NL1011167C2 - Surface leveling formulation for ground on which buildings are being constructed, comprises a liquid polymer formulation pourable into a mould - Google Patents

Abstract

The liquid formulation comprises a synthetic polymer. A liquid, hardenable, surface-leveling formulation comprises a synthetic polymer. Independent claims are also included for: (a) a device for preparing the formulation, comprising a mould formed by two spaced apart frame parts (4, 5), two mould elements (7, 8) forming the mould edges, and a sheet (9) covering the mould; and (b) a method for forming a surface-leveling layer on an underlay, by pouring the formulation into the mould and leaving it to harden.

Description

LIQUID. CURABLE KIM FORMULATION. AND AN APPARATUS AND METHOD FOR FORMING A KIM THEREFOR

The present invention relates to a liquid, curable bilge formulation, and to a device and method for forming a bilge with this liquid, curable bilge formulation on a substrate.

When setting up a building, it is necessary, especially when using sand-lime bricks, that the surface is properly level. In general this is not the case. The surface is irregular or can even be out of plumb. It is therefore necessary to first apply a so-called bilge on this surface, so that a new surface is formed via a relatively thin layer, which is accurately leveled. Before the construction can proceed, it is necessary that this bilge is properly cured. With the techniques currently used, it is often necessary that a long drying time must first be observed before proceeding. Such a drying time usually amounts to more than twelve hours. In addition, 20 specific skilled workers are necessary, so that a higher cost is involved in the application of a bilge and a relatively large loss of time can occur.

Furthermore, it will be clear that it is often necessary in construction to make a curb, for instance a ledge, a sill or the like. Specific professional knowledge is also necessary for applying such bilge, which often leads to delays due to logistical problems.

The object of the present invention is to provide a new type of bilge, which can be applied relatively simply and without great knowledge in any relatively short time, while construction can continue after a likewise relatively short time.

The present invention is based on the insight that if a relatively thin liquid formulation is used for applying a bilge in combination with a mold which is relatively easy to apply, by pouring the bilge formulation into this mold automatically a smooth and level top surface from the bilge is obtained without the fact that relatively complicated techniques are further required. Due to the further choice of the composition of the formulation, depending in particular on weather conditions (temperature), if desired, the short curing time can be determined relatively easily and often set to one hour and less. Because the bilge is no longer removed from the surface, the mold should preferably be very simple. In fact, only the mold is intended to be a construction that determines the location of the mold and, in particular, allows the necessary bilge height.

These objectives are achieved with a bilge formulation according to the invention based on a liquid, curable plastic composition. In principle, both thermosetting and thermoplastic plastic preparations can be used. The only requirement is that the plastic preparation is sufficiently liquid when poured into the bilge mold and can subsequently be cured or hardened in a relatively short time, preferably adjustable.

If the bilge formulation preferably contains a thermosetting plastic preparation, in principle the bilge formulation can consist entirely of the thermoset plastic. However, it is economically advantageous that if the properties of the bilge formulation are substantially not adversely affected, to replace part of the plastic with a filler. An amount of filler is possible until the properties of the bilge are adversely affected. It will be understood that the thermosetting plastic composition must also contain an initiator to initiate the curing reaction. It is further preferred if the thermosetting plastic composition also contains a viscosity control agent. In particular, a viscosity control agent may be desirable if the amount of filler is relatively high, and, for example, if the processing temperature is relatively low. In part, the viscosity control agent can be replaced by an unsaturated compound to be used in the curing reaction, which participates in the curing reaction, such as styrene.

If the synthetic resin is dilutable with water, the resin or filler can also be partly replaced by water. It will also be clear that in that case the amount of viscosity regulating agent can also be adjusted. Furthermore, it may be preferred if the thermosetting plastic composition also contains a stabilizer or dispersant. Such a stabilizer ensures that all components are stabilized in the composition between delivery of the formulation and use and in fact form a sufficiently homogeneous mass.

A kim formulation according to the invention which provides satisfactory results contains 5-99.9 wt% synthetic resin, 0-80 wt% filler, 0.1-5 wt% initiator, 0-10 wt% viscosity control agent, 0 -20 wt% water, and 0-10 wt% stabilizer.

