Polyacrylamide and its derivatives for oil recovery

46 
Their results showed that the phenol and formaldehyde gelation system can withstand 
temperature as high as 120°C. In slim-tube experiments (Slim tube tests are performed to 
observe actual solvent-oil interaction in a physical simulation of reservoir pore space.), 
these gelants possessed excellent injectivity under 140°C. Slim tube tests are performed 
to observe actual solvent-oil interaction in a physical simulation of reservoir pore 
space.[263] Hutchins et al.[258] also showed the phenol-formaldehyde cross-linked 
gelling system could remain stable in oxygen-free seawater at 150°C (300°F) for 12 
months and 177°C (350°F) for five months. With a goal of longer delay time for gelation 
to prevent gelation before the reactants have reached the elevated temperature target 
zones, Huchins et al.[258] reported an organic crosslinking system comprising HPAM 
and a crosslinking combination of hydroquinone (HQ) and hexamethylenetetramine 
(HMTA). The gel was stable for 12 months at 149°C (300°F) and 5 months at 177 °C 
(350°F).
Dovan, et al.[264] described another crosslinking system that can be applied at 
higher temperatures featuring new cross-linkers, HMTA, terephthaldehyde, terephthalic 
acid, and glutaric acid as primary cross-linkers and HQ, dihydroxynaphthalene, and gallic 
acid as secondary cross-linkers. The primary cross-linkers were chemical compounds that 
can form unstable gel networks with HAPAM polymer (Hydrophobically Associative 
Polyacrylamide), while the secondary cross-linkers could stabilize the gels formed by the 
primary cross-linkers at high temperature. This system has a gelation time of several days 
at 168°C, but has not yet been tested in a field application. Due to environmental 
concerns, the use of HQ and formaldehyde are discouraged.

47 
Polyethyleneimine (PEI) was also an organic cross-linker utilized to make 
thermally stable PAM copolymer gels.[245, 265] Morgan, et al.[266] reported a gel 
system based on acrylamide/t-butyl acrylate copolymer (PAtBA) cross-linked with PEI. 
The PEI crosslinking system was shown capable of propagating eight times farther than 
chromium-based systems under equivalent conditions because the crosslinking reaction is 
dependent on a nucleophillic attack by amine nitrogen from PEI at the carbonyl carbons 
of the t-butyl acrylate. Unlike many metal-based ionomer cross-linkers, PEI is not 
susceptible to hydrolysis.[245] Al-Muntasheri, et al.[267, 268] performed a series 
experiments to test PEI/PAM-AtBA gels under high temperature and pressure. The 
reaction mechanism is showed in Figure 11. They first reported the possibility of 
crosslinking PAM with PEI at temperatures up to 140°C (285°F) and pressures up to 30 
bar (435psi). In bulk, the gels were stable up to130°C (194°F) for at least 8 weeks. At the 
same temperature but 69 bar (1000psi) pressure, the PEI gel was stable for 3 weeks. The 
PEI/PAM-AtBA copolymer crosslinking system has also been proven successful in 
controlling water production over a temperature range from 27 to 177°C (80°F to 
350°F).[265] 
NRR'
NR
NRR'
n
C
H
2
C
NH
2
O
PAM chain
PAM chain
NR
NR
O
O
n
NR
NR
O
O
n
+
+
2R'NH
2

Download 4,02 Mb.

Do'stlaringiz bilan baham: