GB2161106A - Apparatus for making cement composite materials - Google Patents

Abstract

To obtain satisfactory operation of apparatus, e.g. of the Hatschek, Magnani or Bell Flow-on types, for making cement composite materials reinforced with glass fibres, using an aqueous slurry of cement, glass fibre, pulverised fuel ash, finely divided amorphous silica, cellulose pulp, flocculant and water which is deposited on a foraminous surface such as the drum of a Hatschek machine or the felt belt of a Magnani or Bell Flow-on machine, the apparatus is provided with means for controlling the temperature of the slurry before and during deposition on the foraminous surface. The temperature control means may comprise means (30 to 38) for heating and for cooling the water in a reservoir (24) which supplies a slurry mixer (10). The apparatus also includes means for adding a flocculant to the slurry adjacent to the foraminous surface. <IMAGE>

Description

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GB2 161 106A

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SPECIFICATION

Apparatus for making cement composite materials

5 This invention relates to apparatus for making cement composite materials reinforced with glass fibres.

For making cement composite materials reinforced with asbestos fibres, three principal types of machine are currently in use, namely the Hatschek, Magnani and Bell machines. All of these machines comprise means for forming an aqueous slurry of cement, asbestos and water, and a 10 foraminous surface on which a layer of the slurry can be deposited and through which water can be removed to de-water the cement composite material. In the Hatschek machine, a dilute slurry with a solids content of around 6 to 10% by weight is used and the foraminous surface is provided on the circumference of a rotating cylindrical drum which is partly submerged in a vat containing the slurry. The layer of slurry is deposited as a film on the surface of the drum 15 through which a proportion of the water is removed and the film is transferred to a felt belt in contact with the emergent part of the drum, further de-watered by suction through the belt and transferred to an accumulator roller on which the desired thickness of cement composite material is built up. In the Magnani machine, a thick slurry of around 45 to 50% solids content by weight is deposited on a travelling felt belt by means of a reciprocating distributor and de-20 watered by suction through the belt. The Bell machine uses a slurry of a solids content intermediate between those used in the Hatschek and Magnani machines, which is fed to the surface of a travelling felt belt through the nip between one of the rollers around which the belt is trained and a superposed contra-rotating roller. The layer of slurry on the belt is de-watered by suction and transferred to an accumulator roller to build up the desired thickness. 25 The operation of these three types of machines with asbestos fibres as the reinforcement for the cement is dependent upon the property of the asbestos fibres to be wetted by the cement slurry and to retain the fine particles of cement.

The replacement of asbestos by glass fibres has long been recognised as desirable from the point of view of health, but it has been found to involve considerable process problems arising 30 from the differences in behaviour between asbestos fibres and glass fibres, in particular the fact that glass fibres are not wetted by a conventional aqueous cement slurry and have a tendency to clump together, resulting in loss of fine cement particles when the material is de-watered and a non-homogeneous structure in the composite material. The use of flocculants and other additives, such as cellulose pulp, in the slurry can improve the retention of fine particles, e.g. as 35 described in our UK Patent Specification No. 1 543951, so as to enable cement composite materials to be produced economically on apparatus designed primarily for production of asbestos cement products, but certain inconsistencies in the glass fibre reinforced cement composite materials have been found in practice.

We have now discovered that these inconsistencies arise from temperature variations which 40 affect the production process when using slurries containing flocculant. In particular, if the slurry temperature is too low, flocculation does not take place effectively and excessive quantities of fine materials pass through the foraminous surface and block it so that filtration ceases. If the temperature is too high, the flocculated particles tend to become over-large, resulting in an open porous structure in the composite material and excessive retention of water, resulting in poor 45 green strength and a lower final strength of the composite material.

