This invention relates to early strength cements, that is to say cements which after mixing with water rapidly set and harden in a controllable way to yield appreciable early strengths.

It is known that conventional Portland cements after mixing with water, although ultimately yielding high strengths, are initially slow to set in comparison with some other cementitious materials and that the early strength and rate of strength development during this setting period is poor. In some applications, such as where movement of shuttering or the turnover of moulds in a short time is essential or where early exposure to mechanical stresses is required such as in the patching of roads or airport runways, the availability of a cement with many of the properties of a Portland cement but with a rapid and controlled set would be a distinct advantage. Although the rate of setting and strength development of Portland cement can be increased by addition of a monocalcium aluminate (CA) cement and/or accelerators and can be marginally improved by increasing its C₃ A content, it is difficult to obtain consistent and reproducible results by these methods, particularly where the process involves pumping a slurry of the cement or a concrete containing it or when used in conjunction with an aggregate contaminated with or containing substances capable of acting as accelerators or retarders of the set of ordinary Portland cements.

Cements containing C₁₂ A₇ which provide rapid but reproducible and controllable setting times can be produced for such applications as described in our British patent application No. 38202/72. These compositions, however, require the use of a high aluminous material such as bauxite in their raw feed preparation, which increases their cost. Moreover, it is generally necessary to intergrind two separately prepared clinkers to obtain the desired phase composition and physical properties.

The object of this invention is the provision of cements of comparable, and in some instances improved, properties to those of British patent application No. 38202/72, but which do not necessitate the use of expensive raw materials such as bauxite, and which in certain instances can be prepared from a single clinker.

It is known that small amounts of potassium or sodium oxide and other compounds which are present as trace impurities in Portland cement compositions enter into solid solutions in certain of the clinker phases during burning and may affect the hydraulic properties of these phases. It has also been reported during investigations of the CaO -- Al₂ O₃ -- Na₂ O ternary system that if additions of Na₂ O exceed the solid solution limit of Na₂ O in the cubic C₃ A phase then it leads to the formation of an ortho-rhombic or possibly tetragonal sodium calcium aluminate phase (or phases). (Y. Suzukawa, Zement-Kalk-Gips, 1956, 9, 345; A. E. Moore, Nature, 1963, 199, 480; J. A. Conwicke and D. E. Day, J. Am. Cer. Soc. 1964, 47, 654; and K. E. Fletcher et al, Mag. Conc. Res. 1965, 17, 171; M. Regourd, Brit. Cer. Soc. Conf. Aberdeen 1973).

Although the exact composition of this compound is disputed in the literature, it is now generally accepted that the initially proposed ternary compound NC₈ A₃ (where N. represents Na₂ O, C represents CaO and A represents Al₂ O₃) is incorrect and that the quantity of Na₂ O required to substitute in place of CaO in the cubic C₃ A structure in order to form the ortho-rhombic form is of the order of 4.5 per cent. This corresponds to a compound with the formula (C_{1 -x} N_x)₃ A where x lies between 0.06 and 0.07 which approximates to NC₁₄ A₅. This nomenclature NC₁₄ A₅ will for convenience be used throughout this specification to refer to the ortho-rhombic and/or tetragonal sodium calcium aluminate phase (or phases) referred to above, but it should be understood that the use of this nomenclature is not to be understood as limiting the invention to a phase or phases of the composition NC₁₄ A₅ should further investigation point to an alternative composition for the phase or phases concerned. The NC₁₄ A₅ may contain Na₂ O or traces of other oxides in solid solution.

For the purpose of identification of the phase concerned, it has been found and reported elsewhere that the cubic C₃ A phase will take up Na₂ O in solid solution to the extent of about 2 per cent by weight. The presence of greater amounts of Na₂ O results in the conversion of C₃ A into NC₁₄ A₅, this conversion being complete when the Na₂ O content reaches about 4.5 per cent by weight. A further increase in Na₂ O content results in a solid solution of Na₂ O in NC₁₄ A₅ until, when the Na₂ O content reaches about 6 per cent by weight, yet a further phase forms resulting in a decrease of the NC₁₄ A₅ content. Phases containing more than 2 per cent or less than 10 per cent by weight of Na₂ O contain sufficient NC₁₄ A₅ to be useful in cements in accordance with the present invention. It should be noted that when the solid solution limit of Na₂ O in NC₁₄ A₅ is exceeded an additional alumina molecule is required for each additional Na₂ O molecule, to maintain saturated solid solution, forming an alkali modified calcium aluminate increasingly richer in alumina or a solid solution of sodium aluminate. Some Na₂ O also enters into solid solution in the C₂ S phase and these two chemical substitutions together eventually preclude the simultaneous formation of C₃ S.

