Being controlled by the gas content of the reservoir, the productivity of CBM well is also mainly determined by its engineering quality and the physical property of the reservoir. In Dafosi mine field, 22 vertical wells from the “26 + 1” CBM wells project that was implemented since 2014 showed great difference in productivity after fracturing construction. With the consistent geological condition of coal reservoirs, fracturing construction parameters are suggested as the priority factor that controlling the well productivity. In this study, being combined with historical production and geological data, an optimized designation of fracturing construction parameters was established based on systematically comparative analysis of construction parameters such as discharge, the total volume of fracturing fluid, the quality of sand, sand ratio, which provides engineering basis for further fracturing construction of CBM wells.
The coalbed methane (CBM) resource is rich in China, but its exploration and development are relatively late. At present, the commercial development of CBM has been realized in high-rank coal areas of southern Qinshui basin and eastern Ordos basin [
Dafosi mine field is one of the state-owned key coal mines and located in the south of Binchang mining area of Jurassic in Shaanxi. The absolute and the relative gas emission are up to 155.49 and 23.40 m3/min respectively, which belong to high gas mine. Dafosi wells were taken underground drainage measures to prevent gas accident, and the gas drainage volume accounts for about 70% of the total gas emissions. It shows that high rate of gas extraction and the drainage effect are better. In order to further improve gas control effect and realize the effective utilization of CBM, the surface CBM development test has been carried out in Dafosi since 2009. The drainage data of several test wells shows that the low-rank coal in Dafosi mine field has better potential in gas production [
Fracturing construction is one of the most effective reservoir stimulation methods, of which hydraulic fracturing was most widely used [
Presently, all the 24 vertical wells (including 22 wells in “26 + 1” project and BCD-C-01, BCD-45) had obtained gas flow with hydraulic fracturing (
Hydraulic fracturing is one kind of fracturing construction methods that inject the fracturing fluid into wells by the high pressure introduced by ground equipment. The pressure would expand the fissures in coalbed. Then add the fracturing
No. | Well | Production Q/m3 | No. | Well | Production Q/m3 |
---|---|---|---|---|---|
1 | BCD-C01 | 3,233,752.49 | 13 | BCD-120 | 61,687.40 |
2 | BCD-45 | 463,556.84 | 14 | BCD-122 | 204,892.23 |
3 | BCD-62 | 3468.69 | 15 | BCD-128 | 636,225.46 |
4 | BCD-67 | 35,713.70 | 16 | BCD-131 | 465,635.11 |
5 | BCD-69 | 157,953.03 | 17 | BCD-132 | 539,127.94 |
6 | BCD-71 | 169,115.2 | 18 | BCD-133 | 1,643,606.58 |
7 | BCD-73 | 302,928.08 | 19 | BCD-134 | 1,300,276.17 |
8 | BCD-74 | 184,512.43 | 20 | BCD-135 | 265,586.12 |
9 | BCD-84 | 147,029.32 | 21 | BCD-148 | 796,871.34 |
10 | BCD-86 | 79,525.89 | 22 | BCD-150 | 162,326.95 |
11 | BCD-105 | 215,913.33 | 23 | BCD-151 | 393.20 |
12 | BCD-117 | 257.56 | 24 | BCD-153 | 4573.20 |
The data ended February 19, 2017.
propping agent, a seepage zone would be formed which connect the cracks in coalbed. Finally, the coalbed methane would desorb and exhaust via drainage and decompression.
Currently, Reactive water fracturing fluid, foam fracturing fluid, gelled fracturing fluid and clean fracturing fluid are the most commonly fracturing fluid used in CBM wells (
The loading strength and cost were the basic principles to choose propping agents. Since the closure pressure in coalbed of Dafosi mine was lower than 10 MPa, most of the propping agents could cover the requirements. In Dafosi mine, the quartz sand, with a compression strength of single particle 60 - 70 MPa, was taken as fracturing propping agents in all coalbed from the perspective of reducing cost and facilitating reactive water fracturing fluid transporting. The physicochemical property was shown in
Types | Sand carrying ability | Fracture making ability | Damaging | Cost | Confection |
---|---|---|---|---|---|
Reactive water fracturing fluid | Weak low viscosity, transport propping agent relay on the displacement, usually short transport distance | Weak low viscosity, limited transformation scale; the vertical extension of fissures are difficult to control | Low | Low | East to confect and not limited by temperature |
Gelled fracturing fluid | Strong transport propping agent relaying on viscosity and displacement, long transport distance | Strong high viscosity, the displacement, transformation scale and vertical extension of fissures are easy to control | High | High | Complex and high quality requirements |
Clean fracturing fluid | Strong transport propping agent relaying on the viscosity and displacement, long transport distance | Strong high viscosity, the displacement, transformation scale and vertical extension of fissures are easy to control | Medium | High | High quality requirements and limited by temperature |
Foam fracturing fluid | Strong transport propping agent relaying on the viscosity and displacement, long transport distance | Strong high viscosity, the displacement, transformation scale and vertical extension of fissures are easy to control | Low | High | Easy to confect, complicated construction procedure |
Main mineral component | Apparent density g/cm3 | Density g/cm3 | Crushing rate 30 MPa | Turbidity |
---|---|---|---|---|
SiO2 | 1.60 | 2.67 | 13.8% | 77.6 |
Plenty of natural cleavage system in coal seam made the CBM wells fracturing construction quite different from that in oil well. The prominent features were the giant loss low-efficiency of fracturing fluid. In order to increase efficiency, the fracturing construction displacement should be large enough. Thus, casing pipe with large construction displacement was adopted in Dafosi mine. The construction displacement in CBM wells was between 5 m3/min and 9 m3/min with most of them with the displacement 8 - 9 m3/min.