The present invention accordingly provides apparatus for making cement composite materials reinforced with glass fibres, comprising:—

(a) means for forming an aqueous slurry comprising cement, glass fibre, pulverised fuel ash, finely divided amorphous silica, cellulose pulp and water,

50 (b) a foraminous surface on which a layer of the slurry can be deposited and through which water can be removed to de-water the cement composite material,

(c) means for adding a flocculant to the slurry adjacent to the foraminous surface, and

(d) means for controlling the temperature of the flocculant-containing aqueous slurry before and during deposition on the foraminous surface.

55 Preferably the means for forming the aqueous slurry comprises a water reservoir from which water can be supplied to a slurry mixer, and the means for controlling the temperature of the flocculant-containing slurry comprises means for heating and for cooling the water in the reservoir. The means for heating the water in the reservoir may comprise a steam generator connected through a regulator valve which is controlled by a temperature controller to a pipe 60 opening into the water in the reservoir, while the means for cooling the water in the reservoir may comprise a pump controlled by the temperature controller and arranged to circulate water from the reservoir to and from a cooling lagoon. The means for controlling the temperature of the slurry may further comprise a temperature sensor in the reservoir, connected to the temperature controller.

65 In a particular embodiment of the invention, the slurry mixer is aranged to supply a relatively

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thick slurry comprising water and cement to a blender provided with means for introducing glass fibres into the slurry, the blender being in turn arranged to supply the glass-fibre-containing slurry to a holding vessel which is connected to the water reservoir for supply of water for diluting the slurry and is also connected to the vat of a Hatschek type machine for feeding the 5 diluted slurry thereto, a tank for containing flocculant solution being connected to the line between the holding vessel and the vat.

A specific embodiment of the invention, as applied to a Hatschek type machine, will now be described by way of example and with reference to the accompanying diagrammatic drawing which illustrates the layout of a Hatschek machine and the supply of temperature-controlled 10 slurry thereto.

As shown in the Figure, a conventional Hatschek-type machine comprises a horizontal, hollow wire mesh cylindrical sieve 55 mounted for anti-clockwise rotation about its cylindrical axis 56 in a slurry-containing vat 57.

Above the sieve 55 is a continuous moving woven felt 62 which is kept in firm contact with 1 5 the sieve 55 by means of a rotatably mounted heavy roller 63 and is trained around further rollers 65, 66, 67, 68. The felt 62 passes from the sieve 55 to an accumulator roller 64 on to which a film of slurry can be transferred as described below. The ends of the sieve 55 are fitted with seals (not shown) so that water from the slurry can only flow through the wire mesh and out through discharge ports mounted through the seals. In operation, the sieve 55 is rotated 20 with a surface speed of the order of 45 metres/min. and a thin, even film of slurry is deposited on its wire mesh surface while the major part of the water is removed. The thickness of the film depends upon the slurry level in the vat 57, its consistency, and the speed of rotation of the sieve 55.

The thin film of glass fibre containing cement slurry which is collected on the wire mesh of 25 the sieve 55 is transferred to the woven felt 62. The film is then processed in the same manner as is used in forming asbestos cement products by Hatschek machinery, by passing it over at least one vacuum box 72 which draws additional water from the film. The film is then passed under the iron or steel accumulator roller 64, further removal of water being caused by compression between rollers 64 and 66, and is transferred in a continuous operation to the 30 accumulator roller 64 until a sheet is built up on the roller 64 to a desired thickness. The sheet can be knifed along a groove in the accumulator roller 64 and peeled from it on to a conveyor table 73, and subsequently trimmed and cut to desired lengths by saws 74.

The operation described so far is conventional for production of cement composite materials on a Hatschek machine.

35 In the present invention, the slurry for supply to the vat 57 is formed by first mixing a relatively thick slurry of cement, pulverised fuel ash, volatilised silica, cellulose pulp and water, with a solids content of 40 to 60%. The slurry is mixed in a high shear mixer 10 of conventional design, to which water and a supply of aqueous cellulose pulp are fed through lines 11,12 and 13, while cement and pulverised fuel ash are supplied through line 14 and an 40 aqueous slurry of volatilised silica is fed through line 1 5. Volatilised silica is a form of finely divided amorphous silica produced as a by-product in the electro-reduction process for production of silicon. If any solid processing additives are to be incorporated, they are dispersed in the cement/pulverised fuel ash mixture supplied through line 14. The resultant thick slurry is fed to an interim storage tank 1 6 where it is kept under agitation by means of a rotating mixer 45 blade 1 7.

