DE3340379A1 - BUILDING MATERIAL BASED ON FIBER REINFORCED HYDRAULIC BINDING AGENT AND METHOD FOR THE PRODUCTION THEREOF - Google Patents

Description

The invention relates to an essentially fiber-reinforced one hydraulic binder existing building material as well as the manufacturing process of this substance.

It is known in building materials based on cement or hydraulic binders and asbestos to replace the asbestos fibers with organic and / or mineral fibers of another type. Since one in the manufacture of asbestos cement products in generally from a mixture of asbestos fibers suspended in water and cement that is then filtered to obtain a layer that is subsequently formed into sheets or tubes, it is necessary to add replacement fibers use which, on the one hand, allow filtration and, on the other hand, strengthen the Effect the end product. Filtration is understood as the retention of the fibers on a filtering surface, which then form a network and thus preventing the flow of cement particles through the interface. The reinforcement fibers are also intended to counteract the inherent fragility of products made from cement. Though the asbestos fibers meet both of these conditions at the same time However, this is not the case. So two different types of fiber are required, one type being filtration and the other type contributes to the mechanical resistance of the end product through reinforcement.

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Cellulose fibers, for example, improve their mechanical resistance of the processed product contribute to the filterability of the slurries which contain other reinforcing fibers. However, these fibers are sensitive to moisture which causes the fibers to swell, which leads to microcracks. Besides, they are due to the influence of weathering Exposed to microorganisms, so that cellulosic fiber products are not in a damp place Environment or outside of buildings.

The invention overcomes these disadvantages. It has a building material as its object, which essentially consists of a hydraulic fiber-reinforced binder, does not contain asbestos and is characterized in that the fibers have a diameter between 3 and 8 μm and a tear strength that is greater than 800 N / mm.

It was surprisingly found that, if the fibers were to be replaced of asbestos meet these two conditions, they meet the two requirements, the manageability of the filtration and the mechanical reinforcement, sufficient able to fulfill.

As mentioned above, the fibers used can be one have mean diameter between 3 and 8 pm. It is possible that fibers smaller than 3 pm in diameter might be adequate, but these cannot be made with today's technology. If the If the diameter exceeds 8 μm, the network of the retained fibers has a mesh that is too large, which then becomes too large during the filtration Allow proportion of cement particles to pass through. The nature of the fibers doesn't matter

Role provided they are the alkaline reactions of the hydraulic binder

2 and have a tear strength greater than 800 N / mm. This value was derived from investigations into the mechanical properties of the end product determined, depending on the intended use as a pipe or as a cover plate at least in the longitudinal direction that corresponds to the direction of flow of the The felt on which the "filter cake" is collected must be sufficiently good. Synthetic organic fibers, especially polyethylene, Polypropylene, polyacrylonitrile, polyacrylamide and polyvinyl alcohol are sufficient

meet these requirements well. Mineral fibers can also be used successfully be ^ on condition that they have an adequate exposure to alkali compounds have a resistant composition.

The thin fibers are either in the commercial form or after a Surface treatment that improves its anchoring in the cement grid is used. These fibers are generally round in cross-section, however a simple or multiple flap shape or a band shape may also be appropriate be. In such a case, replace the diameter of the fibers with the equivalent diameter:

χ equivalent where S is the cross-sectional area.

The length of the fibers is at least 1 mm so that the connection between of the fiber and the cement grid, even if micro-cracks should appear in the end product. It is smaller than 10 mm; for longer lengths difficulties would arise in the application.

The fabric according to the invention also contains a hydraulic binder, such as Cement, with or without additives, such as: aluminum cement, iron Portland cement or a blast furnace cement. Likewise, selenite, lime gypsum or lime can be appropriate be.

In a known manner, the substance still contains inactive or active fillers, the End product the desired properties, such as heat resistance or prevention the release of lime during the hardening of the cement. It is also advantageous to provide known flocculants such as the basis of soluble polymers, the task of which is to hold back the solid particles and the dispersants, their effect in the prevention the formation of fiber clusters or flakes in the filtered suspension, to increase.

The process for producing the substance according to the invention is as follows. First, the fibers are loaded in one of the machine's operating conditions.

