FR2682556A1 - GLASS FIBERS USED AS SUBSTRATE FOR OUTDOOR CULTURE. - Google Patents

Abstract

Glass fibres are disclosed for use as constituents in a substrate for soilless cultivation. Their composition consists essentially of the following components in the proportions indicated in % by weight : 55 - 70 % SiO2, 1 - 8 % Al2O3, 5 - 9 % CaO, 1,5 - 4 % MgO, 13 - 18,5 % Na2O, 0,5 - 10 % K2O, 0 - 4 % Fe2O3, 0 - 4 % ZnO, 0 - 4 % MnO, 0 - 4 % TiO2, 0 - 4 % P2O5, less than 1 % impurities. The total content of B2O3, Li2O and F does not exceed 1 %.

Description

GLASS FIBERS USED IN SUCH
WHAT SUBSTRATE FOR OUTSTANDING CULTURE
The invention relates to glass fibers for use in the field of agriculture.

 The subject of the invention is, more particularly, fibers intended to be used as constituents of a soil-less culture substrate.

 In general, a substrate for above-ground cultivation must have sufficient mechanical strength to avoid sagging under the effect of both the root development and a mechanical stress due to a wetting effect and to a circulation. of the nutrient solution within the substrate. In addition, it must allow an availability of the nutrient solution for the plant and ensure good aeration vis-à-vis the roots. The lowest possible cost and density are obviously sought.

 In known manner, above-ground cultivation substrates are made from rock wool. These substrates have advantageous properties. However, rock wool is obtained from fibers produced by a so-called external centrifugation process. These processes usually lead to a relatively large proportion of unfibrated particles present in the substrate and products of relatively high density, of the order of 60 to 80 kg / m 3.

 Above ground culture substrates made of glass wool have also been proposed. This glass wool is obtained from fibers produced by a process called internal centrifugation, detailed in the following description. The density of these substrates may be substantially lower and is most frequently between 15 and 50 kg / m3.

 Glass fiber compositions having the characteristics required for use as a soil-less substrate have been described.

 Patent EP 201 426 discloses a glass canopy composition intended to be used as a substrate for above-ground cultivation which satisfies the mechanical and hydric requirements for soil-less cultivation.

 However some of these constituents, released in contact with the nutritive solution, may be unfavorable to the growth of certain species.

 The purpose of the present invention is to provide fibers whose glass composition has characteristics such that they are fibrable according to the so-called internal centrifugation process, fibers intended for the constitution of substrates for the cultivation above ground.

 The object of the present invention is to provide a soil substrate for low-density soil cultivation, which plays a root-holding role which is easily impregnated with nutrient solution and which does not harm the growth of plants.

The aims of the invention are achieved by means of fibers whose glass composition is as follows
SiO2 60 - 70%
Al203 3 - 8%
CaO 6 - 9%
MgO 1.5 - 4%
Na, O 15 - 20%
KzO 0.5 - 3%
Fe2O3 0 - 3%
LizO 0 - 3%
ZnO 0 - 3%
MnO 0 - 4%
Impurities S 1% in which the sum of the alkaline oxides (R2O) is greater than or equal to 18% and the boron oxide content is less than or equal to 1%.

 The impurities include all the constituents not included in the preceding list and which are provided by the natural raw materials used to produce these glass compositions. The impurities also include certain components derived from refining agents, such as sulphates, added to the vitrifiable raw material mixture.

 The glass fibers according to the invention are capable of being obtained by the so-called internal centrifugation process. This process makes it possible to obtain, in a reproducible manner, fibers that are practically free of infibrilated particles. Moreover, it is possible by these techniques to produce substrates of low density.

The subject of fiber production technique is the subject of numerous publications. For more details, see in particular patents FR 1 382 917 and
FR 2 443 436. According to these techniques, the molten glass is introduced inside the centrifuge and is projected, under the effect of centrifugal force, on its peripheral band.

A multitude of orifices are arranged on this band. Through these holes, the glass is projected horizontally. The resultant glass nets are advantageously drawn by gaseous streams to turn them into fibers.

 The glass fibers according to the invention are obtained from glasses which have physical characteristics making it possible to fiber them according to this process. These characteristics are defined below. They have, in particular, a viscosity of 1000 poises at a temperature generally below 12000C and preferably below 11500C.

 Another important physical characteristic for fiber production are the devitrification temperatures, i.e. the temperatures corresponding to the formation of crystals in the vitreous mass. These crystals are indeed likely to close the orifices of the centrifuge.

