CN103788289A - Acrylamide copolymer, and preparation method and application thereof - Google Patents

Acrylamide copolymer, and preparation method and application thereof Download PDF

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CN103788289A
CN103788289A CN201210420912.5A CN201210420912A CN103788289A CN 103788289 A CN103788289 A CN 103788289A CN 201210420912 A CN201210420912 A CN 201210420912A CN 103788289 A CN103788289 A CN 103788289A
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CN103788289B (en
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杜凯
黄凤兴
林蔚然
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Sinopec Beijing Research Institute of Chemical Industry
China Petroleum and Chemical Corp
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Sinopec Beijing Research Institute of Chemical Industry
China Petroleum and Chemical Corp
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Abstract

The invention discloses an acrylamide copolymer, and a preparation method and an application thereof. The acrylamide copolymer contains a constitutional unit A, a constitutional unit B, a constitutional unit C and a constitutional unit D, wherein the constitutional unit A is a constitutional unit represented by formula (1) and/or a constitutional unit represented by formula (2), the constitutional unit B is one or more of constitutional units represented by formula (3), formula (4), formula (5) and formula (6) respectively, the constitutional unit C is a constitutional unit represented by formula (7) and/or a constitutional unit represented by formula (8), and the constitutional unit D is a constitutional unit represented by formula (9) and/or a constitutional unit represented by formula (10); and the viscosity average molecular weight of the acrylamide copolymer is 2,000,000-25,000,000. The acrylamide copolymer has the advantages of high drag reduction rate, high heat and salt resistance, good high-shear resistance, good water solubility, good compatibleness with clay inhibitors (alcohol), and small damages to the stratum.

Description

A kind of acrylamide based copolymer and its preparation method and application
Technical field
The present invention relates to a kind of acrylamide based copolymer and its preparation method and application.
Background technology
Utilize as unconventional petroleum resources Typical Representative---the exploitation of shale gas (oil) resource has become a revolution in global unconventional petroleum resources field, the at present development and utilization of shale gas has become countries in the world and has paid close attention to emphatically and the focus technology of development.Because the ultimate attainment close hydrocarbon-bearing pools such as shale gas reservoir have the advantages that rate of permeation extremely low (being generally less than 0.5mD), frac pressure are high, easily cause formation damage.Must adopt the exploitation of " drag reduction water (slippery water) pressure break " technique.
" drag reduction water (slippery water) pressure break " is the one of waterfrac treatment.Compared with current conventional pressure break system (modifyed guar gum cross-linking system), drag reduction water (slippery water) pressure break is not to rely on high viscosity colloid to take sand, but takes sand with high infusion discharge capacity, realizes the final purpose that reservoir fracturing is reticulated to crack.The more conventional pressure break system of drag reduction water (slippery water) pressure break has in greater advantage less to the injury on stratum on cost.
Drag reduction water fracturing liquid core auxiliary agent is water base friction reducer, in practice of construction, adding of water-based drag reducer overcomes the friction resistance of working fluid in pipeline, guarantee the raising of infusion discharge capacity, pressure acted on to greatest extent press off stratum and extend formation fracture, what can be used as at present water base friction reducer mainly contains guanidine glue and derivative thereof, derivatived cellulose, acrylamide copolymer.
At present, flow improver during employing guanidine glue and derivative, Mierocrystalline cellulose and derivative thereof split as drag reduction hydraulic pressure has improved to a certain extent infusion discharge capacity, has reduced (the US 5697444 of the friction resistance in pipeline, US 5271466), but still cannot meet the requirement that drag reduction hydraulic pressure splits, there is following shortcoming mainly due to above-mentioned biopolymer: (1) resistance-reducing performance is limited; (2) because having a small amount of insolubles, guanidine glue and derivative, Mierocrystalline cellulose and derivative thereof very easily stratum is damaged; (3) dissolution time is longer.
In drag reduction water pressing crack construction, flow improver during many employing acrylamide copolymers (partially hydrolyzed polyacrylamide) split as drag reduction hydraulic pressure, improve to a great extent infusion discharge capacity, reduce the friction resistance in pipeline, but the flow improver splitting as shale gas reservoir drag reduction hydraulic pressure uses, there is following major defect: (1) is in order to reduce " the water-sensitive effect " in fracturing process, suppress the hydration swelling of shale medium clay soil component, help the of the fracturing fluid row of returning to reduce " water blocking ", must in fracturing liquid, add part alcohol, but the compatibleness of partially hydrolyzed polyacrylamide and product emulsion thereof and alcohol is poor, very easily produce precipitation, (2) flow improver that partially hydrolyzed polyacrylamide splits as shale gas reservoir drag reduction hydraulic pressure uses anti-filtration property poor, this kind of drag reduction water fracturing liquid very easily leak-off in the middle of stratum, (3) temperature resistant antisalt is poor, and especially, under high salinity high divalent ion content condition, molecular structure is unstable, and resistance reducing effect declines very fast, (4) acrylamide copolymer of traditional high molecular weight is difficult for degraded, easily extremely fine and close shale formation is caused to permanent type injury.
Patent US 20090298721A1 discloses the of the fracturing fluid formula of a kind of drag reduction water: in 1000 gallons of deionized waters, add 0.5 gallon of acrylic acidcoacrylamide thing (FR-56 tM) etc. anionic acrylamide copolymer emulsion as flow improver, add again the complexing agents such as 0.15wt% sodium carbonate or EDTA-2Na, this drag reduction water fracturing liquid has good resistance-reducing performance, indoor average resistance-reducing yield reaches 65.0%, salt tolerance (the especially tolerance to divalent calcium ion) has been had to improvement to a certain degree, but this kind of drag reduction hydraulic pressure splits system and uses as shale gas drag reduction water fracturing liquid, there are the following problems: the compatibleness of (1) and alcohol is poor, very easily produces precipitation with the alcohol effect such as methyl alcohol; (2) anti-filtration property is poor, this kind of drag reduction water fracturing liquid very easily leak-off in the middle of stratum; (3) in practice of construction, " water-sensitive effect " is remarkable; (4) very easily produce " water blocking "; (5) resistance to high speed shear poor performance, unstable under high speed shear effect, and resistance-reducing yield declines very fast; (6) heat-resistant salt-resistant is poor, and especially, under high salinity high divalent ion content condition, molecular structure is unstable, and resistance reducing effect declines very fast; (7) be difficult for degraded, easily extremely fine and close shale formation caused to permanent type injury, pollute stratum, then affect oil and gas production.
Compared with above-mentioned partial hydrolysis acrylamide, the acrylamide copolymer of cationic high-molecular amount also has report as flow improver (US 356226, US 3868328).US 3868328 discloses a kind of polymkeric substance, and this polymkeric substance contains (3-acrylamido-3-methyl) butyl trimethyl ammonium chloride and/or reductive agent, adds or acid adding not.The compatibleness of this kind of structure copolymer and alcohol is better, better with clay inhibitor (as KCl) consistency, " water-sensitive effect " is not remarkable, is difficult for " water blocking ", but this type of friction reducer macromole is also difficult for degraded, easily extremely fine and close shale formation is caused to permanent type injury.
But how further to improve the resistance to high speed shear performance of flow improver, improve inhibition and the anti-leak-off of fracturing liquid to clay, the stability that improves the drag reducing efficiency under high temperature and high salt shear conditions has degradability simultaneously, reduce the injury of polymkeric substance to stratum, be still a problem of needing solution badly.
Summary of the invention
The object of the invention is to overcome the defect of above-mentioned prior art, provide that a kind of high molecular, drag reducing efficiency are high, good water solubility, have good compatibleness with clay inhibitor, there is degradability, little to formation damage, and the short acrylamide based copolymer of dissolution time, and the preparation method and application of this acrylamide based copolymer.
The inventor is through research, be surprised to find that, polymerizable functional monomer, by the method for copolymerization, is incorporated into and is contained on acrylamide macromolecular chain, obtain the multipolymer of high molecular by controlling polymerizing condition, also can improve the drag reducing efficiency under high temperature and high salt shear conditions simultaneously, the compatibleness of raising and clay inhibitor, reduces the generation of water-sensitive and water blocking phenomenon, has degradability, can reduce the injury to stratum, thereby obtain the present invention.
