FR2710359A1 - Vertical wall comprising in itself its decorative appearance and method for making same - Google Patents

Abstract

The invention relates to a vertical wall which may or may not be loadbearing and comprises in itself its decorative appearance and includes an auxiliary support fastened to a framework, which may or may not be loadbearing, which auxiliary support is intended to be covered with a mortar, mixed with water, sprayed mechanically by a wet method in 2 or more successive coats (generally approximately 1 to 4 cm thick), wet on wet.

Description

Vertical wall having in itself its appearance
decorative and method for its realization.

The invention relates to a vertical wall whose outer part (hereinafter referred to as "external wall element") contributes to obtaining the mechanical characteristics required of it and also gives it its decorative function. The invention also relates to a method of producing this wall.

One of the major concerns of builders of everyday structures, mainly those intended for homes, school and hospital buildings and office buildings, under normal conditions of use, lies both in the speed of execution of these structures and the level of mechanical and aesthetic characteristics that these structures must possess.

For this purpose, the applicant is particularly interested in the construction of the vertical walls of these structures, for which it has sought how to quickly and easily perform all types of simple or composite walls, carriers or not.

Several conventional wall construction techniques are currently well known, for example - masonry of small elements or concrete walls
banché, - structures with a wood or metal frame whose
walls consist either of prefabricated elements in
concrete, fiber cement, plywood, etc., or concrete
projected on an auxiliary support, for example of the type
metal lath.

Compared to these techniques which in most cases require the application of finishing products on the wall, such as traditional coatings or monolayer coatings, it has appeared necessary to simplify and accelerate the production of vertical walls by avoiding the constraints related to the multiplication of techniques and materials used.

A main object of the invention is thus a technique for producing a wall, which may or may not be a carrier, which is simple and fast, this wall having a decorative appearance and also having sufficient mechanical strengths, mainly tensile strengths. (going with low modulus of elasticity), as well as compressive strengths and shocks.

In accordance with the invention, these goals are achieved through the combination of the following features - a vertical wall, bearing or non-carrying, comprising a
auxiliary support attached to a frame, carrier or
no, this auxiliary support being intended to receive a
Mortar, tempered with water, mechanically sprayed
wet, in 2 or more successive passes
(usually about 1 to 4 cm thick),
on a fee basis, - a projected mortar constituting the external element of
said vertical wall, the thickness of this element being
adapted to the mechanical characteristics required of such
so that, in most cases, it is not
less than 4 cm, - the same and unique mortar composition, in the case of
these main components, used to achieve
the external wall element, - the external wall element which participates in the
mechanical characteristics of the wall, and presents a
decorative surface appearance, once made on
dressage and decorative finishing, either directly by
operations of the type scraping or float, either by
additional projection of this same mortar for
to obtain a gross projection, rusticated or
other.

In the present invention, the following expressions are to be understood as follows - by "mechanical projection in successive cool passes
on expenses "it is necessary to understand that one observes a time
waiting between passes allowing a firming
enough mortar to support the pass
next without slipping or falling.

- by "vertical wall element", it must be understood that
the wall element is parallel to the direction of the wire to
lead or close to this verticality as is often
the case in the building.

- "auxiliary support" means a support whose
main function is to receive the mortar projected,
the mechanical strengths of the support not being
preponderant in the mechanical strengths of
the outer wall element. The auxiliary support is,
for example, made by means of insulating panels or
perforated metal panels such as, for example, a metal
deployed with adequate features or trellis,
possibly welded, with or without cardboard.

Remarkably, the choice of the technique of construction of the wall combined with the particular characteristics of the external wall element result in a simple realization of walls, carriers or not, which, although the outer element made by projection is of thin (of the order of 4 cm or greater), both the mechanical requirements and aesthetic requirements sought for this wall.

 It is important to note that, in the case of construction of standard structures, mainly those intended for dwellings, school and hospital buildings and office buildings, for normal conditions of use, the thickness of the outer wall element of the invention must be at least 4 cm.

