AT393498B - CONCRETE ADDITIVES - Google Patents

Description

AT 393 498 B

The egg formation affects concrete admixtures that are used as hardening accelerators in cold weather.

The processing of concrete at low temperatures (e.g. between -7 ° C and 5 ° Q is associated with special problems because the concrete mixture can freeze and subsequently have low strength or the concrete only slowly achieves the desired strength.

It has been known to address these problems by adding hardening accelerators, e.g. B. calcium chloride to counter. However, there are no concrete admixtures that 1) are not corrosive and 2) at temperatures ναι -10 ° C to 5 ° C the hardening rate and subsequent compressive strength of the concrete of a normal concrete mix at 10 ° C or exaggerate. It has now been found that by combining different hardening accelerators in certain proportions, concrete admixtures can be obtained with two combined advantages: 1) They lower the melting point of the water in the mixture and in the pores, so that the concrete mixture does not occur in the first critical hours of hardening freezes at temperatures below 0 ° C. 2) They reduce the amount of water required for hardening, which leads to an improvement in the initial strength. The reduction in the amount of water also leads to a lowering of the melting point, because a more concentrated solution of the additive can be used.

The invention thus relates to a chloride-free concrete admixture containing A) 100 parts by weight of at least one water-soluble inorganic salt with a melting point, whereby up to 50 percent by weight can be replaced by urea, B) 133 to 30 parts by weight of at least one concrete plasticizer, Q 3 to 30 parts by weight at least one inorganic hardening accelerator and D) 0 to 10 parts by weight of at least one organic hardening accelerator.

At least 15 parts by weight should preferably be present as component B), the proportion of component C) is from 5 to 10 parts by weight and that as component D) is from 13 to 6 parts by weight.

The stated ratios relate to the dry weight of the components without taking into account any water that may be present.

The concrete admixture according to the invention can be added to the mixed water as a solid product or preferably as an aqueous solution.

Component A) is preferably an ammonium, alkali or alkaline earth nitrate or nitrite, calcium and sodium nitrate or nitrite being preferred. Calcium nitrate is most preferred. Up to 50% of the inorganic salt in component A can be replaced by urea.

Component B) is preferably an alkali or alkaline earth metal salt of a condensate of formaldehyde with naphthalene sulfonate or melamine sulfonate, most preferably a sodium or calcium salt, or an acrylic polymer such as poly (hydroxyethyl methacrylate / acrylic acid). The condensate of formaldehyde with naphthalene sulfonate as the sodium salt is particularly preferred.

Component Q is preferably an ammonium, alkali or alkaline earth thiocyanate and / or thiosulfate, preference is given to a calcium, ammonium or sodium thiocyanate or thiosulfate. Sodium thiocyanate is particularly preferred

Component D) is preferably a methylolglycoluril, dimethylol urea, mono- or di- (N-methylol) hydantoin, mono- or di- (N-methylol) dimethylhydantoin, N-methylolacrylamide, tri- (N-methylol) melamine, N -Hydroxyethylpiperidine, N, N-bis- (2-hydroxyethyl) piperazine, glutaraldehyde, pyruvaldehyde, furfural or a water-soluble urea-formaldehyde resin. The Methylolglycolurils such as. B. tri- (N-methylol) glycoluril and tetra- (N-methylol) glycoluril, especially the latter.

A preferred concrete admixture according to the invention consists of A) calcium nitrate, B) sodium salt of a condensate of formaldehyde with naphthalene sulfonate, C) sodium thiocyanate and D) tetra- (N-methylol) glycoluril in the weight ratios given above. Such an agent is particularly preferred in the ratio of 100 parts A) to 20 parts B), 6.7 parts C) and 4 parts D). This preferred agent is preferably used in the form of an aqueous solution which contains 40-60%, in particular 50% dry weight of components A) to D)

A concrete admixture according to the invention can be used at temperatures from approximately 20 ° C. to -15 ° C. The amount added is from 0.13 to 5.6 parts dry weight per 100 parts dry weight of the cement portion (e.g. Portland cement plus pozzolan cement such as fly ash) in the concrete mixture, preferably from 0.65 to 5.6 parts. For the above-mentioned preferred agent, the dosage is from 1.3 to 4.6 parts per 100 parts of cement and the lower the ambient temperature, the higher the amount required. For example, 2.6 parts / 100 parts of cement of the preferred agent will protect a concrete mix from freezing up to a temperature of about -10 ° C, while a dosage of 3.9 parts / 100 parts of cement is preferred for even lower speeds.

