AU720945B2 - Curable gypsum-containing composition and method for stabilization of unconsolidated core samples - Google Patents
Curable gypsum-containing composition and method for stabilization of unconsolidated core samples Download PDFInfo
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48536DIV DP:MN P/00/011 Regulation 3.2
AUSTRALIA
Patents Act 1990 COMPLETE SPECIFICATION FOR A STANDARD PATENT
ORIGINAL
RESLAB A/S *Actual Inventor(s): HJELMELAND, ODD; ARDO,BJORN *Address for Service- COLLISON CO.,117 King William Street, Adelaide, S.A. 5000 Invention Title: CURABLE GYPSUM-CONTAINING COMPOSITION AND METHOD FOR STABILIZATION OF UNCONSOLIDATED CORE SAMPLES The following statement is a full description of this invention, including the best method of performing it known to us: •Name of Applicant:
S
RESLAB A/S Actual Inventor(s): HJELMELAND, ODD; ARDO,BJORN Address for Service: COLLISON CO.,117 King William Street, Adelaide, S.A. 5000 Invention Title: CURABLE GYPSUM-CONTAINING COMPOSITION AND METHOD FOR STABILIZATION OF UNCONSOLIDATED CORE SAMPLES The following statement is a full description of this invention, including the best method of performing it known to us: WO 96/38394 PCI/N096100 r t 6 1A CURABLE GYPSUM-CONTAINING COMPOSITION AND METHOD FOR STABILIZATION OF UNCONSOLIDATED CORE SAMPLES The invention concerns a curable gypsum-containing composition for the production of a cured gypsum-based matrix, and a method for stabilization ofunconsolidated core samples, according to the introductory of claims 1 and 9, respectively.
Technical background In the production of gypsum articles, casting molds of gypsum and in building applications, such as for wall finishing, for example, it is known to use a solution/suspension of calcined gypsum, optionally added set accellerating or set retarding substances. A common feature of such curing gypsum systems is that the pot life or the time until gelation is about one half of the time to obtain full strength. The disadvantages of set retarding additives for gypsum/water compositions is that the compositions after application to a wall S".i 15 or into a mold, will creep or block the form for a long period of time. Some retarding substances require from 15 minutes to 8 hours to obtain a strength level allowing further processing or handling, dependent on the portion of the retarding substance. On the other Se• hand, normal or set-accelerating additions to gypsum compositions may result in a short pot life since gelation may occur from one minute to fifteen minutes after the preparation of the composition. This may result in problems such as hardening in mixer units and pumps and lead to clogging or blocking of the equipment.
Accordingly, there is a need for a curable gypsum-based composition providing a gypsum composition ready for use, a composition having a long pot life but short setting time after appliaction and preventing creep from for example a finished wall.
In another aspect, core samples are obtained from oil and gas drilling both off-shore and onshore by means of special drill heads provided with a central cylindrical bore. When the sylindrical bore or space extending form the drill head and a certain distance up the drill stern is full, the drill stem is withdrawn, and a so-called core sample is removed from the same.
These core samples represent some of the most important material available for evaluation of the quality of the hydrocarbon-containing sedimentary rock types to be searched for. For that reason it is of considerable importance that the samples are protected from both WO 96/38394 PCTINO96/00116 2 mechanical and chemical strain to obtain correct values from the subsequent evaluation and analysis.
The gelogists evaluation and analysis of the humidity properties of the sample, permeability, porosity and oil and water content, can provide the limits of the gas- and oilcontaining layer thickness, the expected quantity of oil and/or gas to be produced, and the availability of the oil or gas. Therefore, it is important that these samples are as close in the reservoar to their original condition as possible, to provide a proper basis for both visual evaluation of the core material and subsequent analysis. In many cases, the samples are poorly consolidated and have to be protected from disintegration during transportation from the reservoir, during preparative cutting and drilling with diamond equipment and during the following analysis.
Presently, there are one of two important methods used to protect the cores mechanically during tansportation, core sampling and storage. These methods have different advantages and disadvantages: 15 1. Freezing core samples with liquid nitrogen This method will stabilize all core samples containing water and oil since the sand is locked in a matrix consisting of ice and oil-based glass. However, because of the water expansion during freezing, the core material will often be damaged in the process. The damage is caused by the fact that the inherent weak bonds between the sand particles are broken (more or less) because of frost cracking during the freezing step. After cutting with a diamond saw in a frozen condition, the core samples are not suitable for geological evaluation as the samples have been reduced to more or less freely flowing sand. After drilling of test plugs, mounting and thawing in analysis equipment, this frost cracking also frequently causes handling problems which again result in practical problems during subsequent analysis and testing.
2. Stabilisation of core samples in core sample tubes/pipes from injection of a quicksetting two component polymer mass.
A polymer mass is injected in a sickle-formed space between the core sample and the core sample tube. The commonly used polymer mass is based upon polymerization of an aromatic isocyanate composition (MDI/PMDI) catalyzed by a tertiary amine. The catalyst is often triethylene diamine (N(CH,-CH 2 3 or 1,4-diazabicyclo(2,2,2)-octane.
