Method of making concrete

Abstract

A batch composition for concrete includes a cementious material and aggregate material, the cementious material including at least 50% Portland cement and at least 1% of a dolomite mineral filler. The batch composition may be mixed with sufficient water to cause the cementious material in the batch composition to set and bind the entire mass to form a concrete.

Claims

1. A method for forming concrete, comprising: providing a batch composition for concrete comprising a cementious material and aggregate material, the cementious material including at least 50% by weight Portland cement and at least 1% by weight dolomite mineral filler; feeding the aggregate material, Portland cement, and dolomite mineral filler separately into a mixer; and mixing the batch composition with sufficient water to cause the cementious material in the batch composition to set and bind the entire mass to form a concrete; wherein the dolomite mineral filler is a granular powder having a sizing of 99% or more passing a 20 mesh sieve, 5% to 75% passing a 50 mesh sieve, 35% to 65% passing a 100 mesh sieve, 5% to 35% passing a 200 mesh sieve, and no more than 15% passing the 325 mesh sieve.

2. The method of claim 1, wherein the cementious material includes at least 10% by weight dolomite mineral filler.

3. The method of claim 1, wherein the dolomite mineral filler has a moisture content of 0.2 weight % or less.

4. The method of claim 1, wherein the batch composition is mixed with water to form a mixture in which the water is 5 to 6%, by weight.

5. A method for forming concrete, comprising: providing a batch composition for concrete comprising a cementious material and aggregate material, the cementious material including at least 50% by weight Portland cement and at least 1% by weight dolomite mineral filler; feeding the aggregate material, Portland cement, and dolomite mineral filler separately into a mixer; and mixing the batch composition with sufficient water to cause the cementious material in the batch composition to set and bind the entire mass to form a concrete; wherein the dolomite mineral filler is a powder having a sizing of 90% or more passing a 100 mesh sieve, 50% or more passing a 200 mesh sieve, and no more than 40% passing a 325 mesh sieve.

6. The method of claim 5, wherein the cementious material includes at least 10% by weight dolomite mineral filler.

7. The method of claim 5, wherein the dolomite mineral filler has a moisture content of 0.2 weight % or less.

8. The method of claim 5, wherein the batch composition is mixed with water to form a mixture in which the water is 5 to 6%, by weight.

9. A method for forming concrete, comprising: providing a batch composition for concrete comprising a cementious material and aggregate material, the cementious material including at least 50% by weight Portland cement and at least 1% by weight dolomite mineral filler; feeding the aggregate material, Portland cement, and dolomite mineral filler separately into a mixer; and mixing the batch composition with sufficient water to cause the cementious material in the batch composition to set and bind the entire mass to form a concrete; wherein the dolomite mineral filler is a powder having a sizing of 97% or more passing a 100 mesh sieve, 80% or more passing a 200 mesh sieve, and no more than 65% passing a 325 mesh sieve.

10. The method of claim 9, wherein the cementious material includes at least 10% by weight dolomite mineral filler.

11. The method of claim 9, wherein the dolomite mineral filler has a moisture content of 0.2 weight % or less.

12. The method of claim 9, wherein the batch composition is mixed with water to form a mixture in which the water is 5 to 6%, by weight.

13. A method for forming concrete, comprising: providing a batch composition for concrete comprising a cementious material and aggregate material, the cementious material including at least 50% by weight Portland cement and at least 1% by weight dolomite mineral filler; feeding the aggregate material, Portland cement, and dolomite mineral filler separately into a mixer; and mixing the batch composition with sufficient water to cause the cementious material in the batch composition to set and bind the entire mass to form a concrete; wherein the dolomite mineral filler is a very fine powder having a sizing of 90% or more passing a 325 mesh sieve.

14. The method of claim 13, wherein the cementious material includes at least 10% by weight dolomite mineral filler.

15. The method of claim 13, wherein the dolomite mineral filler has a moisture content of 0.2 weight % or less.

16. The method of claim 13, wherein the batch composition is mixed with water to form a mixture in which the water is 5 to 6%, by weight.

