NL8300898A - HEAVY SALT SOLUTIONS WITH LOW FLOWABILITY LOSS CONTAINING HYDROXYETHYLCELLULOSIS. - Google Patents

Description

F - f ir.o. 31650

Heavy saline solutions with low flow loss, containing hydroxyethyl cellulose.

The present invention relates to heavy salt solutions containing zinc bromide and at least one soluble salt selected from the group consisting of calcium chloride and calcium bromide, and in particular to such low fluidity salt solutions containing cycloxyethyl cellulose.

In recent years, the practical operating trajectory of clear saline solutions for use in the oil and gas industry has been significantly expanded by the use of soluble zinc salts, especially zinc bromide, so that the benefits of clear saline solutions can now be obtained with fluids with densities up to 2.3 kg / cLm ^ at ambient temperature and pressure.

3) The high density clear saline solutions are extensively used as completion fluids to minimize clogging of perforation tunnels, to protect the formation permeability and to minimize mechanical problems; as a recovery fluid for the same reasons; as shim fluid, to allow easy movement and restoration of the shim; for under-reaming, gravel filling and sand consolidation applications; as a dead pump or ballast fluid; for waterline work and as drilling fluid.

Clear saline solutions having a density of 1.70 kg / dm 2 or less are generally formulated to contain sodium chloride, sodium bromide, calcium chloride, calcium bromide or mixture of these salts. Clear saline solutions with a density of 1.81 kg / dm 2 can be formulated with calcium chloride and calcium bromide; however, if the brine is to have a low crystallization temperature, clear brines in this density range are generally formulated to contain a soluble zinc salt. Zinc bromide is preferred because salt solutions containing this salt are less corrosive than salt solutions containing zinc chloride. Clear saline solutions with a density greater than about 1.81 kg / dm 2 are formulated to contain zinc bromide.

Generally, hydroxy ethyl cellulose (HEC) and xanthan gum polymers are compatible with the fluids not containing zinc salts.

At the higher densities, however, the hydration of the vice-making agents is considerably less. HEC is generally considered to be unsatisfactory for use in fluids containing zinc salts 8300898 -2- * r *.

Summary of the invention

It has now been found that EEC will function as a flowability additive in certain saline solutions in which EEC does not function efficiently as a viscous agent. These swan salt solutions contain either: 1) about 16 to about 20 wt% zinc bromide or: 2) more than 20% zinc bromide and a zinc chloride ride concentration of at least (2X-33) wt%, wherein X =% zinc bromide .

Therefore, it is an object of the present invention to provide certain heavy salt solutions containing zinc bromide and at least one soluble salt selected from the group consisting of calcium chloride and calcium bromide and a flowability loss reducing amount of hydroxyethyl cellulose.

. Another object of the present invention is to provide heavy salt solutions with a density in the range of about 1.70 to 1.92 kg / dm 2, containing zinc bromide and at least one soluble salt selected from the group consisting of calcium chloride and calcium bromide and containing a flow loss-reducing amount of hydroxyethyl cellulose.

Another object of the present invention is to provide a method of reducing the flow hair loss of heavy saline solutions with a density in the range of about 1.70 to about 1.92 kg / dm 2, which zinc bromide and at least one soluble salt selected from the group consisting of calcium chloride and calcium bromide.

Description of the preferred embodiment

The heavy salt solution for use in the present invention contains zinc bromide and at least one soluble salt selected from the group consisting of calcium chloride and calcium bromide.

In one embodiment of the invention, the concentration of zinc bromide should be in the range of about 16 to about 20 gpw%. Preferably, the concentration of zinc bromide is 1818% en and the concentration of calcium chloride £5 (X-17)% waarin where X is the percentage of zinc bromide.

In another embodiment of the invention, the salt solution should contain more than 20 wt% zinc bromide and a concentration of calcium chloride of at least (2X-33) wt%, wherein X is 40 percent zinc bromide.

8300898 -3- * ......: ......?

The preferred saline solutions have a density in the range from about 1.70 to about 1.92 kg / dm 2.

Generally, heavy saline solutions are prepared by mixing together different commercially available standard saline solutions as follows: calcium bromide saline solutions having a density in the range of about 1.32 to 1.39 kg / dm ^; calcium bromide salt solutions with a density of 1.70 kg / dm 2 and a calcium chloride / zinc bromide solution with a density of 2.30 kg / dm 2 containing about 20% calcium bromide and about 57% zinc bromide. Solid calcium chloride and solid calcium bromide are also used in conjunction with these saline solutions to prepare the heavy saline solutions for use in the present invention. However, it is preferable to use only liquid solutions to formulate the saline solutions in the practice of the present invention. Standard saline mixing / preparation tables are available from the various manufacturers and suppliers of these commercially available saline solutions.