The concrete admixture can be used with any of the cement types ASTMI to V, but types I and Π are preferred. The concrete admixture can be used in both mortar and concrete. -2-

AT 393 498 B

The invention also relates to a method for accelerating the hardening of a mortar or concrete mixture under cold weather conditions by adding 0.65 to 5.6 parts dry weight of the concrete admixture according to the invention to 100 parts dry weight of the cement portion. The mortar or concrete mixture thus obtained contains the following proportions of components A) to D):

Component parts / 100 parts cement

A B C D 0.5 - 4.0 0.1 - 0.8 0.033 - 0.6 0 - 0.16 preferably 0.02 - 0.16

Preferred proportions are:

Component parts / 100 parts cement A 2.0 - 3.0 B 0.4 - 0.6 C 0.1 - 0.6 D 0.04 - 0.12

A method according to the invention also consists in adding to the mortar or concrete mixture per 100 parts of cement 1) 0.5 to 4 parts of at least one component A), 2) 0.1 to 0.8 parts of at least one component B), 3) Add 0.033 to 0.6 part of at least one component Q and 4) 0 to 0.16 part of at least one component D). In the preferred process, at least one component D) is added in amounts of 0.02 to 0.16 parts / 100 parts of cement.

In the examples below, all parts and percentages are to be understood as weights, unless stated otherwise.

Examples of standard procedures A concrete mix without additives according to the invention (hereinafter referred to as reference mix) consists of the following components:

Component kg / nr concrete mix

Cement ASTM Type I 307 aggregate (sand and gravel in the ratio 40:60 to 50:50, broken gravel is used as gravel with a 2 cm long surface) 1900

Water as specified in tables ΙΠ to VH

An air pore additive can also be added. Examples are the Micro-Air and Master Builders Neutralized Vinsol products sold by Master Builders Inc., both of which are -3-

AT 393 498 B

Meet the requirements of ASTM C-260, AASHTO M-154 and CRD-C13.

Concrete mixes containing additives according to the invention are produced like the reference mix, namely that about 80% of the mixed water this reference mix is put into a conventional concrete mill and the additive is added before the cement, sand and gravel are added. The remaining 20% of the mixed water is then used to adapt the slump to that of the reference mixture. The concrete mix is then poured into 10 cm cubes and covered to prevent loss of moisture. The cubes are kept at temperatures during the times as indicated in the examples.

properties

The following «! Properties are routinely determined:

Slump fSlumpk the sagging in cm of a 30.5 cm high cone of the fresh mixture (ASTMC143)

Percent air norms

Water reduction: the difference between the amount used in the reference mix

Water and the (smaller) amount of water in the test mixture, in order to achieve the same slump, as a percentage of the amount of water in the reference mixture.

Compressive strength: expressed in kg / cm ^ and in percent of the compressive strength of the reference mixture under the same condition «!. Hardening rate: time in hours until the beginning strength is reached (ASTM C 403) (RoH = Rate of Hardening)

Examples Ibis 26

Formulations according to the invention for concrete admixtures are given in Tables I and Π, namely the proportions by weight of components B), C) and D) per 100 parts of component A). These formulations are dissolved in water to obtain a solution of 1.36 kg of component A) in 2.56 liters. In view of the specific density of these solutions of about 1.39, they all contain 1.36 kg of component A) in 3.561% solution, i.e. H. 38 percent by weight Together with the other components, the solutions contain a total of about 50% active ingredient.

Tabclkl

Additive 1-18, each containing 100 parts by weight of calcium nitrate A) and in addition:

Parts by weight of example B) naphthalene sulfonate / C) sodium D) tetra (N-methylol) no. Formaldehyde Na salt thiocyanate glycoluril 1 20 6.7 3.3 2 20 20 4 3 20 20 1.6 4 20 6 .7 4 5 20 6.7 1.3 6 13.3 20 4 7 13.3 20 1.3 8 13.3 6.7 4 -4-

AT 393 498 B

Table I (continued)

Parts by weight

Example No. B) naphthalene sulfonate / C) sodium D) tetra (N-methylol) -

Photmaldehyde Na salt thiocyanate glycoluril A) Calcium nitrate 100 100 66.7 100 100 100 100 9 13.3 6.7 1.3 10 20 16 3.2 11 30 30 6 12 30 30 2 13 30 10 6 14 30 10 2 15 20 30 2 16 20 10 6 17 20 10 2 18 20 3 6

Additives 19-26 Tables formulations (parts by weight) Example No.Component 19 20 21 22 23

Calcium nitrite - - 100 33.3 B) Naphthalene sulfonate /

formaldehyde

Ca salt 20 20 ...