It will be clear that for an economically attractive thermosetting plastic preparation it is good to increase the amount of filler. The amount of filler may be between 50-80 wt%, preferably 60-80 wt%, and more preferably between 60-70 wt%.

35 The amount of synthetic resin may correspondingly decrease.

If the synthetic resin is dilutable with water, the amount of synthetic resin is preferably 5-40 wt%, more preferably 10-30 wt%, and more preferably 10-20 wt%. The amount of water 1011167 is correspondingly large and is 5-40% by weight, preferably 10-30% by weight and more preferably 10-20% by weight. Different types of thermosetting synthetic resins are possible. For example, polyester resins 5 can be used, for example resins based on orthophthalic acid, isophthalic acid, isophthalic acid and neo-pentylglycol, vinyl ester, dicyclopendadiene, and HET-acid (hexachloro-endomethylene-tetrahydrophthalic acid). Preferably, however, a polyester resin, ie unsaturated polyester resin, is used as the thermosetting plastic. In particular, the orthophthalic resin based on maleic anhydride and phthalic anhydride with propylene glycol can be used. An iso resin can also be used, in which case the phthalic anhydride is replaced by isophthalic acid. Neopentyl glycol can also be used instead of the propylene glycol. Furthermore, a bisphenol resin can be used, in which case the glycol has been replaced by bisphenol A. If the bil must have flexible properties, it can be advantageous to use as adipic acid and sebacic acid as acid.

The thermosetting plastic will also have to contain a reactive monomer in order to realize the cross-linking between the polymeric molecules. In the case of polyester resins, the reactive monomer may be styrene, methyl methacrylate or further alphamethyl styrene. As mentioned above, the reactive monomer will not only serve to achieve cross-linking between the different polymer molecules, but will also act as a viscosity reducing agent.

It is also important that the reaction takes place at the ambient temperature and that no reaction has taken place before. It is therefore desirable that a retardant is included in the plastic resin preparation which avoids reaction having already taken place for the preparation of the formulation to be cured. A suitable retarder is para-tertiary butyl catechol.

1011167 5

For the reaction to proceed it is important that an initiator or hardener is added. The initiators are often based on peroxides for the radical polymerizations. In particular, methyl ethyl ketone peroxide and benzoyl peroxide can be used.

In order to allow the synthetic resin to gel and to cure at the processing temperature, it is preferable to also add an accelerator to the initiator. Many accelerators are based on either cobalt or amines. Examples are cobalt octoate and dimethylaniline. The dosages can be selected such that gelling and curing take place at the processing temperature in relatively short times. However, it will be clear to the skilled person that, based on existing tables and on-site reactions to be carried out relatively quickly, he can determine the desired amounts of the synthetic resin, the initiator and the accelerator.

According to another variant of the invention, the liquid curable bilge formulation is based on a thermoplastic resin. A thermoplastic resin is a resin which in appearance can present itself as liquid, rubber and solid. This depends on the temperature. By a correct choice of the thermoplastic it is possible to process it at a temperature above the ambient temperature in a liquid and curable state, while after application and at ambient temperature the thermoplastic resin changes into a relatively hard, solid mass. Examples of a useful thermoplastic plastic are polyvinyl chloride, polyethylene, polypropylene and copolymers.

The thermoplastic plastic formulation generally contains 5-100 wt% resin, more preferably 10-50 wt%, and most preferably 10-40 wt% resin. The filler generally bears 0-95 wt%, more preferably 90-50 wt%, such as 90-60 wt%. Furthermore, any desired conventional additive 1011167 6 can be added to this formulation, as long as the properties of the bilge are not affected. In addition, mixtures of thermosets and thermoplastics are possible, such as a thermoplastic in combination with recycled polyester.

It will be clear that other additives can be added to the plastic preparation in order to provide certain properties to the bilge. If it is desired that the flame-retardant quality of the bilge improve, it is preferable to add the flame-retardant additive to be added, such as chloroparaffin or antimony trioxide. If fire retardant properties are desired, it may be advantageous to add aluminum trihydrate to the composition.