Several temperatures make it possible to characterize this devitrification
the temperature at which the growth rate of the crystals is zero, commonly called liquidus,
the temperature at which the growth rate of the crystals is maximum.

 In general, the difference between the temperature corresponding to a viscosity of 1000 poises and the temperature of the liquidus is preferably greater than or equal to 500C.

 It is desirable to obtain a minimum crystal growth rate; it is less than 3 mi cronsstminute and preferably less than or equal to 2 microns / minute.

Another important feature to consider is the hydrolytic resistance of the composition, particularly when it is to be used as a substrate for soil cultivation. This ziscance is measured according to the standard method of
Deutsche Glastechnische Gesellschaft (DGG).

 The DGG of the glasses constituting the fibers according to the invention is preferably less than or equal to 40 milligrams.

 The composition of the glass fibers according to the invention is characterized by a low level of boron oxide.

 It has been found that beyond 1% by weight of BzO3, the amount of boron released by the glass fibers in the nutrient solution exceeds the tolerance threshold of certain plants.

 The glass fiber compositions traditionally used contain about 5% by weight of B2O3.

This element plays an important role vis-à-vis different properties of the glass. In particular, it makes it possible to reduce the viscosity, to reduce the risks of devitrification and to improve the hydrolytic resistance.

 The compositions according to the invention make it possible, despite the sharp decrease in the proportion of this constituent, or even its suppression, to maintain correct physical and chemical properties.

 Thus, an increase in the level of alkaline oxides makes it possible to maintain the viscosity within acceptable limits without causing an increase in devitrification. This result is obtained by introducing at least 18% by weight of alkaline oxides, the sodium oxide content always being at least 15%.

 The Na2O content should not exceed about 20% beyond this value, the DGG of the glass is too high which affects the mechanical properties of the fibers.

 Other alkaline oxides may be introduced into the composition of the fibers according to the invention. Thus K2O and LizO lower the viscosity without causing a significant decrease in DGG. Li 2 O is maintained at a content of less than or equal to 3% by weight, essentially so as not to increase the cost of the composition.

Viscosity and devitrification are also kept within acceptable limits thanks to the alkaline earth oxides CaO and MgO. In particular, the content of
CaO should be at least 6% by weight to avoid an excessive increase in viscosity. Beyond 9%, CaO causes a significant increase in the risk of devitrification.

 Al 2 O 3 is introduced into the composition of the glass fibers according to the invention in a proportion of at least 3% by weight.

This content essentially has the effect of maintaining
DGG at values below 40 milligrams despite the high proportion of alkaline oxides. The proportion of Al 2 O 3 in the compositions according to the invention does not exceed 8%; beyond this value, the viscosity and the risks of devitrification increase considerably.

 Other oxides may be introduced into the composition of the fibers according to the invention, such as ZnO, MnO and Fe, O ,.

These oxides have the effect of fluidifying the glass without affecting the devitrification of the glass while maintaining a
DGG acceptable.

 Series of tests, presented in the attached table, illustrate the influence of the constituents present in a glass composition on the physical characteristics defined above.

The preferred glass compositions according to the invention comprise the following constituents within the following limits, expressed in weight percent
SiO2 62 - 67%
A1203 4 - 7%
CaO 6 - 9%
MgO 1.5 - 4%
Na2O 17 - 20%
K = O 0.5 - 1.5%
Fi203 0 - 2%
Li2O 0 - 2%
ZnO 0 - 2%
MnO 0 - 3%
Impurities <1% of which the sum of the alkaline oxides (RzO) is greater than or equal to 18 8 and the boron oxide content of which is less than or equal to 1%.

 the invention also relates to substrates for above-ground culture consisting of fibers obtained from a glass composition according to the invention.

 These substrates produced by the internal centrifugation process advantageously have a low density and are easily impregnated with the nutrient solution. These substrates according to the invention play no nutritional role vis-à-vis the plant and do not hinder the growth of plants: in contact with the nutrient solution, no harmful element is likely to be released at a content such that it hinders the growth of plants.

 In particular, the inventors have shown that a level of boron, released in contact with the nutrient solution, greater than 0.5 mg / l is detrimental to the growth of certain plants including cucumber or gerbera.