Reported hydration studies (V. P. Ryagin, Tsement No. 11, 1972, 20-21) of NC₁₄ A₅ or its solid solutions suggested that it has less hydraulic activity than pure C₃ A alone. However, we have found that by utilising NC₁₄ A₅ or related compounds in which the sodium is mainly or partially replaced by other alkali metals, to provide a substantial proportion of the hydraulic constituents of an otherwise primarily siliceous cement, together if necessary with retarders and/or accelerators selected and proportioned to provide a desired delay in setting to enable working and placing, it is possible to obtain a rapidly setting and hardening cement giving early strength but at the same time having a setting time which is controllable even in the presence of contaminants which are known to have a retarding effect upon conventional Portland cement.

According to the invention we provide an early strength hydraulic cement comprising: from 15 to 90 per cent by weight based on the cement, of an ortho-rhombic or tetragonal phase XC₁₄ A₅ which is NC₁₄ A₅ as herein defined or the corresponding phase in which the place of the sodium oxide is at least partly taken by at least one other alkali metal oxide; the balance being predominantly calcium silicates. The XC₁₄ A₅ may contain Na₂ O or other alkali metal oxide, or traces of other oxides, in solid solution. C₃ A with or without alkali metal oxides or traces of other oxides in solid solution may be present.

Preferably calcium sulphate in the form of natural or synthetic gypsums or soluble anhydrites is incorporated in the cement in order to obtain optimum strength development. Such an addition slightly retards the set but further small additions of retarders and/or accelerators effective to provide a desired setting time sufficient for the purpose for which the cement is intended are possible. These additional retarders are preferably conventional organic retarders for Portland cements such as citric acid, lignosulfonates and boric acid or special retarders such as sodium bicarbonate and di-sodium hydrogen orthophosphate. In some instances the addition during grinding of a small quantity of water may also be used to provide a retarding action. The preferred accelerators can be incorporated either as additions made to the raw feed, such as alkalies which are retained as alkali metal sulphate within the clinker during burning; or as additions either made at the grinding stage or blended into the final cement, such as potassium sulphate, conventional accelerators for Portland cement or grinding aids such as a mixture of triethanolamine and acetic acid.

The NC₁₄ A₅ or related compound may be incorporated into the cement in several ways. In one method the essentially pure compound may be separately prepared and interground with a Portland cement clinker or thoroughly blended in a finely divided form with a Portland cement. A second method involves the preparation of a clinker rich in NC₁₄ A₅ (or related compound) and sparse in C₃ S which is then interground with a Portland cement clinker or thoroughly blended in a finely divided form with Portland cement in order to provide a final product having a desired concentration of NC₁₄ A₅ or related compound. This method is useful where the risk is present of excess alkali inhibiting the formation of C₃ S in the clinker. A third method involves the preparation of the final cement directly by burning selected raw materials in the presence of an appropriate amount of an alkali metal compound such as sodium carbonate, the initial Al₂ O₃ content of the raw materials being sufficient to permit formation of the desired amount of a NC₁₄ A₅ or related phase during burning.

In each of these suggested methods, the NC₁₄ A₅ or related compound is formed by sintering or melting a mixture of a source of alumina, usually a kaolinitic clay such as china clay, ball clay or fire clay, a source of lime such as chalk or limestone, and a source of alkali such as sodium carbonate; the proportion of alkali being such as to allow where necessary for losses due to volatilisation during firing. The presence of small amounts of impurities or additions in the raw materials may be advantageous when such impurities or deliberate additions aid in the combination of the raw materials or by entering into solid solution in the C₂ S phase stabilise this phase, enhancing its strength by preventing its inversion to the γ-form. In the case of the preparation of the K₂ O-modified C₃ A, it has been found that the presence of a silicate phase and the incorporation of a small amount of iron oxide in the raw mix enhances the formation of this compound. It is believed that this may arise because some of the silica and iron oxide present, is also in solid solution in the potassium-modified C₃ A. It has also been shown that for certain applications of the cement of the present invention, where long term stability is not required, the presence of significant amounts of MgO can be tolerated, permitting the use in the raw feed preparation of a dolomitic limestone, otherwise precluded from normal Portland cement manufacture. Where the raw materials are prenodulised before firing it may be necessary to provide a source of alkali which is essentially insoluble in water. This prevents the formation of a heterogeneous distribution of alkali in the nodules during drying due to soluble matter tending to concentrate in the outer layers of the nodules. In conventional cement making processes in which materials are not prenodulised before being fed to the kiln, this additional step may not be necessary.

