate, 2,6-toluene diisocyanate, 2,2-diphenylmethane diisocyanate, 4,4'-diphenyl methane diisocyanate, 2,4-diphenylmethane diisocyanate. , mixtures of diphenylmethane diisocyanate isomers, and mixtures of one or more toluene diisocyanates with one or more diphenylmethane diisocyanates. Advantageously, technical diphenylmethane diisocyanate can be used, that is to say diphenylmethane diisocyanate in its undistilled form which contains in particular polyphenyl polymethylene polyisocyanate molecules of greater than two functionality.

 The polyol component is a compound or a mixture of compounds having several hydroxyl functions. Typical examples of compounds which can be used as polyol components are sucrose on which propylene oxide linkages, sorbitol on which propylene oxide, glycerol or even water have been grown.

 The swelling agent is most often a halogenated hydrocarbon of the haloalkane type known commercially under the name "FREON", for example trichlorofluoromethane designated by the trade name "FREON 11".

 As catalyst are especially suitable compounds selected from tertiary amines, especially dimethylcyclohexylamine, dimethylbenzylamine, dimethylpiperazine, and metal salts, for example potassium octoate, zinc dioctoate, lead octoate, said compounds can be used alone or under the form of mixtures, for example mixtures of a tertiary amine and a metal salt.

 As regards the additives possibly present in the formulation of the foam, they may consist in particular of surfactants, in particular dimethylsiloxane / polypropylene glycol copolymers, flame retardants, for example halogenated phosphonates, pigments, fillers.

 The bringing into contact of the aforementioned ingredients for forming the foam is carried out under conditions of intense agitation suitable for allowing an intimate mixing of said ingredients.

For more complete information on the nature and proportions of the ingredients from which semi-rigid to rigid closed-cell foam is formed, as well as the processes and devices used to develop said foam, reference may be made to monograph "POLYURETHANE" by R. VIEWEG and
A. HÖCHTLEN, volume VII of the KUNSTOFF-HANDBUCH manual, edited by
CARL HANSER, MUNCHEN (1966), and more particularly in chapter 8 of this work.

 The powder constituting the material according to the invention is advantageously obtained by grinding the semi-rigid to rigid foam with a majority of closed cells, and more particularly by grinding falls of said foam. By the term "grinding" is meant here any operation to reduce the foam, and in particular the falls of said foam, grains or granules having the desired dimensions. To carry out this grinding operation, it is possible to use any technique and any apparatus known in the art for reducing a solid material into grains or granules of appropriate dimensions.

 The grains or granules of the powder of the material according to the invention may have dimensions that vary rather widely, said dimensions being generally between about 50 microns and 15 millimeters and advantageously between about 150 microns and 10 millimeters.

 The nature of the falls from rigid to rigid foam with a majority of closed cells, from which the material according to the invention is produced, is not critical. It is possible to obtain said material from cutting cuttings of the foam alone or else to use falls for which the foam is coated with facings, for example Kraft paper, paper coated with polyethylene, bituminous paper, as is the case with falls. cutting of thermal insulation panels, without having to separate the facings of the foam.

 After its production by grinding the pulverulent material according to the invention may be subjected to a slight compaction for the purposes of its handling and transport. The density of the powdery product can vary quite widely depending on whether orpact or not. However, said density is generally less than 180 kg / m3.

 As indicated above, the material according to the invention can be used for the absorption of liquid hydrocarbons polluting the surface of various media, in particular absorption of liquid hydrocarbon layers on unstirred water surfaces. It is particularly suitable for the absorption of liquid hydrocarbons spread on the ground, which allows a quick and efficient cleaning of the part of the soil polluted by these hydrocarbons.

 In this application of the material according to the invention to the cleaning of soils polluted by liquid hydrocarbons, for example the cleaning of the emptying and washing areas of the service stations, a spreading of an appropriate quantity of said material on the part is generally carried out. soil polluted by hydrocarbons, then, after a few minutes of contact during which the material is swept over the polluted part, the material impregnated with the hydrocarbons is collected and removed. After such treatment, the treated soil is substantially free of hydrocarbons and it is not useful to follow this treatment by washing with water containing detergents.

 The quantity of the material according to the invention to be used for treating the surface of the soil polluted by liquid hydrocarbons must be such that the material impregnated with the hydrocarbons remains pelletable.

 The material impregnated with the absorbed hydrocarbons can be incinerated easily in the presence of a source of heat and a sufficient aeration, for example incineration in a boiler.

Incineration is very fast because of the division of the hydrocarbon absorbed in the material and the ash content remains very low, of the order of 1%. In addition, compared to the fumes resulting from the combustion of hydrocarbons alone, the fumes produced by the incineration of the material impregnated by the hydrocarbons has a lower opacity and a comparable toxicity.

 The invention is illustrated by the following examples given without limitation.

EXAMPLE 1
A powder obtained by grinding block cutting scrap was used of a rigid polyurethane foam containing about 95% closed cells and having a density of about 30 to 35 kg / m 3, said foam being produced from a polyisocyanate component of the technical diphenylmethane diisocyanate type and a sorbitol-type polyol component on which propylene oxide rings have been grown.

 The powder consisted of grains whose dimensions were between 200 microns and 2 millimeters with a majority of grains having dimensions of around 500 microns.