Na salt - - 20 20 20 20 20 20 Q sodium thiocyanate 6.7 - - 6.7 6.7 6.7 6.7 6.7

Ammonium thiocyanate 6.7 6.7 ... -5-

AT 393 498 B

Tables (continued!

Additive 19-26

Formulations (parts by weight)

Example No.Component 19 20 21 22 23 24 25 26 D) tetra (N-methylol) glycoluril 4 4 4 4. . • Pyruvaldehyde - - - 4 - - - Glutaraldehyde - - - - - 4 - N-Hydroxyethylpiperidin - - - - 4 - - N, N-Bis- (2-Hydroxy-ethyl) piperazine - - - - - - 4 Sodium acetate (buffer) 1.4 1.4 1.4 1.4 1.4 1.4 1.4 1.4

In the following examples, the solutions of concrete admixtures are added to the concrete mixes in such quantities that the stated dosage of the total admixture (without water) is reached to 100 pounds (= 453 kg) of cement,

Example 27

In an outdoor experiment, all samples, including the reference mix, are made at 5 ° C and poured at -7 to -8 ° C. During curing, the outside temperature varied between -15 0 and +18 ° C. The results are given in Table ΙΠ, whereby experiment No. 1 shows the optimal results that can be achieved with the known, corrosive CaC ^ addition, while experiments No. 2 and 3 show that similar

Results can be achieved with the non-corrosive additives of the invention.

Example 28

On the one hand, a reference mixture is made at 10 ° C, poured and cured at this temperature. The samples of experiments 1 to 5, on the other hand, are produced at 10 ° C., for 3 days at temperatures from -8 to -6 ° C. and then cured at 10 ° C. In these experiments, the additives of Examples 1 and 4 (with a very similar composition) are added in dosages of about 2 to 4.5 parts / 100 parts of cement. The results can be found in Table IV. In all cases, the hardening rate is higher than that of the normal concrete mix at 10 ° C and the compressive strength after 28 days is equally good. (Tables m and IV follow) -6-

Table m m AT393 498 B 4 > SP cs 0 OV in «n & in in on r- oo μ H o \ ^ vo a \ m ^ 00 cn ^ S cn CS o g > & m cn cn cn cn r- * s% s $ s o o \ θ \ w-i Ο) / * \ fH CS ä ^ t > • ä cs *? g, <]) cs Sv n i 47 190 ιλ cn 't 00 v ™ i 59 241 cn * > 3.8 r- m 00 On 00 C $ 11.5 04 «N cn ή d cn # £ ll o \ Ov cs o Γ- 'S * in RoH i. Hrs freeze frozen 5.5 cn H »in ¢ 5 9 00 OV 00 o vo in vo * vo’ ft - 00 i s 00 o \ OV Γ '- * OO t * 1 s = s so m o > o cs in ON Tf- I o * cs o —I ö cn ö 1 1 cs A " S Tf A • SA ia U 8 .co a S * a rv Q 2 ü 2 «2« 2 έ 1 o H es ^ OT mm cs o cn in cn -7-