The invention provides a kind of acrylamide based copolymer, wherein, described acrylamide based copolymer contains structural unit A, structural unit B, structural unit C and structural unit D, wherein, described structural unit A is the structural unit shown in the structural unit shown in formula (1) and/or formula (2), described structural unit B is for having formula (3), formula (4), one or more in structural unit shown in formula (5) and formula (6), described structural unit C is the structural unit shown in the structural unit shown in formula (7) and/or formula (8), described structural unit D is the structural unit shown in the structural unit shown in formula (9) and/or formula (10), and take the total mole number of structural unit in described acrylamide based copolymer as benchmark, the content of described structural unit A is 5-95 % by mole, the content of described structural unit B is 2.5-90 % by mole, the content of described structural unit C is 0.5-90 % by mole, and the content of described structural unit D is 0.0001-1 % by mole, preferably, the content of described structural unit A is 10-70 % by mole, and the content of described structural unit B is 5-60 % by mole, and the content of described structural unit C is 5-30 % by mole, and the content of described structural unit D is 0.001-0.5 % by mole, the viscosity-average molecular weight of described acrylamide based copolymer is 2,000,000-2,500 ten thousand, is preferably 4,000,000-1,500 ten thousand,
Figure BDA00002322952500021
formula (1),
Figure BDA00002322952500022
formula (2),
Figure BDA00002322952500023
Formula (3),
Figure BDA00002322952500024
formula (4), formula (5),
Figure BDA00002322952500031
formula (6),
Figure BDA00002322952500032
formula (7),
Figure BDA00002322952500033
formula (8),
Figure BDA00002322952500034
formula (9),
Figure BDA00002322952500035
formula (10),
Wherein, R 1, R 1', R 4and R 4' be the alkylidene group of C1-C4 independently of one another; R 2, R 3, R 5, R 6, R 7, R 12, R 13, R 2', R 3', R 5', R 6', R 7', R 12' and R 13' be the alkyl of C1-C4 independently of one another; R 8and R 9be the straight or branched alkyl of H, C1-C20 independently of one another, and R 8and R 9when different, be H; R 8' be the straight chain branched-chain alkyl of C1-C20; R 10, R 11, R 10' and R 11' be the straight or branched alkylidene group of C1-C20 independently of one another; M is at least one in H, K and Na; X -for Cl -, Br -, I -, SCN -,
Figure BDA00002322952500036
or
Figure BDA00002322952500037
The present invention also provides a kind of preparation method of acrylamide based copolymer, this preparation method comprises, under the solution polymerization condition of alkene, under initiator exists, make a kind of monomer mixture in water, carry out polyreaction, it is characterized in that, described monomer mixture contains monomer E, monomer F, monomer G and monomer H, described monomer E is the monomer shown in the monomer shown in formula (19) and/or formula (20), described monomer F is formula (21), formula (22), one or more in monomer shown in formula (23) and formula (24), described monomer G is the monomer shown in the monomer shown in formula (25) and/or formula (26), described monomer H is the monomer shown in the monomer shown in formula (27) and/or formula (28),
Figure BDA00002322952500038
formula (19),
Figure BDA00002322952500039
formula (20), formula (21),
Figure BDA00002322952500041
formula (22),
Figure BDA00002322952500042
formula (23),
Figure BDA00002322952500043
formula (24),
Figure BDA00002322952500044
formula (25),
Figure BDA00002322952500045
formula (26),
Figure BDA00002322952500046
formula (27),
Figure BDA00002322952500047
formula (28),
Wherein, R 1, R 1', R 4and R 4' be the alkylidene group of C1-C4 independently of one another; R 2, R 3, R 5, R 6, R 7, R 12, R 13, R 2', R 3', R 5', R 6', R 7', R 12' and R 13' be the alkyl of C1-C4 independently of one another; R 8and R 9be the straight or branched alkyl of H, C1-C20 independently of one another, and R 8and R 9when different, be H; R 8' be the straight or branched alkyl of C1-C20; R 10, R 11, R 10' and R 11' be the straight or branched alkylidene group of C1-C20 independently of one another; M is at least one in H, K and Na; X -for Cl -, Br -, I -, SCN -,
Figure BDA00002322952500048
or
In addition, the present invention also provides a kind of preparation method of acrylamide based copolymer, this preparation method comprises water and oil phase is mixed to form to reversed-phase emulsion, then under emulsion polymerization condition, this reversed-phase emulsion is contacted with initiator, described water is the aqueous solution that contains monomer mixture, described oil phase contains oil and emulsifying agent, the condition of contact makes monomer mixture polymerization reaction take place, wherein, described monomer mixture contains monomer E, monomer F, monomer G and monomer H, described monomer E is the monomer shown in the monomer shown in above-mentioned formula (19) and/or formula (20), described monomer F is above-mentioned formula (21), formula (22), one or more in monomer shown in formula (23) and formula (24), described monomer G is the monomer shown in the monomer shown in formula (25) and/or formula (26), described monomer H is the monomer shown in the monomer shown in above-mentioned formula (27) and/or formula (28).
In addition, the present invention also provides the acrylamide preparing by aforesaid method based copolymer, and the application of described acrylamide based copolymer in flow improver.
Acrylamide based copolymer of the present invention has high viscosity-average molecular weight, and the viscosity-average molecular weight of the multipolymer making in embodiment 1-6 all can reach more than 4,000,000; Insolubles content in water is only 0.01 % by weight; Be in the NaCl of 2 % by weight, 4 % by weight, 8 % by weight, 10 % by weight, 12 % by weight or KCl solution and in pH value under the condition at 2.5-10 in concentration, drag reducing efficiency all can reach more than 60%; Under the shearing rate of 2500rpm, this polymkeric substance does not produce precipitation at water/alcoholic solution, can dissolve completely; In the time that pH value is less than under 2.5 condition, this polymkeric substance can be degraded, and the injury on stratum is less than to 10%.Illustrate that acrylamide based copolymer of the present invention still has high drag reducing efficiency under high salt, shear conditions, have good consistency with inhibitor (as KCl), cleanup additive (as methyl alcohol) conventional in fracturing liquid formula, and to the low injury in stratum.In addition, two of acrylamide based copolymer provided by the invention kinds of preparation methods (solution polymerization process and reversed emulsion polymerization) have advantages of easy and monomer conversion is high.
Other features and advantages of the present invention are described in detail the embodiment part subsequently.
Embodiment
Below the specific embodiment of the present invention is elaborated.Should be understood that, embodiment described herein only, for description and interpretation the present invention, is not limited to the present invention.
(1) acrylamide based copolymer
The invention provides a kind of acrylamide based copolymer, wherein, described acrylamide based copolymer contains structural unit A, structural unit B, structural unit C and structural unit D, wherein, described structural unit A is the structural unit shown in the structural unit shown in formula (1) and/or formula (2), described structural unit B is formula (3), formula (4), one or more in structural unit shown in formula (5) and formula (6), described structural unit C is the structural unit shown in the structural unit shown in formula (7) and/or formula (8), described structural unit D is the structural unit shown in the structural unit shown in formula (9) and/or formula (10), and take the total mole number of structural unit in described acrylamide based copolymer as benchmark, the content of described structural unit A is 5-95 % by mole, the content of described structural unit B is 2.5-90 % by mole, the content of described structural unit C is 0.5-90 % by mole, and the content of described structural unit D is 0.0001-1 % by mole, preferably, the content of described structural unit A is 10-70 % by mole, and the content of described structural unit B is 5-60 % by mole, and the content of described structural unit C is 5-30 % by mole, and the content of described structural unit D is 0.001-0.5 % by mole, more preferably, the content of described structural unit A is 50-70 % by mole, and the content of described structural unit B is 20-40 % by mole, and the content of described structural unit C is 5-20 % by mole, and the content of described structural unit D is 0.005-0.2 % by mole, the viscosity-average molecular weight of described acrylamide based copolymer is 2,000,000-2,500 ten thousand, is preferably 4,000,000-1,500 ten thousand,
Figure BDA00002322952500051
formula (1),
Figure BDA00002322952500052
formula (2),
Figure BDA00002322952500053
formula (3),
Figure BDA00002322952500054
formula (4),
Figure BDA00002322952500055
formula (5),
Figure BDA00002322952500061
formula (6),
Figure BDA00002322952500062
formula (7),
Figure BDA00002322952500063
formula (8),
formula (9),
Figure BDA00002322952500065
formula (10),
Wherein, R 1and R 1' be the alkylidene group of C1-C4 independently of one another, under preferable case, R 1and R 1' be methylene radical; R 4and R 4' be the alkylidene group of C1-C4 independently of one another, under preferable case, R 4and R 4' be sub-n-propyl, more preferably-CH 2cH 2cH 2-; R 2, R 3, R 5, R 6, R 7, R 12, R 13, R 2', R 3', R 5', R 6', R 7', R 12' and R 13' be the alkyl of C1-C4 independently of one another, be preferably methyl; R 8and R 9be the straight or branched alkyl of H, C1-C20 independently of one another, be preferably the straight or branched alkyl of H or C1-C5, and R 8and R 9when different, be H; R 8' be the straight or branched alkyl of C1-C20, be preferably the straight or branched alkyl of C1-C5, more preferably methyl, ethyl, sec.-propyl, the tertiary butyl; R 10, R 11, R 10' and R 11' be the straight or branched alkylidene group of C1-C20 independently of one another, be preferably the straight or branched alkylidene group of C1-C3, more preferably ethylidene, most preferably is-CH 2cH 2-; M is at least one in H, K and Na, is preferably H; X -for Cl -, Br -, I -, SCN -,
Figure BDA00002322952500066
or
Figure BDA00002322952500067
be preferably Cl -.
The present inventor finds under study for action, and the polymkeric substance being made up of specific structural unit B, structural unit C and structural unit D can be obtained fabulous resistance reducing effect.
For example, preferably, described structural unit B is one or more in the structural unit shown in formula (11), formula (12) and formula (13), described structural unit C is one or more in the structural unit shown in formula (14), formula (15), formula (16) and formula (17), described structural unit D is the structural unit shown in formula (18)
Figure BDA00002322952500068
formula (11),
Figure BDA00002322952500069
formula (12),
Figure BDA00002322952500071
formula (13),
Figure BDA00002322952500072
formula (14),
Figure BDA00002322952500073
formula (15),
Figure BDA00002322952500074
formula (16), formula (17),
Figure BDA00002322952500076
formula (18),
Wherein, R 1for the alkylidene group of C1-C4, under preferable case, R 1for methylene radical; R 4and R 4' be the alkylidene group of C1-C4 independently of one another, under preferable case, R 4and R 4' be sub-n-propyl, more preferably-CH 2cH 2cH 2-; R 10' and R 11' be the straight or branched alkylidene group of C1-C20, be preferably the straight or branched alkylidene group of C1-C3, more preferably ethylidene, most preferably is-CH 2cH 2-.