The EEC polymers suitable as flow control loss agents in the present invention are solid, particulate materials, which are water-soluble or water-dispersible gums and which, upon dissolution or dispersion in an aqueous medium, increase the viscosity of the system. EEC polymers are generally high yield water-soluble, non-ionic materials achieved by treating cellulose with sodium hydroxide followed by reaction with ethylene oxide. Each anhydroglucose unit in the cellulose molecule has three reactive hydrochloric groups. The average number of moles of ethylene oxide bound to each anhydroglucose unit in cellulose is called the number of moles of 50 combined substituent. The average number of hydroxyl groups of each anhydroglucose unit reacted with ethylene oxide is called degree of substitution. In general, it is preferred to use EEC polymers with a mole substitution greater than 1.

Usually after the addition of dry, powdered hydrophilic polymers, such as EEC, to water, the polymer particles undergo hydration, which prevents the interior of the particles from being easily hydrated, solubilized or otherwise dispersed in the aqueous medium. As a result, long shear mixing times with high shear and / or elevated temperatures should be used 8300898 ~ 4 ~ * to obtain a homogeneous system.

It was also appreciated that HEC and other hydrophilic polymers can be activated such that the polymers will render heavy saline solutions viscous at ambient temperature. Activated HEC 5 compositions and method of activating HEC are described in U.S. Patent Applications 115,805 filed February 8, 1980 and 146,286 filed May 5, 1980. Method of activating other hydrophilic polymers are described in U.S. Patent Application 196,367 filed October 14 1980.

Activated EEC compositions include: 1) HEC, a solubilizing agent containing a water-miscible polar organic liquid which when homogeneously mixed HEC in a 1: 2 weight ratio HEC to solubilizing agent produces a mixture with substantially no free liquid solubilizing agent present after resting for 1 week at ambient temperature in a sealed container and a diluent containing an organic liquid which is not a solubilizing agent and 2) HEC, an aqueous liquid and a water-soluble po -20 l organic liquid, which when homogeneously mixed with HEC in a 1: 2 weight ratio HEC to polar organic liquid produces a mixture with free liquid present after a quiet stay for 1 week at ambient temperature in a sealed container. Preferably, the aqueous liquid has a pH greater than 70%.

Generally speaking, it has been found that virtually any organic compound that passes the solubilization test described above will function to a useful degree as a solubilizing agent. Non-limiting, however preferred, earning solubilizers include: aliphatic glycols containing 2 to 5 carbon atoms such as ethylene glycol, 1,2-propanediol, 1,4-butanediol, 1,3-pentanediol and the like; alkylene trolls containing 2 to 6 carbon atoms such as glycerol, 1,2,3-butanetriol, 1,2,3-pentanetriol and the like; amides containing from 1 to 4 carbon atoms such as formamide, acetamide, dimethylformide and the like and mixtures of several of the above compounds.

The diluent will generally be any liquid organic compound or the like which is not a solubilizing agent. In general, the diluents are 8300898-5, which do not appreciably swell the HEC polymers, ie they do not produce partially solid or viscous mixtures, which do not contain free liquid after the 1 week solubilizing period described in the preliminary test for determining solubilizing agents. Non-limiting examples of diluents include liquid aliphatic and aromatic hydrocarbons containing 5 to 10 carbon atoms; gasoline, diesel oil, isopropanol, alkylene glycol ethers, vegetable oils, etc. Particular preference is given to organic liquids which are water-soluble or miscible, most preferably alkanols with at least 3 carbon atoms, ethylene glycol monoalkyl ethers, dialkylene glycol monoalkyl ethers and the like. The diluent will contain the polymeric composition in a liquid, pourable state at a temperature of about 20 ° G. However, it will be appreciated that smaller amounts of diluent may be used if desired and that the final amount of diluent used will depend on the type of shear available to disperse the thickener. In general, it has been found that desirable thickeners, which are pourable liquids, can be produced from compositions containing about 10 to 25 wt% HEC polymer, about 2 to about 70 wt% diluent, and about 5 to about 88% soluble. making agent.

EEC has been added to heavy saline to increase the viscosity of the saline such that the ratio of loss of the saline to the formation in contact with the saline is reduced. Hormaliter, in the presence of cross-linking particles, hydroxyethyl cellulose provides a low flowability control in those saline solutions in which the HEC 30 is fully hydrated. See, for example, U.S. Patent Application 161,444 filed June 20, 1980.