Description

DETAILED DESCRIPTION OF THE INVENTION

(1) It is to be understood that the specific compositions and processes described in the following description are simply exemplary embodiments of the inventive concepts defined in the appended claims. Hence, specific compositions and properties relating to the embodiments disclosed herein should not be considered as limiting, unless the claims expressly state otherwise. Unless otherwise specifically stated otherwise, all percentages referred to are by weight.

(2) The invention provides a batch composition for concrete that includes a cementious material and aggregate material, the cementious material including at least 50% Portland cement and at least 1% of a dolomite mineral filler. The Portland cement is as defined by ASTM C150 Type I/II.

(3) The DMF of the present invention is a dry powdered calcium magnesium carbonate, preferably having a moisture content of 0.2 weight % or less and a broader range of particle sizes than is evident in Portland cement or other conventional hydraulic binder materials. The DMF may be a granular powder, powder, or very fine powder material.

(4) The granular powder DMF used in accordance with the invention has a sizing of 99% or more passing the 20 mesh sieve, 5% to 75% passing the 50 mesh sieve, 35% to 65% passing the 100 mesh sieve, 5% to 35% passing the 200 mesh sieve, and no more than 15% passing the 325 mesh sieve.

(5) The powder DMF used in accordance with the invention has a sizing of 90% or more passing the 100 mesh sieve, with 50% or more passing the 200 mesh sieve, but with no more than 40% passing the 325 mesh sieve. Even more preferably, the sizing of the powder DMF used in the invention is 97% or more passing the 100 mesh sieve, with 80% or more passing the 200 mesh sieve, but with no more than 65% passing the 325 mesh sieve.

(6) The very fine powder DMF used in accordance with the invention has a sizing of 90% or more passing the 325 mesh sieve.

(7) Although not wishing to be bound to any particular theory, it is felt that introducing DMF into a blend of Portland cement and other hydraulic binder materials (or as a single Portland cement replacement) creates a mixture with a broader spectrum of particle sizes enabling better consolidation of the cement paste, which results in a stronger cured cement matrix.

(8) It is also suspected that the presence of DMF in the cement mixture provides additional nucleation sites enhancing opportunities for additional cement crystallization (the process which gives rise to compressive strength in concrete).

(9) The following examples are presented solely for the purpose of further illustrating and disclosing the present invention, and are not to be construed as a limitation on the invention.

EXAMPLES

(10) Test results for a series of test batches of concrete are shown in the Table. All compositional percentages are weight %.

(11) The Control Mix, Trial Mix, and other batches identified as Lab were prepared with bench scale equipment in a laboratory environment, and as set forth in ASTM C 192, Making and Curing Concrete Test Specimens in the Laboratory. The aggregate material, Portland cement, and DMF were added separately into a mixer and mixed with the water. The Portland cement and DMF were not premixed. The mixes identified as Field were prepared using a commercial ready-mix plant process, and as set forth in ASTM C 685, Concrete Made By Volumetric Batching and Continuous Mixing.

(12) The Control Mix (shown in column C) had the following composition (per cubic yard): 564 pounds of hydraulic binder material; 1245 pounds of crushed coarse dolomite aggregate meeting AASHTO #57 material specification; 710 pounds of crushed intermediate aggregate meeting AASHTO #8 material specification; 1056 pounds of coarse sand meeting AASHTO #703.02 material specification.

(13) This mix (with air entrainment) was designed to attain 4,000 psi compressive strength at 28 days.

(14) The same composition (except for the noted changes in the makeup of the hydraulic binder material) was used for all the experimental batches shown in the Table, columns D through O. The dolomite mineral fillers identified as DMF1 and DMF2 (powder), DMF3 (granular powder), and DMF4 (very fine powder) were the same apart from their respective particle size distributions, as set forth in rows 16-20 of the Table.

(15) The Trial Mix batch (shown in column D) maintains the same Portland cement (419 lbs.) and slag content (90 lbs.) as the Control Mix, but adds DMF1 (55 lbs.) in place of fly ash (i.e., 10% of the hydraulic binder material has been replaced by DMF). This cement mixture produced concrete having compressive strength of 6,310 psi at 28 days far exceeding the 4,000 psi design for the Control Mix.