Finally, with regard to the plastic, it can be reported that this plastic can, in particular for the thermosetting plastic, be based on cylicates, quartz sand and filter sand, but plastic particles or plastic parts can also be added. Plastic particles can originate from the sawing operations of such cured plastic. However, the plastic parts can be inserts. That is to say strips of already cured plastic which merely serve to reduce the volume in the mold in which the bilge is formed. It will be clear that both thermosetting and thermoplastic plastic preparations can be used here. If necessary, operations may be performed to improve adhesion to these fillers or inlays.

Another aspect of the present invention relates to the device for manufacturing a bilge on a substrate. This device comprises a mold which is formed by two spaced-apart frame parts, two mold elements determining a mold edge, and a sheet to be applied over the mold elements determining the shape of the bilge. In particular, the device is thus formed by two spaced apart frame parts. Mold elements are arranged between these two frame parts, which in fact define an upper edge of the mold 1011167. A sheet is placed between these mold elements and over these mold elements, in effect creating a trough which determines the space in which the bilge formulation must be poured and in which the bilge formulation hardens. It will be clear that if this bilge formulation is sufficiently liquid over the entire length of the bilge, that is to say between the two frame parts, the surface will automatically level and a surface will be obtained that is almost exactly horizontal. According to a first exemplary embodiment, the mold elements can consist of mold cables which are tensioned between the two frame parts. The cables are brought to such a tension that they do not substantially sag along the length between the two frame parts. Distances can be reached that are in practice between 5 and 35 meters. Instead of these cable-shaped mold elements, it is also possible to use rods or strips which extend between the two frame parts 20.

If desired, it may be necessary to properly position the mold elements at the right height and to achieve sufficient leveling. In that case it is preferred that the device comprises means 25 for raising the height of the mold elements.

In fact, any type of flexible sheet can be used to form the mold cavity of the mold. The sheet should be of such a nature that its loss does not significantly increase the cost. Preferably, a plastic sheet is used, and in particular a plastic sheet that is water- or moisture-proof. It is thus realized that a moisture-proof partition is realized between the substrate and the bilge and thus also with respect to the wall that is placed on the bilge. Finally, the present invention relates to a method of manufacturing such a bilge. This method includes the steps for the 1011167 δ i. forming a mold on the substrate by forming a mold from a sheet; ii. pouring the liquid curable formulation into the mold; and 5 iii. curing of the bilge formulation to form the bilge on the substrate.

Mentioned and other features of the bilge formulation, and the method and apparatus for the manufacture thereof, will be further elucidated hereinbelow on the basis of a number of exemplary embodiments which are only given by way of example without the invention being considered to be limited thereto.

Figure 1 shows a floor 2 built up from floor parts 1, which has an irregular surface. Before applying a bilge 3 (see figure 4), a frame part 4 and 5 are fixed on two floor parts by means of bolts 6. Two mold elements are tensioned between the two frame parts. These mold elements consist of mold cables 7 and 8. Subsequently, a waterproof foil 9 is draped over these mold cables 7, 20 and 8, the side walls of the foil 9 being passed over the mold cables 7 and 8.

Figure 2 shows in more detail the frame part 5 which is fastened to a floor part 1 with the bolts 6. The frame part 5 has essentially an angled shape. The upright edge 10 is provided with slots 11 through which the cables 7 and 8 pass. By using several slots 11 it is possible to manufacture a bilge of different widths with the same frame parts. The cables 7 and 8 are attached to cable tensioners 12 which in turn are attached to stub 13. The cables 7 and 8 are further guided over spindle 15 adjustable with a wing nut 14, so that the height relative to the floor part 1 is adjustable.

Figure 3 shows in more detail the spindle 15, or wing nut 14 in the case of the frame part 4. The frame part 4 has the same construction as the frame part 5, so that in this case too there are two 1011167 i 9 cable stubs 16, around which the cables 7 and 8 are confirmed.