WO 96/38394 PCT/N096/0016 3 Research has shown that the method may involve formation of secondary products which may change the humidity properties of the samples. Moreover, in the hardening step there health hazardous secondary products may be formed and which may be liberated in subsequent working and cleaning of the core sample material.
The polymer material which is formed during the polymerzation is a polyurea, and this material is sensitive to high temperatures. During core sample cutting with a diamond saw, local elevated temperatures can result, and in addition to health hazardous secondary products, some monomeric isocyanate including the more complex degradation products can be formed. The formation of such compounds make it desirable to use other methods to eliminate the risk of liberation of health hazardous products in the processing steps.
i.:!:General evaluation of different other protecting nialerials: After having performed a critical research of different possible organic based materials, it appears that the most of them have the potential to cause various type of problems. Such problems will usually arise from the fact that the curing processes are strongly affected by S.temperature, the mass ratio between water and oil in the core, the type of drilling fluid, the pH of the drilling fluid, and so on. Moreover, it appears that the humidity properties of a core sample may change due to migration of surface-active monomeric derivatives. These products usually arise from side reactions with polar components in the oil or additives in o* the drilling fluid. Moreover, it appears that more or less serious industrial hygiene problems S.may arise when several potentially applicable organic polymers are heated in connection with slabbing and core sampling where the core sample material is cut with diamon equipment.
Rinsing with strong solvents in connection with preparation of core samples prior to analysis may also give rise to industry health problems because of the risk of extraction of low molecular poisonous compounds from polymers polymerized in unfavourable conditions.
Inorganic materials of a concrete basis may result in problems with slow strength formation. However, there are concrete types available which set rapidly, including additives controlling the setting rate, but none of these allow removal of possible permanent mineral precipitate which may cause local permeability and porosity damage in the core sample material without simultaneously causing damage to the core sample. The setting process can, as mentioned above, now be controlled by the addition of surface-active organic agents, but WO 96/38394 PCT/NO96/00116 4 these agents may again result in undesirable changes in the humidity properties of the core samples. In a low-speed setting environment the samples must be left stationary for a longer period of time, thus preventing normal activity on the drilling floor. As a consequence of said properties, protection with concrete will cause a risk of irreversible changes in the core samples, which again result in increased uncertainty in the metering results.
Object An object of the invention is to provide a curable gypsum-based composition for the production of cured gypsum, enabling an efficient use of gypsum as material in different situations, such as in building constructions, for example wall and floor finishing, production of casting molds ofgypsum and in the production ofgypsym articles in general.
Another object of the invention is to provide a method of stabilizing core samples of unconsolidated material from drilling holes, in a way which does not affect the core material 9* S:chemically or physically and thereby causes as little as possible change in humidity 15 properties, porosity and permeability. In addition, it is desirable that the protected material does not result in industry health problems caused by the liberation of health hazardous compounds in subsequent handling operations.
Because of the short period of time available for core sampling on a drilling rig for example, and a wish for quick protection-of the material to mechanical damage without affecting the humidity properties and subsequent industry health problems, there is a need for a quick-setting inorganic protecting material. In addition, the curing material should have S properties allowing for a proper control of the curing time in practical applications. The composition should, in a mixed condition, maintain its fluid state for 5 to 8 minutes, thus allowing the mass of material to enter all cavities before setting. Because of the time limitation mentioned above, the composition should set sufficiently to allow the core samples to be moved without risk of damage during 10 to 20 minutes, thus ensuring that the time required to protect the core samples does not delay the costly drilling operation more than is absolutely necessary.
To ensure the core sample is not contaminated by the protecting material, it should be possible to remove the latter by flushing with a liquid not affecting the properties to be examined at a later stage.
WO 96/38394 PCT/NO96/00116 The invention These objects are achieved by a composition according to the characterizing pan of claim 1 and a method according to the characterizing part of claim 9. Further advantageous features appear in the respective dependent claims.
In one aspect, the invention is related to a curable gypsum-based composition for the production of cured gypsum for, wall finishing, production of gypsum articles, and production of casting molds of plaster, by using a water solution of calcined gypsum comprising a set retarding substance. According to the present invention, the composition comprises a two-component composition comprising: a first component comprising calcined gypsum suspended in water, and a set retarding substance comprising an organic acid containing at least two acid groups selected from the group .consisting ofcarboxyl, sulphate, sulphonate, phosphate or phosphonate, said acid optionally also containing at least one hydroxyl group per molecule; and/or 15 (ii) inorganic anions selected from the group consisting of polyphosphate and polyborate, or mixtures thereof, and a second component comprising a set accelleating substance comprising (iii) water soluble salts of multivalent metal ions, and optionally (iv) organic or inorganic salts of ammonium and/or elements from the first group 20 of the periodic table of elements.
The set retarding substance preferably comprises citric acid, fruit acid or polyphosphate.