 Two types of liquid hydrocarbon absorption tests were carried out by said powder while operating at room temperature.

 The first type of test (test I) was to determine the maximum amount of hydrocarbons absorbable by the powder without being rejected and so as to obtain an impregnated powder having the consistency of a pelletable product. To do this, 100 g of the above-mentioned rigid polyurethane powder were placed in a glass beaker and then the hydrocarbon was added until it was appreciated that a small additional quantity would cause a refusal, the impregnated product still having the consistency. a pelletable product. When the beaker was returned, only the strands formed by the hydrocarbon impregnated powder remained on the walls.

 The second type of test (Test II) involved the etching, using rigid polyurethane powder, of a surface formed of earthenware tiles soiled by hydrocarbons.

In this test about 800 g of hydrocarbon was poured onto the tiled surface and then the oil was dusted with 100 g of the rigid polyurethane powder. The powder was left in contact with the hydrocarbon for about 5 minutes and stirred with a small broom on the soiled surface to thoroughly clean the surface. The hydrocarbon impregnated powder was collected and collected and placed in a beaker for hydrocarbon saturation according to Test I to check the residual absorbency.

The tilted surface freed of the hydrocarbon impregnated powder was clean and did not require any additional cleaning treatment.

 The Type I test was carried out on two hydrocarbons, namely crude oil from KUWAIT (hydrocarbon A) with a viscosity greater than 1000 cSt, and a mineral oil (hydrocarbon B) with a viscosity of 200 SSU, while the test of type II was carried out only on the hydrocarbon A.

The results obtained are recorded in the table below.

<tb><SEP> Type <SEP> Nature <SEP> Quantity <SEP> Quantity <SEP> Residual <SEP> of
<SEB><SEP><SEP><SEP><SEP><SEP><SEP>
<tb><SEP> Hydrochloride <SEP> Powder <SEP> (g) <SEP> Absorbed <SEP> (g) <SEP> Absorbent (g)
<tb><SEP> I <SEP> A <SEP> 100 <SEP> 1260
<tb><SEP> B <SEP> 100 <SEP> 1160
<tb><SEP> II <SEP> A <SEP> 100 <SEP> 800 <SEP> 640
<Tb>
It can be seen that the material according to the invention, produced from drops (waste) of rigid polyurethane foam with essentially closed cells, has a high absorption capacity with respect to liquid hydrocarbons (about 10 times its own weight). In addition, the surface treatment (tiled floor) contaminated with hydrocarbon by the material according to the invention makes this surface a clean appearance without further processing.

 Comparative tests were also performed using a commercial absorbent based on treated leather waste.

Under the conditions of Test I, 100 g of the commercial absorbent respectively absorbed 150 g of the hydrocarbon A and 200 g of the hydrocarbon B. In addition under the conditions of the test II, an acceptable cleaning of the surface tiled with 100 g of the commercial absorbent was possible only if the amount of hydrocarbon spread on said surface did not exceed 230 g and for this value the residual absorbency of the impregnated absorbent was only equal at 100 g.

EXAMPLE 2
The powder defined in Example 1 was also used to clean the floor of the draining and washing area of a service station. The soil in this area was oily with some old oil stains (formed about 48 hours previously) and water (droplets or small plates) mixed with the oil was noted.

 A sufficient quantity of the powder was spilled on the soil contaminated with oil to form an impregnable product.

After 3 to 5 minutes of contact to let the powder impregnate, a brief sweeping back and forth made the floor look clean, the water remaining in the form of fragmented drops.

 By replacing the material according to the invention with sawdust, the treated soil, freed from the impregnated sawdust, noted not sufficiently clean (persistence of oil stains) and, to make it look comparable to that obtained by the Only action of the material according to the invention, it was necessary to follow the treatment with sawdust by washing with water containing a detergent product.

Claims (8)

1- Material capable of absorbing liquid hydrocarbons,  characterized in that it consists of a powder obtained from  from a semi rigid rigid polyurethane foam to majority  closed cells. 2- material according to claim 1, characterized in that  consists of a powder obtained from falling foam. 3- material according to claim 2, characterized in that the  powder is obtained from falls for which the  foam is coated with siding, including Kraft paper, paper  asphalt, and paper coated with polyethylene. 4- Material according to one of Claims 1 to 3, characterized  in that the powder is obtained by a grinding operation of  the foam, and in particular falls of the foam. 5- material according to one of claims 1 to 4, characterized  in that the foam contains from 70 to 100% of closed cells,  and its density is between 20 kg / m3 and 150 kg / m3. 6- Material according to one of Claims 1 to 5, characterized  in that the constituent powder is formed of grains or  granules having dimensions of between 50 microns and  15 millimeters, and advantageously between 150 microns and 10  millimeters. 7- Application of the material according to one of claims 1 to 6  the absorption of hydrocarbons polluting the surface of media  various, in particular water surfaces not agitated or surface  of the ground. 8- Application according to claim 7 to the absorption of  liquid hydrocarbons polluting the soil surface with a view to  direct cleaning of the polluted surface, characterized in that  spreading of an appropriate amount of the material  according to one of claims 1 to 6, on the part of the ground  polluted, said quantity being such that the impregnated material  oil remains shovelable, then after a few  minutes of contact during which the material is brewed  by sweeping over the polluted part, one collects and collects  the material impregnated with hydrocarbons.