The present invention relates to an aqueous cementing composition and a method of using the same in cementing oil and gas wells and the like. More particular­ly, the present invention relates to the incorporation into the cementing composition of copolymers, prepared by the copolymerization of acrylamide and vinyl imidazole in ratios of from about 95:5 to 5:95 by weight, as fluid loss additives in oil and gas well cementing operations.

The copolymerization of acrylamide and vinyl imidazole with a suitable third monomer generally does not affect the effectiveness of these materials as fluid loss additives for cement slurries. Partial substitution of vinyl imidazole with lower cost monomers which do not have deleterious effects on the stability of the polymer and rheology of the cement slurries can, in fact, be advanta­geously considered.

The incorporation of such copolymers and/or terpolymers as fluid loss additives for the cement slurries used in the completion of oil and gas wells, greatly reduces the loss of water from the cement slurry to the rock formation.

Optionally, a dispersant such as polynaphthalene sulfonate may also be incorporated into the cement slurry with the copolymer and/or terpolymer. When polynaphthalene sulfonate is incorporated into the slurry with the fluid loss additive, there is a synergistic effect between the dispersant and the additive which results in an even greater reduction of fluid loss than could be achieved using either ingredient alone.

The incorporation of the fluid loss additives of the present invention into cement slurries greatly reduces fluid loss in oil and gas well cementing operations and allows for a more efficient bonding between the oil or gas well liners and the rock formations.

Oil well cementing and other underground cementing operations often require placement of a slurry of cement, water and other additives in a porous environment such as porous earthen or rock strata. For example, cement com­positions are routinely used in the oil and gas industry to cement the annular space in the well bore between the surrounding formation and the pipe or casing. Typically, the cement slurry is pumped down the inside of the casing and back up the outside of the casing through the annular space. The slurry is allowed to set up or harden in the annular space, thereby forming a rigid column which ideally forms a bond with the earth or rock formations as well as with the metal pipe or casing. To achieve a satisfactory primary cementing job, it is essential to achieve a tight bond to prevent vertical communication of fluids or gas along or within the column, which could contaminate the producing zone, or permit a loss of reserves.

The primary functions of the cementing process are to restrict fluid movement between geological formations and to bond and support the casing or metal pipe. In addition, the cement aids in protecting the casing from corrosion, preventing "blow-outs" by quickly sealing formations, protecting the casing from shock loads in drilling deeper wells and sealing off lost circulation or thief zones.

A common problem in petroleum well cementing is the flow of liquid from the slurry into the porous earth formations in contact with the cement. This fluid loss is undesirable since it causes thick filter cakes of cement solids which can ultimately plug the well bore. The fluid loss can also damage rock formations and affect well production. Fluid loss from cement slurries is particularly a problem in a process known as "squeeze cementing".

Problems develop when water filters out of the slurry and into the porous media during the placement and setting period of the cement. As a result of the attendant rapid water loss, the cement experiences impaired qualities of strength and an uncontrolled setting rate. Also, the water loss from the cement frequently damages the porous rock formations. This problem cannot be solved by adding more water to the slurry as this approach only exacerbates the problem. In addition, serious placing and setting problems may occur.

It is therefore of utmost importance that fluid loss control be achieved in order to insure satisfactory primary cementing. Inadequate fluid loss control can result in the formation of a bridge in the annulus opposite a permeable zone, thus isolating a lower zone from the hydrostatic pressure above the bridge. Only a small amount of filtrate loss beneath such a bridge is then necessary to drop the annular pressure to beneath that of the forma­tion. The result is an influx of formation fluids and pressure, thereby creating flow channels and the need for often times expensive remedial work.

In order to attempt the control of fluid loss from the cement slurry to the surrounding rock formation, the cement matrix permeability must be reduced. This reduction allows the retention of a greater amount of water during the initial set, thereby effectively blocking the porous strata from the cement. The art is replete with examples of methods to achieve this goal. One way is to reduce filtrate mobility by increasing the filtrate viscosity to counter the normal thinning of the cement slurry which occurs at down hole temperatures. An increase in filtrate viscosity at down hole temperatures minimizes thermal thinning and increases the retention of the filtrate within the cement matrix. Conventional fluid loss additives do not satis­factorily address the problem of thermal thinning with increased temperature, thereby allowing increased fluid loss from the slurry to the formation and promotion of stratific­ation of solids within the cement slurry column.