Alkali-resistant glass fibres, e.g. as described and claimed in our UK Patent Specification No. 1,290,528, are mixed into batches of the thick slurry in a blender 1 8. The glass fibres are fed by a vibrating feeder 19 from a hopper 20 and filded into the slurry by rotary and vertical circulation in the blender 18.

50 The batches of thick fibre-containing slurry are transferred to a large holding vessel 21 which contains a low shear rotary agitator 211 and in which the slurry is diluted to a solids content of 6 to 10%, typically 7.5%, by weight, by water supplied through line 22. Line 22 receives the dilution water from a main conical reservoir 24 which also supplies the water through line 11 to the high shear mixer 10. The dilute slurry is supplied from vessel 21 through line 23 to the vat 55 57. Flocculant solution from tank 25 is added to the slurry in line 23 so that the flocculant is mixed into the slurry just before it passes into the vat 57.

The vat 57 is provided with an agitator 26 in the form of a series of similar parallel blades 27 (only one of which can be seen in the Figure) disposed in vertical planes perpendicular to the axis 56 of the sieve 55 and spaced from one another across the width of the vat. The blades are 60 mounted on wheels 28 so that they can be reciprocated parallel to the axis of the sieve for producing the desired agitation of the slurry.

For controlling the temperature of the slurry, a sensor 29 is provided in the conical reservoir 24 and connected to a thermostat device 30 which controls a valve 31 in a steam supply line 32 which has an outlet 33 in the reservoir 24. A non-return valve 34 is provided in the steam 65 line 32 to vent the line 32 when the steam supply is cut off.

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For cooling the water in the reservoir 24 when necessary, inlet and outlet lines 35, 36 and a pump 37 are provided for circulating the water to an external cooling lagoon 38, again under the control of the thermostat device 30.

As an alternative to the heating arrangement described above, employing direct supply of 5 steam through line 32 into the reservoir 24, a heat exchanger could be incorporated in the line 23 before or after its junction with the supply from the flocculant-containing tank 25, using recirculated steam or hot water as the heating medium. Furthermore, the sensor 29 could be located in the vat 57 instead of in the water reservoir 24.

In specific examples of production of glass fibre reinforced cement composite materials on the 10 apparatus described above and illustrated in the accompanying drawing, a slurry was used having a solids content of 7.5% by weight, the solids comprising, in weight percentages:—

Ordinary Portland Cement 60.5%

Pulverised fuel ash 24.5%

15 Volatilised silica 8.0%

Dispersible chopped glass fibre strands 3.5%

Cellulose pulp 2.0%

Processing aids (dispersing agents, flocculating agent) 0.5%

20 The temperature of the slurry in the vat 57 was gradually increased from a temperature of 1 5°C. At this low temperature, it was not possible to collect material on the rotating sieve 55 because the flocculating action was ineffective and excessive quantities of fine cement particles passed through the sieve. As the temperature was increased, it became possible to collect material from the drum but it was clearly of inferior quality and the amount of solids passing 25 through the drum remained at an unacceptably high level until the temperature of the slurry reached 20°C. At this temperature, the process began to run well, in the manner described above, and the product was of good quality, the best properties being achieved with the slurry temperature around 23°C. Above 25°C, the quality began to deteriorate and as the temperature was increased beyond 27°C the product was found to have a porous character and when cured 30 gave a low final strength.