(16) The Mix 1 Lab batch (shown in column E) maintains the same slag content (90 lbs.) and fly ash content (-0- lbs.) as the Trial Mix, but increases DMF1 to 94 lbs. and reduces Portland cement to 380 lbs. Compared to the Control Mix, 17% of the hydraulic binder material has been replaced by DMF. This cement mixture produced concrete having compressive strength of 5,100 psi at 28 days exceeding the 4,000 psi design for the Control Mix.

(17) The Mix 1 Field batch (shown in column F) duplicates the Mix 1 Lab batch using a ready-mix plant process. The cement mixture produced concrete having compressive strength of 5,240 psi at 28 days exceeding the 4,000 psi design for the Control Mix.

(18) The Mix 4 Lab batch (shown in column G) also duplicates the Mix 1 Lab batch except that the DMF1 was replaced by DMF2. This cement mixture produced concrete having compressive strength of 4,730 psi at 28 days exceeding the 4,000 psi design for the Control Mix.

(19) The Mix 9 Lab batch (shown in column H) also duplicates the Mix 1 Lab batch except that the DMF1 was replaced by DMF3. This cement mixture produced concrete having compressive strength of 5,570 psi at 28 days exceeding the 4,000 psi design for the Control Mix.

(20) The Mix 11 Lab batch (shown in column I) also duplicates the Mix 1 Lab batch except that the DMF1 was replaced by DMF4. This cement mixture produced concrete having compressive strength of 5,280 psi at 28 days exceeding the 4,000 psi design for the Control Mix.

(21) The Mix 5 Field batch (shown in column J) maintains the same slag content (90 lbs.) and fly ash content (-0- lbs.) as the Trial Mix, but increases DMF1 to 115 lbs. and reduces Portland cement to 359 lbs. Compared to the Control Mix, 20% of the hydraulic binder material has been replaced by DMF. This cement mixture produced concrete having compressive strength of 5,310 psi at 28 days, exceeding the 4,000 psi design for the Control Mix.

(22) The Mix 6 Field batch (shown in column K) contains only Portland cement (449 lbs.) and DMF1 (115 lbs.). Compared to the Control Mix, 20% of the hydraulic binder material has been replaced by DMF. This cement mixture produced concrete having compressive strength of 4,840 psi at 28 days, exceeding the 4,000 psi design for the Control Mix.

(23) The Mix 2 Lab batch (shown in column L) maintains the same slag content (90 lbs.) and fly ash content (-0- lbs.) as the Trial Mix, but increases DMF1 to 142 lbs. and further reduces Portland cement to 332 lbs. Compared to the Control Mix, 25% of the hydraulic binder material has been replaced by DMF. This cement mixture produced concrete having compressive strength of 4,280 psi at 28 days exceeding the 4,000 psi design for the Control Mix.

(24) The Mix 2 Field batch (shown in column M) duplicates the Mix 2 Lab batch using a ready-mix plant process. This cement mixture produced concrete having compressive strength of 3,960 psi at 28 days nearly matching the 4,000 psi design for the Control Mix.

(25) The Mix 3 Lab batch (shown in column N) maintains the same slag content (90 lbs.) and fly ash content (-0- lbs.) as the Trial Mix, but increases DMF1 to 190 lbs. and further reduces Portland cement to 284 lbs. Compared to the Control Mix, 34% of the hydraulic binder material has been replaced by DMF. This cement mixture produced concrete having compressive strength of 3,420 psi at 28 days.

(26) The Mix 3 Field batch (shown in column 0) duplicates the Mix 3 Lab batch using a ready-mix plant process. This cement mixture produced concrete having compressive strength of 3,200 psi at 28 days.

(27) The chemistry of the DMF in each of the examples was around 54% CaCO.sub.3 and around 44% MgCO.sub.3. The water required for normal consistency of DMF1 (as described in the Table) according to ASTM C187 was 22.50%, and the methylene blue value C595 (using AASHTO T330) was 0.5 mg/g.

(28) TABLE-US-00001 TABLE E F G H I J K L M N O C D Mix Mix Mix Mix Mix Mix Mix Mix Mix Mix Mix Control Trial 1 1 4 9 11 5 6 2 2 3 3 A B Mix Mix Lab Field Lab Lab Lab Field Field Lab Field Lab Field Powder Portland 419 419 380 380 380 380 380 359 449 332 332 284 284 Ingre- Cement dients (lbs) (Pounds GGBFS 90 90 90 90 90 90 90 90 0 90 90 90 90 per CY) (lbs) DMF 1 0 55 94 94 0 0 0 115 115 142 142 190 190 (lbs) DMF 2 0 0 0 0 94 0 0 0 0 0 0 0 0 (lbs) DMF 3 0 0 0 0 0 94 0 0 0 0 0 0 0 (lbs) DMF 4 0 0 0 0 0 0 94 0 0 0 0 0 0 (lbs) Fly Ash 55 0 0 0 0 0 0 0 0 0 0 0 0 (lbs) Total 564 564 564 564 564 564 564 564 564 564 564 564 564 Powder Content Pro- Portland 74% 74% 67% 67% 67% 67% 67% 64% 80% 59% 59% 50% 50% portions Cement of Other 26% 16% 16% 16% 16% 16% 16% 16% 0% 16% 16% 16% 16% Powder Hydraulic Ingre- Binder dients DMF 0% 10% 17% 17% 17% 17% 17% 20% 20% 25% 25% 34% 34% % 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% Passing US 20 Mesh % 100% 100% 100% 100% 99% 100% 100% 100% 100% 100% 100% 100% Passing US 30 Mesh % 99% 99% 99% 90% 55% 100% 99% 99% 99% 99% 99% 99% Passing US 100 Mesh % 87% 87% 87% 55% 15% 99+% 87% 87% 87% 87% 87% 87% Passing US 200 Mesh % 58% 58% 58% 38% (est) 6% 97% 58% 58% 58% 58% 58% 58% Passing US 325 Mesh Admixes Air, 8% 5% 6.7% 4% 6.7% 6.0% 6.0% 5.50% 6.60% 7% 6.60% 7.1% 6.40% ASTM C231 MRWR, 6 6 6 6 6 6 6 6 6 6 6 6 6 oz/cwt Water/ 0.45 0.45 0.45 0.45 0.39 0.45 0.45 0.45 0.45 0.45 0.45 0.45 0.45 Cement Ratio Slump, 4.25 6.5 3.5 4 3.75 4 4 3.75 4 4.5 6.5 3.75 6 ASTM C143 Compres- 3 Day 1607 2670 2175 2490 2880 2920 1890 2770 1930 1523 1450 1143 sion Avg. Tests 7 Day 2487 4437 3720 3820 3380 3770 3720 3470 3847 2830 2737 2340 2173 (psi) Avg. (ASTM 14 Day 4450 4160 4670 4503 3540 3050 C39) Avg. 28 Day 3730 6310 5100 5240 4730 5570 5280 5310 4840 4280 3960 3420 3200 Avg.

(29) The compositions of the invention thus comprise a cementious material and aggregate material, the cementious material including at least 50% Portland cement and at least 1% DMF. Even more preferably, the cementious material includes at least 10% DMF.

(30) The DMF may be a granular powder, powder, or very fine powder material.

(31) The granular powder DMF used in accordance with the invention has a sizing of 99% or more passing the 20 mesh sieve, 5% to 75% passing the 50 mesh sieve, 35% to 65% passing the 100 mesh sieve, 5% to 35% passing the 200 mesh sieve, and no more than 15% passing the 325 mesh sieve.

(32) The powder DMF used in accordance with the invention has a sizing of 90% or more passing the 100 mesh sieve, with 50% or more passing the 200 mesh sieve, but with no more than 40% passing the 325 mesh sieve. Even more preferably, the sizing of powder DMF used in the invention is 97% or more passing the 100 mesh sieve, with 80% or more passing the 200 mesh sieve, but with no more than 65% passing the 325 mesh sieve.

(33) The very fine powder DMF used in accordance with the invention has a sizing of 90% or more passing the 325 mesh sieve.

(34) The compositions of the invention are mixed with sufficient water to cause the cementious materials therein to set and bind the entire mass to form a concrete. Typically, the mixture is on the order of 5 to 6% water.

(35) In accordance with the provisions of the patent statutes, the present invention has been described in what is considered to represent its preferred embodiment. However, it should be noted that the invention can be practiced otherwise than as described without departing from its spirit and scope.