Accordingly, there is a greatly felt need for new materials which, when added to the cement slurries, reduce fluid loss to the surrounding rock formations.

Fluid loss additives in cementing compositions are old and well known in the art. Fluid loss additives have been discussed in the following articles:

Carter, Gregg and Slagle, Knox, "A Study of Completion Practices to Minimize Gas Communication", Society of Petroleum Engineers, Paper No. 3164, November 1970.

Christian, W.W., Chatterji, Jiten and Ostroot, Warren, "Gas Leakage in Primary Cementing - A Field Study and Laboratory Investigation", Society of Petroleum Engi­neers, Paper No. 5517, October, 1975.

Cook, C. Cunningham, W., "Filtrate Control: A Key in Successful Cementing Practices", Journal of Petroleum Technology, August, 1977, page 951.

Smith, Dwight, "Cementing: SPE Monograph Volume 4, published by Millet the Printer, Inc., Dallas, Texas, 1976.

The patent literature is also replete with many attempts to overcome the fluid loss control problems associated with oil and gas well cementing operations. There are many references directed to protecting potable water by isolating hydrocarbon bearing strata by efficient cementing operations.

Uhl, U.S. Patent No. 4,471,097 relate to auxiliary agents for chemical flooding of petroleum deposits and auxiliary agents used in well drilling fluids. These agents are water-soluble copolymers containing 20 to 80 percent by weight of unsaturated olefinic sulfonic acid, 5 to 15 percent by weight vinylacylamine, 0 to 40 percent by weight acrylamide and/or methacrylamide, 5 to 50 percent by weight vinylimidazole, 0 to 10 percent by weight of

wherein R⁵ is hydrogen or methyl, and R⁶ represents hydroxy, alkoxycarbonyl with 1 to 12 carbon atoms in alkoxy moiety, cycloalkoxycarbonyl with 6 to 10 carbon atoms in cycloalkoxy moiety, phenyl, alkanoyloxy with 1 to 4 carbon atoms, or β-­hydroxyalkoxycarbonyl with 2 or 3 carbon atoms in hydroxyalkoxy moiety; and 0 to 25 percent by weight of a cross-linking agent containing at least two olefinic double bonds.

These copolymers are used in drilling fluid additives during drilling operations. WP 8302449, which is the equivalent of U.S. Patent 4,471,097 discloses the use of these copolymers in deep bore cement compositions to act as rheology additives.

No showing is made in Uhl et al of using these copolymers as fluid loss additives in cement slurries to avoid fluid loss from the cement to surrounding rock formations, and without adversely affecting the viscosity of the cement slurry.

Siegle, U.S. Patent No. 3,197,428 discloses compositions comprising cement and copolymers of acrylamide and acrylic acid to improve well cementing operations and reduce fluid loss from the cement to the rock formations. However, the compositions of Siegle are not entirely satisfactory because they retard cement setting at high temperatures and so cannot be used at elevated temperatures and pressures such as are encountered in deep oil and gas well operations.

Weisend, U.S. Patent No. 3,359,225 discloses cement additives containing polyvinylpyrrolidones and a condensate of sodium naphthalene sulfonate and formalde­hyde. The polyvinylpyrrolidone reduces the separation of water from the cement slurry. The naphthalene sulfonate condensate is the dispersant. There is no teaching of the copolymers and/or terpolymers of the present invention.

Gibson et al, U.S. Patent No. 3,491,040 disclose an aqueous hydraulic cement slurry including hydraulic cement, water, a surfactant and a small amount of poly­alkylenepolyamine, polyalkenimine or mixtures thereof. Gibson et al also disclose a sulfonated naphthalene conden­ sate dispersant as an additional additive to the cement slurry which cooperates with the polyamine additive to provide satisfactory fluid loss in cement slurries used at about 200°F and below. The sulfonated naphthalene disper­sant is typically a low molecular weight material, e.g., in the range of about 1,000 to 3,000.

Harrison, U.S. Patent No. 3,409,080 discloses an aqueous cementing composition which is adapted to high turbulent flow. The disclosure teaches the polyvinyl alcohol and polyvinyl acetate can be used as fluid loss additives in oil well cements.

Perisinski et al, U.S. Patent No. 4,015,991, discloses a fluid loss additive for cement compositions which is a copolymer of acrylamide/2-acrylamido-2-methyl-­propane sulfonic acid derivative. These copolymers are useful only in operations where the bottom hole circulation temperature ranges from 90° to 125°F. Further, these copolymers have a salt tolerance of only up to 10 percent.