Similar tests were made on a Bell machine as described in our copending Patent Application No. 8400226 filed 5th January 1984. Slurry composition was made up to have a solids content of 30%, and the solids had the following composition:

35 Ordinary Portland Cement 61%

Pulverised fuel ash 25% Volatilised silica 9% Dispersible chopped glass fibre strands 3% Cellulose pulp 2% 40 Dispersing agents, flocculating agents 0.1%

It was found that at temperatures of the order of 1 5 to 1 6°C, there was very poor flocculation, and due to the fine cement materials clogging or blinding the felt belt, it was extremely difficult to collect any material. With a temperature of 1 8 to 1 9°C, cement composite 45 material was collected on the accumulator roller but the water retention was excessive. With a slurry temperature in the region of 20 to 25°C, the machine operated at maximum speed with good de-watering and the felt belt remained clean, while the properties of the cement composite material were satisfactory. With a slurry temperature of 27°C the properties of the material were found to deteriorate due to porosity.

50 It is believed that the nature of the flocculant used inflences to some extent the appropriate temperature for operation. It is clear, however, that the provision of means for controlling the temperature of the flocculant-containing aqueous slurry before and during deposition on the foraminous surface, in accordance with the invention, enables consistent production of satisfactory cement composite material to be achieved.

55 The glass fibre used is preferably in the form of chopped strands of filaments sized with a size composition such that the strands separate or filamentise into individual filaments in the slurry as in the foregoing Examples, but strands which retain their integrity may be used instead of or in addition to the dispersible fibres.

Claims (1)

1. 60 CLAIMS

   1. Apparatus for making cement composite materials reinforced with glass fibtres, comprising:—

   (a) means for forming an aqueous slurry of cement, glass fibre, pulverised fuel ash, finely divided amorphous silica, cellulose pulp and water,

   65 (b) a foraminous surface on which a layer of the slurry can be deposited and through which

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   water can be removed to de-water the cement composite material,

   (c) means for adding a flocculant to the slurry adjacent to the foraminous surface, and

   (d) means for controlling the temperature of the flocculant-containing aqueous slurry before and during deposition on the foraminous surface.

   5 2. Apparatus according to Claim 1 wherein the means for forming the aqueous slurry 5

   comprises a water reservoir from which water can be supplied to a slurry mixer, and the means for controlling the temperature of the flocculant-containing slurry comprises means for heating and for cooling the water in the reservoir.

   3. Apparatus according to Claim 2 wherein the means for heating the water in the reservoir

   10 comprises a steam generator connected through a regulator valve which is controlled by a 10

   temperature controller to a pipe opening into the water in the reservoir.

   4. Apparatus according to Claim 3 wherein the means for cooling the water in the reservoir comprises a pump controlled by the temperature controller and aranged to circulate water from the reservoir to and from a cooling lagoon.

   15 5. Apparatus according to Claim 3 or 4 wherein the means for controlling the temperature of 15 the slurry further comprises a temperature sensor in the reservoir, connected to the temperature controller.

   6. Apparatus according to any one of Claims 2 to 5 wherein the slurry mixer is arranged to supply a relatively thick slurry comprising water and cement to a blender provided with means

   20 for introducing glass fibres into the slurry, the blender being in turn arranged to supply the 20

   glass-fibre-containing slurry to a holding vessel, which is connected to the water reservoir for supply of water for diluting the slurry and is also connected to the vat of a Hatschek type machine for feeding the diluted slurry thereto, a tank for containing flocculant solution being connected to the line between the holding tank and the vat.

   25 7. Apparatus for making cement composite materials reinforced with glass fibres, comprising 25 means for controlling the temperature of a flocculant-containing slurry of cement, glass fibre, pulverised fuel ash, finely divided amorphous silica, cellulose pulp and water before and during deposition on a foraminous surface, substantially as hereinbefore described with reference to the accompanying drawing.

   Printed in the United Kingdom for Her Majesty's Stationery Office. Dd 8818935, 1986. 4235.

   Published at The Patent Office. 25 Southampton Buildings, London, WC2A 1AY. from which copies may be obtained.