According to a preferred variant of the invention, the mortar used to produce the external wall element is a mortar powder and ready to wet, based on silicic hydraulic binder, which comprises as main components (in% by dry weight of the composition before mixing with water):
at least one silicic hydraulic binder, preferably
at a rate of 10 to 25% inclusive
. at least one compound to compensate for the initial withdrawal
mortar after application;
. calcareous fillers in quantities not exceeding 20%
and at least enough to complete the rate
fine elements (hydraulic binders included) at 30%
minimum
. various main components, whose presence
allows to obtain the rheological characteristics
sought after, in particular good adhesion to the
auxiliary support as well as cohesion between
granular components, and can influence the speed
hydration of hydraulic binders and level
required waterproofing, among which
find
* one or more mineral lamellar products
who play the role of thixotropy regulators
mortar pastes, to be dosed in total quantity
less than or equal to 5% but greater or
equal to 0,5% (% of the total weight of
dry mortar before mixing)
* one or more organic components
synthetic or natural, soluble or swelling
to water in a strongly alkaline medium, playing a
complementary role of thixotropy regulator
and having a facilitating glue function
the initial adhesion on the supports as well as
the cohesion of the granular part of the pasta of
mortar
in a quantity complementary to 100%, aggregates
siliceous, calcareous, silico-calcareous or mixtures of
these various types of aggregates whose granulometry can
reach 5 mm and preferably does not exceed 4 mm.

Preferably, the amount of aggregates is at least equal to 55% by dry weight of the composition of the mortar before mixing because below this value, it is practically impossible to achieve the desired mechanical characteristics without then calling for high proportions. expensive compounds such as synthetic resins or large amounts of cement.

By way of example of mineral lamellar products which may be suitable for the preparation of the mortar of the invention, mention may be made of fillers derived from micaceous rocks, expanded or non-expanded vermiculite, talc, or mixtures of these products. in varying proportions.

By way of example of synthetic or natural organic components, soluble or swelling with water in an alkaline medium which may be suitable for the preparation of the mortar of the invention, mention may be made of: cellulose ethers, polyvinyl alcohols, synthetic resins redispersible with water, gelatines ... or mixtures of some of them in variable proportions. It is preferred to use a cellulose ether and / or gelatin in proportions not exceeding 0.2% (inclusive) in total because they lead to the most interesting rheological characteristics and provide better adhesion to the auxiliary support.

Advantageously, the compound to compensate for the initial shrinkage of the mortar after its application is quicklime resulting from the calcination of calcium carbonates or mixed carbonates of calcium and magnesium, and preferentially still, quicklime resulting from the calcination of these in an amount not exceeding 10% (inclusive) of magnesium oxide in the total composition of the product.

Of course, the mortar of the invention may contain, in addition to the above-mentioned main components, other components, hereinafter referred to as "accessory components", such as, optionally, water-proofing substances,
preferably solid salts soluble in water of acids
saturated or unsaturated fats such as, for example, oleate
sodium or potassium stearate, or their mixture, in
amount ranging from 0 to 0.2% (inclusive).

optionally, a catalyst for hydrating the binders
hydraulic silicas such as calcium chloride
and / or sodium chloride. The quantities of
added catalysts must match
- not more than 0.15% (inclusive) of chloride ion per
in relation to the quantity of the hydraulic binder in the
where the auxiliary support and / or the frame
may be incorporated into the mortar
includes (s) steel elements and,
- not more than 0.30% (inclusive) of chloride ion in the
where the auxiliary support and / or the reinforcement
does not have.

- possibly other current additions such as
water reducers to complete the action of the catalyst
hydration or short fibers (length of
preferably less than 12 mm), preferably
synthetic materials, intended to improve the intrinsic
products put in place or pigments, preferably
mineral pigments, to ensure the coloration
desired.

As opposed to the main components of the mortar, the so-called accessory components may be present in all successive passes of mortar or only in some of them.

Under the conditions of the invention, the construction of the outer wall element is simple.

Indeed, to do this, it is sufficient to a) to mount a frame, carrier or not, for example in
concrete, of wood or metal; (b) to bring in and attach an auxiliary support (c) and then mechanically project the mortar
constitute the external element of the wall in the
conditions of the invention d) to set the mortar projected to make flat, but
not necessarily smooth, its surface e) finally to achieve the decorative finish be
directly on this surface by operations of the
type scraping or float, or by projection of a
extra pass of that same mortar to get a
gross projection, rustically leveled, etc., the
projection, dressage and finishing operations
mentioned above being executed according to the rules
known to those skilled in the art.