Table TV AT 393 498 B 4 > g > £ 8 368.1 100 444.3 121 445.8 121 364 99 394.9 107 369.9 100 4) 8P CO SO CO P ~. • pS O / * “> • a > £ «PT H f» §8 cs ^ 224 108 Tf 00 es o CS r-t p- · wo Os Os co oo cs o CS 1-H en so so es | 4 | e 3 days «Ί S§ ^ f-4 86.4 74 76.4 65 47.25 40 00 o wo where SO 00 m -sj · M £ 27.9 100 CS c ^ E: CO Koo CS ♦ M vo so 00 f rt WO r * ^ 00 es os es os cs t- ~ cs © H es os CO έ -S t # # 1 ^ 00 in SO © " OS r-- ’fl OS p4 > CK RoH i. Std < N where cs CS © where 00 < N CO so CO VO co where co l > ft 'S 1.9 3.0 2.7 CO * »cs 2.2 0¾ Λ Ä i I r» * 1 cs cs CO «k CO t " «K cs t- cs * cs 55 Ä *“ < 60 where it is SO where o Os CS vq On '«for CO CO cs *’ S je .¾ ü §, Tj-' 'fr i «ß > Λ JS ö 9 o cs CO Tfr m > 8 © WO o wo © WO «“ H cs cs CO co -8

AT 393 498 B

Example 29

In addition to the reference mixture (test 0), which is produced, poured and cured at 10 ° C., a further mixture (test 1) is produced, poured and cured at -3 ° C. for 3 days and then at 10 ° C. for 3 days . Test 2 is carried out in the same way as test 1, but the mixture contains 3.48 parts / 100 parts of cement of the concrete admixture from example 10. The results are summarized in table V.

Example 30

The reference mixture is again made at 10 ° C, poured and cured. Samples of Runs 1-17 are made at 10 ° C, cast and cured for one day at -5 ° C and then for 28 days at 10 ° C. The results in Table VI show that the time to reach initial strength (RoH ) greatly reduced in experiments 1 to 17 compared to the reference mixture and the compressive strength is better after 28 days. The must »'not born at -5 ° C.

Example 31

The reference mixture and the mixtures from experiments 1 to 3 (containing the additive from Example 4) are all cast and cured at 21 ° C. The results in Table VII show that the additives according to the invention are also effective at this higher temperature.

Example 32

The reference mixture (test 0) is produced and cured at 10 ° C. Another mixture (test 1) is prepared as tests 2 to 9 at 3-5 ° C. for 3 days at a temperature between -15 and 0 ° C. and then cured at a temperature between -15 and 5 ° C. The results are given in Table VIR. (Tables V, VI, VH and VHI follow) -9-

AT 393 498 B σ \ cs

! S g • P · o e > 0 1 3

4 > Ϊ2Ι £ 'Z9P g > £ S 001 tzsz § (oo in OS § 2 § 00 oo * n 85 < 0 / —N CS < -1 pH CO pH 'S ^ a es ft P 14 s * o g > s Ό in S 8 34 , 1 31 ZL SL'SL CO pH pH bO o \ 00 00 SH 19 100 oC Os ^ t * 20, 105 CO E έ 5 1 ^ pH ci pH OS £ (2 r · »pH RoH i. Std. 10, 50 15.5 4.63 < ä 9 00 in in SO < £ pH r- CO i cs' cs * CO • 3 3 cn pH pH pH M ΪΠ m oo in oo Tf © * o * o * cn ö ii 1 o '| IP έ ea | Cu y CG' h9 a 2 m 2 N fc ao pH CS ^ CO oph cs cs o co

CO -10-

Table VI (Example 30) AT 393 498 B O M 00 wn iS r * < cn H H ¢ 8 «“ * 00 es' © Os O cn Os 00 32 m cn 32 cs Cn r-H Tf 1-4 ^ 1 — t Xj- t-H Q > ^ · &Amp; £ flrT X 6 1Ä 00 00 Ό. tS 58 cn cn vo m 00 vo vo m O cn H cs o \ -H vo i — i ^ vo es oo cn ε 1 Λ Π M r " r ~ 1’s O C " o \ 00 ci vo vn · £ Ci fH K 'S * n 00 cn vn P »3 t- * 00 © 1“ H o t ~; Pi 00 en cn% air 00 cn iH q. cs “cn cn cn cs o, it cs ci cn cn en cn en cn cn cn iM« m «im4 Ul cs m CS 3 es c (cn cs Ov 1-H Tf Tp cn cn 1 ε a 1 cs cn v > vo 8 s N (B 'S o H cs cn m > 3 © wn o in o in H CS CS cn cn 11