It has been found, as described in U.S. Patent Application 161,444, filed June 20, 1980, that when the concentration of zinc bromide is less than about 20% by weight, the HEC will not efficiently gel or make the saline solution viscous. Indeed, it has been found that while it is possible to make a saline solution containing no zirite bromide or a saline solution containing a high concentration of zinc bromide viscous with HEC when the two thickened solutions are mixed to produce a solution containing 40 zinc bromide at a concentration of less than about 20% by weight, 8300898 K —6 “the viscosity of the mixed salt solution will be substantially the same as if no EEC is present.

As indicated herein, it is a feature of the present invention that EEC functions as an excellent additive to control the loss of flowability in certain heavy saline solutions, wherein EEC is a very ineffective viscous agent. The EEC-containing salt solutions of the present invention are cloudy or opaque compared to the clear salt solutions, which are obtained when the EEC is fully or almost completely hydrated. Apparently, the EEC is not completely dissolved in these saline solutions and so at least part of the EEC is available to act as a bridging agent to reduce the loss of flowability of these saline solutions *

In the practice of the present invention, it is preferred that the EEC be activated such that the HEC will hydrate in these heavy salt solutions at ambient temperature.

The concentration of HEC need only be sufficient to reduce the loss of flowability of the saline.

Preferably, the concentration of HEC will be from about 0.71 to about 14.25 kg / m2, more preferably from about 0.71 to about 8.55 kg / m2.

It is another embodiment of the present invention to provide a method for reducing the flowability loss of heavy salt solutions containing zinc bromide and at least 25 L of soluble salt selected from the group consisting of calcium chloride and calcium bromide, which method of formulating the salt solution contains about 16 to about 20% by weight of zinc bromide and mixing with a brine a flowability-reducing amount of HEC as described above.

Yet another embodiment of the present invention provides a method of reducing the flowability loss of heavy saline solutions containing zinc bromide, calcium chloride and calcium bromide, the method comprising formulating the saline solution to more than 20 wt% zinc bromide and a concentration of calcium chloride of at least (2X-35) wt%, wherein X is the percentage of zinc bromide, and mixing with the saline a flow loss-reducing amount of HEC as described above.

40 Tenx end to explain the invention more fully 83 0 0 8 9 8 _ -7- '? the following non-limiting examples are given.

Heavy saline solutions, with the compositions listed in Table A, were prepared by mixing together the indicated amounts of the following materials. A 2.30 kg / dm 2 calcium bromide / zinc bromide solution containing 20% calcium bromide and 57% zinc bromide, a 1.70 kg / dm 2 calcium bromide solution containing 53% calcium bromide and a 1.39 kg / dm 2 calcium chloride solution containing 37% 6% calcium chloride and calcium chloride granules containing 95% calcium chloride. After cooling to room temperature, the side-activated 8.55 kg / m 2 -ISOLOSOL 250 HHR hydroxyethylcellulose or 8.55 kg / m 2 of activated-250 SO 250 HHR (ie 42.75 kg / m 2 of a composition containing 20% HEC, 25% glycerol, 54 6 isopropanol and 0.4% with CAB-0-SIL 1 ©). Thereafter, the heavy brines were rolled at room temperature for 16 hours and the API HP 13B rheology and flowability loss were obtained. The heavy salt solutions were then rolled at 66 ° C and rolled at 60 ° C for 16 hours, cooled to room temperature and again the API RP 13B data was obtained. The data obtained are shown in Table B.

20 The data indicate that heavy saline solutions containing HEC

can be formulated to have a very low APE current ^ I.

Provide loss of stability provided that the percentage of zinc bromide in the saline in the range of from about 16 to j is about 20% by weight or the percentage of zinc bromide is greater than 25 and the percentage of calcium chloride is greater than (2X-33), where X is the percentage of zinc bromide in the saline. Preferably, the percentage of zinc bromide is in the range of about 18 to about 20% and the percentage of calcium chloride is less than about 5 (2-17)%. In this preferred range, the HEC is solubilized to such an extent that a noticeable viscosity is imparted to the heavy saline. Data also indicate that it is preferable to omit any solid calcium chloride from the heavy saline.