.Moreover, it is preferred that the set retarding substance constitutes 0.001-0.5 preferably 0.01-0.2 and most preferred from 0.02 to 0.1 by weight of the gross water quantity in the first component In accordance with the invention, the set accellerating substance in the component (b) above comprises multivalent metallic ions, such as easily soluble salts of Fe(III), Fe(II), AI(III), Gallium(III), Titanum(IV), Zirkonium(IV), Vanadium(III), Cobolt(III) and/or Chromium(Ill). In view of availability, health hazard and effect, it is preferred to use salts ofFe(III), Fe(II) and AI(III).
WO 96/38394 PCTI096/00116 6 The multivalent cations in component form complexes with, or precipitate the set retarding substances in component thus preventing or eliminating the effect of the latter on the hydration reaction between water and calcined gypsum.
Moreover, it is preferred that component which preferably is present in a solution, also contains set accellerating substances in the form of easily soluble salts of ammonium, such as NH 4 CI, and/or easily soluble salts of metals from the first group of the periodic table of elements, such as NaCI, KCI and K2S0 4 Combinations thereof can also be used.
When the set retarding substance of component in general comprises phosphate or a polyphosphate, it is preferred to use salts of AJ(III) in the set accellerating component thus avoiding discoloring of the end product, which may occur from the use of ferric ions.
As set forth in further detail below, one or both of the components, preferably component may in addition contain crystallization seeds in the form of comminuted gypsum (CaSO 4 2H20O) to promote the setting rate of the curable composition.
In use, separate units of component and above are prepared, wherein the retarded gypsum suspension may exhibit a pot life of about 1 hour. The pot life may, if desired, be changed by altering the quantities of the components. Immediately before use, component is mixed with the accellerator component whereupon the gypsum composition obtains a gelation time of 2-15 minutes, preferably 5-19 minutes.
Accordingly, the composition according to-theinvention provides a gypsum-based curable composition having a long pot life and a short setting time, thus enabling effective use of said material in different fields of use, such as for wall finishing, production of casting molds for casting of different plaster products in industry and in construction engineering, and many other uses are conceivable. The selection of set controlling substances and the concentration thereof will usually vary from one application to another.
In another aspect, the invention is related to a method for stabilizing unconsolidated core samples taken from drilling holes. We have surprisingly found that different types of calcined gypsum (CaSO 4 '/H20 and CaSO 4 which re-crystallize to form gypsum (CaSO 4 2HO) by addition of water, are well suited for protection of poorly consolidated core sample material.
Since gypsum expands linearly 0.2-0.3% during hardening, this material is suited for locking and supporting of the core material to be used. Moreover, it is convenient to control the WO 96/38394 PCIU096/00116 7 setting time for gypsum wihin wide limits through additions having low molecular weight.
The additives used in this case shall have small or no effect on the humidity properties.
In the following, the invention is described with emphazis on encapsulation of unconsolidated core material from drilling holes, since the basic idea of the invention is common for both emdodiments.
Particularly in encapsulation of core samples, gypsum has in addition to the other properties an advantage of being easily removable fom the core material. This is achieved by flushing with water solutions having a high content of salts such as NaCI, NaAc, Na 2
SO
4 KCI, KAc, K 2
SO
4
NH
4 CI, NHAc, (NH 4 or if necessary, through additions of sugar alcohols as glycerol, sorbitol, maltitole, different mono- and di-saccarides and complexforming compounds as NTA and EDTA. The list above should not be considered limiting to low molecular compounds which may contribute to increased solubility of gypsum. When organic additives are used, the water must still contain at least 0.5% salt (NaCl/KCI) to *prevent migration of clay particles.
For example, one of the parameters affecting flow property, concentration of gypsum in the gypsum slurry and the strength of cured gypsum, is the quality of the calcined gypsum used. There are two major types of calcined gypsum having the formula (CaSO- 4
',H
2 0) in use today: the a form which is formed by dehydration of gypsum to calcined gypsum in an atmosphere of saturated water vapour, in boiling pressurized water or in salt solutions at elevated temperatures and a certain pressure, and the P form which is produced by dry heating of gypsum. Whereas the a form allows for high density and high compression -strength within a heavy but to a certain degree brittle final product, the P form will provide a final product having a lower total compressive strength because of a lower gypsum content, but the products are in return less brittle because of the particular structure.
Moreover, there are other qualities of dry calcined gypsum (CaSO,) which also easily cure to form gypsum (CaSO 4 -2H20) in the presence of water. The different qualities of dry calcined gypsum are obtained by varying the calcining temperature from 100 to 700 0 C and changing the curing profile. The most commonly used commercial qualities of the P form of calcined gypsum (CaSO4-/H 2 0) also contain smaller amounts of dry calcined gypsum (CaSO,), and therefore in practice the curing process for gypsum qualities of this type consists of several simultaneous hydrating reactions.
WO 96/38394 PCr/N096100116 8 It is commonly known that the most of the calcined gypsum qualitites enable production of a curing material when mixed with water. Moreover, it is known that such compositions may contain larger or smaller amounts of substances accellerating or retarding the curing process.