On firing the mixture discussed above at a temperature typically in the range 1350° - 1450°C to provide satisfactory degree of combination and on cooling at a rate sufficient to permit crystallisation, a clinker is obtained in which the presence of NC₁₄ A₅ or related compound may be confirmed by X-ray diffraction; the remaining phases being tricalcium silicate C₃ S and dicalcium silicate C₂ S with a calcium alumino ferrite, magnesia, alkali sulphates and the double sulphate 2CaS)₄.sup.. K₂ SO₄ and possibly either cubic C₃ A or C₁₂ A₇ with or without alkali metal oxides in solid solution present in minor quantities. In general the clinker is burned to a free lime content in the range of 1-3 per cent, but provided the requisite phases are formed, harder burning to lower free lime contents can be tolerated without loss in the physical properties. By intergrinding the clinker with Portland cement, the C₃ S and alkali modified C₃ A content can be adjusted in the final product to provide the desired strength properties. In general the higher the NC₁₄ A₅ content and the lower the C₃ S content, the higher the early strength but the lower the ultimate strength.

The quantity of calcium sulphate, expressed as SO₃, added to the cement in order to achieve optimum strength development lies typically between 0-15 per cent and preferably between 2-8 per cent. It has, however, been found that for compositions containing more or less Na₂ O than that required to form NC₁₄ A₅, the preferred range of SO₃ is often narrower. By increasing the CaSO₄ content in the cement either as natural or synthetic gypsum, soluble anhydrite, hemihydrate or a mixture thereof, the setting time can be extended.

The final product is normally ground to a surface area as specified by the air permeability test according to BSS.12 (1971), in the range 225-600 m² /kg, higher surface areas tending to shorten the initial set time and increase the early strength development. Further control of the setting times is possible by the incorporation in the final product of either an organic retarder, typically citric acid, or other organic hydroxy acids or inorganic retarders such as boric acid, sodium bicarbonate or di-sodium hydrogen orthophosphate. These may be ground with the clinker or in some instances either blended in the final cement before supply to a user, or supplied separately so that the user may add it during mixing in order to suit the setting time and hardening rate to his own requirements.

The cements of this invention may be used in a conventional way, employing good quality aggregates, in applications where a short initial setting time and high ultimate strength are desired. The cement also finds utility as a binder in fibre reinforced composites, as a binder for light-weight aggregates and as a bonding agent in the agglomeration of ores and foundry sands. The cements according to the present invention find special utility in binding material from coal measures even when contaminated with or consisting of coal, the organic constituents of which can have a considerable but unpredictable effect upon the behaviour of some other known rapidly hardening cements.

The preparation and use of cements in accordance with this invention is illustrated in the following Examples in which all percentages and proportions are by weight.

EXAMPLE 1

A clinker rich in alkali modified C₃ A was prepared as follows.

In order to avoid a heterogeneous distribution of soluble sodium carbonate during drying of pre-fabricated pellets of raw material, a source of largely insoluble Na₂ O was prepared by blending a china clay whose principal constituents were SiO₂ 48.2 per cent, Al₂ O₃ 36.0 per cent, Fe₂ O₃ 1.1 per cent and CaO 0.1 per cent, a finely divided silica (89.1 per cent SiO₂) and a sodium carbonate in the approximate proportions (dry basis) 55 per cent clay, 22 per cent silica, and 23 per cent sodium carbonate. The mix was sintered in an oil-fired furnace at 1000°C. for approximately 5 minutes to yield a product of the analysis:

SiO2          56.0 per centAl2 O3   21.0 per centFe2 O3   0.6 per centCaO                0.2 per centNa2 O (water soluble)              5.5 per centNa2 O (water insoluble)              10.7 per cent

This alkali-frit product was ground in a ball mill to a residue of 10 per cent on a B.S. 90 μm sieve and the Na₂ O source thus produced was blended to form a raw feed with the above china clay, and a whiting with the analysis:

SiO2       1.2 per centAl2 O3           0.2 per centFe2 O3           0.1 per centCaO             54.7 per centMgO             0.3 per centL.O.I           0.4 per centCO2        42.6 per centSO3        0.09 per centK2 O       0.04 per centNa2 O      0.06 per centMn2 O3           0.04 per centP2 O5 0.06 per centTiO2       0.01 per cent

in the approximate proportions (dry basis) 75.7 per cent whiting, 17.1 per cent china clay, 7.2 per cent Na₂ O source, these proportions being such as to allow for approximately 15 per cent loss of Na₂ O during firing. The raw feed was sintered in an oil fired furnace at about 1420°C to produce a free lime content as determined by the hot ethylene glycol extraction method of 1.3 per cent. The final clinker analysis was as follows:

SiO2       20.5 per centAl2 O3           12.0 per centFe2 O3           0.5 per centCaO             63.7 per centMgO             0.5 per centSO3        0.03 per centK2 O       0.2 per centNa2 O      1.5 per cent

The lime saturation factor as defined in BSS 12 (1971) of this clinker was 0.883, the silica ratio (S/A+F) 1.64 and the alumina ratio (A/F) 24.0. The potential phase analysis of this clinker as calculated from its oxide analysis, and assuming all the Na₂ O reacted with the calcium aluminate phase to form an NC₁₄ A₅ -- Na₂ O solid solution is:C₃ S 21.4 per centC₂ S 38.1 per centNC₁₄ A₅ (with Na₂ O in solid solution) 31.2 per centC₄ AF 1.5 per cent

together with other minor phases. The presence of the above principal phases was confirmed by X-ray diffraction techniques. A cement was prepared by grinding this clinker with gypsum and citric acid to a surface area of 468m² /kg measured by the air permeability method according to B.S.S. 12 (1971). The quantity of gypsum added was such as to give a total SO₃ content attributable both to the added gypsum and to that present in the clinker of 2.5 per cent as determined by analysis, whilst the amount of citric acid added was 1.5 per cent.

EXAMPLE 2

The cement of Example 1 was tested for setting time according to B.S.S. 12 (1971) and gave a time to initial set (per cent consistency water 30.3 per cent) of 14 minutes and a time to final set (per cent consistency water 30.3 per cent) of 20 minutes.

The pumpability time of a paste having a water/cement ratio of 0.5 was 10 minutes.

A concrete for compressive strength tests was made up from 1 part cement, 2.5 parts Mount Sorrel granite, 3.5 parts of Curtis sand and 0.6 parts water. The test results were as follows for the compressive strengths of 100 mm concrete cubes:

After 1     hour         50      p.s.i2           hours        765     p.s.i4           hours        860     p.s.i8           hours        910     p.s.i24          hours        1090    p.s.i3           days         1535    p.s.i7           days         1745    p.s.iAfter 28    days         2420    p.s.i3           months       3305    p.s.i

EXAMPLE 3

The cement of Example 1 was used as a binder for a coal shale, the overall composition of the mix being 1 part cement, 6 parts dry shale and 2 parts water. The setting time of the slurry produced was approximately 10 minutes and the compressive strengths of 100 mm cubes of the mix were:

After 2 hours             110 p.s.i4 hours                   110 p.s.i24 hours                  110 p.s.i3 days                    155 p.s.i7 days                    245 p.s.i28 days                   265 p.s.i

EXAMPLE 4

The cement described in Example 1 was prepared without a citric acid addition and tested as in the previous Example except that the coal shale and cement were initially mixed dry before water was added and the final mix placed. The approximate setting time was 20 minutes and the compressive strengths of the cubes were:

After 1/2   hour         17      p.s.i1           hours        50      p.s.i2           hours        110     p.s.i4           hours        110     p.s.i24          hours        110     p.s.i

EXAMPLE 5

The cement of Example 1 was modified by replacing half the gypsum added at the grinding stage by potassium sulphate, the total SO₃ content of the cement being raised to 2.5 per cent as before. 2.5 per cent citric acid was added to the cement. A paste prepared from the cement with a water/cement ratio of 0.5 had a pumpability time of 10 minutes; when the cement was used as in Example 3 as a binder for coal shale, the approximate setting time was 45 minutes and the compressive strengths were:

After 2      hours        130 p.s.i4            hours        140 p.s.i24           hours        150 p.s.i

EXAMPLE 6

The cement of Example 1 was modified by adding a mixture of 0.15 per cent of the final cement of triethanolamine and 0.07 per cent of the final cement of acetic acid as a grinding aid to the clinker and gypsum before grinding. 2.5 per cent citric acid was added to the cement which was tested as in the previous Example.