In the present invention, the example of the alkyl of described C1-C4 can include but not limited to: methyl, ethyl, n-propyl, sec.-propyl, normal-butyl, sec-butyl, isobutyl-and the tertiary butyl.
Described alkylidene group refers to that alkane loses two residues after hydrogen atom, and described two hydrogen atoms can be two hydrogen atoms on same carbon atom, two hydrogen atoms on also can different carbon atoms, it can be straight chain, also can be side chain, for example, described ethylidene can be-CH 2cH 2-or-CH (CH 3)-.
In the present invention, described alkyl can be straight chain, can be also side chain.The example of the straight chained alkyl of described C1-C20 or the branched-chain alkyl of C3-C20 can include but not limited to: methyl, ethyl, n-propyl, sec.-propyl, normal-butyl, sec-butyl, isobutyl-, the tertiary butyl, n-pentyl, isopentyl, tert-pentyl, neo-pentyl, n-hexyl, n-heptyl, n-octyl, positive decyl, dodecyl, hexadecyl and eicosyl.
In the present invention, described alkylidene group can be straight chain, can be also side chain.The example of the straight or branched alkylidene group of described C1-C20 can include but not limited to: methylene radical, ethylidene, sub-n-propyl, isopropylidene, sub-normal-butyl, sub-sec-butyl, isobutylidene, the sub-tertiary butyl, sub-n-pentyl, isopentylidene, sub-tert-pentyl, sub-neo-pentyl, sub-n-hexyl, sub-n-heptyl, sub-n-octyl, sub-positive decyl, sub-dodecyl, sub-hexadecyl and sub-eicosyl.
(2) solution polymerization process
The present invention also provides a kind of preparation method of acrylamide based copolymer, this preparation method comprises, under the solution polymerization condition of alkene, under initiator exists, make a kind of monomer mixture in water, carry out polyreaction, it is characterized in that, described monomer mixture contains monomer E, monomer F, monomer G and monomer H, described monomer E is the monomer shown in the monomer shown in formula (19) and/or formula (20), described monomer F is formula (21), formula (22), one or more in monomer shown in formula (23) and formula (24), described monomer G is the monomer shown in the monomer shown in formula (25) and/or formula (26), described monomer H is the monomer shown in the monomer shown in formula (27) and/or formula (28), and take the total mole number of monomer in described monomer mixture as benchmark, the content of described monomer E is 5-95 % by mole, the content of described monomer F is 2.5-90 % by mole, and the content of described monomer G is 0.5-90 % by mole, and the content of described structure monomer H is 0.0001-1 % by mole, preferably, the content of described monomer E is 10-70 % by mole, and the content of described monomer F is 5-60 % by mole, and the content of described monomer G is 5-30 % by mole, and the content of described structure monomer H is 0.001-0.5 % by mole, more preferably, the content of described monomer E is 50-70 % by mole, and the content of described monomer F is 20-40 % by mole, and the content of described monomer G is 5-20 % by mole, and the content of described monomer H is 0.005-0.2 % by mole, it is 2,000,000-2,500 ten thousand that the condition of described polyreaction makes the viscosity-average molecular weight of resulting polymers after polyreaction, is preferably 4,000,000-15,000,000,
Figure BDA00002322952500081
formula (19),
Figure BDA00002322952500082
formula (20),
Figure BDA00002322952500083
formula (21),
Figure BDA00002322952500084
formula (22),
Figure BDA00002322952500085
formula (23), formula (24),
Figure BDA00002322952500087
formula (25), formula (26),
Figure BDA00002322952500089
formula (27),
Figure BDA000023229525000810
formula (28),
Wherein, R 1and R 1' be the alkylidene group of C1-C4 independently of one another, under preferable case, R 1and R 1' be methylene radical; R 4and R 4' be the alkylidene group of C1-C4 independently of one another, under preferable case, R 4and R 4' be sub-n-propyl, more preferably-CH 2cH 2cH 2-; R 2, R 3, R 5, R 6, R 7, R 12, R 13, R 2', R 3', R 5', R 6', R 7', R 12' and R 13' be the alkyl of C1-C4 independently of one another, be preferably methyl; R 8and R 9be the straight or branched alkyl of H, C1-C20 independently of one another, be preferably the straight or branched alkyl of H or C1-C5, and R 8and R 9when different, be H; R 8' be the straight or branched alkyl of C1-C20, be preferably the straight or branched alkyl of C1-C5, more preferably methyl, ethyl, sec.-propyl, the tertiary butyl; R 10, R 11, R 10' and R 11' be the straight or branched alkylidene group of C1-C20 independently of one another, be preferably the straight or branched alkylidene group of C1-C3, more preferably ethylidene, most preferably is-CH 2cH 2-; M is at least one in H, K and Na, is preferably H; X -for Cl -, Br -, I -, SCN -,
Figure BDA00002322952500091
or
Figure BDA00002322952500092
be preferably Cl -.
According to the present invention, when described polyreaction starts, the ratio of the gross weight of the weight of described monomer mixture and water and monomer mixture is various ratio known in those skilled in the art, the ratio of the gross weight of the weight of described monomer mixture and water and monomer mixture is preferably 0.05-0.5:1, more preferably 0.15-0.4:1, most preferably is 0.2-0.35:1.
According to the present invention, described initiator can be the various initiators in this area.For example, be selected from azo series initiators and redox series initiators.Take the total mole number of monomer in described monomer mixture as benchmark, the consumption of described azo series initiators is 0-10 % by mole, the consumption of described redox series initiators is 0-10 % by mole, and total consumption of described azo initiator and redox initiator preferably meets: total consumption of described initiator is the 0.0001-10 % by mole of the total mole number of monomer in monomer mixture.
In the present invention, preferably, described azo series initiators is selected from Diisopropyl azodicarboxylate, 2,2'-Azobis(2,4-dimethylvaleronitrile), the two methylpent hydrochlorates, 2 of azo, 2 '-azo diisobutyl amidine hydrochloride and 2, at least one in 2 '-azo two [2-(2-tetrahydroglyoxaline-2-propane)-dihydrochloride], more preferably 2,2 '-azo diisobutyl amidine hydrochloride and 2, at least one in 2 '-azo two [2-(2-tetrahydroglyoxaline-2-propane)-dihydrochloride].
Described redox series initiators comprises Oxidizing and Reducing Agents, preferably, the mol ratio of described oxygenant and described reductive agent is 0.5-2:1, meet under the condition of aforementioned proportion, the consumption of described oxygenant is preferably the 0.0001-0.01 % by mole of the total mole number of monomer in monomer mixture, more preferably 0.001-0.008 % by mole; Under preferable case, described oxygenant is selected from least one in ammonium persulphate, Potassium Persulphate, Sodium Persulfate and hydrogen peroxide, more preferably at least one in ammonium persulphate, Potassium Persulphate and Sodium Persulfate; The consumption of described reductive agent is preferably the 0.0001-0.005 % by mole of the total mole number of monomer in monomer mixture, is preferably the 0.001-0.004 % by mole of the total mole number of monomer in monomer mixture; Described reductive agent can be inorganic reducing agent (helping reductive agent), preferably, described inorganic reducing agent is selected from least one in sodium bisulfite, S-WAT, rongalite, Sulfothiorine, ferrous sulfate, vat powder, xitix and urea, more preferably sodium bisulfite and/or Sulfothiorine.
In the present invention, need to particularly point out ground, described monomer H plays the effect of chainextender and organic reducing agent in polymerization process simultaneously, need in polymerization process, not add again organic reducing agent, this may be that when can participating in polyreaction because of the two key groups in described monomer H, the tertiary amine group of end can participate in redox initiation reaction, produces free radical endways on methyl, then on terminal methyl, continue trigger monomer polymerization, likeness in form " bridge formation ".
In addition, the acrylamide based copolymer provided by the invention over the ground injury of layer reduces, and this may be owing to having ester carbonyl group in this polymkeric substance, easily under acidic conditions, DeR occurs.
According to the present invention, described polyreaction can also be carried out under various auxiliary agents exist, and described auxiliary agent can be selected from sequestrant and/or other auxiliary agents; Take the total mole number of monomer in described monomer mixture as benchmark, the consumption of described sequestrant is 0-2 % by mole, be preferably 0.0001-1 % by mole, more preferably 0.0001-0.05 % by mole, the consumption of described other auxiliary agents can be 0-2 % by mole, be preferably 0.0001-1 % by mole, more preferably 0.0001-0.2 % by mole; Preferably, the consumption of described sequestrant and other auxiliary agents makes: take the total mole number of monomer in described monomer mixture as benchmark, the consumption of described auxiliary agent is 0.0001-4 % by mole.
Described sequestrant can be selected from least one in disodium ethylene diamine tetraacetate (EDTA), Triethylene Diamine pentaacetic acid, citric acid, Citrate trianion and poly-hydroxyl acrylic, more preferably one or more in EDTA and/or Citrate trianion, described Citrate trianion can be Tripotassium Citrate, Trisodium Citrate, citrate of lime and ammonium citrate etc.
Described other auxiliary agents can be selected from least one in urea, sodium formiate, Virahol and sodium hypophosphite, are preferably urea and/or sodium formiate.
The present inventor's discovery, exists under the condition of above-mentioned various initiator and auxiliary agent at the same time, and solution polymerization process can obtain the controlled acrylamide based copolymer of viscosity-average molecular weight.