In addition, the mortar according to the invention offers the advantage of having sufficient tensile-flexural and compressive strengths to give the entire wall in combination with its other elements, mechanical characteristics meeting the requirements applicable in the construction to the different types of walls encountered.

In comparison with a concrete that can be used to build a wall, the mortar which constitutes one of the elements of the wall made according to the invention has a high deformability. Thus, the ratio of the tensile-flexural strength on the compressive strength (ie RT / RC), which is one of the indicators of this deformability, is actually higher in the case of the mortar according to the invention (of the order 1/3 to 1/4 against 1/5 to 1/8 for a conventional concrete).

Another indicator of the high deformability of the mortar of the invention lies in the values of elongation at break that it can reach (up to 300 microns per meter against values generally below 200 microns per meter for a conventional concrete) .

Due to the high deformability of the mortar of the invention, the probability of cracking of the walls made according to the invention, because of accidental shocks and arising from human activities, normally practiced or withdrawal phenomena, is thus reduced.

Another important characteristic of the invention lies in the fact that it uses mortar construction and application techniques which allow a significant shortening of the construction time of construction as indicated by way of example in the table below. .

<Tb>

<SEP> Time limit
<tb><SEP> of
<tb> realizes <SEP> Achievements <SEP> of <SEP> walls <SEP> decorated <SEP> of <SEP> same <SEP> dimension
<tb><SEP> sation <SEP> (individual <SEP> house <SEP> of <SEP> 100 <SEP> to <SEP> 120 <SEP> m2 <SEP> of <SEP> outer <SEP> walls)
<tb><SEP> in
<tb> weeks
<tb><SEP> In <SEP> Block <SEP> According to
<tb><SEP> Finishing <SEP> 2 <SEP> or <SEP> 3 <SEP> Finishing <SEP> the invention
<tb><SEP> layers <SEP> DTU <SEP> 26/1 <SEP> monolayer
<tb><SEP> 0 <SEP> --------------------------------- <SEP> ---- ------------------ <SEP>
<tb><SEP> a) <SEP> Editing <SEP> in <SEP> blocks <SEP> of <SEP> a) <SEP> Assembling <SEP> of framing
<tb><SEP> exterior <SEP> walls. <SEP> with <SEP> chaining <SEP> and
<tb><SEP> b) <SEP> Laying <SEP> of reinforcement <SEP> and <SEP> concreting <SEP> support
<tb><SEP><SEP> Chains <SEP> Auxiliary <SEP>: <SEP> 4 <SEP> days
<tb><SEP> a) <SEP> + <SEP> b) = <SEP> 3 <SEP> days
<tb><SEP> 1 ------------------------------------
<tb><SEP> b) <SEP> setting <SEP> out <SEP> of water
<tb><SEP> c) <SEP> Setting <SEP> out <SEP> of water <SEP>: <SEP> 14 <SEP> days <SEP> 14days
<tb><SEP> 2
<tb><SEP> delay
<tb><SEP> waiting <SEP> c) <SEP> projecting <SEP> from
<tb><SEP> legal <SEP>: <SEP> 30 <SEP> days <SEP> to <SEP> count <SEP> mortar <SEP>: <SEP> 2 <SEP> days
<tb><SEP> of <SEP> step <SEP> (b)
<tb><SEP> 3
<tb><SEP> 4
<tb><SEP> d) <SEP> end <SEP> of the <SEP><SEP> wait time <SEP> legal
<tb><SEP> before <SEP><SEP> application of <SEP> the coating
<tb><SEP> Coated <SEP> in <SEP> 2 <SEP> MONOLAYER
<tb><SEP> or <SEP> 3 <SEP> layers
<tb><SEP> 6 <SEP> to <SEP> 9 <SEP> days <SEP> 1 <SEP> day
<tb><SEP> 5 <SEP> --------------------------------- <SEP> ---- ------------------- <SEP>
<tb><SEP> Time <SEP> total <SEP> of <SEP> Timeout <SEP> total <SEP> of <SEP> Timeout <SEP> total
<tb><SEP> Achievement <SEP>: <SEP> Achievement <SEP> of <SEP> Achievement
<tb><SEP> between <SEP> 39 <SEP> and <SEP> 34 <SEP> days <SEP> 20 <SEP> days
<tb><SEP> 42 <SEP> days
<Tb>
The present invention relates, finally, to the use of the wall construction technique according to the invention for the construction of decorated walls, simple or composite, carriers or not, of current structures, mainly those already mentioned in the present application . Said simple or composite walls may be of the type provided for in the unified technical document n020.1 of September 1985, the walls and masonry walls of small elements then being replaced by the wall of the invention.