 The substrates according to the invention release, in contact with the nutritive solution, a boron content of less than or equal to 0.5 mg / l. This content is measured after 30 days of saturation imbibition of the substrate with a nutrient solution. The absence of harmful effects for plants is tested by careful observation of the behavior of the cultivated plants as well as by observation of their growth.

 Advantageously, according to the invention, the substrates have a particular structure in order to improve their mechanical strength.

 The substrates according to the invention may have a structure, described in the patent application FR 89 03372, in which the fibers are oriented in random directions giving the material isotropic properties, in particular improved mechanical strength.

 The patent application FR 90 15809, unpublished, describes another structure for improving the mechanical strength of the substrate. The latter consists of a mixture of fine fibers and larger fibers. Larger fibers impart improved mechanical strength of the substrate.

 Advantages of the invention are evidenced by experimental tests described in the following detailed description.

 The release of boron from a substrate in contact with the nutrient solution is tested. Three samples of substrates, of identical dimensions, differ only in their glass compositions. Substrate A is derived from a known glass composition comprising essentially: 68.1% Six, 3% Al 2 O 3, 7.7% CaO, 3.6% MgO, 14.8% Nua 2 O % of K20 and 1.5% of Bz03 substrates B and C are in accordance with the invention (respectively compositions 3 and 6 in the table).

 These three substrates are immersed at saturation, separately, for 30 days in a bath of nutrient solution, of identical composition, initially containing 0.25 mg / l of boron.

 After 30 days, the amounts of boron assayed in the various nutrient solutions are 0.85 mg / l for substrate A, 0.25 mg / l for substrate B and 0.29 mg / l for substrate C.

 The glass fibers constituting the substrates tested released, respectively, 0.6 mg / l, O mg / l, 0.04 mg / l of boron in the nutrient solution.

 These tests show the influence of the boron content contained in the glass fibers constituting a substrate on the boron content released by said fibers in the nutrient solution.

BOARD

<tb>: <SEP> Composition <SEP>: <SEP> 1 <SEP>: <SEP> 2 <SEP>: <SEP> 3 <SEP>: <SEP> 4 <SEP>: <SEP><SEP> 5 <SEP>: <SEP> 6
<tb><SEP> (%)
<tb> SiO2 <SEP>: <SEP> 64.75: <SEP> 62.80: <SEP> 65.21: <SEP> 63.7 <SEP>: <SEP> 62.82: <SEP> 64 , 98:
<tb> Al2O3 <SEP>: <SEP> 4.55: <SEP> 6.5 <SEP>: <SEP> 4.55: <SEP> 4.55: <SEP> 4.45: <SEP> 4 , 53:
<tb> CaO <SEP>: <SEP> 7.75: <SEP> 7.2 <SEP>: <SEP> 7.65: <SEP> 7.85: <SEP> 7.75: <SEP> 7 , 62:
<tb><SEP> MgO <SEP>: <SEP> 2.5 <SEP>: <SEP> 2.5 <SEP>: <SEP> 2.8 <SEP>: <SEP> 2.7 <SEP> : <SEQ> 2.65: <SEQ> 2.79:
<tb> Na2O <SEP>: <SEP> 19 <SEP>. <SEP> 19.55: <SEP> 18.2 <SEP>: <SEP> 18.6 <SEP>: <SEP> 18.45: <SEP> 18.14:
<tb> K2O <SEP> 0.9 <SEP> 0.9 <SEP> 1.05 <SEP> 1.05 <SEP> 1 <SEP> 1.05
<tb>;<SEP> Fe2O3 <SEP>: <SEP> 0.11: <SEP> 0.11: <SEP> 0.105: <SEP> 1.05: <SEP> 2.4 <SEP>: <SEP>
<tb> Li2O <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP >
<tb> ZnO <SEP> - <SEP> - <SEP> - <SEP> - <SEP> - <SEP>
<tb> B2O3 <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP ><SEP> 0.35:
<tb> Impurities <SEP> 0.44 <SEP> 0.44 <SEP> 0.435 <SEP> 0.50 <SEP> 0.48 <SEP> 0.54
<tb><SEP> -------------------------------------------- ----------
<tb> Properties
<tb>: <SEP> Temperature <SEP> to <SEP>
<tb>: <SEP> a <SEP> viscosity <SEP>
<tb>: <SEP> of <SEP> 1000 <SEP> poises <SEP>
<tb> (C) <SEP> [1] <SEP> 1096 <SEP> 1101 <SEP> 1120 <SEP> 1117 <SEP> 1103 <SEP> 1113
<tb> Liquidus <SEP> (C)
<tb> [2] <SEP>: <SEP> 1000 <SEP>: <SEP> 1010 <SEP>: <SEP> 960 <SEP>: <SEP> 970 <SEP>: <SEP> 990 <SEP>: <SEP> 958
<tb>: <SEP> [1] - [2] <SEP> (C) <SEP>: <SEP> 96 <SEP>: <SEP> 91 <SEP>: <SEP> 160 <SEP>: <SEP > 147 <SEP>: <SEP> 113 <SEP>: <SEP> 155
<tb>: <SEP> Speed <SEP> maxi- <SEP>
<tb>: <SEP> male <SEP> of <SEP> cris- <SEP>
<tb> tallization <SEP>: <SEP>: <SEP>: <SEP>: <SEP>: <SEP>: <SEP>
<tb>: <SEP> (m / min) <SEP>: <SEP> 1.61: <SEQ> 1.67: <SEP> 1.8 <SEP>: <SEP> 1.41 <SEP>: <SEP> 1.58: <SEP> 1.7
<tb> DGG <SEP> (mg) <SEP>: <SEP> 39.6 <SEP>: <SEP> 37.3 <SEP>: <SEP> 29.2 <SEP>: <SEP>: <SEP > 26.5 <SEP>: <SEP> 29.2
<Tb>
TABLE (continued)