According to the present invention, the condition of described polyreaction can be the condition of this area routine.For example, described polyreaction is carried out under rare gas element exists, and described polymeric reaction condition can comprise: temperature is 0-80 ℃, and the time is 1-24 hour, and pH value is 5-13; Under preferable case, temperature is 4-60 ℃, and the time is 4-24 hour, and pH value is 5-9, and described pH value is by adding acid or alkali to regulate, and described acid is preferably mineral acid, and described mineral acid is preferably at least one in hydrochloric acid, sulfuric acid, sulfonic acid, nitric acid and phosphoric acid; Described alkali can be mineral alkali or organic amine compound, as being selected from least one in sodium hydroxide, potassium hydroxide, ammoniacal liquor, methylamine, ethamine, thanomin and trolamine, is preferably sodium hydroxide.
The present inventor finds under study for action, take following condition can further improve the molecular weight of polymkeric substance:, preferably, described polyreaction comprises the three phases carrying out successively: the reaction conditions of first stage comprises: temperature is 0-10 ℃, be preferably 4-10 ℃, time is 1-15 hour, is preferably 3-10 hour; The reaction conditions of subordinate phase comprises: temperature is 15-30 ℃, is preferably 20-30 ℃, and the time is 3-8 hour, is preferably 3-5 hour; The reaction conditions of phase III comprises: temperature is 35-60 ℃, is preferably 45-55 ℃, and the time is 2-14 hour, is preferably 2-12 hour.
In addition, the present inventor finds under study for action, in the time selecting specific monomer F, monomer G to react with monomer H, can further improve the resistance reducing effect of the polymkeric substance of gained.For example, preferably, described monomer F is one or more in the monomer shown in formula (29), formula (30) and formula (31), described monomer G is one or more in the monomer shown in formula (32), formula (33), formula (34) and formula (35), described monomer H is the monomer shown in formula (36)
Figure BDA00002322952500101
formula (29),
Figure BDA00002322952500102
formula (30),
Figure BDA00002322952500103
formula (31),
Figure BDA00002322952500104
formula (32),
Figure BDA00002322952500105
formula (33),
Figure BDA00002322952500106
formula (34),
Figure BDA00002322952500107
formula (35),
Figure BDA00002322952500108
formula (36),
Wherein, R 1for the alkylidene group of C1-C4, under preferable case, R 1for methylene radical; R 4and R 4' be the alkylidene group of C1-C4 independently of one another, under preferable case, R 4and R 4' be sub-n-propyl, more preferably-CH 2cH 2cH 2-; R 10' and R 11' be the straight or branched alkylidene group of C1-C20, be preferably the straight or branched alkylidene group of C1-C3, more preferably ethylidene, most preferably is-CH 2cH 2-.
(3) reversed emulsion polymerization
In addition, the present invention also provides a kind of preparation method of acrylamide based copolymer, this preparation method comprises water and oil phase is mixed to form to reversed-phase emulsion, then under emulsion polymerization condition, this reversed-phase emulsion is contacted with initiator, described water is the aqueous solution that contains monomer mixture, described oil phase contains oil and emulsifying agent, the condition of contact makes monomer mixture polymerization reaction take place, wherein, described monomer mixture contains monomer E, monomer F, monomer G and monomer H, described monomer E is the monomer shown in the monomer shown in above-mentioned formula (19) and/or formula (20), described monomer F is above-mentioned formula (21), formula (22), one or more in monomer shown in formula (23) and formula (24), described monomer G is the monomer shown in the monomer shown in above-mentioned formula (25) and/or formula (26), described monomer H is the monomer shown in the monomer shown in above-mentioned formula (27) and/or formula (28), and take the total mole number of monomer in described monomer mixture as benchmark, the content of described monomer E is 5-95 % by mole, and the content of described monomer F is 2.5-90 % by mole, and the content of described monomer G is 0.5-90 % by mole, and the content of described monomer H is 0.0001-1 % by mole, preferably, the content of described monomer E is 10-70 % by mole, and the content of described monomer F is 5-60 % by mole, and the content of described monomer G is 5-30 % by mole, and the content of described structure monomer H is 0.001-0.5 % by mole, more preferably, the content of described monomer E is 50-70 % by mole, and the content of described monomer F is 20-40 % by mole, and the content of described monomer G is 5-20 % by mole, and the content of described structure monomer H is 0.005-0.2 % by mole, it is 2,000,000-2,500 ten thousand that the condition of described polyreaction makes the viscosity-average molecular weight of resulting polymers after polyreaction, is preferably 4,000,000-15,000,000.
The elaboration of monomer and preferable case shown in formula (19)-Shi (28) with describe identically above, do not repeat them here.
According to the present invention, described water is the aqueous solution that contains monomer mixture.Elaboration and the preferable case of the weight of described monomer mixture and the ratio of the gross weight of water and monomer mixture and describe identically above do not repeat herein.
According to the present invention, part by weight to described water and oil phase has no particular limits, as long as make described water and oil phase be thoroughly mixed to form reversed-phase emulsion, under preferable case, the part by weight of described water and oil phase can be 1:0.1-2, more preferably 1:0.2-0.8
According to the present invention, described oil can be this area various for letex polymerization with the mutual exclusive nonpolar or organic solvent that polarity is little of water, can be for example at least one in toluene, dimethylbenzene, hexane, hexanaphthene, normal heptane, isomery paraffin, isoparaffin, gasoline, kerosene and white oil, under preferable case, at least one in toluene, dimethylbenzene, normal heptane, isoparaffin, hexanaphthene and kerosene of described grease separation.
According to the present invention, described oil phase contains oil and emulsifying agent.The consumption of described oil is not had to special requirement, can in wider scope, change, as long as described oil and emulsifying agent are mixed to form oil phase, under preferable case, take the gross weight of described emulsion as benchmark, the consumption of described oil can be 10-60 % by weight, more preferably 15-35 % by weight.
According to the present invention, described emulsifying agent can be the various nonionic emulsifier for letex polymerization in this area, for example, can be sorbitan fatty acid ester, alkylphenol polyoxyethylene, isomery polyoxyethylenated alcohol, ethoxylated dodecyl alcohol, propylene glycol fatty acid ester, laureth, benzylphenol oxygen Soxylat A 25-7, styroyl phenol polyethenoxy ether, polyoxyethylene sorbitan fatty acid ester, sorbitan fatty acid ester ethylene oxide adduct, benzyl dimethyl phenol polyethenoxy ether, at least one in fatty alcohol-polyoxyethylene ether and aliphatic amine polyoxyethylene ether, under preferable case, described emulsifying agent is selected from sorbitan fatty acid ester, polyoxyethylene sorbitan fatty acid ester, polyoxyethylene nonylphenol ether, polyoxyethylene octylphenol ether, benzylphenol oxygen Soxylat A 25-7, styroyl phenol polyethenoxy ether, isomerous tridecanol polyoxyethylene ether, at least one in ethoxylated dodecyl alcohol and benzyl dimethyl phenol polyethenoxy ether, the compound emulsifying agent that the hydrophile-lipophile balance value being more preferably made up of above-mentioned two or more emulsifying agent is 5-9 can be for example sorbitan fatty acid ester and polyoxyethylene nonylphenol ether.
According to the present invention, consumption to described emulsifying agent is not particularly limited, can in wider scope, change, as long as described emulsifying agent and oil are mixed to form oil phase, under preferable case, take the gross weight of described emulsion as benchmark, the consumption of described emulsifying agent can be 1-10 % by weight, more preferably 2-9 % by weight.
According to the present invention, described initiator can be various initiators in this area, the elaboration of described initiator and preferable case with describe identically above, repeat no more herein.
In the present invention, under preferable case, can first azo series initiators be added to water, then be mixed to form reversed-phase emulsion with oil phase, then reversed-phase emulsion be contacted with redox series initiators, by redox initiator initiated polymerization.
According to the present invention, described polyreaction can also be carried out under various auxiliary agents exist, and described auxiliary agent can be selected from sequestrant and/or other auxiliary agents, the elaboration of described auxiliary agent and preferable case with describe identically above, repeat no more herein.
According to the present invention, to there is no special requirement the reinforced opportunity of described sequestrant, as long as make sequestrant and metal ion generation sequestering action so that multipolymer is played to static stabilization, can be chosen in water adds or adds in oil phase, under preferable case, in order to make the sequestrant effect of playing stably more fully, can be chosen in and in water, add sequestrant.
According to the present invention, the elaboration of described sequestrant and preferable case with describe identically above, repeat no more herein.
Equally, the present inventor's discovery, exists under the condition of above-mentioned various initiator and auxiliary agent at the same time, and reversed emulsion polymerization can obtain the acrylamide based copolymer that viscosity-average molecular weight is controlled and dissolution rate is fast.
According to the present invention, the condition of described polyreaction can be the condition of this area routine.The elaboration of described polymeric reaction condition and preferable case with describe identically above, repeat no more herein.
Equally, the present inventor finds under study for action, take following condition can further improve the molecular weight of polymkeric substance:, preferably, described polyreaction comprises two stages of carrying out successively: the reaction conditions of first stage comprises: temperature is 0-20 ℃, be preferably 5-10 ℃, the time is 1-15 hour, is preferably 1-5 hour; The reaction conditions of subordinate phase comprises: temperature is 20-60 ℃, is preferably 25-55 ℃, and the time is 2-8 hour, is preferably 2-5 hour.