Cellulose-based fluid loss additives such as methyl cellulose, carboxymethylcellulose (CMC) and hydroxy-­ethylcellulose (HEC) may be employed with or without a dispersant such as polynaphthalenesulfonic acid salts. However, there are several disadvantages to the use of CMC or HEC as cement fluid loss control additives. These materials are solid and as a result are difficult to handle in offshore operations. In addition, they tend to consider­ably increase slurry viscosity, thereby preventing its movement under turbulent flow conditions and retard the set of the cement. Also, these materials lose effectiveness in the presence of soluble calcium salts and at elevated temperatures.

Hence, the industry desires a fluid loss additive that has as little effect on cement properties as is possible and still provides for the fluid loss properties which are necessary for the cementing of casings to rock formations. Further, any fluid loss additives should be compatible with as many other additives as possible and should be useable over as wide a range of temperatures and other environmental conditions as is possible.

The present invention relates to cementing compositions and more particularly to fluid loss additives which may be incorporated into the cement compositions. The cement compositions are useful in cementing operations in oil and gas wells and are comprised of water, hydraulic cement and copolymers and/or terpolymers. When a copolymer of acrylamide and vinyl imidazole is used, they are present in a ratio of 95:5 to 5:95, and more preferably in a ratio of from about 80:20 to 20:80. When a terpolymer is to be used, it may consist of acrylamide and vinyl imidazole and any other suitable monomer. The terpolymer is comprised of 5 to 95 to 95 to 5 weight percent of acrylamide and vinyl imidazole, and 0 to 60 weight percent additional monomer. The copolymer has a molecular weight range of from about 10,000 to 3,000,000 and preferably between 100,000 to 1,000,000 where the molecular weights have been determined by GPC using polyethylene glycol standards. When a ter­polymer is employed, it has a molecular weight range of from about 10,000 to 3,000,000, and preferably between 100,000 to 1,000,000. The copolymer and/or terpolymer function as fluid loss additives and are present in an amount effective to reduce fluid loss from the cement slurry to surrounding rock formations.

Optionally, the cementing composition may contain an effective amount of a dispersant such as polynaphthalene sulfonate. When this dispersant is present, there is a synergistic effect between the dispersant and the fluid loss additive which results in greater effectiveness of the system in reducing fluid loss than could be expected when using the dispersant and copolymer and/or terpolymer separately. The dispersant also further decreases the viscosity of the slurry, thereby aiding in pumping of the slurry into the annular space.

The fluid loss additive may be used in any amount which is effective in reducing the fluid loss from the cement slurry to the surrounding rock formations. Ideally, the fluid loss additive should be present in an amount of about 0.05 to 2.0 percent by weight of the cement, and preferably in an amount of about 0.125 to 1.0 percent by weight of the cement.

Cementing compositions are disclosed which provide for fluid loss control and use over a wide range of temper­ature and well conditions. The cementing compositions are comprised of water, hydraulic cement, a fluid loss additive comprising a particular copolymer of an acrylamide type monomer and a basic vinylheterocyclic monomer such as vinylimidazole, vinylpyridine their derivatives, and mixtures thereof, or a terpolymer of acrylamide, vinyl imidazole and any other suitable monomer, and optionally, a dispersant such as polynaphthalene sulfonate. The use of a dispersant has a synergistic effect on the copolymer or terpolymer and results in an unexpected increase in its effectiveness as a fluid loss additive.

The copolymer used in the cementing compositions of this invention include an acrylamide and associated acrylamide derivatives selected from the group consisting of acrylamide, methacrylamide, N,N, dimethyl(meth)acrylamide, N,N, dialkylamino- alkyl(meth)acrylamide, and mixtures thereof. The other monomer of the acrylamide/vinyl imidazole copolymer is a basic vinyl heterocyclic monomer selected from the group consisting of 1-vinylimidazole, 2-­vinylimidazole, 2-methyl-1-vinylimidazole, 4-methyl-1-­vinylimidazole, 5-methyl-1-vinylimidazole, 2-ethyl-1-­vinylimidazole, 2-propyl-1-vinylimidazole, 2-isopropyl-1-­vinylimidazole, 2-phenyl-1-vinylimidazole, 1-vinyl-4, 5-­benzimidazole, 2-vinylpyridine, 4-vinylpyridine, 5-methyl-2-­vinylpyridine and mixtures thereof. Preferred is 1-vinyl imidazole. These are copolymerized in a weight ratio of from about 95:5 to 5:95 and preferably 80:20 to 20:80. The copolymer has a molecular weight of from about 10,000 to 3,000,000 and preferably between 100,000 to 1,000,000.

