Surfactant-grafted Polyacrylamide (S-PAM), as a new type of oil displacement agent in oilfield, integrates the advantages of both polymer and surfactant. The oil displacement experiments using S-PAM in multi-blocks reveal that in-use S-PAMs differ greatly from ordinary polymers and the physical properties remain unclear. This is unfavorable to production application and occupational health and safety. This research compared the physical properties of S-PAMs selected from two producing area, including specific gravity, particle size and viscosity. The compared results showed that specific gravity of Lianhua S-PAM was smaller than Haibo S-PAM; Lianhua S-PAM and Haibo S-PAM accounted for the 93.8% and 80.1% of the total amount via the particles with 40 mesh and 60 mesh; the viscosity of Lianhua S-PAM was higher than that of Haibo S-PAM in two S-PAM solutions with different concentrations.
Polymer flooding is a tertiary oil recovery technique which was developed in 1960s. It is able to highly improve the recovery factor and a more economical and efficient monadic chemical flooding [
In oil exploitation, water-soluble polymer surfactant is usually adopted to improve recovery factor. However, ordinary polymer surfactants are restricted by their poor temperature resistance and salt resistance in deep oil reservoir, high temperature in oil well and high salinity in tertiary oil recovery. This research proposed the surfactant-grafted polyacrylamides. In water soluble process, the association of hydrophobic segment was found. On the condition of high temperature and high salinity, due to the association, the S-PAM solution leads to that viscosity increases with the increasing concentration of electrolyte and rising temperature [
This study analyzed the physical properties of Lianhua S-PAM and Haibo S-PAM comparatively using chemical analysis method and instrument analysis method etc.
Two S-PAMs used in this experiment were: Daqing Refining & Chemical Company S-PAM (Lianhua type III), which is called Lianhua S-PAM in the research; Shanghai Haibo company S-PAM (Haibo type III), which is called Haibo S-PAM; the instrument used in the experiment was Brookfield viscometer LVDV-II.
The specific gravity is also called relative density, namely, density ratio. It is a ratio of determining substances’ density to the density of water without unit. The experiment employed the bulk density of S-PAM solid particles. With water density of 1000 kg/m3, based on the definition of specific gravity (specific = density/1000 kg/m3), the specific gravity of two S-PAMs can be obtained. The surfactants A and B were conducted five groups of tests, by taking average value, the specific gravity of two surfactants were acquired.
In this experiment, a sieving method was used to determine the particle size of two S-PAMs as follows:
1) A set of screens were selected and put on the oscillator according to the sizes of meshes from up to bottom.
2) The S-PAM sample of 100 g was measured and poured on the upper sieving layer, by covering it using sieve cove and fixing the whole set of sieves, the oscillator was started up as starting the timer. The oscillation and screen were conducted for a certain period.
3) By stopping the oscillation and screen, taking off the sieving cap, each screen was taken off in turn. Afterwards, the masses of each screen were measured and compared with that of empty screen. To reduce errors, each sample was conducted two tests.
Brookfield viscometer LVDV-II was used to measure the viscosities of the fresh water prepared S-PAM solution of 1200 mg/L, the sewage prepared S-PAM solution of 1200 mg/L and the S-PAM mother solution of 3000 mg/L.
In solid state, the Lianhua S-PAM was white granular substance; while Haibo S-PAM was slightly light yellow granular substance. By putting S-PAM particles on the paper surface for a while, the oil like substance leached was found. In addition, Lianhua S-PAM showed viscosity S-PAM B in preparation of S-PAM solution with a certain concentration; in mixing process, Lianhua S-PAM is more likely to generate bubbles than that of Haibo.
Lianhua S-PAM and Haibo S-PAM were conducted five groups of test respectively. By employing the average, the specific gravities of two S-PAMs could be obtained; the experimental results are shown in
By calculating the average of the density ρ in
The water density is 1000 kg/m3, the specific gravity of two S-PAMs can be acquired based on the definition of specific gravity (specific = density/1000 kg/m3, unit: kg/m3) as
Particle size is defined as the size and distribution of solid particle. It denotes the percentage of particle mass in the mass of total samples with a range of particle size. The research employed a sieving method to measure the size of S-PAM particle. The principle of using sieving method to measure the particle size is described as:
The dimensions of particle and its distribution (particle size) were determined using a series of screens with varied mesh sizes. Then, the screens were well folded form up to bottom in turn according to the decreasing order of mesh diameters. The sample to be determined was poured from upper end. By covering the sieve, the whole set of screens were fixed to oscillate on the oscillator. The samples were screened using a series of screens, then collected from each screen. By measuring the mass of each screen before and after test, the mass of the material on the screen can be acquired. Taking the particle size as the percentage of the particle mass in a certain size range, the formula is as follows.
where D refers to the particle size of samples; m denotes the mass of sample (unit: g); m' is the mass of samples which fail to pass through the screen with some pore diameter (unit: g). The particle size distribution results are shown in
Brookfield viscometer LVDV-II was adopted to determine the viscosities of the fresh water prepared S-PAM solution of 1200 mg/L, the sewage prepared S-PAM solution of 1200 mg/L and the S-PAM mother solution of 3000 mg/L.