The paste with a water/cement ratio of 0.5 had a pumpability time of 10 minutes. The approximate setting time was 45 minutes and the compressive strengths were:

After 2      hours        135 p.s.i4            hours        150 p.s.i24           hours        180 p.s.i

EXAMPLE 7

The cement of Example 1 was admixed with sand and molasses to make up a conventional foundry sand in which the quantity of cement was 7.8 per cent. The compressive strengths of 2 inch × 2 inch air cured cylinders formed from this mix were:

After 3      hours        110 p.s.i6            hours        172 p.s.i24           hours        320 p.s.i

EXAMPLE 8

The cement of Example 1 was used as a binder for ground iron ore by producing a mix of 8 parts iron ore, 1 part cement and 1 part water. The compressive strengths of 1 inch × 1 inch air cured cubes formed from this mix were:

After 2     hours        94      p.s.i4           hours        171     p.s.i6           hours        337     p.s.i

EXAMPLE 9

A raw material mix was prepared as in Example 1, the materials being blended in the approximate proportions (dry basis) 73.7 per cent whiting, 16.4 per cent china clay, 2.1 per cent aluminum oxide and 7.8 per cent Na₂ O source, and was sintered in an oil fired furnace at about 1420°C. to produce a free lime content of 1.0 per cent as determined by the hot ethylene glycol extraction method. The final clinker analysis was as follows:

SiO2       19.9 per centAl2 O3           14.2 per centFe2 O3           0.65 per centCaO             58.8 per centMgO             0.5 per centSO3        0.12 per centK2 O       0.1 per centNa2 O      1.6 per cent

It had a lime saturation factor of 0.802, a silica ratio of 1.34 and an alumina ratio of 21.8. The potential phase analysis, calculated as in Example 1 was:

C2 S            57.1 per centNC14 A5 with NA3 O in solid solution                35.0 per centC3 A            1.7 per centC4 AF           2.0 per cent

together with other minor phases, the presence of the principal phases being confirmed by X-ray diffraction techniques.

A cement was prepared by grinding this clinker with gypsum and citric acid to a surface area of 492 m² /kg measured by the method previously described. The quantity of gypsum added was such as to give 2.5 per cent SO₃ in the final cement and the citric acid added was 2 per cent.

The pumpability time of a paste with a water cement ratio of 0.5 per cent was 10 minutes.

The cement when used as a binder for coal shale in Example 3 gave a slurry setting time of approximately 45 minutes and compressive strengths of 100 mm cubes of:

After 2      hours        140 p.s.i4            hours        145 p.s.i24           hours        145 p.s.i

EXAMPLE 10

A raw material mix was prepared as in the previous Examples, the material being blended in the approximate proportions (dry basis) 74.2 per cent whiting, 7.5 per cent china clay, 7.7 per cent aluminium oxide and 10.6 per cent Na₂ O source, and was sintered in an oil fired furnace at about 1380°C. to give a free lime content of 1.5 per cent, as determined by the method previously specified. The final clinker analysis was as follows:

SiO2       17.3 per centAl2 O3           18.7 per centFe2 O3           0.5 per centCaO             58.9 per centMgO             0.5 per centSO3        0.1 per centK2 O       0.3 per centNa2 O      2.3 per cent

It had a lime saturation factor of 0.827, a silica ratio of 0.90 and an alumina ratio of 37.4. The potential phase analysis, as calculated in the previous examples was:

C2 S          49.0 per centNC14 A5 (with Na2 O in solid    solution)      48.0 per centC4 AF         1.5 per cent

together with minor phases, the presence of the principal phases being confirmed by X-ray diffraction techniques. A cement was prepared by grinding this clinker with gypsum and citric acid to a surface area of 470m² /kg as measured by the method previously specified. The quantity of gypsum added was such as to give 2.5 per cent SO₃ in the final cement and the citric acid added was 3.0 per cent.

The pumpability time of a paste with a water cement ratio of 0.5 was 12 minutes.