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correct proportion suspended in water, this proportion is between 1 to 5 vol.% Fibers in relation to the total volume of the final product. Nevertheless, in order to take into account the different nature of the fibers used, a Introduced parameter that brings in the density of the fibers, namely d ^ s "specific ratio" Pf / e, where Pf is the percentage by weight of the Fibers in relation to the total weight of the dry matter and £ the volume-related mass of the fibers in g / cm h ratio "is advantageously between I and 5.

is the volume-related mass of the fibers in g / cm. This "specific

Then the cement is added, namely 60 to 98 parts by weight in relation to the total weight of the dry mass. If the products are manufactured on a machine of the type "cardboard machine ¹ *., The proportion of active or inactive fillers in general does not exceed 3G% by weight in relation to the cement, which corresponds to Q up to 3d % by weight of the total weight of the dry matter. In the case of others Manufacturing techniques, such as casting, molding, centrifuging and extrusion, the filler content can be larger.

After homogenizing the aqueous slurry by stirring this is filled into the machine. The two main muscle types are those who use a sieve in the process, such as the HATSCHECK. and those that do not use a sieve, such as the MAGNANI machine.

In the method of using a sieve, a tub takes the watery one Suspension on, attached by a on a rotating cylinder Metal cloth is filtered. So there is a thin one on the sieve Layer of fibers and cement deposited on the felt after transfer Elementary layer forms. The stacking of several elementary Layers results, in the event that several trays with filters are used, a single layer that is rolled up on a cytinder body until the desired thickness of the product is obtained. As soon as this is achieved, it is made possible a device for cutting the dough mass along a surface line, roll off the dough in the form of a flat plate, which is then placed in even, corrugated or profiled shape is aged. Another common one Application of this mixture consists in the manufacture of pipes.

In both of these cases, the products obtained are either exposed to air, under water or in a heat chamber in a liquid-saturated atmosphere

aged.

Several mixtures were prepared under the conditions according to the invention, with a view to creating flat specimens on which fracture tests, as provided by the ASTM D-38 80-80 standard, are carried out. In the accompanying the tables that complete the description are those with different Fiber types achieved results as a function of various machine parameters and, for comparison, the results obtained with asbestos-containing samples are summarized.

example 1

In a first production example, a mixture of cement and viscose fibers sold by RHONE POULENC TEXTILES under the registered trademark "FIBRANNE" with a diameter of 6.5 μm, a length of 5 mm and a tensile strength of 800 N / mm is used. The mixture consists of 5% by weight of fibers _; and 3 g / l of a known flocculant (E 318) were added. The flat plate, which was obtained from the individual layer resulting from the filtration, is pressed at a pressure of 100 bar and then aged at ambient temperature. After IA days will be

then fracture tests carried out in the saturated state and the bending resistance, both in the direction of flow L of the belt of the machine and in the direction T, perpendicular to this flow.

Example 2

The same type of fibers as in Example 1 is made under the same conditions used, but the tests are carried out after 21 days in a dry state. The density is then 1.65 g / cm.

Example 3

There are very tough viscose fibers with a diameter of 6 pm, a length

2 of 5 mm and a tear strength of 930 N / mm are used. The filtered mixture

contains 2% by weight fibers and 98% by weight cement. The aging takes place at ambient temperature in a closed system. The density of the board, which was not processed further after 14 days of testing, is 1.75 g / cm ³ .

Example 4

Polyvinyl alcohol (PVA) fibers with a diameter of 7μηη, a length of

6 mm and a tensile strength of 1,100 Wmm become 4 parts by weight

mixed with 96 parts by weight of cement. The plate is not compressed after manufacture. The aging process takes place in a saturated atmosphere, and the breaking tests take place in the non-processed state after 14 days. The density of the plate is 1.55 g / cm ³ .

Example 5

The same fibers as from Example 4 are added to the cement in a ratio of 4 parts by weight of fibers to 96 parts by weight of cement. The plate is pressed at 200 bar after production, but the other conditions of aging and the tests are identical to those from Example 4.

Example 6

An amount of 1.5% by weight polyvinyl alcohol fibers, having a diameter of 12 μm, a length of 6 mm and a tear strength of 1,100 N / mm added to 98.5 wt.% cement and filtered the mixture. During this process it is found that it is impossible to select an elementary layer of a suitable one Composition on the sieve, since 80 to 90% of the cement particles are washed away with the filter water and almost exclusively the felt only picks up fibers.

Example 7

The comparison element is composed of asbestos of the chrysotile type in the form of a mixture of grade A - 5 - 6. 80% of the fibers have a diameter between 1 and 10 μm. As in the previous one, a plate is made

BATH ORIGINAL

without compression after manufacture _/ but with aging at ambient temperature in a closed system. This plate is then subjected to the tear tests.