It is known to accellerate the curing process of gypsum through the addition of some water soluble salts to the plaster slurry, such as NaCI, NaAc, Ns 2 SO,, KCI, KAc, KSO 4
NH
4 CI, NH 4 Ac, (NH4)SO 4 without limitation. Addition ofaccellerators allow for production of a plaster slurry, water and accellerator additives which is able to set and harden to a solid mass within 2-30 minutes, dependent on the quantity of accelerating additives and the gypsum quality used. By selecting a proper quantity for supply, dependent on type, quality and concentration of gypsum in the plaster slurry, the setting time (with some limitations) may be adjusted to a desired value.
Moreover, there are insoluble salts having a crystal structure catalyzing the conversion from one form or another of calcined gypsum to gypsum. In this connection, gypsum 15 (CaSO 4 -2HO) must be emphasized, since this salt in a comminuted form will increase the conversion rate by increasing the number of seeds.
By increasing the curing time one may use additions of multivalent organic acids such as citric acid, fruit acid and their soluble salts, simple phosphates, condensed phosphates or borates. There are no distinct rules for the chemical structures, which in low concentration 20 establish a bond to components in a curing gypsum system, and the hardening process is retarded simultanesously and the requirement of forming sufficiently stable precipitates or complexes with supplied multivalent metal ions which result in blocking of the retarding effect. But within the group organic polyanions there will be many compounds having the ability of extending the setting time of gypsum vith varying effectiveness. Organic polyanions will then be based on containing at least two carboxyl, sulphate, sulphonate, phosphate and phosphonate groups, or mixtures thereof, optionally also one or more hydroxy groups.
Inorganic anions having the same effect are condensed borates, simple and complexed phosphates, particularly Grahams salt.
The simplest embodiment of the method in accordance with the invention is characterized in that a predetermined quantity of gypsum is mixed with a predetermined quantity of fresh water, or water of similar quality, forming a liquid slurry, and then filling the slurry in the slit WO 96/38394 PCT/N096/00116 9 space between the core sample and the core sample tube whereupon the slurry hardens and provides sufficient stiffness and protection of the core sample within 10-30 minutes, and hardens completely within about twice the time set forth above. The resulting plaster slurry may also contain one or more accellerating substances in varying quantities, so that the time required to obtain sufficient stiffness and protection of the core sample may be decreased to a desired level of between two minutes and the native setting time of the plaster slurry without additives, but preferably with a hardening time of from 8 to 20 minutes.
When stabilizing several poorly consolidated core samples quickly one after another, the operations may result in stress on the operator because the time between mixing and gelation is fairly short if the gypsum is to have a sufficient stiffness within 10-15 minutes to thereby allow the core samples to be moved. Continous weighing of calcined gypsum coupled with volumetric dosing of water or acccelerator solution in a mixing unit results in further practical problems as dosing of a hygroscopic powder having a poor flow property, as the case is with gypsum, is practically difficult. However, the flow property of the gypsum 15 powder may be enhanced through the addition of hydrophobic silica or stearate salts from the second and third main group of the periodic table of the elements. This type of additives, however, may interfer with the porosity, permeability or the humidity properties of the samples.
As mentioned above, handling and continous weighing is problematic when a hygroscopic 20 powder having a poor flow property is present in a humid environment. Moreover, the plaster slurry formed must be able to be pumped continously from a mixer unit to the user location. The demand on low viscosity of the plaster slurry interferes with a desire for quick gelation and establishment of strength. In shorter interruptions in a casting operation using continous weighing and mixing, the plaster slurry will tend to harden in the apparatuses, which again requires a cleaning operation to remove cured gypsum mass before the casting operation can take place. Such problems will cause a time delay and therefore incur increased costs in connection with sample core protection.
The viscosity of the plaster slurry may also be modified through additives. It is known that addition of substances such as alkylaryl sulphonates, lignosulphonates and melamines provides improved flow of gypsumrn/water compositions and in this way provide pumpability even with a low water content. An important disadvantage is that these compounds, often WO 96/38394 PCT/NO96/00116 having a high molecular weight, also may affect the humidity properties of the core sample material. Additives of this type are for that reason avoided.
Based upon the available knowlegde of the effect of different compounds on gypsum hardening including the knowledge of structure, stability and rate of formation of complexes and precipitates from anions and multivalent cations, we have surprisingly found that it is possible to produce a hardening system based upon calcined gypsum in water including additives, which in practice perform like a system hardening through mixing of two flowing components. The hardening system is characterized in that gypsum, which initially has become retarded through the addition of certain anions, again retain a hardening rate close to the original by adding cations establishing a bond to the anions added with a strength sufficient to substantially suspend the anion's effect on the curing rate. The process is also 66 characterized in that the addition may contain one or more chemical components increasing the hardening rate above the native hardening rate of the plaster slurry.
*6#6 Since the different qualities of calcined gypsum (CaSO 4 1/ 2 HO) and dry calcined gypsum "i 15 (CaSO 4 with the different combinations of additives provides a variety of ways of acheiving the desired process, it is in practice impossible to describe all these possibilities. In the following, there is set forth a description of some examples of possible compositions with a commonly available 3 form of calcined gypsum. The description primarily shows examples i of typical quantities which may be used to obtain a result useful for encapsulation of core 20 samples. This is not meant to limit the number of possible compositions and quantities which can provide useful protection of core samples. The possibility of using a similar process in other industrial operations based upon different types of calcined gypsum, water and 6O*6 additives in a composition or mixture is not precluded either.