Other advantages and features of the present invention will appear on reading the following description and non-limiting examples given.

In particular, Example 1 demonstrates a particularly high wall impact strength of up to 1300 joules (under the conditions of the French standard P08302 of October 1990).

Examples 2 and 3 show how it is possible to realize simply either a wall constituting a double wall provided with an insulator, or a wall replacing a wall reinforced concrete reinforced and decorated with a coating.

The mortars used in Examples 1 to 3 and their characteristics are respectively reported in Tables 1 and 2 below.

TABLE 1
Example of mortar compositions

<tb> SEP Reference <SEP> M <SEP> O <SEP> R <SEP> T <SEP> I <SEP> E <SEP> R <SEP> S
<tb> mortars
<tb> specified <SEP> in <SEP> the <SEP> text <SEP> I <SEP> II <SEP>
<tb> Components <SEP> a <SEP> b <SEP> c
<tb><SEP> kg <SEP> kg <SEP> kg <SEP> kg
<tb> 1. <SEP><SEP> siliceous sands> and / or
<tb><SEP> Limestones <SEP> of <SEP> 2050 <SEP> 2050 <SEP> 2050 <SEP> 2000
<tb><SEP> granulometry
<tb><SEP> nominal <SEP> of <SEP> O <SEP> to
<tb><SEP> 4 <SEP> mm
<tb> 2. <SEP> Cement <SEP> of the <SEP> type
<tb><SEP> CPA <SEP> 55
<tb> 2a <SEP> white <SEP> 550 <SEP> 550 <SEP> - <SEP> 720
<tb> 2b <SEP> gray <SEP> - <SEP> - <SEP> 550 <SEP>
<tb> 3. <SEP> Filler <SEP> Limestone <SEP> 500 <SEP> 500 <SEP> 500 <SEP> 270
<tb> 4. <SEP> Lime <SEP> fast <SEP> 100 <SEP> 100 <SEP> 100 <SEP> 60
<tb><SEP> magnesian
<tb> 5. <SEP> Components
<tb><SEP> lamellar <SEP>
<tb> 5a <SEP> Talc <SEP> from <SEP> Luzenac <SEP> 60 <SEP> 60 <SEP> 60 <SEP>
<tb> 5b <SEP> Vermiculite
<tb><SEP> expanded <SEP> ss <SEP> 2mm <SEP> - <SEP> - <SEP> - <SEP> 30
<tb> 6. <SEP> Ether <SEP> Cellulose <SEP> from
<tb><SEP> viscosity <SEP> nominal <SEP> 1.5 <SEP> 1.5 <SEP> 1.5 <SEP> 1.5
<tb><SEP> of <SEP> the <SEP> order of <SEP> 105
<tb><SEP> mPa.sec.
<Tb>

7. <SEP> Natural <SEP> glue
<tb><SEP> Protein <SEP> 1.5 <SEP> 1.5 <SEP> 1.5 <SEP> 1.5
<tb><SEP> (gelatin)
<tb> 8. <SEP> Waterproofing <SEP> 2 <SEP> 2 <SEP> 0 <SEP> ~ <SEP><SEP> 2
<tb> 9. <SEP> Accelerator <SEP> of
<tb><SEP> Hydration <SEP> of <SEP> 1 <SEP> 1 <SEP> 1 <SEP>
<tb><SEP> cement
<tb> 10. <SEP> Organic <SEP> Fibers
<tb><SEP> synthetic <SEP> 2 <SEP> - <SEP> 2 <SEP>
<tb> Weight <SEP> totals <SEP> of
<tb> compositions <SEP> in <SEP> kg <SEP> 3268 <SEP> 3266 <SEP> 3266 <SEP> 3085
<tb> * The indicated grain size does not exclude the upper grain size limits above 4 mm.