8300898 - "-8-

Q? Abel A

Zinc solution composition

Saline- Close- 95%> lossin ^ -ness, ° / o%% 2.30 * 1.39 -z 1.70, CaCl2 number kg / dnr ZnBr2 CaCl2 CaBr2 kg / dnr kg / dar kg / dnr kg, 1 1.80 0 16.3 43.5 0 0.0285 0.8637 46.7 2 1.80 0 16.3 43.3 0 0.0285 0.8637 46.7 3 1.84 5.1 14. 9 41.2 0.0714 0.0271 0.8014 43.3 4 1.84 5.1 14.9 41.2 0.0714 0.0271 0.8014 43.3 5 1.80 11.7 0 46 , 2 0.160 0 0.840 o 6 1.80 11.7 0 46.2 0.160 0 0.840 0 7 1.90 13.2 12.5 38.0 0.190 0.0229 0.700 37.8 8 1.90 13.2 12 .5 38.0 0.190 0.0229 0.700 37.8 9 1.84 15.7 0 43.9 0.220 0 0.780 0 10 1.84 15.7 0 43.9 0.220 0 0.780 0 11 1.84 16.0 0 43.7 0.224 0 0.776 0 12 1.78 16.0 5.0 36.8 0.217 0.170 0.613 0 13 1.73 16.0 10.0 29.6 0.2 105 0.330 0.4595 0 14 1.92 16.3 11.6 36.7 0.238 0.02140.658 35.4 15 1.92 16.3 11.6 36.7 0.238 0.0214 0.658 35.4 16 '1.85 17.0 0 43, 1 0.239 0 0.761 0 17 1.79 17.0 5.0 36.1 0.2317 0.171 0.5973 0 18 1.86 18.0 0 42.5 0.255 0 0.745 0 19 1.80 18.0 5. 0 35.5 0.2465 0.172 0.5815 o 20 1.77 18.0 7.5 32.0 0.2427 0.2537 0.5036 o 21 1.74 18.0 10.0 28.5 0.239 0.334 0.4 27 0 22 1.86 18.4 0 42.4 0.260 o 0.740 0 23 1.86 18.4 0 42.4 0.260 0 0.740 o 24 1.86 19.0 0 42.1 0.270 0 0.730 o 25 1, 81 19.0 5.0 34.8 0.2615 0.1735 0.565 o

26 1.75 19.0 10.0 28.0 0.2535 0.3335 0.413 O

27 1.71 19.0 14.0 22.3 0.2474 0.45730.2953 O

28 1.87 20.0 O 41.5 0.2855 O 0.7H5 O

29 1.78 20.0 8.0 30.2 0.2714 0.2729 0.4557 O

30 1.78 20.0 8.0 30.2 0.2714 0.2729 0.4557 O

31 1.72 20.0 14.0 21.7 0.2614 0.460 0.2786 O

32 1.72 20.0 14.0 21.7 0.2614 0.460 0.2786 O

33 1.92 22.0 11.7 31.0 0.3214 0.120 0.4957 25.9 34 1.92 22.0 11.7 31.0 0.3214 0.120 0.4957 25.9 35 1.75 22.0 12.0 23.4 0.2943 0.40280.3029 o

36 1.75 22.0 12.0 23.4 0.2943 0.4028 0.3029 O

37 1.73 22.0 14.0 20.7 0.290 0.4628 0.2472 O

318 1.73 22.0 14.0 20.7 0.290 0.4628 0.2472 O

8300398 _: _ · * - -. "1 ft · ...... ---.. Κ -9-

Table 3

Valuation of saline solutions _8.55 kg / m? HATROSOL 250 SER ^ 1) _

16 hours at 23.3 ° C 16 hours at 66 ° C

Saltop API API

discharge API sewerage Straw reversible- Flow path-

number 600 500] [heat loss 60Q 500 ^ spec

1> 300> 300 130 23> 300> 300 149 60 2 (¢ 8) (35) (0) (20) (> 500) $ 300) (69) (so)

3 56 29 2 125 67 34 1 HO

4 (62) (31) (0) (HC) (60) (30) (1) (187) 5 15 8 o JSTC 32 16 0 3 6 (14) (7) (0) (HC) (16) (8) (O) (18)

7 51 26 0 131 63 32 2 HC

8 (49) (25) (0) (HC) (51) (26) (0) (150) 9 24 12 0 HC 98 36 1 1 10 (15) (7) (0) (HC) (40) (24) (2) (4) 11 44 23 1 22 58 30 1 1 12 24 11 0 HC 33 15 0 4 13 21 11 0 HC 44 17 0 9> 5