A retarded plaster slurry is formed of 3 gypsum with retarding additives which are dispersed in the water which is not to be used for metal ion solvation, which again will increase the hardening rate of the plaster slurry. A plaster slurry with decreased hardening rate is characterized by containing from 0.001 to 0.5 retarding compounds based upon the water quantity in the form of an organic acid or the anion of the acid. Preferably, the plaster slurry should contain from 0.01 to 0.2% organic acid in one form or another, and perferably from 0.02 to 0O. 1% retarding material in the form of a free acid or its anions all based upon the total water quantity. Moreover, the retarded plaster slurry is characterized WO 96/38394 PCTINO96/00116 11 in using citric acid, fruit acid or their salts as organic anionic additive. Other organic acids which may provide a desired effect are available, and they are characterized by containing two or more carboxyl, sulphonate, sulphate, phosphonate and/or phosphate groups optionally including one or more hydroxy groups in the same molecule.
The remainder of the water is required to dissolve a salt ofmultivaltent metal ions forming complexes or insoluble salts of the acids or of their anions, thus substantially eliminating the retarding effect of the acids or their anions on the hardening rate. This will cause the hardening rate of a plaster slurry to approach the rate of a slurry without addition of retarding substances. The metal ions used for this purpose are characterized by a rapid formation of complexes or insoluble salts with the acids or their anions, which extend the hardening time of the gypsum. The complexes or insoluble salts formed are characterized by being so stable that the effect of the acids or the salts on the gypsum hardening rate is substantially neutralized.
In accordance with the present invention, it has been found that the Fe(III) ion is the 15 cation which is most suited for forming a complex or an insoluble salt with the acids/salts inhibiting the gypsum hardening process, and having a stability causing the acids or anions to all substantially be removed. However, bivalent ferric ions may also be added, which by S oxidation with dissolved oxygen or a water soluble oxidating agent produce trivalent ferric ions providing the desired effect.
20 When using phosphate or condensated phosphates in order to extend the curing time of o gypsum, several polyvalent metal ions besides Fe(III) can be used. It is in particular the highest condensated linear polyphosphates (Grahams salt) which are most effective in extending the hardening time. Because of the structure of the polyphosphates and the characteristic hydrolysis stability, insoluble salts will be rather rapidly formed via the first complexes by adding trivalent ions from the third group of the periodic table of elements, or ions of the inner transition elements and rare earth metals having-high oxidation levels The effect of polyphosphates may therefore conveniently be removed by the addition of several types of multivalent metal ions. One disadvantage of metal ions except iron(III) and aluminum(III) is the high price and that such ions are formation enhancing involving a risk of introducing cations and undesirable effects in the core samples. Both aluminum(III) and iron(III) ions have acted excellently in practical tests. Accelerating additives together with WO 96/38394 PCT/N096/00116 12 the polyvalent additive ions can also in this case increase the hardening rate in the same way as mentioned above for the organic polyanions.
For organic anions and acids it appears that the assortment of cations giving the desired effect is more limited as for the moment only Fe(III) with some exceptions give the desired result with regard to formation conformability, stability, rate of formation and toxicity of the complex. By the addition of for example NTA which retards the hardening process, one has to resort to formation enhancing cations to restrain the retarding effect of the acid, whereas for fruit acid, aluminum ions will also provide fairly acceptable results.
To facilitate the mixing process when using two liquid components, two volumetric pumps 10 and one static mixer are used, and the final plaster slurry, still not yet hardened, can be supplied directly but gradually to the sickle formed space between the core sample and the core sample pipe. The plaster slurry forms a gel within 4-9 minutes and hardens to S* sufficiently strong gypsum within 7-20 minutes. With a fresh plaster slurry it may be necessary to use as much as 20 minutes to develop sufficient strength, whereas a retarded slurry which has been put aside for almost one hour need no more than 7 to 9 minutes to develop sufficient strength.
Example 1 3.75 kg calcined gypsum is added to 2.5 I water while stirring to form a plaster slurry 20 having a volume of about 3_925 1. This composition cures sufficiently to protect a core sample in a core sample pipe to allow the core sample to be moved after 35-45 minutes.
Example 2 3.75 kg calcined gypsum and 62.5 g NaCI are dissolved in 2.5 1 water while stirring to form a plaster slurry having a volume of about 3.925 1. This composition sets sufficiently to protect a core sample in a core sample pipe and allow the core sample to be moved after 15 minutes.
Example 3 3.75 kg calcined gypsum and 40.0 g KCI are added to 2.5 1 water while stirring to form a plaster slurry having a volume of about 3.925 1. This composition hardens sufficiently to WO 96/38394 PCTIN096/00116 13 protect a core sample in a core sample pipe to allow the core sample to be moved after 15 minutes.