According to the present invention, the method contacts described polyreaction products therefrom after being also included in described polyreaction with phase inversion agent.Described phase inversion agent can be for this area be for the various phase inversion agent of letex polymerization, as long as described polyreaction products therefrom is dissolved fast in fracturing liquid application in water, it can be for example polyoxyethylene sorbitan fatty acid ester, polyoxyethylene nonylphenol ether, polyoxyethylene octylphenol ether, Ben-zylphenol Polyoxyethyl Ether, styroyl phenol polyethenoxy ether, isomery ten polyoxyethylenated alcohol, isomery undecyl alcohol Soxylat A 25-7, at least one in the nonionic emulsifier of isomerous tridecanol polyoxyethylene ether and aliphatic amine polyoxyethylene ether, under preferable case, described phase inversion agent is selected from polyoxyethylene sorbitan fatty acid ester, isomery ten polyoxyethylenated alcohol, isomery undecyl alcohol Soxylat A 25-7, isomerous tridecanol polyoxyethylene ether, at least one in polyoxyethylene nonylphenol ether and polyoxyethylene octylphenol ether.
According to the present invention, the consumption of described phase inversion agent is not had to special requirement, as long as can make described polyreaction products therefrom dissolve in water fast in fracturing liquid application, the consumption of described phase inversion agent makes: take the gross weight of described emulsion as benchmark, the consumption of described phase inversion agent can be 0.5-10 % by weight, is preferably 1-5 % by weight.
In addition, the present inventor finds under study for action, in the time selecting specific monomer F, monomer G to react with monomer H, can further improve the resistance reducing effect of the polymkeric substance of gained.For example, preferably, described monomer F is one or more in the monomer shown in formula (29), formula (30) and formula (31), described monomer G is one or more in the monomer shown in formula (32), formula (33), formula (34) and formula (35), described monomer H is the monomer shown in formula (36), the elaboration of monomer and preferable case shown in formula (29)-Shi (36) with describe identically above, do not repeat them here.
The present invention also provides the acrylamide based copolymer making according to above-mentioned two kinds of methods.
In addition, the present invention also provides the application of described acrylamide based copolymer in flow improver.Adopt described acrylamide based copolymer provided by the invention as fracturing liquid flow improver, can obtain high and stable drag reducing efficiency, the technology that concrete application method is well known to those skilled in the art.
By the following examples the specific embodiment of the present invention is elaborated.Should be understood that, embodiment described herein only, for description and interpretation the present invention, is not limited to the present invention.
Intrinsic viscosity is measured according to GB12005.1-89 polyacrylamide For Intrinsic Viscosity Measurements method; Viscosity-average molecular weight is according to formula M v=([η]/K) 1 α, wherein K=4.5 × 10 -3, calculate α=0.80; Dissolution time is measured by GB12500.8-89, and (sample quality is all by straight polymer quality in sample), the powdered samples dissolution time recording is all less than 20min, and samples of latex dissolution time is all less than 5min; The composition of molecular structure and structural unit adopt IR spectrum and 13c-NMR measures; Water insoluble matter content is pressed SY/T 5862-1993 and is measured; Indoor drag reducing efficiency is pressed SY/T 6376-2008 and is measured; Friction reducer carries out rock core matrix permeability infringement experiment by fracturing liquid filtrate in oil and gas industry standard SY/T 5107-2005 " aqueous fracturing fluid method of evaluating performance " the nocuity of rock core.
Monomer M 3 shown in monomer M 1 shown in following embodiment Chinese style (37) and formula (40) is all purchased from Sigma-Aldrich company, and in addition, unless specified otherwise, the reagent of using in embodiment, comparative example and test case etc. is commercially available product.
Embodiment 1
The present embodiment is used for illustrating that solution polymerization process provided by the invention prepares acrylamide based copolymer.
Under room temperature, by the M1 monomer shown in the formula (37) of the acrylamide of 38.38g (AM), 39.65g, the N of 4.03g, M2 monomer shown in the formula (38) of N-DMAA (purchased from Sigma-Aldrich company) and 0.41g is (according to document Macromolecular Bioscience, 2006,6 (7), the method for 540-554 makes, identical below) join in reaction flask, add deionized water 329.88g, stir monomer is dissolved completely, and stir.Respectively to the EDTA aqueous solution 5.4g that adds 1 % by weight in flask, 1 % by weight azo diisobutyl amidine hydrochloride aqueous solution 2.0g, urea 0.12g, fully stirs it is mixed.With the sodium hydroxide solution pH to 7.4 of 1 % by weight, add 0.5 % by weight sodium sulfite solution 1.1g, hierarchy of control initial temperature to 4 ℃, logical nitrogen deoxygenation, after 30 minutes, adds 1 % by weight ammonium persulfate aqueous solution 1.1g, and continues letting nitrogen in and deoxidizing 20 minutes.Reactor is airtight, remain on 4 ℃, react after 10 hours, after being risen to 20 ℃, temperature reacts 5 hours, then temperature is risen to 50 ℃ of reactions 5 hours, the gluey product obtaining is taken out, through granulation, dry, pulverize and can obtain high molecular weight acrylamide based copolymer P1.
P1 is carried out to various mensuration, in IR spectrum, 1660cm -1and 1635cm -1there is respectively belonging to amide Ⅰ absorption peak (C=O stretching vibration) and the acid amides II band absorption peak (N-H flexural vibration) of amide group, 2792cm in place -1for the methyl C-H asymmetrical stretching vibration absorption peak of quaternary ammonium group, at 1430cm -1there is the stretching vibration absorption peak of C-N, 1729cm in place -1there is the feature stretching vibration peak of M2 monomeric ester carbonyl, 2936cm -1appearance-CH 3absorption peak, 1356 and 1401cm - 1occur typical methyl symmetric curvature vibration absorption peak, can determine that the copolymer molecule obtaining has the structure shown in formula (39), recording its viscosity-average molecular weight Mv by viscosity method is 1,391 ten thousand, and monomer conversion is more than 99.9%.Wherein, formula (39) and x 1, x 2, y 1, y 2, z 1, z 2only express type and the number of structural unit with u, and do not represent the mode of connection of structural unit.X 1, x 2, y 1, y 2, z 1, z 2determined by charging capacity with the concrete numerical value of u, the composition of molecular structural formula and structural unit adopts quantitatively 13c composes mensuration, obtains (x 1+ x 2): (y 1+ y 2): (z 1+ z 2): u=1:0.35:0.08:0.003.
Figure BDA00002322952500131
formula (37),
Figure BDA00002322952500132
formula (38),
Figure BDA00002322952500141
formula (39)
Comparative example 1
Prepare acrylamide based copolymer according to the method for embodiment 1, different, do not add N,N-DMAA and M2 monomer, thereby obtain multipolymer DP1, record its viscosity-average molecular weight M vbe 1,400 ten thousand.
Comparative example 2
Prepare acrylamide based copolymer according to the method for embodiment 1, different is, acrylamide is carried out to polyreaction with (3-acrylamido-3-methyl) butyl trimethyl ammonium chloride of identical mole number, thereby obtain copolymer DP2, record its viscosity-average molecular weight M vbe 1,370 ten thousand.
Embodiment 2
The present embodiment is used for illustrating that solution polymerization process provided by the invention prepares acrylamide based copolymer.
Under room temperature, M2 monomer shown in M3 monomer shown in the formula of the Methacrylamide of 35.23g, 72.1g (40), the tert-butyl acrylate of 10.25g and the formula of 0.01g (38) is joined in polymerization bottle, add 218.38g deionized water, stirring is dissolved monomer completely, respectively to the EDTA aqueous solution 7.56g that adds 1 % by weight in flask, add 1 % by weight azo diisobutyl amidine hydrochloride aqueous solution 2.13g, add 0.1 % by weight sodium sulfite solution 3.2g, add urea 0.20g, fully stir it is mixed.Hierarchy of control initial temperature to 8 ℃, logical nitrogen deoxygenation, after 30 minutes, adds 1% ammonium persulfate aqueous solution 1.0g and continues letting nitrogen in and deoxidizing 10 minutes.Reactor is airtight, remain on 8 ℃, react after 8 hours, be warming up to 30 ℃, react after 3 hours, be warming up to 55 ℃ of reactions 2 hours, the gluey product obtaining is taken out, through granulation, dry, pulverize the acrylamide copolymer p 2 that can obtain high molecular.
P2 is carried out to IR spectrometry, 1660cm in IR spectrum -1and 1635cm -1there is respectively belonging to amide Ⅰ absorption peak (C=O stretching vibration) and the acid amides II band absorption peak (N-H flexural vibration) of amide group, 2792cm in place -1for the methyl C-H asymmetrical stretching vibration absorption peak of quaternary ammonium group, 1394cm -1in appearance tert-butyl acrylate-(CH 3) 3absorption peak, 1729cm -1there is the feature stretching vibration peak of M2 monomeric ester carbonyl.Can determine that the copolymer molecule obtaining has the structure shown in formula (41), recording its viscosity-average molecular weight Mv by viscosity method is 1,467 ten thousand, and monomer conversion is more than 99.9%.Wherein, formula (42) and x 1, x 2, y 1, y 2, z 1, z 2only express type and the number of structural unit with u, and do not represent the mode of connection of structural unit.X 1, x 2, y 1, y 2, z 1, z 2determined by charging capacity with the concrete numerical value of u, the composition of molecular structural formula and structural unit adopts quantitatively 13c composes mensuration, obtains (x 1+ x 2): (y 1+ y 2): (z 1+ z 2): u=1:0.79:0.19:0.0001.
formula (40),
Figure BDA00002322952500152
formula (41).
Embodiment 3
The present embodiment is used for illustrating that solution polymerization process provided by the invention prepares acrylamide based copolymer.
