DE2525327A1 - PROCESS TO ACCELERATE THE HARVESTING AND IMPROVE THE FINAL STRENGTH OF CONCRETE AND PREFABRICATED WALL STRUCTURES - Google Patents

Description

Process to accelerate hardening and improve the ultimate strength of concrete and prefabricated masonry structures

The invention relates to a process for the production of concrete or prefabricated masonry structures, which is characterized in that 1. used as a cementitious material in such structures, a Portland cement containing eggs a Vinylidenchloridpolymerlatex in an amount sufficient to provide 5 to 20 wt.% To give latex solids based on the weight of the cementitious material; and 2. heated the uncured structure substantially uniformly to temperatures of 38 ° C to 121 ° C with less than 80 % relative humidity for a period of at least 4 hours.

The term "prefabricated masonry structures" is intended to mean any structures made of brick, Cement blocks or clay bricks. made using cement or a cement mortar as a binder will. Particularly useful prefabricated structural

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ren are the load-bearing outer brick walls, which consist of a single row of bricks, associated with the specified specific latex modified cement mortar. Usually they are Mortar joints in such structures 1/8 "to 5/8" thick.

The term "vinylidene chloride polymer latex" as used herein is used means any aqueous colloidal dispersion of an organic interpolymer, where the Interpolymer from 35 to 90 parts by weight of vinylidene chloride and from 65 to 10 parts by weight of at least one other interpolymerized material of the general formula

contains, wherein R is a hydrogen atom or the methyl group and X denotes -CN, halogen atoms with an atomic number of 9 to 35 or ester-forming groups, -COOY, in which Y is a primary Denotes an alkyl group or a secondary alkyl group, each of the aforementioned alkyl groups from 1 to 18 and including 18 carbon atoms.

Examples of water-insoluble vinylidene chloride polymers which are very effective as latex components and which are used in the superior latex modified concrete or portland cement mortar compositions of the invention can be used are those interpolymers listed in Table I below.

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TABLE I Vinylidene chloride interpolymer compositions

Monomeric organic components parts by weight

Vinylidene chloride 40 60 89 90

Vinyl chloride
g ethyl acrylate 60 40

to methyl methacrylate 10

oo 2-ethylhexyl acrylate

^ Acrylonitrile 11

50 88 50 52 70 75 75 75 40 35 20th 20th 20th 20th 40 7th 10 10 5 5 10 2 13th 5 5 252532

For the production of particularly strong latex-modified concrete or Portland cement mortar compositions according to the invention an interpolymer latex containing 75 parts by weight of interpolymerized vinylidene chloride and 20 parts by weight of interpolymerized vinylidene chloride is particularly favorable Vinyl chloride, 5 parts by weight of interpolymerized ethyl acrylate and 2 parts by weight of interpolymerized methyl methacrylate contains.

The present invention relates in particular to latex-modified Portland cement mortar compositions which contain on a volume basis calculated on the volume that is displaced when the components are immersed in water:

a) approximately 100 volumes of Portland cement,

b) between 200 and 10,000 volumes of a mineral aggregate,

c) between 40 and 170 volumes of water,

d) between 8 and 40 volumes of polymer solids of an aqueous dispersion of an organic interpolymer latex and

e) up to 160 volumes of a processing agent, which consists of a natural carbonate and contains the minerals calcite, dolomite and magnesite and can contain a continuous gradation from calcium carbonate to calcium magnesium carbonate to magnesium carbonate, the processing agent having an average particle size so that it passes through a 200 mesh US Standard Sieve Series with at least 50 % of the particulate processability agent passing through a 200 mesh screen.

The respective cement can be a hydraulic cement, Portland cement, natural or aluminous cement.

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The mineral aggregate used can be stone, coarse sand or gravel, pebbles or rubble, granite, carborundum, Aluminum oxide, emery, grainy corundum, pieces of marble, Slag or any other aggregate commonly used in cement mortars or concrete. The intended End use of the cement system can be used as a guide for selecting the preferred particle size of the cement system Serve aggregate material.

The method according to the invention can be carried out with any commonly used Portland cement mortar or concrete system.