Example 4 3.75 kg calcined gypsum and 60.0 g NHCI are added to 2.5 1 water while stirring to form a plaster slurry having a volume of about 3.925 i. This composition hardens sufficiently to protect a core sample in a core sample pipe to allow the core sample to be moved after 15 minutes.
10 Example 3.75 kg calcined gypsum and 30.0 g KSO 4 are dispersed in 2.5 I water to form a plaster slurry having a volume of about 3.925 1. This composition hardens sufficiently to protect a core sample in a core sample pipe to allow the core sample to be moved after 10 minutes.
Example 6 Component 1: 1I g citric acid in the form of a soluble citrate and 3.75 kg calcined gypsum are dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 I. This composition has a hardening rate so low that it will remain liquid for almost one hour. Prior to gelation, the composition will be usable as one of said two components, which will harden when mixed with an accelerator solution.
Component 2: The accelerator solution comprises a saturated solution of KCI. The volumetric mixing ratio between accelerator and hardener and retarded plaster slurry will be close to 1: 14.7 resulting in 0.25 1 of component 2 and a total volume of 3.925 I. The time required to obtain a sufficient strength to move the core sample is from 22 to 35 minutes.
WO 96/38394 PCT/N096/00116 14 Example 7 Component 1: 1 g citric acid in the form of a soluble citrate and 3.75 kg calcined gypsum are dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 i. This composition has a hardening rate so slow that it will remain liquid for almost an hour. Prior to gelation, the composition will be usable as one of said two components in a two-component system, which will harden rapidly when mixed with an accelerator solution.
Component 2: The accelerator solution comprises 0.25 I saturated KCI solution supplied with 1.408 g of the water soluble metal ion salt FeCI 3 6H,O. The Fe-ions form stable complexes and *o V establishes a bond to citrate anions more strongly than to gypsum, thus blocking the retarding effect. The volumetric mixing ratio of accelerator and hardener and retarded plaster slurry will be close to 1: 14.7, resulting in 0.25 1 of component 2 and a total volume of 3.925 15 1. Time to obtain sufficient strength to allow the core sample to be moved is 15 to minutes.
*9 Example 8 Component 1:.
1 g citric acid in the form of a soluble citrate and 3.75 kg calcined gypsum are dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 1 volume. The composition has a hardening rate so slow that the composition will remain liquid for almost one hour. Prior to gelation, the composition will be usable as said one commponent in a two-component system, which will harden rapidly when mixed with an accelerator solution.
Component 2: The accelerator solution comprises 0.25 I saturated KCI solution supplied with 2.816 g of the water soluble metal ion salt FeCI 3 6H0,. The Fe-ions form stable complexes and will become more strongly bonded to citrate ions than to gypsum, thus blocking the retarding effect. The volumetric mixing ratio of accelerator and hardener and retarded plaster slurry will be close to 1: 14.7. resulting in 0.25 I of component 2 and a total volume of 3.925 1. The WO 96/38394 PCT/N096/00116 time required to obtain a sufficient strength to allow the core sample to be moved is from to 16 minutes.
Example 9 Component 1: 1 g citric acid in the form of a soluble citrate and 3.75 kg calcined gypsum are dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 1. This composition has a hardening rate so slow that it will remain fluid for almost one hour. Prior to gelation, the composition will therefore be usable as said one component in a two-component system, 10 and will harden rapidly when mixed with an accelerator solution.
Component 2.
The accelerator solution comprises 0.25 1 saturated KCI solution supplied with 4.224 g of the water soluble metal ion salt FeCI 6H,O. The Fe-ions form stable complexes and 15 bonds more strongly to citrate ions than to gypsum, thus blocking the retarding effect. The volumetric mixing -ratio between accelerator and hardener and retarded plaster slurry will be close to 1: 14.7, resulting in 0.25 1 of component 2 and a total volume of 3.925 1. The time 9required to obtain a sufficient strength to allow the core sample to be moved is from 9 to minutes.
Example Component J.
1 g citric acid in the form of a soluble citrate and 3.75 kg calcined gypsum are dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 I. This composition exhibits a setting rate so slow that it will remain fluid for about one hour. Prior to gelation, the composition is usable as said one component in a two-component system, and will harden rapidly when mixed with an accelerator solution.
Component 2: The accelerator solution comprises 0.25 I saturated KCI solution supplied with 5.617 g of the water soluble metal ion salt FeCI 3 6H,O. The Fe-ions form stable complexes and will WO 96/38394 PCT/N096/00116 16 establish a stronger bond to the citrate ions than to gypsum, thus blocking the retarding effect. The volumetric mixing ratio between accelerator and retarded plaster slurry will become close to 1:14.7, resulting in 0.25 1 of component 2 and a total volume of 3.925 1. The time required to obtain a sufficient strength to allow the core sample to be moved is from 9 to 15 minutes.
Example 11 Component 1: 0.75 g citric acid in the form of a soluble citrate and 3.75 kg calcined gypsum are 10 dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 I. This composition exhibits a setting rate so slow that it will remain fluid for about one hour. Prior to gelation, the composition is usable as said one component in a two-component system, and will harden rapidly when mixed with an accelerator solution.