<tb>: <SEP> Composition <SEP>: <SEP> 7 <SEP>: <SEP> 8 <SEP>: <SEP> 9 <SEP>: <SEP> 10 <SEP>: <SEP> 11 <SEP >: <SEP> 12
<tb> (%)
<tb>: <SEP> SiO2 <SEP>: <SEP> 64.21: <SEP> 63.21: <SEP> 64.21: <SEP> 62.21: <SEP> 64.21: <SEP> 63.21:
<tb> Al2O3 <SEP>: <SEP> 4.55: <SEP> 4.55: <SEP> 4.55: <SEP> 4.55: <SEP> 4.55: <SEP> 4.55:
<tb> CaO <SEP>: <SEP> 7.65: <SEP> 7.65: <SEP> 7.65: <SEP> 7.65: <SEP> 7.65: <SEP> 7.65:
<tb>: <SEP> MgO <SEP>: <SEP> 2.8 <SEP>: <SEP> 2.8 <SEP>: <SEP> 2.8 <SEP>: <SEP> 2.8 <SEP >: <SEP> 2,8 <SEP>: <SEP> 2,8
<tb> Na2O <SEP>: <SEP> 18.2 <SEP>: <SEP> 18.2 <SEP>: <SEP> 18.2 <SEP>: <SEP> 18.2 <SEP>: <SEP > 18.2 <SEP>: <SEP> 18.2
<tb>: <SEP> K2O <SEP>: <SEP> 1.05: <SEP> 1.05: <SEP> 1.05: <SEP> 1.05: <SEP> 1.05: <SEP> 1.05:
<tb>: <SEP> Fe2O3 <SEP>: <SEP> 0.105: <SEP> 0.105: <SEP> 0.105: <SEP> 0.105: <SEP> 0.105: <SEP> 0.105:
<tb>: <SEP> Li2O <SEP>: <SEP> 1 <SEP>: <SEP> 2 <SEP><SEP> - <SEP>. <SEP> - <SEP>. <SEP> - <SEP> - <SEP>
<tb>;<SEP> MnO <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> 1 <SEP>: <SEP><SEP> 3 <SEP> - <SEP> - <SEP>
<tb><SEP> ZnO <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> 1 <SEP>: <SEP> 2
<tb> Impurities <SEP> 0.435 <SEP> 0.435 <SEP> 0.435 <SEP> 0.435 <SEP> 0.435 <SEP> 0.435
<tb> ----------------------------------------------- -------
properties
<tb>: <SEP> Temperature <SEP> to <SEP>: <SEP>: <SEP>: <SEP>: <SEP>:
<tb>: <SEP> one <SEP> viscosity <SEP>: <SEP>: <SEP>: <SEP>: <SEP>:
<tb>: <SEP> of <SEP> 1000 <SEP> poises: <SEP><SEP>:<SEP>:<SEP>:<SEP>:<SEP>:<SEP>
<tb> (C) <SEP> [1] <SEP> 1076 <SEP> 1032 <SEP> 1109 <SEP> 1087 <SEP> 1110 <SEP> 1100
<tb>: <SEP> Liquidus <SEP> (C) <SEP>: <SEP><SEP>:<SEP>:<SEP>:<SEP>:<SEP>:<SEP>
<tb>: <SEP> 2] <SEP>: <SEP> 940 <SEP>: <SEP> 920 <SEP>: <SEP> 972 <SEP>: <SEQ> 996 <SEP>
<tb> [1] - [2] <SEP> (C) <SEP> 136 <SEP> 112 <SEP> 137 <SEP> 91
<tb>: <SEP> Speed <SEP> maxi- <SEP>: <SEP><SEP>:<SEP>:<SEP>:<SEP>:<SEP>:<SEP>
<tb>: <SEP> male <SEP> of <SEP> cris- <SEP>: <SEP><SEP>:<SEP>:<SEP>:<SEP>:<SEP>:<SEP>
<tb>: <SEP> tallization <SEP><SEP>:<SEP>:<SEP>:<SEP>:<SEP>:<SEP>:<SEP>
<tb>: <SEP> (m / min) <SEP>: <SEP> 1.88: <SEP> 1.96: <SEP>: <SEP>: <SEP> 1.76: <SEP> 1, 72:
<tb>: <SEP> DGG <SEP> (mg) <SEP>: <SEP> 31 <SEP>: <SEP> 33 <SEP>: <SEP>: <SEP>: <SEP> 29 <SEP>: <SEP> 28
<Tb>