AT 393 498 B

Table VI (Example 30) Continuation

«0 130 m 0 t " 00 · * o \ H · u-l ss ci \ n \ o vd os 00 vo t- 00 t- * CO 00 cn cs t— cn Os 1? * öcs ^ js ε? § Ci 1-4 Tf fl Tj- i-H ^ rH g > £ 15.75 64 co o \ 00 vo 00 in -¾ O cn CO Ci o H Ο * -H ^ Γ ** «- < c ** CS 00 CS < 3 \ CS 00 H Tf PH pH PN. I 'S OS 00 VO Os d pH W 3 m 00 00 00 00 00 O CO * CO 00 CO CO CO 00 cd CO 00 cd «1« n 00 00 «n Ci Ci Ci cs cd cd o. Ε' Ξ ' l > cs' Ci Ι οί ci cd CO cd CO cd CO ^ H 1-4 pH pH | s cs Γ " _ 3 00 Ci CO $ 1 CO CO CO cd cd 1 ε 1 00 ON © ci 1-H pH 9 N i 1 vo (" 00 OV o iH pH ^ W o \ no < Λ1 © « n HH Ci CS CO CO -12

Table VI (Example 30) - continued AT 393 498 B 28 days 432.9 125 436.4 126 435.3 125 434.8 125 425.7 123 405.1 117 O / —s öo a «sss 4» I ® a > £ 00 00 * vo 1-4 Γ " · * 16.2 66 18.6 75 17.9 73 VO rf 0 \ < -h in 14.6 59 1 i t *; 1 > Tf H 1 'S ^ ea H cn \ o 00 ON RoH i. Hr 4.50 4.38 4.13 4.0 in nm% air 2.9 2.9 2.4 2.5 2.7 2.9 slump (cm) Tf ^ 4 13.3 12.7 12 , 7 13.3 13.3 b0 CO δ CS 3 s CS Γ-; $ 00 in < N CS cn CS CN ci 2 w • w ε iS cn in VO H r * * > 4 00 CO P N try CN »• 4 cn iM Tf m VO rH r- r- < o 1 * H in o es in CS o cn in cn -13-

Table VH (Example 31) from AT 393 498 B 28 days 388.5 100 506.4 130 484.3 125 530.9 137 * ** 'S, -N f ^ g 7 days 299.7 100 398.8 133 397.9 133 425.5 142 | 2 3 days 202.1 100 283.9 140 298.8 160 v £ 00 CO rH 1 day 81.8 100 133.6 163 142.9 175 175.4 214 Water Reduct . cn f 00 m t- * vo < N 00 10.5 RoH i. Std. 5.375 3.25 2.75 2.50 SJ r- < o < N ui VO " t vo * Slump (cm) NO m U ") ui ui 60 i 0.6 1.31 0.04 2.62 0.1 3.92 0.09 3 S * * * * SSS 3 MB-VI example 4 MB-VI example 4 MB-VI example 4 MB-VI test o cs co vo VO cS O cn δ vo co 14

Table VIII (Example 32)

AT 393 498 B ω gP £ 8 't P- P »m äs in e * O CO Os 00 o t " * · CO CS SS cs CS» H Tf ^ Tf * - «CO * H CO IH tj? 4 > 'S «Os m vH 1 ^ # S S8 • * t m rH Q " t CO ι-H O SS y? 00 © Q > t— i— (m cs cn cs CS iH CO vH 3 days m 00 64.05 100 178.4 278 188.5 294 153.9 240 166.1 260 CO CO H ε i 1 " Sb Sb MM CO 00 in in J 3 ^ Oi os vo iH $ H ei in OS θ 'nm in m B' S * 5 w CO cs o cs 'S cs vq cs »Γ ·' * 00 06 in 00 TJ- CO m in„ < e CO 'S ·. 00 in 00 * 3 in in f " in in Qi »oab 9 u L6.2 £» 16.2 15.2 16.5 SO So 00 mp \ n CS cs cs 2? cs a osö 8 1 • Os OS os.o • Ψ * CO 3 o CO CO wo «io • j3 OS © es 'ä 1-H CS CS X CS T 8 § a * a'. § & & &. J & .J se% mmm § «1 ή Ί o H cs CO m > £ o > no in © in cs cs CO CO 15