Under room temperature, M2 monomer shown in M4 monomer shown in the formula of the Methacrylamide of 14.38g, 11.61g (42), the N tert butyl acrylamide of 7.12g and the formula of 0.06g (38) is joined in reaction flask, add deionized water 77.26g, stir monomer is dissolved completely, and stir.Respectively to the EDTA aqueous solution 4.65g that adds 1 % by weight in flask, 1 % by weight azo diisobutyl amidine hydrochloride aqueous solution 1.03g, urea 0.21g, fully stirs it is mixed.PH is adjusted to 7.1 with sodium hydrate solid.Add 0.5 % by weight sodium sulfite solution 1.1g, hierarchy of control initial temperature to 10 ℃, logical nitrogen deoxygenation, after 30 minutes, adds 1 % by weight ammonium persulfate aqueous solution 1.1g, and continues letting nitrogen in and deoxidizing 20 minutes.Reactor is airtight, remain on 10 ℃, react after 3 hours, after being risen to 25 ℃, temperature reacts 4 hours, then temperature is risen to 45 ℃ of reactions 12 hours, the gluey product obtaining is taken out, through granulation, dry, pulverize and can obtain high molecular weight acrylamide based copolymer P3.
P3 is carried out to various mensuration, in IR spectrum, 1660cm -1and 1635cm -1there is respectively belonging to amide Ⅰ absorption peak (C=O stretching vibration) and the acid amides II band absorption peak (N-H flexural vibration) of amide group, 1729cm in place -1there is the feature stretching vibration peak of M2 monomeric ester carbonyl, at 1040cm -1there is the stretching vibration absorption peak of O-S in place, at 601cm -1there is the stretching vibration absorption peak of C-S, 2936cm in place -1appearance-CH 3absorption peak, 1380cm -1there is tert-butyl acrylate-(CH 3) 3absorption peak, can determine that the copolymer molecule obtaining has the structure shown in formula (43), and recording its viscosity-average molecular weight Mv by viscosity method is 8,450,000, and monomer conversion is more than 99.9%.Wherein, formula (43) and x 1, x 2, y 1, y 2, z 1, z 2only express type and the number of structural unit with u, and do not represent the mode of connection of structural unit.X 1, x 2, y 1, y 2, z 1, z 2determined by charging capacity with the concrete numerical value of u, the composition of molecular structural formula and structural unit adopts quantitatively 13c composes mensuration, obtains (x 1+ x 2): (y 1+ y 2): (z 1+ z 2): u=1:0.33:0.33:0.002.
formula (42),
Figure BDA00002322952500162
formula (43).
Embodiment 4
The present embodiment is used for illustrating that emulsion polymerization provided by the invention prepares acrylamide based copolymer.
(1) the M2 monomer shown in the M4 monomer shown in the formula of the acrylamide of 12.01g, 11.61g (42), the NIPA of 6.34g and the formula of 0.06g (38) is joined in configuration bottle, add 70.05g deionized water, stirring is dissolved monomer completely, respectively to the EDTA aqueous solution 4.65g that adds 1 quality % in flask, add 1 % by weight azo diisobutyl amidine hydrochloride aqueous solution 1.03g, add urea 0.21g, fully stir it is mixed, pH is adjusted to 7.1 with sodium hydrate solid, obtains water.
(2) by sorbitan fatty acid ester (span60, Sigma-Aldrich company, identical below) 3.5g, alkylphenol polyoxyethylene (Igepal CA720, Sigma-Aldrich company, below identical) 2g, 45.54g kerosene is mixed into oil phase, and the water obtaining in step (1) is joined in oil phase, mix formation reversed-phase emulsion by high speed and join in reactor.
(3) 5 ℃ of hierarchy of control initial temperatures, logical nitrogen deoxygenation, after 30 minutes, adds 1 % by weight aqueous solution of sodium bisulfite 2.0g, then adds 1 % by weight ammonium persulfate aqueous solution 4.0g, and continue letting nitrogen in and deoxidizing 10 minutes.Reactor is airtight, remain on 5 ℃, react after 5 hours, be warming up to 55 ℃, react 2 hours.After question response temperature cool to room temperature, add 7.2g phase inversion agent polyoxyethylene nonylphenol ether (Sigma-Aldrich company, below identical), obtain emulsion form product with 80 order filter-cloth filterings.After using acetone and methanol mixed solvent deposition out reversed-phase emulsion product, can obtain acrylamide copolymer p 4.
P4 is carried out to IR spectrometry, 1660cm in IR spectrum -1and 1635cm -1there is respectively belonging to amide Ⅰ absorption peak (C=O stretching vibration) and the acid amides II band absorption peak (N-H flexural vibration) of amide group in place,, 1729cm -1there is the feature stretching vibration peak of M2 monomeric ester carbonyl, at 1040cm -1there is the stretching vibration absorption peak of O-S in place; At 601cm -1there is the stretching vibration absorption peak of C-S, 1387cm in place -1, 1367cm -1form bimodal divided in the symmetrical deformation vibration coupling that occurs two methyl on sec.-propyl.Can determine that the copolymer molecule obtaining has the structure shown in formula (44), recording its viscosity-average molecular weight Mv by viscosity method is 1,280 ten thousand, and monomer conversion is more than 99.9%.Wherein, formula (44) and x 1, x 2, y 1, y 2, z 1, z 2only express type and the number of structural unit with u, and do not represent the mode of connection of structural unit.X 1, x 2, y 1, y 2, z 1, z 2determined by charging capacity with the concrete numerical value of u, the composition of molecular structural formula and structural unit adopts quantitatively 13c composes mensuration, obtains (x 1+ x 2): (y 1+ y 2): (z 1+ z 2): u=1:0.33:0.33:0.002.
formula (44).
Comparative example 3
Prepare acrylamide based copolymer according to the method for embodiment 4, different, do not add NIPA and M2 monomer, thereby obtain multipolymer DP3, record its viscosity-average molecular weight M vbe 1,200 ten thousand.
Comparative example 4
Prepare acrylamide based copolymer according to the method for embodiment 4, different is, acrylamide is carried out to polyreaction with (3-acrylamido-3-methyl) butyl trimethyl ammonium chloride of identical mole number, thereby obtain copolymer DP4, record its viscosity-average molecular weight M vbe 1,325 ten thousand.
Embodiment 5
The present embodiment is used for illustrating that emulsion polymerization provided by the invention prepares acrylamide based copolymer.
(1) by the M3 monomer shown in the formula of the acrylamide of 38.17g, 96.1g (40), the N of 10.71g, M2 monomer shown in the formula (38) of N-DMAA and 0.01g joins in configuration bottle, add 269.27g deionized water, stirring is dissolved monomer completely, respectively to the EDTA aqueous solution 5.2g that adds 1 quality % in flask, add 1 % by weight azo diisobutyl amidine hydrochloride aqueous solution 1.0g, add urea 0.58g, fully stir it is mixed, with the sodium hydroxide solution pH to 7.1 of 1 % by weight, obtain water.
(2) by sorbitan fatty acid ester (span60) 38g, alkylphenol polyoxyethylene (Igepal CA720) 16.98g, 240.72g kerosene is mixed into oil phase, and the water obtaining in step (1) is joined in oil phase, mixes formation reversed-phase emulsion join in reactor by high speed.
(3) 5 ℃ of hierarchy of control initial temperatures, logical nitrogen deoxygenation, after 30 minutes, adds 1 % by weight aqueous solution of sodium bisulfite 0.80g, then adds 1 % by weight ammonium persulfate aqueous solution 2.5g and continue letting nitrogen in and deoxidizing 10 minutes.Reactor is airtight, remain on 8 ℃, react after 1 hour, be warming up to 25 ℃, react 5 hours, after question response temperature cool to room temperature, add 15.8g polyoxyethylene nonylphenol ether, obtain emulsion form product with 80 order filter-cloth filterings.After using acetone and methanol mixed solvent deposition out reversed-phase emulsion product, can obtain the acrylamide copolymer p 5 of high molecular.
P5 is carried out to IR spectrometry, 1660cm in IR spectrum -1and 1635cm -1there is respectively belonging to amide Ⅰ absorption peak (C=O stretching vibration) and the acid amides II band absorption peak (N-H flexural vibration) of amide group, 2792cm in place -1for the methyl C-H asymmetrical stretching vibration absorption peak of quaternary ammonium group, 1729cm -1there is the feature stretching vibration peak of M2 monomeric ester carbonyl, at 1430cm -1there is the stretching vibration absorption peak of C-N, 2936cm in place -1appearance-CH 3absorption peak, 1356 and 1401cm - 1occur typical methyl symmetric curvature vibration absorption peak, can determine that the copolymer molecule obtaining has the structure shown in formula (45), recording its viscosity-average molecular weight Mv by viscosity method is 1,498 ten thousand, and monomer conversion is more than 99.9%.Wherein, formula (45) and x 1, x 2, y 1, y 2, z 1, z 2only express type and the number of structural unit with u, and do not represent the mode of connection of structural unit.X 1, x 2, y 1, y 2, z 1, z 2determined by charging capacity with the concrete numerical value of u, the composition of molecular structural formula and structural unit adopts quantitatively 13c composes mensuration, obtains (x 1+ x 2): (y 1+ y 2): (z 1+ z 2): u=1:0.81:0.20:0.0001.
Embodiment 6
The present embodiment is used for illustrating that emulsion polymerization provided by the invention prepares acrylamide based copolymer.