As clearly shown in figure 3, the foil 9 with its foil edges 17, which are passed over the cables 7 and 8, forms a mold cavity 18. Into this mold cavity 18, the liquid and curable kim formulation can be poured. The amount of formulation poured in fact determines the height of the bilge. The top surface 19 of the cast and hardened bilge 3 is smooth and level. In order to prevent the film edges 17 from coming off during pouring, or due to wind and insufficient formation of the mold cavity 18, it is preferable to use a film whose edges 17 stick again to the upright edges 15 by adhesion. 20 of the foil located between the cables 7 and 8.

According to a first formulation, the liquid curable kim formulation based on polyester comprises 26% polyester / dicyclopentadiene, 5-10% styrene as monomer and viscosity adjusting agent, 1-3% benzoyl peroxide, 1.5-2.5% dimethylaniline, 27% quartz flour, 37% filter sand (0.5-1.0mm), and 1-2% dispersant.

The amounts of styrene, benzyperoxide and dimethylaniline are mutually selected such that the bil formulation can be used at 30 ambient temperatures ranging from -10 to + 30 ° C, generally from -5 to 20 ° C.

In a second recipe, a water-dilutable polyester resin is used. In this case, the recipe contains 15 15% polyester resin, 11% water, 5-10% styrene, 1.5-2.5% dimethylaniline, 1011167 10 1.1-3% benzyl peroxide, 37% quartz flour, and 37% filter sand (0, 5-1, Otran).

In this preparation, the amount of resin 5 can be further reduced by the amount of water.

Finally, figure 5 shows a variant of the frame parts 4 and 5 described above. In this case use is made of a frame part 21, which is only provided with one cable tensioner 22 and one cable 7 which is wrapped around the frame part 4 and only acts on one cable stop 23.

Furthermore, it will be appreciated that the mold cable may have been replaced by mold bars, uprights, and the like, as long as they form a support member around which the film can be wrapped with its film edge to form the mold cavity for the liquid curable bilge formulation.

1011167

Claims (15)

A liquid, curable, formulation containing a liquid, curable plastic composition. Kim formulation according to claim 1, wherein the plastic preparation comprises a curing plastic preparation. Kim formulation according to claim 2, wherein the thermosetting plastic composition contains 5-99.9 wt% synthetic resin, 0-80 wt% filler, 0.1-5 wt% initiator, 0-10 wt% viscosity control agent, 0 -20 wt% water, and 0-10 wt% stabilizer. Kim formulation according to claim 3, containing 20-50%, preferably 20-40%, more preferably 22-30% by weight synthetic resin, and 50-80% by weight, preferably 60-80% by weight, more preferably 60-70 wt% filler. Kim formulation according to claim 3, containing 5-40 wt% synthetic resin, preferably 10-30 wt%, more preferably 10-20 wt% synthetic resin, and 5-40 wt% water, preferably 10- 30 wt%, more preferably 10-20 wt% water. Kim formulation according to claims 1-5, comprising a thermoplastic plastic preparation. Kim formulation according to claim 6, wherein the thermoplastic plastic composition contains 5-100 wt% synthetic resin, and 0-95 wt% filler, Kim formulation according to claim 7, containing 10-50 wt% synthetic resin, preferably 10-40 wt% synthetic resin, and 90-50 wt% filler, preferably 90-60 wt% filler. 1011167 ft Kim formulation according to claims 3-7, wherein the filler comprises silicate, quartz sand, filter sand, plastic particles or plastic parts. 10. Apparatus for manufacturing a bilge with a liquid curable bilge formulation comprising a mold formed by two spaced frame members, two mold edge defining mold elements, and a sheet to be applied over the mold elements. 11. Device as claimed in claim 10, wherein the mold elements comprise a mold cable and the frame parts are provided with tensioning means for tensioning the mold cable. 12. Device as claimed in claim 10, wherein the mold elements comprise a mold rod extending between the two frame parts. Device as claimed in claims 10-12, comprising means for raising the height of the mold elements. The device of claims 1-13, wherein the sheet to be applied over the mold elements is a waterproof sheet, such as a plastic film. 15. Method for manufacturing a bilge on a substrate with a preparation according to claim 1, comprising the steps of: i. forming a mold on the substrate by forming a mold from a sheet, · 11. pouring the liquid, curable formulation into the mold; and 30 iii. curing of the bilge formulation to form the bilge on the substrate. 1011167