14 50 25 0 103 63 31 0 HC

15 (52) (26) (0) (HC) (49) (25) (o) (120) 16 42 22 0 5 61 34 3 1 17 32 16 1 25 55 30 2 1 18 222 153 35 1 283 198 37 1 19 162 106 15 1 192 127 11 1 20 31 115 0 50 47 25 3 1 21 57 31 1 16 62 32 1 2 22 205 158 33 1> 300 184 44 1 23 (15) (8) (1) ( NC) (50) (25) (1) (2) 24 222 196 52 1> 300 227 59 1 25 193 161 39 1 274 198 46 1 26 158 104 12 1 187 120 10 1 27 41 21 0 4 52 28 1 1 28 202 218 57 1> 300 249 76 1 29 230 161 34 0 264 205 41 3 30 (H) (8) (0) (HC) (63) (33) (1) (1) 31 152 101 9 1 > 300 233 57 5x 32 (14) (7) (0) (HC) (48) (24) (1) (2) 33 46 23 1 29 172 101 5 1 34 (37) (19) (0) ( HC) (47) (24) (0) (2) 35 234 191 42 4 212 197 44 4 36 (16) (8) (0) (HC) (103) (59) O) 0.5 37 229 170 39 2 213 HO 11 5 38 (16) (8) (0) (HC) (77) (41) (1) (0.2)

(1) Data in brackets obtained using dry powdered MATROSOL 250 HHR

(2) HC = no control 8 3 0 0 S 9 8

Claims (18)

A heavy salt solution containing zinc bromide and at least one soluble salt selected from the group consisting of calcium chloride and calcium bromide and a flow loss-reducing amount of hydroxyethyl cellulose, the salt solution containing about 16 to about 20 wt% zinc bromide. The saline solution of claim 1 having a density in the range of from about 1.70 to about 1.92 kg / dm 2. Saline solution according to claim 1 or 2, characterized in that the concentration of hydroxyethyl cellulose is about 0.71 to about 10 14-25 kg / m 2 *. Saline solution according to claims 1 to 3, characterized in that the concentration of hydroxyethyl cellulose is about 0.71 to about 8.55 kg / m 2. Saline solution according to claims 1 to 4t, characterized in that the hydroxyethyl cellulose is activated such that the hydroxyethyl cellulose will hydrate in the salt solution at ambient temperature. 6. Heavy saline containing zinc bromide, calcium chloride and calcium bromide and a loss of flowability of hydroxyethyl cellulose, the saline containing more than about 20% by weight zinc bromide and a concentration of calcium chloride of at least (2X-33)% by weight. wherein X is the weight percent of zinc bromide in the saline. The saline solution of claim 6 having a density in the range of from about 1.70 to about 1.92 kg / dm 2. Salt solution according to claim 6 or 7), characterized in that the concentration of hydroxyethyl cellulose is about 0.71 to about 14.25 kg / m 2. Saline according to claims 6 to 8, characterized in that the concentration of hydroxyethyl cellulose is about 0.71 to about 8.55 kg / m 2. A salt solution according to claims 6 to 9, characterized in that the hydroxyethyl cellulose is activated such that the hydroxyethyl cellulose in the salt solution will hydrate at ambient temperature. 11. A method for reducing the flowability of heavy saline solutions containing zinc bromide and at least one soluble salt selected from the group consisting of calcium chloride and calcium bromide, characterized in that the concentration of 3300898 * -11- zinc bromide in the brine ranges from about 16 to about 20 wt% and mixes a flow loss-reducing amount of hydroxyethyl cellulose with the brine. 12. Process according to claim 11, characterized in that a salt solution is used with a density in the range from about 1.70 to about 1.92 kg / dm 2. 15. Process according to claim 11 or 12, characterized in that a hydroxyethyl cellulose concentration of from about 0.71 to about 14.25 kg / m 2 is used. 10 Η. Process according to claims 11 to 13, characterized in that a hydroxyethyl cellulose concentration of from about 0.71 to about 8.55 kg / m 2 is used. 15. Process according to claims 11 to 14, characterized in that a hydroxyethyl cellulose is used which is activated in such a way that the hydroxyethyl cellulose will hydrate in the salt solution at ambient temperature. 16. A method for reducing the loss of flowability of heavy salt solutions containing zinc bromide, calcium chloride and calcium bromide, characterized in that the concentration of zinc bromide in the salt solution is adjusted to more than 20% by weight, the concentration of calcium chloride in the saline to at least (2X-33) wt%, wherein X is the weight percent of zinc bromide, and mixes a flow-loss reducing amount of hydroxyethyl cellulose with the saline. 17. Process according to claim 16, characterized in that a salt solution is used with a density in the range from about 1.70 to about 1.92 kg / dm 2. 18. Process according to claim 16 or 17, characterized in that a concentration of hydroxyethyl cellulose is used from about 0.71 to about 14.25 kg / m 2. 19. Process according to claims 16 to 18, characterized in that a concentration of hydroxyethyl cellulose of about 0.71 to about 8.55 kg / m 2 is used. · 20. Process according to claims 16 to 19, characterized in that a hydroxyethyl cellulose is used, which is activated such that the hydroxyethyl cellulose in the salt solution will hydrate at ambient temperature. 8300898