(1) the M2 monomer shown in the M1 monomer shown in the formula of the Methacrylamide of 47.06g, 36.55g (37), the tert-butyl acrylate of 5.25g and the formula of 0.41g (38) is joined in configuration bottle, add 357.08g deionized water, stirring is dissolved monomer completely, respectively to the EDTA aqueous solution 8.0g that adds 1 quality % in flask, add 1 % by weight azo diisobutyl amidine hydrochloride aqueous solution 4.1g, add urea 0.3g, fully stir it is mixed, with the sodium hydroxide solution pH to 7.1 of 1 % by weight, obtain water.
(2) by sorbitan fatty acid ester (span60) 13g, alkylphenol polyoxyethylene (Igepal CA720) 1.7g, 95.51g kerosene is mixed into oil phase, and the water obtaining in step (1) is joined in oil phase, mixes formation reversed-phase emulsion join in reactor by high speed.
(3) 35 ℃ of hierarchy of control initial temperatures, logical nitrogen deoxygenation, after 30 minutes, adds 1 % by weight aqueous solution of sodium bisulfite 0.150g, then adds 1 % by weight ammonium persulfate aqueous solution 0.6g and continue letting nitrogen in and deoxidizing 10 minutes.Reactor is airtight, remain on 10 ℃, react after 4 hours, be warming up to 40 ℃, react 4 hours, after question response temperature cool to room temperature, add 5.0g polyoxyethylene nonylphenol ether, obtain emulsion form product with 80 order filter-cloth filterings.By reversed-phase emulsion product with acetone and methanol mixed solvent deposition out after,, can obtain the acrylamide copolymer p 6 of high molecular.
P6 is carried out to IR spectrometry, 1660cm in IR spectrum -1and 1635cm -1there is respectively belonging to amide Ⅰ absorption peak (C=O stretching vibration) and the acid amides II band absorption peak (N-H flexural vibration) of amide group, 2792cm in place -1for the methyl C-H asymmetrical stretching vibration absorption peak of quaternary ammonium group.1394cm -1there are tert-butyl acrylate-(CH3) 3 absorption peaks, 1729cm -1there is the feature stretching vibration peak of M2 monomeric ester carbonyl.Can determine that the copolymer molecule obtaining has the structure shown in formula (46), recording its viscosity-average molecular weight Mv by viscosity method is 7,500,000, and monomer conversion is more than 99.9%.Wherein, formula (46) and x 1, x 2, y 1, y 2, z 1, z 2only express type and the number of structural unit with u, and do not represent the mode of connection of structural unit.X 1, x 2, y 1, y 2, z 1, z 2determined by charging capacity with the concrete numerical value of u, the composition of molecular structural formula and structural unit adopts quantitatively 13c composes mensuration, obtains (x 1+ x 2): (y 1+ y 2): (z 1+ z 2): u=1:0.32:0.07:0.003.
formula (45).
Figure BDA00002322952500192
formula (46).
Test case 1
Water-insoluble is to measure according to the method stipulating in SY/T 5862-1993.By P1-P6, DP1-DP4 and hydroxypropyl guar gum (JXY wellfracturing hydroxypropyl melon rubber powder, Shandong Ju Xin Chemical Co., Ltd., below identical) carry out water-soluble mensuration, result is as shown in table 1.
Table 1
As can be seen from the above table, in acrylamide copolymer p 1-P6 prepared by two kinds of methods provided by the invention, water-insoluble is starkly lower than the conventional hydroxypropyl guar gum that cooks flow improver in site operation, and this explanation is to use P1-P6 low to the injury on stratum compared with hydroxypropyl guar gum as shale gas pressure break flow improver.
Test case 2
Under 2500rpm shearing rate, respectively by P1-P6, DP1-DP4, partially hydrolyzed polyacrylamide (HPAM, Zibo Tian Jian Chemical Co., Ltd., trade mark TJY-3, viscosity-average molecular weight are 1800-2000 ten thousand, identical below) slowly to join respectively volume ratio be in water/alcoholic solution (using methyl alcohol in this test case) of 80/20 and 60/40,0.01 % by weight (sample quality is by straight polymer quality in sample) that P1-P6, DP1-DP4, partially hydrolyzed polyacrylamide are water/alcoholic solution, dissolution time is 30min, and result is as shown in table 2.
Table 2
Figure BDA00002322952500202
As can be seen from Table 2, acrylamide copolymer p 1-P6 prepared by two kinds of methods provided by the invention is as shale gas pressure break flow improver, compared with partially hydrolyzed polyacrylamide, good with the compatibleness of alcohol.
Test case 3
Be under the condition of 25 ℃ in temperature, by P1-P6, DP1-DP4, HPAM and hydroxypropyl guar gum are dissolved in respectively pure water and concentration is 2 % by weight, 4 % by weight, 8 % by weight, 10 % by weight, in the NaCl of 12 % by weight or KCl solution, the solution of the 500mg/L being mixed with and 1000mg/L (sample quality is by straight polymer quality in sample), then on GLM-1 pipeline frictional resistance determinator, measure the drag reducing efficiency of above-mentioned solution according to the method stipulating in SY/T 6376-2008, (test condition: the internal diameter of test section pipeline is 8mm, the length of test section pipeline is 9m, infusion discharge capacity is 30L/min), result as shown in Table 3 and Table 4.
Table 3
Figure BDA00002322952500212
Figure BDA00002322952500221
Table 4
Figure BDA00002322952500222
Figure BDA00002322952500231
From table 3 and table 4, can find out, acrylamide copolymer p 1-P6 prepared by two kinds of methods provided by the invention, as shale gas pressure break flow improver, compares with hydroxypropyl guar gum, HPAM and DP1-DP4, with clay inhibitor (as, KCl) compatibleness is good, anti-salt property excellence.
Test case 4
Drag reducing efficiency is to measure according to the method stipulating in SY/T 6376-2008.P1-P6, DP1-DP4 are dissolved in respectively to pure water, are mixed with the solution (sample quality is by straight polymer quality in sample) of 500mg/L, by adding HCl or NaOH, the pH value of regulation system changes between 2.5-10, and result is as shown in table 5.
Table 5
Figure BDA00002322952500241
As can be seen from Table 5, the acrylamide copolymer p 1-P6 that prepared by two kinds of methods provided by the invention has good resistance reducing effect as shale gas pressure break flow improver within the scope of very large pH value.
Test case 5
Friction reducer carries out rock core matrix permeability infringement experiment by fracturing liquid filtrate in oil and gas industry standard SY/T 5107-2005 " aqueous fracturing fluid method of evaluating performance " the nocuity of rock core, on American core company formation injury tester (FDS-800), test, the matrix permeability of rock core is 2md.
P1-P6, DP1-DP4 are dissolved in respectively to pure water, be mixed with the solution (sample quality is by straight polymer quality in sample) of 1000mg/L, by adding HCl, the pH value of regulator solution is 2, at upper its nocuity to rock core of testing of American core company formation injury tester (FDS-800), result is as shown in table 6.
Table 6
Figure BDA00002322952500242
As can be seen from the above table, acrylamide copolymer p 1-P6 prepared by two kinds of methods provided by the invention is starkly lower than the conventional comparative sample of cooking flow improver in site operation to the injury of rock core, and this explanation is to use P1-P6 low to the injury on stratum as shale gas pressure break flow improver.
The explanation of above-mentioned test result, acrylamide based copolymer provided by the invention has good water-soluble, low to the injury on stratum; And can be dissolved in completely in water-alcohol solution, good with the compatibleness of alcohol; Owing to improving with the compatibleness of alcohol and clay inhibitor (NaCl or KCl), make the moisture in pressure break water be difficult for running off, improve anti-filtration property; And still there is high drag reducing efficiency under high salt, wider pH value condition; There is degradability, be less than 2.5 o'clock degradables in pH value, low to the injury on stratum.In addition, the preparation method of acrylamide based copolymer provided by the invention has advantages of easy and monomer conversion is high.

Claims (18)

1. an acrylamide based copolymer, it is characterized in that, described acrylamide based copolymer contains structural unit A, structural unit B, structural unit C and structural unit D, wherein, described structural unit A is the structural unit shown in the structural unit shown in formula (1) and/or formula (2), described structural unit B is formula (3), formula (4), one or more in structural unit shown in formula (5) and formula (6), described structural unit C is the structural unit shown in formula (7) and/or has the structural unit shown in formula (8), described structural unit D is the structural unit shown in the structural unit shown in formula (9) and/or formula (10), and take the total mole number of structural unit in described acrylamide based copolymer as benchmark, the content of described structural unit A is 5-95 % by mole, the content of described structural unit B is 2.5-90 % by mole, the content of described structural unit C is 0.5-90 % by mole, and the content of described structural unit D is 0.0001-1 % by mole, preferably, the content of described structural unit A is 10-70 % by mole, and the content of described structural unit B is 5-60 % by mole, and the content of described structural unit C is 5-30 % by mole, and the content of described structural unit D is 0.001-0.5 % by mole, the viscosity-average molecular weight of described acrylamide based copolymer is 2,000,000-2,500 ten thousand, is preferably 4,000,000-1,500 ten thousand,
Figure FDA00002322952400011
formula (1),
Figure FDA00002322952400012
formula (2),
Figure FDA00002322952400013
formula (3),
Figure FDA00002322952400014
formula (4),
Figure FDA00002322952400015
formula (5),
Figure FDA00002322952400016
formula (6),
Figure FDA00002322952400017
formula (7),
Figure FDA00002322952400018
formula (8),
Figure FDA00002322952400021
formula (9),
Figure FDA00002322952400022
formula (10),
Wherein, R 1, R 1', R 4and R 4' be the alkylidene group of C1-C4 independently of one another; R 2, R 3, R 5, R 6, R 7, R 12, R 13, R 2', R 3', R 5', R 6', R 7', R 12' and R 13' be the alkyl of C1-C4 independently of one another; R 8and R 9be the straight or branched alkyl of H, C1-C20 independently of one another, and R 8and R 9when different, be H; R 8' be the straight chain branched-chain alkyl of C1-C20; R 10, R 11, R 10' and R 11' be the straight or branched alkylidene group of C1-C20 independently of one another; M is at least one in H, K and Na; X-is Cl -, Br -, I -, SCN-,
Figure FDA00002322952400023
or
Figure FDA00002322952400024
2. acrylamide based copolymer according to claim 1, wherein, described structural unit B is one or more in the structural unit shown in formula (11), formula (12) and formula (13), described structural unit C is one or more in the structural unit shown in formula (14), formula (15), formula (16) and formula (17), described structural unit D is for having the structural unit shown in formula (18)
formula (11),
Figure FDA00002322952400026
formula (12),
Figure FDA00002322952400027
formula (13),
formula (14),
Figure FDA00002322952400029
formula (15),
Figure FDA000023229524000210
formula (16),
Figure FDA00002322952400031
formula (17),
Figure FDA00002322952400032
formula (18),
Wherein, R 1, R 4and R 4' be the alkylidene group of C1-C4 independently of one another; R 10' and R 11' be the straight or branched alkylidene group of C1-C20.