The copolymer is made in a conventional copoly­merization process such as solution, emulsion or bulk polymerization in the presence of conventional free radical initiators. Such procedures are well documented and are well known to those skilled in the art.

The terpolymer may include any suitable monomer in addition to the copolymer mentioned above. These monomers may include unsaturated acid monomers and alkali metal, ammonium or organic amine salts thereof, water soluble or dispersible derivatives of acrylic acid and acrylamide such as N,N-dialkylaminoalkyl(meth)acrylamide, N,N-dialkylamino­alkyl(meth)acrylate, ethyl acrylate, methyl acrylate, acrylamido methylpropane sulfonic acid sodium salt, hydroxy-­propylacrylate and other vinyl monomers with sufficient water solubility or dispersibility such as vinyl pyr­rolidone, vinyl amine, vinyl formamide, sodium vinyl­sulfonate, acrylonitrile, vinylacetate. The quaternary salts of the appropriate amino containing monomers listed above are also suitable comonomers for the terpolymers in question.

In its terpolymer form, the range of the three components is from about 0 to 60 weight percent additional monomer, from about 5 to 95 weight percent acrylamide and from about 5 to 95 weight percent vinyl imidazole.

The terpolymers are made by conventional poly­merization techniques as are well known to those skilled in the art.

The polymers can be added to the cement composition in dry, solution or emulsion form.

The result of the inclusion of the fluid loss additives of the present invention are improved pumpability of the cement which generally improves drilling fluid removal and reduced possibility of lost circulation, when cementing a conduit penetrating a permeable earthen form­ation.

The cement component of the cement composition of this invention may be any of the API classes of cement or cement blends, as are defined in the American Petroleum Institute Bulletin entitled "API Specification for Material and Testing for Well Cements", Third Edition, dated July 1, 1986 ("API Spec. l0"), and incorporated herein by refer­ence. These include cements defined as Classes A through H in API Spec. 10.

As previously stated, the cement compositions of this invention may optionally include dispersants such as any anionic surfactant i.e., any compound which contains a hydrophobic portion (e.g., any hydrocarbon substituent such as alkyl, aryl or alkylaryl group) and a hydrophilic portion (e.g., any negatively charged moiety, such as O⁻, CO⁻₂, or SO⁻₃). Suitable dispersants include sulfonic acid deriv­ atives of aromatic hydrocarbons, such as naphthalene sulfonic acid formaldehyde condensation product derivatives, particularly their sodium or potassium salts. Examples of dispersants which may be used include lignosulfonates, sodium and potassium naphthalene sulfonate formaldehyde condensation products (such as LOMAR D commercially avail­able from Diamond Shamrock Chemical Company), and sodium salts of ketone sulfonate formaldehyde.

The cement compositions may also include at least one inorganic salt. Suitable salts include inorganic monovalent and polyvalent metal salts, such as magnesium chloride, ammonium chloride, sodium and potassium chloride and calcium chloride.

Other additives conventionally added to cement compositions useful in cementing casings in the bore hole of a well can also be added to the cement compositions of this invention in the amount which are normally used by those skilled in the art. These additives may include, for example, (1) heavy weight additives, such as hematite, ilmenite, silica flour and sand; (2) cement retarders such as lignins and lignosulfonates; and (3) additives for controlling lost circulation; such as walnut hulls and cellophane flakes.

The fluid loss additives of the present invention will effect a substantial reduction in the rate of water loss by filtration and in the apparent viscosity of the cement slurries. They are easily mixable and result in good fluid loss control while still exhibiting good flow proper­ties at 0.05 percent to 2 percent by weight addition to the cement, depending upon the type of cement. Under API standards, excellent fluid loss rates below 100 cc/30 min can be achieved by the addition of about 0.05 percent to 2 percent by weight of the cement of such fluid loss additive to cement slurry of average density. Typically, a fluid loss of between about 20 and 100 cc/30 min., can be observed with a 0.25 percent to 0.50 percent by weight of the cement (BWOC) addition of the additives of the present invention.

Fluid loss properties can be controlled in salt cement formulations (such as up to saturated NaCl and seawater) with the addition of 0.25 percent to 0.50 percent by weight of the cement of the additives of the present invention without affecting rheology adversely.