If you study the table you can see that after hardening, the Substance differs from asbestos cement by a higher deformation capacity, which leads to increased safety in its use. Indeed it can one or more unforeseen excesses of the elastic limit values without necessarily causing cracks or dangerous fractures. It is also found that the density of the filtrate or the density of the effluent during manufacture is indicative of the good filtration of the mixture is in suspension, which is achieved by the fibers of the invention. the Using these fibers leads to a considerable simplification of manufacture of mixtures and slurries, as they do not have any prior refining or other treatments that require a great deal of energy consumption.

In a variant, the building material according to the invention can also consist of a mixture different fibers and hydraulic binders. The only conditions to consider are those related to the characteristic Sizes of the fibers (diameter, length), the mechanical strength and the resistance to alkali compounds.

BATH ORIGINAL

2 g

Examples: I ι Ambient temp.
^a water 2 3 1 4 5 5 I 6 J 6 1.006-1.012 J. 1.003. - 1.026 J 1.003 - 1.026 yes- (200 bar) u days
*) 6th 7th no I. 13 850
j 12 800 Type of fiber j ^viscous .. 1.63 viscose Viscous high viscous _PVA PVA 930 I UOO j 1100
I I .1 ..la (loo bat «,) j no 1 no ambient temp, I ambient temp. Ambient temp.
completed. Isaturated ■ ·.,! Saturated. 35.5
25.2 PVA Asbestos cement J Ambient temp.
j completed » 1
Diameter of fiber (µm) I 6.5 I. H days
saturated 6.5 I 6 I 7 1 7. 2 I 4 I 4
II ambient temp.
water 1.75 I 1.55 J 1.80 17.9
3.7 12th 1 l 10 - 1 1.58 Length (mm). I si 17.7
14.1 5 I. 1.020 j 1.848 - 1.036 | 1,070 | .. 1,070 1.65 [U days j. _u days
I ... ·) .., .... W 6th ~ - I η days
I saturated 1.8
1.3 800
Ϊ, 003 * 1.004 2i days
dry 18.2 J 27.3
ί 12.0 j 18.5 1100 ^ - I 29
■ - I 22 Composite, the ι ₅ ι
Mixed. (% By weight / total gevy) ι 12 500
10 800 5
. 22.β
'16.5 I 2.61 I 32.6
i .. 1.48 j 13.8 1.5 U - I 2.92
II 2.28 Sealed tray sieve I ΐ · «ο I 1.9
\ 1.3 12 700 I 14 400
U 500 j 13 200 - 1.050-1.060 21 900 I -
19 300 j "^ Sealed tub spout | ^ ₀₀₃ _ _ltO ö _% I 14 600
12 100 - I 1.003-1.004 ISfTSaSftiMia " ⁸⁰ · ¹ I.la (ι» »bar.) -. Aging process Density of the final product Fracture conditions Bending resistance l
... (MPa) T Bending deformation l
... (xio " ³ ) τ Flexion module l
(HPa) T

*) in the not further processed state

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Claims (1)

Claims 1. Building material, which consists essentially of a hydraulic fiber-reinforced Consists of binding agents and does not contain asbestos, characterized, that the fibers have a diameter between 3 and 8 pm, and a tear strength that is greater than 800 N / mm. 2. Building material according to claim 1,
characterized, that for fibers with a non-circular cross-section the equivalent diameter, given by - * ■ equi equivalent to _ ο where S is the cross-sectional area, between 3 and 8 pm. Building material according to claim 1 or 2, characterized in that the length of the fibers is between 1 and 10 mm. Building material according to claims 1 to 3, characterized in that the fibers used are synthetic organic fibers. 796-1 / 82025 CM / Al -2- 5. Building material according to claim 4,
characterized in that the fibers used consist of polyvinyl alcohol. 6. Building material according to one of claims 1 to 3, characterized in that that the fibers used are mineral fibers. 7. Process for the manufacture of the substance? according to one of claims 1 to 6, in which fibers, a hydraulic binder and optionally filler materials are mixed in water, is filtered to a or to collect several elementary layers which form a single layer, which is rolled up and finally cut into shape is brought and dried, characterized, that the specific proportion of the fibers or the ratio between the percentage by weight of the fibers and the total of the dry matter and the specific
is between 1 and 5. masses and the specific mass of the fibers, expressed in g / em 8. The method according to claim 7, characterized in that that 60 - 98 parts of cement are added in relation to the total dry matter will. 9. The method according to claim 7, characterized, that the mixture of fibers and cement in aqueous suspension in proportion 0-30% by weight of active or inactive fillers added to the dry matter will.