It has also been found that the portland cement mortar or concrete systems described in the present application can be cured immediately after the addition of the polymeric latex modifier and that there is no need to control the rate of temperature rise. The temperatures used and the duration of treatment at such temperatures will depend somewhat on the cement system used. In any event, exposure to heat at temperatures in the range of 38 ° C to 121 ° C with a relative humidity of less than 80 % for a period of 4 hours is generally required, temperatures of 43 ° C to 99 ° C with Advantageously, temperatures of 60 ° C to 77 ° C and a relative humidity of less than 50 % are generally preferred.

The following examples illustrate the invention.

Example 1 Portland cement mortar systems

The following general recipe is used to make it

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used a number of custom cement mortar systems.

formulation Material kg (pounds)

Huron Type I Portland cement 42.6 (94)

Processability agent 22.7 (.50)

Masonsand 126.8 (280) containing interpolymer latex

50 % solids / 6 with a composition of 18.6 (41) if used

75 parts by weight of vinylidene chloride
20 parts by weight of vinyl chloride

5 parts by weight of ethyl acrylate

3 parts by weight of methyl methacrylate

0.4% by weight silicone as an antifoam agent

6% by weight nonionic surfactant

In all cases the sand and portland cement are first mixed well and then in those cases where the interpolymer latex is used, this is added. The entire mass is then placed in a conventional mortar mixer Mix with a shovel until a uniform consistency is obtained (approximately 4 to 5 minutes).

A series of tests are then carried out using individual parts of the above portland cement mortar composition as the mortar in the manufacture of individual brick pillars (7 bricks high). The mortar is hardened under different time and temperature conditions, and the masonry structures are tested for their flexural strength, which is determined by the absolute tensile modulus when bending with three-point load (ASTM test No. C-78-64). The brick used has an absorption of approximately 16 to 28 g Η ,, Ο / 193.5 cm (30 in ² ) as determined according to ASTM No. C67-62 method. The results obtained are shown in the following table. 509881/0776

Table II Flexural Strength of Masonry Structures

Curing conditions

Sample no.

Mortar modified with latex

Row I.

as comparison

Row II
as comparison
6th

7th
8th

Row III
according to the invention

10
11
12th

13th
14th

no no no no no

da da da

there there

there there

da da temperature time relative humidity ° C days %

ro ro ro

CMCMCM

1 1

28 1 1

28

1/6

(4 hours)

1/6 (4 hours)

1/6

(4 hours) 1/2

(12 hours)

1 28

30-50

100

30-50

30-50

30-50

30-50

100

30-50

30-50 30-50 30-50 30-50

30-50 30-50

Flexural strength kff / cm (psi)

1.4 £ 20) 1.4-2.1 (20-30) 3.5-6.3 (50-90) 4 ()

3.5-4.2 (50-60) ■
<3.5 (<50) -o
29.8 (425) ι (170-180) cn 11.9-12.6 (170-180) cn
co 11.9-12.6 (170-180) 11.9-12.6 (220-230) 15.4-16.1 21 (300)
^ 35 (<500)

From the above values it can be seen that it was not possible to work with the masonry structure made using the was not made with latex modified cement mortar (rows I), flexural strengths of at least 10.5 kg / cm (150 psi), a strength that is now considered in the industry as the minimum requirement for successful handling of prefabricated wall structures. Sample No. 2 (Series I) illustrates that the use of high humidity the hardening speed of the masonry structures, which from the portland cement mortar, which is not modified with latex, are produced, are somewhat accelerated.

The values given above in rows II of Table II explain that the hardening of masonry structures which contain cement mortar modified with latex, as required according to the invention, but when using temperatures below 43 ^° C. (sample no. 6), likewise does not give the required minimum flexural strength and that the use of high humidity air actually degrades the obtained flexural strength (sample No. 7).