Fluid loss varies as a function of molecular weight (MW). The molecular weight is a significant determinant in the properties of a product. The viscosity of a solution increases at a fixed concentration with higher MW of the solute. In addition, film and solution properties change with MW values. The molecular weight grades of various copolymers may be identified by a determination of, the intrinsic viscosities of the polymers which are defined in the following equation:

Intrinsic Viscosity = K(MW)^a

where K and a are constant for a given series of polymers.

As the intrinsic viscosity increases, one may extrapolate that the molecular weight of the additive increases. Further, the higher the molecular weight of the additive presumably the more viscous the cement slurry becomes, and the better the fluid loss properties become. However the data, as indicated in Example 2, reveals that there is an optimum acrylamide/vinylimidazole copolymer molecular weight after which no further improvement in fluid loss is possible.

The polymeric additives of the present invention exhibit some retardation effects on the cement slurry. The magnitude of the increase in thickening time of the cement slurries will depend on the temperature, pressures and slurry composition. Also, the additives of the present invention do not excessively thicken the cement, which allows for the incorporation into the cement of other additives and ingredients as many be dictated by on-site use conditions.

The following examples are presented in order to illustrate various aspects of the invention. Those skilled in the art will appreciate that the examples are not to be construed as limiting the scope and spirit of the invention.

In the following Examples, all cement slurries were prepared according to API Spec. 10, Third Edition, July 1, 1986.

Table I is an explanation of the symbols and abbreviations used in the tables containing the data of the examples. The symbols and abbreviations used therein are standard in the art and are well known to those of ordinary skill in the art.

Explanation of the Symbols Used in the Following Tables

AM/VI

Acrylamide/vinylimidazole copolymer

Comp A: AM=80%; VI=20% by weight

Comp B: AM=60%; VI=40% by weight

Comp C: AM=40%; VI=60% by weight

Dispersant

Sodium salt of condensed naphthalene sulfonate, Lomar D from Henkel

BWOC

By Weight of Cement

BWOW

By Weight of Water

Fluid Loss

Amount of water lost by the slurry over 30 min. under the conditions of the test.

Compressive Strength

Pounds per square inch needed to crush the cement after 24 hour set at the test temperature.

Reference:

American Petroleum Institute, Specification 10, July, 1986.

MAM/VI

methylacrylamide/vinylimidazole

AM/MAM/VI

acrylamide/methylacrylamide/vinylimidazole

AM/VP/VI

acrylamide/vinylpyrrolidone/vinylimidazole

Example 1

Example 1, as depicted in Table II, shows the effectiveness of the acrylamide/vinylimidazole copolymers as fluid loss additives for oilfield cement. Slurries contain­ing these materials at different concentrations are compared with neat cement slurries or cement slurries containing only the polynaphthalene sulfonate dispersant. An increase in the content of vinyl imidazole in the copolymers does not greatly affect the fluid loss of the slurry but considerably reduces the thickening times and improves the 24-hour compressive strength of the set cement.

Example 2

Example 2 shows how the molecular weight of the copolymers used affects, to a certain extent, the amount of fluid lost by the cement slurry. In Table III, the differ­ent molecular weights of the additives used are expressed by the "intrinsic viscosities", where increasing intrinsic viscosity values correspond to higher molecular weights. It is apparent from the data that there are optimal molecular weights at which the additives claimed in the patent perform the most effectively in controlling fluid loss from cement slurries.

Example 3

Example 3, as described in Table IV, shows the synergistic interaction of a sulfonated polynaphthalene dispersant with an acrylamide/vinylimidazole copolymer to reduce the fluid loss of a Class H cement slurry containing 38% water. The data indicate that when no dispersant is used, an acceptable fluid loss is obtained at 0.5 percent additive BWOC but an almost ten fold increase in the fluid loss is experienced if the level of additive is reduced by half. However, the addition of dispersant increases the effectiveness of the additive to such an extent that slurries containing 0.25 percent of the claimed additive and 0.5 percent of dispersant have a fluid loss similar to that of slurries containing 0.5 percent of the additive but no dispersant.

Example 4

Example 4 shows the performance of the additives claimed in high salt content cement slurries. As seen from Table V, the fluid loss of the cement slurry is not greatly affected by the amount of NaCl present in the slurry up to 9.0 percent BWOW. Only when 18 percent of salt BWOW is introduced in the slurry, the fluid loss increases. The slurry is not retarded by the addition of high levels of salt (18%- NaCl) contrary to what is seen with many commer­cial fluid loss additives.

Example 5

Example 5, as depicted in Table VI, shows that the use of acrylamide derivatives and/or the addition of a third monomer does not have deleterious effects on the effective­ness of the claimed additives. Some additives, however, tend to increase the viscosity of the cement slurries if an excessive amount of the third monomer is introduced in a terpolymer.

Performance of Acrylamide/Vinylimidazole Copolymers as Cement Fluid Loss Additives

API Tests, Class H Cement, 38% Water 180 Deg. F. 1000 psi

Test No.

% Additive BWOC

% Dispersant BWOC

Fluid Loss (ml)

Thickening Time (Hr:min)

Compressive Strength (psi)

1 Neat Cement

0.000

0.00

1628

01:45:00

5000

2 Neat Cement

0.000

0.50

775

N.A.

N.A.

3 Comp A

0.125

0.75

71

N.A.

N.A.

4 Comp A

0.250

0.50

62

N.A.

N.A.

5 Comp A

0.500

0.50

27

>5:00

No Set

6 Comp B

0.125

0.75

115

05:17:00

3842

7 Comp B

0.250

0.50

100

04:13:00

3841

8 Comp B

0.500

0.50

32

>4.00

3485

9 Comp C

0.500

0.50

24

N.A.

N.A.

Effect of MW as Expressed by "Intrinsic Viscosity" on the Performance of AM/VI Copolymers as Cement Fluid Loss Additives

API-Tests, Class H Cement, 38% Water 180 Deg. F, 1000 psi

Test No.

Intrinsic Viscosity (100 ml/g)

% Additive BWOC

% Dispersant BWOC

Fluid Loss (ml)

1 Comp A

1.13

0.25

0.5

102

2 Comp A

1.31

0.25

0.5

87

3 Comp A

1.71

0.25

0.5

62

4 Comp A

2.575

0.25

0.5

86

5 Comp A

2.87

0.25

0.5

97

6 Comp B

1.4

0.25

0.5

262

7 Comp B

1.68

0.25

0.5

153

8 Comp B

2.12

0.25

0.5

75

9 Comp B

2.61

0.25

0.5

74

Synergistic Effect of Polynaphthalene Sulfonate Dispersant With AM/VI Copolymers as Fluid Loss Additives for Cement Slurries

Class H Cement, 38% H₂O 180 Deg. F, 1000 psi

Test No.

% Additive BWOC

% Dispersant BWOC

Fluid Loss (ml)

Thickening Time (Hr:min)

Compressive Strength (psi)

1 Comp B

0.50

0.00

70

02:48

N.A.

2 Comp B

0.25

0.00

619

N.A.

3829

3 Comp B

0.50

0.25

35

03:44

4300

4 Comp B

0.25

0.25

119

N.A.

3818

5 Comp B

0.50

0.50

32

06:41

4000

6 Comp B

0.25

0.50

74

05:31

4049

Performance of Acrylamide/Vinylimidazole Copolymers as Cement Fluid Loss Additives in Salt Cement

API Tests, Class H Cement, 38% Water 180 Deg. F, 1000 psi

Test No.

% Additive BWOC

% Dispersant BWOC

%Salt(NaCl) BWOW

Fluid Loss (ml)

Thickening Time (Hr:min)

Compressive Strength (psi)

1 Comp B

0.5

0.5

0

32

05:00

3485

2 Comp B

0.5

0.5

5

26

02:44

4255

3 Comp B

0.5

0.5

9

28

02:41

4277

4 Comp B

0.5

0.5

18

101

01:33

3682

Performance of Copolymers and Terpolymers Containing Vinyl Imidazole and Acrylamide Derivatives as Cement Fluid Loss Additives

API Tests, Class H Cement, 38% Water 180 Deg. F, 1000 psi

Comonomers

Ratios Wt. %

% Additive BWOC

% Dispersant BWOC

Fluid Loss (ml)

1 MAM/VI

80/20

0.5

0.5

88

2 AM/MAM/VI

40/40/20

0.5

0.5

59

3 AM/MAM/VI

60/20/20

0.5

0.5

38

4 AM/VP/VI

60/20/20

0.5

0.5

41

5 AM/VP/VI

40/40/20

0.5

0.5*

6 AM/VP/VI

20/60/20

0.5

0.5*

*Cement slurries too thick to mix.