Component 2: The accelerator solution comprises 0.25 I saturated KCI solution supplied with 4 g of the water soluble metal ion salt FeCI 3 61- O. The Fe-ions form stable complexes and will establish a stronger bond to the citrate ions than to gypsum, thus blocking the retarding effect. The volumetric mixing ratio between accelerator and retarded plaster slurry will become close to 1:14.7, wherein component 2 constitutes 0.25 1 resulting in a total volume of 3.925 1. The time required to obtain a sufficient strength to allow the core sample to be moved is from 9 to 15 minutes.
Example 12 Component 1: 0.75 g citric acid in the form of a soluble citrate and 3.75 kg calcined gypsum are dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 I. This composition exhibits a setting rate so slow that it will remain fluid for about one hour. Prior to gelation, the composition is usable as said one component in a two-component system, and will harden rapidly when mixed with an accelerator solution.
WO 96/38394 PCT/N096/00116 17 Component 2: The accelerator solution comprises 0.25 I saturated K 2
SO
4 solution supplied with 3.96 g of the water soluble metal ion salt FeCI 3 6H 2 0. The Fe-ions form stable complexes and will establish a stronger bond to the citrate ions than to gypsum, thus blocking the retarding effect. The volumetric mixing ratio between accelerator and retarded plaster slurry will become close to 1:14.7, wherein component 2 constitutes 0.25 1 resulting in a total volume of 3.925 1. The time required to obtain a sufficient strength to allow the core sample to be moved is from 13 to 20 minutes.
10 Example 13 *too Component 1: 1 g fruit acid in the form of a soluble salt and 3.75 kg calcined gypsum are dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 1. This composition exhibits a setting rate so slow that it will remain fluid for about one hour. Prior to gelation, •15 the composition is usable as said one component in a two-component system, and will harden rapidly when mixed with an accelerator solution.
Component 2: The accelerator solution comprises 0.25 1 saturated KCI solution supplied with 4 g of the 20 water soluble metal ion salt FeCI 3 6H 0. The Fe-ions form stable complexes and will establish a stronger bond to the fruit acid ions than to gypsum, thus blocking the retarding effect. The volumetric mixing ratio between accelerator and retarded plaster slurry will become close to 1:14.7, wherein component 2 constitutes 0.25 I resulting in a total volume of 3.925 1. The time required to obtain a sufficient strength to allow the core sample to be moved is from 7 to 12 minutes.
Example 14 Component 1: 1 g fruit acid in the form of a soluble salt and 3.75 kg calcined gypsum are dispersed in 2.25 i water to form a plaster slurry having a volume of about 3.675 1 This composition exhibits a setting rate so slow that it will remain fluid for about one hour. Prior to gelation, WO 96/38394 PCT/N096/00116 18 the composition is usable as said one component in a two-component system, and will harden rapidly when mixed with an accelerator solution.
Component 2: The accelerator solution comprises 0.25 1 saturated KCI solution supplied with 3.573 g of the water soluble metal ion salt AIC 1 6H,O. The aluminum ions form complexes with the fruit acid anions, wherein the complexes will establish a stronger bond to the anions than to gypsum, thus substantially blocking the retarding effect. The volumetric mixing ratio between accelerator and retarded plaster slurry will become close to 1:14.7, wherein 10 component 2 constitutes 0.25 1 resulting in a total volume of 3.925 1. The time required to obtain a sufficient strength to allow the core sample to be moved is from 14 to 20 minutes.
Example Component 1:
U
15 1.25 g polyphosphoric acid in the form of a soluble salt and 3.75 kg calcined gypsum are dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 I. This -composition exhibits a setting rate so slow that it will remain fluid for about one hour. Prior to gelation, the composition is usable as said one component in a two-component system, and will harden rapidly when mixed with an accelerator solution.
a.
Component 2: The accelerator solution comprises 0.25 i saturated KCI solution supplied with 4 g of the water soluble metal ion salt FeC 3 6H 0. The Fe-ions form complexes with the polyphosphate ions and insoluble precipitate with the low molecular weight hydrolysis products of the poly anions. These complexes and precipitates establish a stronger bond to the phosphoric acid based anions than to gypsum, thus blocking the retarding effect. The volumetric mixing ratio between accelerator and retarded plaster slurry will become close to 1:14.7, wherein component 2 constitutes 0.25 i resulting in a total volume of 3.925 I. The time required to obtain a sufficient strength to allow the core sample to be moved is from 6 to 10 minutes.
WO 96/38394 PCT/N096/00116 19 Example 16 Component 1: 1.25 g poly phosphoric acid in the form of a soluble salt and 3.75 kg calcined gypsum are dispersed in 2.25 1 water to form a plaster slurry having a volume of about 3.675 1. This composition exhibits a setting rate so slow that it will remain fluid for about one hour. Prior to gelation, the composition is usable as said one component in a two-component system, and will harden rapidly when mixed with an accelerator solution.