The cement was used as a binder for coal shale as in the previous Example and gave a slurry setting time of approximately 45 minutes and compressive strengths of 100 mm cubes of:

After 2      hours        150 p.s.i4            hours        150 p.s.i24           hours        160 p.s.i

EXAMPLE 11

A raw material mix was prepared as in the previous Example, the material being blended in the approximate proportions (dry basis) 74.4 per cent whiting, 13.0 per cent Na₂ O source, 12.6 per cent aluminium oxide, and was sintered in an oil fired furnace at about 1380°C to yield a free lime content of 1.4 per cent as determined by the method previously specified. The final clinker analysis was as follows:

SiO2       14.9 per centAl2 O3           22.9 per centFe2 O3           0.4 per centCaO             58.3 per centMgO             0.5 per centSO3        0.1 per centK2 O       0.3 per centNa2 O      3.0 per cent

It had a lime saturation factor of 0.839, a silica ratio of 0.64 and an alumina ratio of 57.2. The potential phase analysis as calculated in the previous Examples was

C2 S       40.0 per centNC14 A5           57.0 per centC4 AF      1.2 per cent

together with minor phases, the presence of the principal phases being confirmed by X-ray diffraction techniques.

A cement was prepared by grinding this clinker with gypsum and citric acid to a surface area of 450 m² /kg as measured by the method previously specified. The quantity of gypsum added was such as to give 2.5 per cent SO₃ in the final cement and the citric acid added was 3.5 per cent.

The pumpability time of a paste with a water cement ratio of 0.5 per cent was 10 minutes.

The cement when used as a binder for coal shale as in Example 3 gave a slurry setting time of approximately 35 minutes and compressive strengths of 100 mm cubes of:

After 2      hours        150 p.s.i4            hours        160 p.s.i24           hours        160 p.s.i

EXAMPLE 12

A cement was prepared by intergrinding 80 per cent of the clinker prepared as in Example 9, with 20 per cent of a Portland cement clinker, gypsum and citric acid to a surface area of 450 m² /kg as measured by the method previously described. The P. C. clinker employed had an analysis as follows:

SiO2   20.2      P2 O5                      0.16    SO3                                     1.0Al2 O3   5.1       TiO      0.11    K2 O                                     0.93Fe2 O3   4.6       CaO      65.0    Na2 O                                     0.37Mn2 O3   0.1       MgO      0.9

It had a lime saturation factor of 0.99, a silica ratio of 2.08, an alumina ratio of 1.11 and a free lime content of 1.8 per cent. Its potential phase analysis as calculated from the oxide analysis was:

C4 AF      14.0 per centC3 A       5.8 per centC2 S       5.0 per centC3 S       70.1 per cent

The resultant potential phase composition of the final cement, taking into account only the clinkers was thus:

C3 S          14.0 per centC2 S          46.7 per centC3 A          2.5 per centNC14 A5 (with Na2 O in solid    solution       28.0 per centC4 AF         4.4 per centFree lime          1.2 per cent

The quantity of gypsum added was such as to give a total SO₃ in the cement of 2.5 per cent and the quantity of citric acid added was 1.0 per cent.

The pumpability time of a paste with a water/cement ratio of 0.5 was 9 minutes. The cement when used as a binder of coal shale as in the previous Examples gave a slurry setting time of approximately 15 minutes and compressive strengths of 100 mm cubes of:

After 2     hours        75      p.s.i4           hours        85      p.s.i24          hours        125     p.s.i

EXAMPLE 13

A cement was prepared by intergrinding 30 per cent of the clinker as prepared in Example 11 with 70 per cent of the Portland cement clinker used in the previous Example, gypsum and citric acid to a surface area of 450 m² /kg as measured by the method previously specified. The resultant potential phase composition of the final cement, taking into account only the clinkers was thus:

C3 S          49.1 per centC2 S          15.5 per centC3 A          4.1 per centNC14 A5 (with Na2 O in solid    solution)      17.0 per centC4 AF         10.2 per centFree Lime          1.7 per cent

The quantity of gypsum added was such as to give a total SO₃ in the cement of 2.8 per cent and the quantity of citric acid added was 1.0 per cent.