TABLE 2
Characteristics of the mortars of Table l

<tb><SEP><SEP> Reference <SEP> mortars <SEP> I <SEP> II <SEP>
<tb> Index <SEP> or <SEP> quality
<tb> Rate <SEP> of <SEP> tempering, <SEP>% <SEP> 17.5 <SEP> - <SEP> 18 <SEP> 16.5 <SEP> - <SEP> 17
<tb> weight
<tb> Final <SEP> Densities <SEP> 1.72 <SEP> - <SEP> 1.77 <SEP> 1.85 <SEP> - <SEP> 1.9
<tb><SEP> products <SEP> applied
<tb> after <SEP> 28 <SEP> days <SEP> (according to <SEP> NFB
<tb> 10-511)
<tb> Resistors <SEP> to <SEP><SEP> tens- <SEP> 40 <SEP> - <SEP> 45 <SEP> 43 <SEP> - <SEP> 47
<tb> flexion, <SEP> in <SEP> dN / cm2 <SEP> (Rtf)
<tb> (according to <SEP><SEP> standards
<tb> EN <SEP> 196-1 <SEP> and <SEP> NF <SEP> P15-471)
<tb> Resistors <SEP> to <SEP><SEP> 140 <SEP> - <SEP> 150 <SEP> 175 <SEP> - <SEP> 185
<tb> compression, <SEP> in <SEP> dN / cm2 <SEP> (Rc)
<tb> (according to <SEP> EN <SEP> 196-1)
<tb> Modules <SEP> of elasticity <SEP> 125 <SEP> - <SEP> 135 <SEP> 150 <SEP> - <SEP> 170
<tb> dynamic, <SEP> according to <SEP> NF <SEP> B <SEP> 10
<tb> 511,
<tb> in <SEP> dN / cm2 <SEP> x <SEP> 103
<tb> Lengthening <SEP> relative <SEP> before <SEP> 320 <SEP> 280
<tb> break, <SEP> in <SEP> ssm <SEP> by <SEP> meter,
<tb> of <SEP> the <SEP> order of
<tb><SEP> Index of <SEP> Deformability <SEP> 3.3 <SEP> - <SEP> 3.5 <SEP> 3.9 <SEP> - <SEP> 4.1
<tb> Rc <SEP> / <SEP> Rtf <SEP> *
<tb> * Values for building concretes are in the range of 5 - 8.

EXAMPLE 1
A vertical supporting structure was made using I-shaped metal profiles 80 mm, 2.60 m high and spaced from each other by 1.20 m.

35 mm T-shaped metal studs were placed vertically equidistant from the previous ones, all of the uprights being fixed in a concrete base. Chaining is carried out with 80 mm I-channels, thus linking the different vertical uprights.

This structure, which has a surface area of 4 x 2.60 m2, has been equipped with an auxiliary support consisting of expanded metal panels with the special NERGALTO exterior designation, nailed to the posts and chaining; the different panels overlap and are stapled to each other every 30 cm.

On this auxiliary support thus prepared, a pass of the mortar I, variant a (see Table 1) tempered at the rate of 18% water was sprayed mechanically (thickness 3.5 + 0.5 cm) and raised summarily. This pass was then covered, after 3 hours, another pass of the mortar I, variant b (see Table 1), well adjusted and smoothed.

The final thickness of the mortar, measured during the dismantling of the model after the tests have been carried out, is 6 cm + 0.5 cm.

Three weeks after its manufacture, the model was subjected to several tests of soft body shocks (50 kg) according to the standard NF PO8-302 of October 1990, in this case shocks of 400, 900 and 1300 Joules, the point of impact being always the same and located in the center of the model.

Shocks of 1300 Joules were repeated, in series or alone, 18 times, without destruction or cracking.

The characteristics of the mortar I, variants a and b, are shown in Table 2.