. The bulk density of Lianhua S-PAM.
V (mL) | 2.15 | 4.08 | 6.11 | 8.05 | 9.95 |
---|---|---|---|---|---|
m (g) | 1.3153 | 2.5202 | 3.9368 | 5.3063 | 6.5207 |
ρ (g/mL) | 0.612 | 0.618 | 0.644 | 0.659 | 0.655 |
. The bulk density of Haibo S-PAM.
V (mL) | 2.10 | 4.08 | 5.90 | 7.80 | 9.60 |
---|---|---|---|---|---|
m (g) | 1.3479 | 2.5704 | 3.9019 | 5.3056 | 6.6074 |
ρ (g/mL) | 0.642 | 0.630 | 0.661 | 0.680 | 0.688 |
. The densities of S-PAMs.
Density of Lianhua S-PAM (g/mL) | 0.6376 |
---|---|
Density of Haibo S-PAM (g/mL) | 0.6602 |
. The specific gravity of S-PAMs.
Specific gravity of Lianhua S-PAM | 0.6376 |
---|---|
Specific gravity of Haibo S-PAM | 0.6602 |
The field investigations showed that there were two dilution methods in the preparation of S-PAM solution: S-PAM mother solutions were transferred to single well after diluting by fresh water and sewage to a certain concentration respectively. The viscosities of the solutions diluted using two abovementioned methods were measured according to in situ temperature. The results are presented in
Viscosity results determined suggest that the viscosity of Lianhua S-PAM solution is higher than that of Haibo in terms of both S-PAM mother solution of 3000 mg/L and the mother solution prepared S-PAM solution of 1200 mg/L. In addition, the comparison of viscosities of S-PAM solutions prepared by fresh water at 15.3˚C and sewage at 45.5˚C reveals that preparation of S-PAM solution at higher temperature can greatly reduce the viscosity of solution.
On the basis the research results above mentioned, unlike traditional polymer, multi-constitutes S-PAM is a new oil displacement polymer which is formed by multi-constitutes graft copolymerization with flexible hydrocarbon chain as the frame based on interactions of molecules. Its structure is shown in
Where X, Y refer to --HZ, --ONa, --OR, --HR, --RSO3Na, --: the surfactants of quaternary ammonium salt, --(EO)n(PO)Mr, --: cationic Gemini, and -RSH. Lianhua S-PAM refining factory polymerized the nonionic and cationic surfactants, while that Haibo S-PAM polymerized the nonionic surfactants on the main chain of polyacrylamide. Moreover, the functional groups of the two S-PAM are different. Different surfactants copolymerized on the main chains of two S-PAMs lead to the varied f physical properties.
Comparative study of the physical properties of S-PAM implied that, specific gravity of Lianhua S-PAM was
. The particle size of Lianhua S-PAM.
Mesh number | 20 | 40 | 60 | 80 |
---|---|---|---|---|
Experiment 1 | 2.5 | 62.3 | 30.0 | 6.1 |
Experiment 2 | 2.2 | 63.6 | 31.6 | 2.8 |
Particle size | 2.4% | 63.0% | 30.8% | 4.5% |
. The particle size of Haibo S-PAM.
Mesh number | 20 | 40 | 60 | 80 |
---|---|---|---|---|
Experiment 1 | 19.8 | 54.5 | 25.4 | 0.7 |
Experiment 2 | 12.2 | 54.8 | 25.3 | 8.2 |
Particle size | 16.0% | 54.7% | 25.4% | 4.5% |
. Viscosity results determined of S-PAM solution.
Name | Concentration (mg/L) | Temperature (˚C) | The type of rotor | Rotating speed (RPM) | Viscosity (cP) |
---|---|---|---|---|---|
Fresh water prepared S-PAM (Lianhua) | 1200 | 15.3 | LV2 | 30 | 306.9 |
Fresh water prepared S-PAM (Haibo) | 1200 | 15.3 | LV2 | 30 | 158.0 |
Sewage prepared S-PAM ( Lianhua) | 1200 | 45.5 | LV1 | 30 | 30.8 |
Sewage prepared S-PAM (Haibo) | 1200 | 45.5 | LV1 | 60 | 19.3 |
S-PAM mother solution (Lianhua) | 3000 | 15.7 | LV3 | 6 | 3179 |
S-PAM mother solution (Haibo) | 3000 | 14.6 | LV3 | 6 | 2739 |
Molecular structure of S-PAM
smaller than Haibo S-PAM; Lianhua S-PAM and Haibo S-PAM accounted for the 93.8% and 80.1% of the total amount via the particles with 40 mesh and 60 mesh; the viscosity of Lianhua S-PAM was higher than that of Haibo S-PAM in two S-PAM solutions with different concentrations.