In contrast, the values given in rows III of Table II illustrate that the use of the invention Method gives the required minimum flexural strength with a curing time that is as short as 4 hours (Sample No. 9), and that this procedure significantly increased "optimal strength" using the usual 28 standard days results (sample # 14) compared to that obtained when using curing temperatures below 43 ° C used (sample no. 8 of series II) "

Example 2

The following general recipes are used to make a Range of custom portland cement concrete systems

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- Q -

place. In the formulations containing a polymeric latex, the latex contains approximately 50 weight percent interpolymer solids of the following composition: 75 weight parts vinylidene chloride 20 weight parts vinyl chloride
5 parts by weight of ethyl acrylate
2 parts by weight of methyl methacrylate.

Mixture A - not modified with latex - usual density

Material parts by weight

Huron Type III cement 7.14

Water 3.36

Pea size 10 pebbles

2 NS sand 15

Silicone as an anti-foam agent 0.013

Mixture B - modified with latex - usual density

Material parts by weight

Huron Type III cement 7.14

V / ater 1.38

Pea size 10 pebbles

2 NS sand 15

Interpolymer latex 2.32

Mixture C - not modified with latex - lightweight

Material parts by weight

Huron Type I Portland cement water

2 NS sand

Light-weight aggregate admixture of water reducing means to trap air

336 5 174 1 652 700 1, O,

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Mixture D - modified with latex - lightweight

Material parts by weight

Huron Type I Portland cement 336

Water 172

2 NS sand 652

Lightweight unit 700

Interpolymer latex 70

In all cases the sand and portland cement were first mixed well and then the interpolymer latex became admitted. The entire formulation was then placed in a standard paddle-type mixer until it had a uniform consistency, mixed (approximately 4 to 5 minutes). Individual, highly compressed cylinders with a 10 cm (4 inches) in diameter and 20 cm (8 inches) in height were made from each of the above blends, and the cubes or pieces were hardened and then their compressive strength or compressive force was determined. In the following Table III lists the conditions used and the results obtained.

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Mixture A
(Comparison) Table III Mixture C
(Comparison) Mixture D
(according to the invention) example 1 Mixture B
(according to the invention) Example 3 Example 4 0 Example 2 0 10 % Latex solids, based on
the weight of the cement 7th 15th 0 0 Swelling time (hours) 8th 7th 4th 4th Curing time (hours) 121 4th 93 93 Curing ^{temperature (0} C) 121 Relative humidity 78
50 - - (A) (%) immediately after
of hardening
(B) (%) 200 days after the
Hardening 91
58

Compressive strength or compressive force in kg / cm ^ (psi) C-39)

(A) immediately after curing

(B) 200 days after curing

348.6 (4980) 354.9 (5070)

(6000) 40.6 (580)
632.1 (9030)

ro - ¹ cn ι

85.3 (1218)

From the above results it can be seen that the initial and ultimate ultimate strengths found in Portland cement concrete systems obtained is improved when using the curing process of the invention.

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Claims (4)

- 13 claims \ 1 _v Process for accelerating the hardening and improving the final strength of prefabricated masonry structures, characterized in that one (1) uses Portland cement or Portland cement mortar as the cementitious material in such structures, which contain a vinylidene chloride polymer latex in an amount sufficient to contain from 5 to 20 weight percent polymer solids, based on the weight of the mortar or on the cementitious material, and you (2) heating the non-hardened structure is substantially uniformly to a temperature of 38-121 ⁰ C in less than 80% relative humidity for a period of at least 4 hours. 2. The method according to claim 1, characterized in that the vinylidene chloride polymer contains: from 35 to 90 parts by weight of vinylidene chloride and from 65 to 10 parts by weight of at least one other interpolymerizable Materials of the general formula CH ₀ = CX R.
wherein R is a hydrogen atom or the methyl group and X is -CN, halogens with atomic numbers from 9 to 35 or ester-forming groups, -COOY, where Y is a primary alkyl group or a secondary alkyl group, and each of the aforesaid alkyl groups containing from 1 to 18 and including 18 carbon atoms. 3. The method according to claim 2, characterized in that the vinylidene chloride polymer 75 parts by weight Vinylidene chloride, 5 parts by weight of ethyl acrylate, 2 parts by weight of methyl 509881/0776 - 14 methacrylate and 20 parts by weight vinyl chloride contains _o 4. Hardened, essentially crack-free, prefabricated masonry or concrete structure, manufactured according to at least a method of claims 1 to 3. 509881/0776