Claims (6)

 1. Glass fibers intended to be used as constituents for an above-ground culture substrate, characterized in that their composition essentially comprises the following constituents, the proportions of which are expressed in percentage by weight  Sio, 60 - 70%  Al203 3 - 8%  CaO 6 - 9%  MgO 1.5 - 4%  Na2O 15 - 20%  K2O 0.5 - 3%  Fe2O3 0 - 3%  Li2O 0 - 3%  ZnO 0 - 3%  MnO 0 - 4%  Impurities # 1% of which the sum of the alkaline oxides <R2O) is greater than or equal to 18% and whose boron oxide content is less than or equal to 1%.  2. Glass fibers according to claim 1, characterized in that their composition essentially comprises the following constituents, the proportions of which are expressed in percentage by weight.  SiO2 62 - 67%  Al2O3 4 - 7%  CaO 6 - 9%  MgO 1.5 - 4%  Na2O 17 - 20%  K20 0.5 - 1.5%  Fe2O3 0.1 - 2%  Li2O 0 - 2%  ZnO 0 - 2%  MnO 0 - 3%  Impurities # 1% of which the sum of the alkaline oxides (R2O) is greater than or equal to 18% and whose boron oxide content is less than or equal to 1%.  3. Substrate for above-ground culture consisting of glass fibers, the composition of which consists essentially of the following constituents, the proportions of which are expressed in percentages by weight  SiO2 60 - 70%  Al2O3 3 - 8%  CaO 6 - 9%  MgO 1.5 - 4%  Na2O 15 - 20%  K20 0.5 - 3%  Fe2O3 0 - 3%  Li2O 0 - 3%  ZnO 0 - 3%  MnO 0 - 4%  Impurities <1% of which the sum of the alkaline oxides (R2O) is greater than or equal to 18% and the boron oxide content of which is less than or equal to 1%.  4. Substrate for the above-ground culture according to claim 3 consisting of glass fibers whose composition essentially comprises the following constituents, the proportions of which are expressed in percentage by weight  SiO2 62 - 67%  A1203 4 - 7%  CaO 6 - 9%  MgO 1.5 - 4%  Na2O 17 - 20%  K20 0.5 - 1.5%  Fe2O3 0.1 - 2%  Li <0 0 - 2%  ZnO 0 - 2%  MnO 0 - 3%  Impurities <1% of which the sum of the alkaline oxides (R2O) is greater than or equal to 18% and the boron oxide content of which is less than or equal to 1%.  5. Substrate for cultivation above ground according to claims 3 and 4, characterized in that it consists of fibers which, in contact with a nutrient solution, release only elements whose nature and concentration in the solution nutrients are devoid of effects that may hinder the growth of plants.  6. Substrate for the above-ground culture according to claim 5, characterized in that when the substrate is saturated at 75% by volume with a nutrient solution, the boron content released in the latter is less than or equal to 0.5 mg. / l.