3. the preparation method of an acrylamide based copolymer, this preparation method comprises, under the solution polymerization condition of alkene, under initiator exists, make a kind of monomer mixture in water, carry out polyreaction, it is characterized in that, described monomer mixture contains monomer E, monomer F, monomer G and monomer H, described monomer E is the monomer shown in the monomer shown in formula (19) and/or formula (20), described monomer F is formula (21), formula (22), one or more in monomer shown in formula (23) and formula (24), described monomer G is the monomer shown in the monomer shown in formula (25) and/or formula (26), described monomer H is the monomer shown in the monomer shown in formula (27) and/or formula (28),
Figure FDA00002322952400033
formula (19),
Figure FDA00002322952400034
formula (20),
Figure FDA00002322952400035
formula (21),
Figure FDA00002322952400036
formula (22), formula (23), formula (24),
Figure FDA00002322952400041
formula (25),
Figure FDA00002322952400042
formula (26),
Figure FDA00002322952400043
formula (27),
Figure FDA00002322952400044
formula (28),
Wherein, R 1, R 1', R 4and R 4' be the alkylidene group of C1-C4 independently of one another; R 2, R 3, R 5, R 6, R 7, R 12, R 13, R 2', R 3', R 5', R 6', R 7', R 12' and R 13' be the alkyl of C1-C4 independently of one another; R 8and R 9be the straight or branched alkyl of H, C1-C20 independently of one another, and R 8and R 9when different, be H; R 8' be the straight or branched alkyl of C1-C20; R 10, R 11, R 10' and R 11' be the straight or branched alkylidene group of C1-C20 independently of one another; M is at least one in H, K and Na; X -for Cl -, Br -, I -, SCN -,
Figure FDA00002322952400045
or
Figure FDA00002322952400046
4. the preparation method of an acrylamide based copolymer, this preparation method comprises water and oil phase is mixed to form to reversed-phase emulsion, then under emulsion polymerization condition, this reversed-phase emulsion is contacted with initiator, described water is the aqueous solution that contains monomer mixture, described oil phase contains oil and emulsifying agent, the condition of contact makes monomer mixture polymerization reaction take place, wherein, described monomer mixture contains monomer E, monomer F, monomer G and monomer H, described monomer E has the monomer shown in the monomer shown in formula (19) and/or formula (20) described in claim 3, described monomer F is formula described in claim 3 (21), formula (22), one or more in monomer shown in formula (23) and formula (24), described monomer G is the monomer shown in the monomer shown in formula described in claim 3 (25) and/or formula (26), described monomer H is the monomer shown in the monomer shown in formula described in claim 3 (27) and/or formula (28).
5. preparation method according to claim 4, wherein, the weight ratio of described water and oil phase is 1:0.1-2, is preferably 1:0.2-0.8.
6. preparation method according to claim 4, wherein, take the gross weight of described emulsion as benchmark, the consumption of described oil is 10-60 % by weight, and the consumption of described emulsifying agent is 1-10 % by weight, preferably, the consumption of described oil is 15-35 % by weight, and the consumption of described emulsifying agent is 2-9 % by weight.
7. preparation method according to claim 4, wherein, the method contacts described polyreaction products therefrom after being also included in described polyreaction with phase inversion agent.
8. preparation method according to claim 7, wherein, take the gross weight of described emulsion as benchmark, the consumption of described phase inversion agent is 0.5-10 % by weight, is preferably 1-5 % by weight.
9. according to the preparation method described in claim 3 or 4, wherein, take the total mole number of monomer in described monomer mixture as benchmark, the content of described monomer E is 5-95 % by mole, the content of described monomer F is 2.5-90 % by mole, the content of described monomer G is 0.5-90 % by mole, and the content of described monomer H is 0.0001-1 % by mole; Preferably, the content of described monomer E is 10-70 % by mole, and the content of described monomer F is 5-60 % by mole, and the content of described monomer G is 5-30 % by mole, and the content of described monomer H is 0.001-0.5 % by mole; It is 2,000,000-2,500 ten thousand that the condition of described polyreaction makes the viscosity-average molecular weight of resulting polymers after polyreaction, is preferably 4,000,000-15,000,000.
10. according to the preparation method described in claim 3 or 4, wherein, described monomer F is one or more in the monomer shown in formula (29), formula (30) and formula (31), described monomer G is one or more in the monomer shown in formula (32), formula (33), formula (34) and formula (35), described monomer H is the monomer shown in formula (36)
Figure FDA00002322952400051
formula (29),
Figure FDA00002322952400052
formula (30),
Figure FDA00002322952400053
formula (31),
formula (32), formula (33),
Figure FDA00002322952400056
formula (34),
Figure FDA00002322952400057
formula (35),
Figure FDA00002322952400058
formula (36),
Wherein, R 1, R 4and R 4' be the alkylidene group of C1-C4 independently of one another; R 10' and R 11' be the straight or branched alkylidene group of C1-C20.
11. according to the preparation method described in claim 3 or 4, and wherein, the ratio of the gross weight of the weight of described monomer mixture and water and monomer mixture is 0.05-0.5:1, is preferably 0.15-0.4:1.
12. according to the preparation method described in claim 3 or 4, wherein, described initiator is selected from azo series initiators and redox series initiators, take the total mole number of monomer in described monomer mixture as benchmark, the consumption of described azo series initiators is 0-10 % by mole, the consumption of described redox series initiators is 0-10 % by mole, and total consumption of described initiator is 0.0001-10 % by mole; Described azo series initiators is selected from Diisopropyl azodicarboxylate, 2,2'-Azobis(2,4-dimethylvaleronitrile), the two methylpent hydrochlorates, 2 of azo, 2 '-azo diisobutyl amidine hydrochloride and 2, at least one in 2 '-azo two [2-(2-tetrahydroglyoxaline-2-propane)-dihydrochloride], described redox series initiators comprises Oxidizing and Reducing Agents, the mol ratio 0.5-2:1 of described oxygenant and described reductive agent, described oxygenant is selected from least one in ammonium persulphate, Potassium Persulphate, Sodium Persulfate and hydrogen peroxide; Described reductive agent is inorganic reducing agent, and described inorganic reducing agent is selected from least one in sodium bisulfite, S-WAT, rongalite, Sulfothiorine, ferrous sulfate, vat powder, xitix and urea.
13. according to the preparation method described in claim 3 or 4, and wherein, described polyreaction is carried out under auxiliary agent exists, and described auxiliary agent is selected from least one in sequestrant and other auxiliary agents; Take the total mole number of described monomer mixture as benchmark, the consumption of described sequestrant is 0-2 % by mole, the consumption of described other auxiliary agents is 0-2 % by mole, and take the total mole number of monomer in described monomer mixture as benchmark, total consumption of described auxiliary agent is 0.0001-4 % by mole; Described sequestrant is selected from least one in disodium ethylene diamine tetraacetate, Triethylene Diamine pentaacetic acid, citric acid, Citrate trianion and poly-hydroxyl acrylic, and described other auxiliary agents are selected from least one in urea, sodium formiate, Virahol and sodium hypophosphite.
14. according to the preparation method described in any one in claim 3-13, and wherein, described polyreaction is carried out under rare gas element exists, and described polymeric reaction condition comprises: temperature is 0-80 ℃, and the time is 1-24 hour, and pH value is 5-13.
15. preparation methods according to claim 3, wherein, described polyreaction comprises the three phases carrying out successively, and the reaction conditions of first stage comprises: temperature is 0-10 ℃, and the time is 1-15 hour; The reaction conditions of subordinate phase comprises: temperature is 15-30 ℃, and the time is 3-8 hour; The reaction conditions of phase III comprises: temperature is 35-60 ℃, and the time is 2-14 hour.
16. preparation methods according to claim 4, wherein, described polyreaction comprises two stages of carrying out successively, and the reaction conditions of first stage comprises: temperature is 0-20 ℃, and the time is 1-15 hour; The reaction conditions of subordinate phase comprises: temperature is 20-60 ℃, and the time is 2-8 hour.
The 17. acrylamide based copolymers that make according to the preparation method described in any one in claim 3-16.
The application of acrylamide based copolymer in 18. claim 1-2 and 17 described in any one in flow improver.
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