The pumpability time of a paste with a water cement ratio of 0.5 was 9 minutes. The cement when used as a binder of coal shale as in the previous Example gave a slurry setting time of approximately 20 minutes and compressive strengths of 100 mm cubes of:

After 2     hours        40      p.s.i4           hours        80      p.s.i24          hours        120     p.s.i

EXAMPLE 14

The cement described in the previous Example was tested as in Example 2 for setting times according to BSS 12 (1971) and gave a time of initial set (per cent consistency water 35 per cent) of 30 minutes and a time to final set (per cent consistency water 35 per cent) of 40 minutes. The compressive strengths of concrete cubes prepared as in Example 2 were:

After 1     hour         40      p.s.i2           hours        160     p.s.i4           hours        210     p.s.i24          hours        1207    p.s.i

EXAMPLE 15

The composition of the clinker described in Example 1 was modified by preparing a raw material mix by blending in the approximate proportions (dry basis) 70.5 per cent whiting, 17.8 per cent china clay, 6.8 per cent Na₂ O source and 5.6 per cent magnesium oxide. This was sintered in an oil fired furnace at about 1380°C. to produce a free lime content of 0.7 per cent as determined by the method previously described. The final clinker analysis was as follows:

SiO2       19.6 per centAl2 O3           11.0 per centFe2 O3           0.5 per centCaO             54.7 per centMgO             8.85 per centSO3        0.20 per centK2 O       0.40 per centNa2 O      1.30 per cent

It had a lime saturation factor of 0.80, a silica ratio of 1.70 and an alumina ratio of 22.0. The potential phase analysis as calculated in Example 1 was:

C3 S        NilC2 S        56.2 per centNC14 A5            28.4 per centC4 AF       1.5 per centFree Lime        0.7 per cent

together with other minor phases, the presence of the principal phases being confirmed by X-ray diffraction techniques.

A cement was prepared by grinding this clinker with gypsum and citric acid to a surface area of 450 m² /kg as measured by the method previously described. The quantity of gypsum added was such as to give 2.5 per cent SO₃ in the final cement and the citric acid addition was 1.0 per cent.

The pumpability time of a paste with a water cement ratio of 0.5 was 10 minutes.

The cement when used as a binder for coal shale as in Example 3 gave a slurry setting time of approximately 10 minutes and compressive strengths of 100 mm cubes of:

After 2     hours        105     p.s.i4           hours        105     p.s.i24          hours        110     p.s.i

EXAMPLE 16

A clinker rich in alkali modified C₃ A in which the C₃ A phase was modified by both Na₂ O and K₂ O entering into solid solution was prepared as follows:

A potash feldspar of the analysis:

SiO2       65.9 per centAl2 O3           18.5 per centFe2 O3           0.1 per centCaO             0.5 per centMgO             0.1 per centSO3        0.1 per centK2 O       11.6 per centNa2 O      2.9 per cent

was ground in a ball mill to a residue of 10 per cent on a B.S. μm sieve and was blended with the whiting and china clay used in Example 1 and an iron oxide and aluminium oxide in the approximate proportions (dry basis) 74.0 per cent whiting, 14.8 per cent potash feldspar, 6.4 per cent china clay, 1.5 per cent iron oxide and 3.3 per cent aluminium oxide. These proportions being such as to allow for a loss of K₂ O during firing.

The raw feed was sintered in an oil fired furnace at about 1420°C. to produce a free lime content of 1.4 per cent as determined by the method previously specified.

The final clinker analysis was as follows:

SiO2       21.6 per centAl2 O3           11.7 per centFe2 O3           2.3 per centCaO             58.3 per centMgO             0.5 per centSO3        0.1 per centK2 O       2.3 per centNa2 O      0.7 per cent

The lime saturation factor of this clinker was 0.767, the silica ratio 1.54, and the alumina ratio 5.09. The potential phase analysis of this clinker as calculated from its oxide analysis and assuming all the Na₂ O had entered into solid solution in the calcium aluminate phase and that sufficient K₂ O was also in solution to modify all of the C₃ A was as follows:

C2 S          61.9 per centNC14 A5 -KC14 A5 -alkali solidsolution           27.5 per cent*C4 AF         7.0 per cent *`K` represents K2 O.

together with other minor phases. The presence of the above principal phases was confirmed by X-ray diffraction techniques. No cubic C₃ A was detected.

A cement was prepared by grinding this clinker with gypsum and citric acid to a surface area of 470 m² /kg as measured by the previously specified method. The quantity of gypsum added was such as to give 2.5 per cent SO₃ in the cement, whilst the amount of citric acid added was 1.0 per cent.

The pumpability of a paste having a water/cement ratio of 0.5 was 10 minutes.

When used as a binder for a coal shale as in Example 3, the setting time of the slurry produced was approximately 20 minutes. The compressive strengths of 100 mm cubes of the mix were:

After 2     hours        90      p.s.i4           hours        100     p.s.i24          hours        110     p.s.i