Table VIII (Example 321 - continued AT 393 498 B Üg > S cn 00 Q \ in j > q \ r- cn r ** in 8 o \ vo vo m cn ^ Tf * -4 «tf ^ *« -η • < fr iH 'Ö ^ o gp £ • a ^ L 3 8 I ^ IO cn Ov m oo cs 88 in cs CS fl * H oC r * · ^ o cn cs cn cs cn cs CO cs 00 00 £ cs o " 00 in in iH 00 VO W Ov Ov r- r- r- ό cn ^ CS ** cs fl cs 1-H CS M VO cn in PN 1 'S cs cs' © 00 £ «w 3 * 3 vx in o in cs in r- * Pi - · VO VO * m vo *% air 5.9 6.9 5.8 5.3 5.3 o, _ ε 's “Ov Ov ms £ vn in VO VO en g) in 3 cs cs .s 1 vo o 10 * 0 5.6 5.6 vo omoa | 3 in cs 8 | i 1 3 · * < £ 8- il n ε n m «i 6 a VO P '00 OV Kl 3 r CO o in o in H cs cs -16

Claims (13)

AT 393 498 B PATENT CLAIMS 1. Chloride-free concrete admixture containing A) 100 parts by weight of at least one water-soluble inorganic salt with a melting point-reducing effect, whereby up to 50% by weight can be replaced by urea, B) 133 to 30 parts by weight of at least one concrete plasticizer, C) 3 to 30 parts by weight of at least one inorganic hardening accelerator and D) 0 to 10 parts by weight of at least one organic hardening accelerator. 2. Concrete admixture according to opening 1, characterized in that at least 15 to 30 parts B), 5 to 10 parts C) and 1.3 to 6 parts D) are contained per 100 parts of A). 3. Concrete admixture according to claims 1 or 2, characterized in that component A) is an ammonium, alkali and / or alkaline earth nitrate and / or nitrite, preferably calcium nitrate 4. Concrete admixture according to one of claims 1 to 3, characterized in that component B) is an alkali or alkaline earth metal salt of a condensate of formaldehyde with naphthalene sulfonate or melamine sulfonate or an acrylic polymer 5. Concrete admixture according to claim 4, characterized in that component B) is an alkali salt of a condensate of formaldehyde with naphthalene sulfonate 6. Concrete admixture according to one of claims 1 to 5, characterized in that component C) is an ammonium, alksdi or alkaline earth thiocyanate and / or thiosulfate, preferably sodium thiocyanate 7. Concrete admixture according to one of claims 1 to 6, characterized in that component D) is a methylolglycoluril, dimethylol urea, mono- or di- (N-methylol) hydantoin, mono- or di- (N-methyl-ol) dimethylhydantoin, N-methylol acrylamide, tri- (N-methylol) melamine, N-hydroxyethylpiperidine, N, N-bis (2-hydroxyethyl) piperazine, glutaraldehyde, pyruvaldehyde, furftiral or a water-soluble urea-formaldehyde resin, preferably tetra- (N- methylol) glycoluril 8. Concrete additive according to one of claims 1 to 7, characterized in that on A) 100 parts of calcium nitrate B) 20 Teüe sodium salt of a condensate of formaldehyde with naphthalene sulfonate C) 6.7 parts of sodium thiocyanate and D) 4 parts of tetra- (N-methylol ) glycoluril are included. 9. concrete admixture according to one of claims 1 to 8, characterized in that it is present as an aqueous solution 10. A method for accelerating the hardening of a concrete or mortar mixture for use in cold weather, characterized in that 0.13 to 5.6 parts by weight (dry content) of a concrete admixture according to one of claims 1 to 9 are added to 100 parts by weight of the dry cement material . 11. The method according to claim 10, characterized in that - 03 to 4% of at least one component A), - 0.1 to 0.8% of at least one component B), - 0.033 to 0.6% of at least one component C) and - 0 to 0.16% of at least one component D) is used. -17- AT 393 498 B 12. Concrete or mortar mixture containing per 100 parts by weight of the dry cement material - 0.5 to 4% of at least one component A), - 0.1 to 0.8% of at least one component B), 5 - 0.033 to 0.6% at least one component Q and - 0 to 0.16%, preferably 0.02 to 0.16% of at least one component D), components A), B), Q and D) being defined in claim 1. 13. Concrete or mortar mixture according to claim 12, characterized in that - 2.0 to 3.0% of component A), - 0.4 to 0.6% of component B), - 0.1 to 0.6 % of component C) and 15 - 0.04 to 0.12% of component D) are included. -18-