Component 2: The accelerator solution comprises 0.25 1 saturated KCI solution supplied with 3.573 g o. of the water soluble metal ion salt AIClI 6H,0. The aluminum ions form complexes with the polyphosphate ions and insoluble precipitate with the low molecular weight hydrolysis products of the polyanions. These complexes and the precipitate establish a stronger bond to the phoshporic acid-based anions than to gypsum, thus blocking the retarding effect. The 15 volumetric mixing ratio between accelerator and retarded plaster slurry will become close to 1:14.7, wherein component 2 constitutes 0.25 1 resulting in a total volume of 3.925 I. The •time required to obtain a sufficient strength to allow the core sample to be moved is from 6 to 10 minutes.
S
Claims (6)
1. A curable gypsum-based composition for the production of a cured gypsum matrix, particularly for the production of gypsum articles, casting molds of plaster, and for construction applications such as wall smoothing, wherein the composition comprises an aqueous suspension of calcined gypsum and set retarding polyanions, and set accelerating salts, characterized in that the composition in combination comprises a two- component composition comprising: 1 0 a first component comprising calcined gypsum suspended in water, and a set retarding substance comprising: an organic acid containing at least two acid groups selected from the group consisting of carboxyl, sulphate, sulphonate, phosphate or o phosphonate, said acid optionally also containing at least one hydroxy group per molecule; and/or (ii) inorganic anions selected from the group consisting of polyphosphate and polyborate, or mixtures thereof, and a second component comprising a set accelerating substance comprising: (iii) water soluble salts of multivalent metal ions, and optionally (iv) organic or inorganic salts of ammonium and/or elements from the first group of the periodic table of elements.
2. The composition of claim 1, characterized in that the set retarding substance comprises citric acid, fruit acid and/or polyphosphoric acid.
3. The composition of claim 1 or 2, characterized in that the set retarding substance constitutes from 0.001 to 0.5 percent by weight of the gross water quantity in said first component 21
4. The composition of claim 1 or 2, characterized in that the set retarding substance constitutes from 0.01 to 0.2 percent by weight, preferably from 0.02 to 0.1 percent by weight, of the gross water quantity in said first component The composition of any one of claims 1 4, characterized in that the set accelerating substance comprises salts of Fe(lll), Fe(ll) and/or A1 (III), wherein the salts neutralizes the effect of the set retarding substances in said component by forming insoluble salts or stable complexes. 10 6. The composition of any one of claims 1-5, characterized in that the set accelerating substance comprises salts or ions from the first group of the periodic table of the elements, such as Na+ or K+ and/or NH4+.
7. The composition of claim 5 or 6, characterized in that the set 'accelerating substances in said component are present in a water 15 solution.
8. The composition of claim 1, characterized in that the composition comprises a seed initiator in the form of comminuted gypsum (CaSO4 2H20). Dated this 8th day of April 1999 RESLAB A/S By their Patent Attorneys, COLLISON CO
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| AU23657/99A AU720945B2 (en) | 1995-05-30 | 1999-04-08 | Curable gypsum-containing composition and method for stabilization of unconsolidated core samples |
Applications Claiming Priority (4)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| NO952124A NO302538B1 (en) | 1995-05-30 | 1995-05-30 | Procedure for stabilizing unconsolidated core borehole material |
| NO952124 | 1995-05-30 | ||
| AU60187/96A AU702653B2 (en) | 1995-05-30 | 1996-05-14 | Curable gypsum-containing composition and method for stabilization of unconsolidated core samples |
| AU23657/99A AU720945B2 (en) | 1995-05-30 | 1999-04-08 | Curable gypsum-containing composition and method for stabilization of unconsolidated core samples |
Related Parent Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| AU60187/96A Division AU702653B2 (en) | 1995-05-30 | 1996-05-14 | Curable gypsum-containing composition and method for stabilization of unconsolidated core samples |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| AU2365799A AU2365799A (en) | 1999-06-10 |
| AU720945B2 true AU720945B2 (en) | 2000-06-15 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| AU23657/99A Ceased AU720945B2 (en) | 1995-05-30 | 1999-04-08 | Curable gypsum-containing composition and method for stabilization of unconsolidated core samples |
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| Country | Link |
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| AU (1) | AU720945B2 (en) |
Citations (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| GB1538103A (en) * | 1977-07-14 | 1979-01-10 | Ici Ltd | Set-promoting composition for calcium sulphate hemihydrate plaster |
| EP0063232A1 (en) * | 1981-04-22 | 1982-10-27 | Gebr. Knauf Westdeutsche Gipswerke | Self-levelling mortar composition |
-
1999
- 1999-04-08 AU AU23657/99A patent/AU720945B2/en not_active Ceased
Patent Citations (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| GB1538103A (en) * | 1977-07-14 | 1979-01-10 | Ici Ltd | Set-promoting composition for calcium sulphate hemihydrate plaster |
| EP0063232A1 (en) * | 1981-04-22 | 1982-10-27 | Gebr. Knauf Westdeutsche Gipswerke | Self-levelling mortar composition |
Also Published As
| Publication number | Publication date |
|---|---|
| AU2365799A (en) | 1999-06-10 |
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