EXAMPLE 2
A vertical wooden supporting structure was made from 8 x 6 cm rafters, 1.2 m apart and 2.60 m high, all fixed to the ground on a concrete footing. Chaining is achieved by means of the same rafters.

This structure, 7 m long and 1 m wide with 2 openings (windows), corresponds bilaterally to a wall surface of 40 m2.

On this structure, were fixed by nailing on the longitudinal edges, expanded polystyrene panels of 2.5 m × 1.2 m and 6 cm thick.

On the auxiliary support thus prepared, was projected a mortar I, variant c (see Tables 1 and 2), of thickness 1 to 1.5 cm, raised summarily. After sufficient consolidation of this first pass (between 1 h and 2 hours at 200C), it was covered with a second pass of about 2 cm of the mortar I, variant c. In this last pass, was drowned a galvanized metal grid (wire diameter 0.6 mm, mesh 1 × 1 cm), the different strips of the grid overlapping and being stapled to each other. This same grid served to reinforce the edges of the openings.

The screen pass was then covered with a mortar pass I, variant c, carefully adjusted.

Finally, the next day, the surface was finished by applying a mortar pass I, variant b, approximately 1.5 cm thick, adjusted and smoothed, then scraped 3 hours after smoothing. The appearance of the surface of the wall thus prepared is, in aesthetic terms, quite satisfactory.

The total thickness of mortar applied is 6.5 + 0.5 cm.

After 6 months of observation, no cracking appeared, the behavior of this wall is therefore satisfactory. In addition, the mechanical characteristics of this wall are satisfactory.

EXAMPLE 3
A vertical structure was made using 25 mm T-shaped metal sections, 60 cm apart and fixed in a concrete footing; the soles of the profiles were oriented towards the outside of the wall.

A grid to arm the concrete (ribbed iron diameter 6 mm, mesh 10 x 10 cm) was fixed continuously, by spot welding, on the wings of the uprights. The covering width of the panels of this grid corresponds to a mesh; the soldering points were made every 30 cm approximately. Expanded metal grid, lattice
Galto 018, was stapled on the sole side of the uprights (with a 5 cm overlap between the strips) and on the concrete grid, in such a way as to create a corrugation of the metal batten in the plane of the future wall.

Chaining is achieved by welding strips 30 cm from the same grid to arm the concrete on the soles of the uprights.

Mortar II (see Tables I and II) was mechanically sprayed on the Galto lath in a first pass of thickness of 1 to 2 cm, remaining rough projection so as to create a rigid membrane, support for subsequent bilateral applications .

After sufficient firming, bilateral applications of the mortar II, in successive passes, were performed until a total thickness of 6.5 to 7.5 cm, the mortar being summarily adjusted on each side.

A last operation was to apply the mortar Il - on the outside, in a pass of about 1.5 cm set and reduced by scraping to a thickness of 10 to 12 mm.

- on the inner side, in a pass of 1 cm, carefully adjusted and smoothed and then floated with the sponge trowel.

The total thickness of the wall obtained is 8.5 + 0.5 cm.

The appearance of the surface of the wall thus prepared is aesthetically quite satisfactory.

In addition, the mechanical characteristics of the mortar used to make this wall as well as those of the mortar used to make the wall of Example 2 (see Table II), associated with the elements of the structure of these walls, make it possible to respond largely to the usual requirements for walls made of masonry of small elements, reinforced reinforced concrete etc.

Claims (12)

 or others.  get a raw look of projection, rustic flush  by additional projection of this same mortar for  by operations of the type scraping or float, either  dressage and decorative finishing, either directly  a decorative surface appearance, once made on  mechanical characteristics of the wall, and presents  the outer wall element participates in the  the outer wall element,  of these main components, is used for real  - one and the same composition of mortar, with regard to  not less than 4 cm,  so that, in most cases, it does not  being adapted to the mechanical characteristics required  said vertical wall, the thickness of this element  - the sprayed mortar constitutes the external element of  ranging from 1 to 4 cm), fresh on fees,  several successive passes (usually thick  mechanically sprayed wet, in 2 or  being intended to receive a mortar, mixed with water,  a frame, carrier or not, this auxiliary support  this wall comprises an auxiliary support fixed on  than  1. Vertical wall, carrier or not, characterized in that 2. Wall according to claim 1, characterized in that  the mortar used to make the external element of  wall is a mortar powder and ready to wet,  silicic hydraulic binder base, which comprises  as the main components (in% by dry weight of the  composition before mixing with water)  at least one silicic hydraulic binder,  preferably from 10 to 25% inclusive;  at least one compound to compensate for the initial withdrawal  Mortar after application  . calcareous fillers in quantities not exceeding 20%  and at least enough to complete the rate  fine elements (hydraulic binders included) at 30%  minimum;  . various main components whose presence  allows to obtain the rheological characteristics  sought after, in particular good adhesion to the  auxiliary support as well as cohesion between  granular components and can influence the speed  hydration of hydraulic binders and level  required waterproofing, among which  find  * one or more mineral lamellar products  who play the role of thixotropy regulators  mortar pastes, to be dosed in total quantity  less than or equal to 5% but greater or  equal to 0,5% (% of the total weight of  dry mortar before mixing)  * one or more organic components  synthetic or natural, soluble or swelling  to water in a strongly alkaline medium, playing a  complementary role of thixotropy regulator  and having a facilitating glue function  the initial adhesion on the supports as well as  the cohesion of the granular part of the pasta of  mortar; in a quantity complementary to 100%, aggregates  siliceous, calcareous, silico-calcareous or mixtures of  these various types of aggregates whose granulometry can  reach 5 mm and preferably does not exceed 4 mm. 3. Wall according to claim 2, characterized in that  the mineral lamellar products are chosen from  fillers from micaceous rocks, vermiculite  expanded or not, talc, or mixtures of these  products in varying proportions. 4. Wall according to claim 2 or 3, characterized in  what synthetic organic components or  natural, soluble or swelling with water in medium  alkali are selected from cellulose ethers,  polyvinyl alcohols, synthetic resins  redispersible to water, gelatins or mixtures  some of them in varying proportions. 5. Wall according to claim 4, characterized in that  as organic, synthetic or  natural, soluble or swelling with water in medium  alkaline, a cellulose ether and / or  gelatin in proportions not exceeding 0.2%  (included) in total. Wall according to one of Claims 2 to 5,  characterized in that the compound to compensate for  initial removal of the mortar after its application is  preferably quicklime resulting from calcination  of calcium carbonates or mixed carbonates of  calcium and magnesium, and more preferably  still quicklime resulting from the calcination of these  last in quantities corresponding to not more than 10%  (included) magnesium oxide in the composition  total product. Wall according to one of Claims 2 to 6,  characterized in that the mortar contains  waterproofing substances, preferably salts  water soluble saturated fatty acids or  not like, for example, sodium oleate or  potassium stearate, or their mixture, in quantity  ranging from 0 to 0.2% (inclusive). Wall according to one of claims 2 to 7,  characterized in that the mortar contains a  hydration catalyst for hydraulic binders  silicones such as calcium chloride and / or  sodium chloride. 9. Wall according to one of claims 2 to 8,  characterized in that the mortar contains fibers  short. 10. Wall intended for dwellings, school buildings and  hospital and office buildings, for  normal conditions of use, according to one of the  Claims 1 to 9, characterized in that  the thickness of the outer wall element is at least  equal to 4 cm. 11. Method of constructing the wall defined in the  Claims 1 to 10, characterized in that  consists of  a) to mount a frame, carrier or not, for example  concrete, wood or metal;  (b) bring back and attach auxiliary support  c) then mechanically project the aforementioned mortar for  constitute the external element of the wall in the  conditions of the invention  d) to set the mortar projected to make plane, but  not necessarily smooth, its surface;  e) finally realize the decorative finish is  directly on this surface by operations of the  type scraping or float, or by projection  an extra pass of this same mortar for  get a rough, rustic look  slashed, etc., projection operations,  dressage and finishing mentioned above being performed  following the well-known rules of the man from  job. 12. Single or composite wall, whether or not carrying structures  currents mainly those intended for dwellings,  school and hospital buildings and buildings  offices, for normal conditions of use,  including the wall defined in one of the  Claims 1 to 10.