Considering that the coal seams in study area was in large thickness, shallow burial depth and good permeability, the fracturing quality of sand was adopted as the following: the quality of sand was set 7 m3/m for the target coal seam thickness more than 12 meters, 8 m3/m for thickness between 10 and 12 m, 9 m3/m for thickness between 8 and 10 m and 10 m3/m for thickness less than 8 m. It is worth mentioning that the BCD-71 and BCD-135 was taken secondary fracturing due to the rough appeared in the first fracturing construction. Finally, all the wells finished the designed sand fracturing except BCD-71, BCD-74 and BCD-84. According to the construction data, the averaged sand ratio was kept in 10% to 13%.
According to the fracturing construction data of 24 vertical wells for 27 coalbeds in Dafosi mine field, generally, the normal fracturing pressure was lower than 20 MPa, and Shut-in pressure was lower than 15 MPa. 1 h after the termination of pumping, the wellhead pressure in CBM wells decreased directly to zero or sharply to zero in several hours, which indicated a high permeability in coal seams in study area and favorable conditions for the diffusion and migration for CBM. However, the high permeability would enhance the loss in fracturing fluid and show negative effects on fracturing construction. Therefore, 1 or 2 fine sand slugs were performed during preflush construction stage. The slugs would not only decrease the loss of fracturing fluid but also improve the efficiency of fissures making and sand carrying, and decrease the possibility of sand plugging during fracturing operation.
Generally, the fracturing construction effect was controlled by two categories: the coal reservoirs parameters and the fracturing construction parameters [
1) The influence of displacement to fracturing construction
The displacement of fracturing construction in CBM wells influence the sand carrying and geometrical morphology of fracturing fractures. Increasing the displacement would increase the fissure net pressure, therefore the geometrical morphology changes of fractures, especially the height of the fracture. Thus, it was possible to limit the fractures in fracturing layer if the displacement was controlled in a rational range.
Since 6 of those CBM wells was shut off before the stage of stable production, the average daily gas production and the average daily gas production in steady stage of the rest 18 CBM wells were statistically analyzed in this study. The result showed that the displacement was between 8 and 8.5 m3/min for those wells with high average daily gas production values (
2) The influence of fracturing scale to fracturing construction
The fractures were the main channels of drainage and gas migration. Enlarging the fracturing scale meant the increased substance was brought into the coal seam, which would intensify spatial extension of fractures in length, width and height, especially in length direction. Generally, the fracturing effect was in proportion to fracturing scale. However, if the fracturing scale was too large, the fractures would extend to roof and floor of coal seam and link to the aquifer, which was negative for drainage and gas production. Moreover, the excessive
fracturing scale would destroy the coal seam structure and decrease the permeability of coal seam. Thus, the total volume of fracturing fluid and the quality of sand were critical for fracturing construction.
In the early fracturing stage, the quality of sand was relevant to the coal seam thickness. In this study, 12 m was taken as the critical thickness to discuss the relationship of the quality of sand and the gas production. The statistical relationship of the quality of sand VS the average daily gas production or the average daily gas production in steady stage, and the total volume of fracturing fluid VS the average daily gas production or the average daily gas production in steady stage were shown in
3) The influence of sand ratio to fracturing construction
There was a positive correlation between the sand ratio to the concentration of propping agent in fractures and the fracture conductivity. Since the Young’s modulus of the coal seam was low, in practice, the embedded propping agent would decrease the fracture width. Thus, increasing the sand ratio would harmful to the migration of carrying fluid. Even worse, the propping agent might plug and form a sand dune in fractures which would seriously influence the fracturing construction. Thus, the sand ratio and the choice of propping agent should be considered comprehensively.
The correlations of sand ratio, the ratio of used medium sand propping agent/coarse sand propping agent and the average daily gas production, the
average daily gas production in steady stage were presented in
Based on the relationship between the fracturing parameters and their influence on fracturing construction, an optimization design of fracturing parameters of CBM vertical wells in Dafosi mine field was proposed as following:
1) Fracturing fluid and propping agent
Clay minerals were widely distributed in Dafosi mine field. It was important to consider the damage of coal reservoirs brought by the expansion of clay minerals with the invasion of fracturing fluid during fracturing construction. The addition of KCl in fracturing fluid could not only prevent the expansion of clay minerals, but also increase the contact angle of coalbed and fracturing fluid. It was beneficial for the drainage of fracturing fluid. Moreover, the addition of KCl showed universal and positive effect to different coal rank reservoirs. Balance the costs and effects, the active water with 1% KCl and 0.05% fungicide was suggested as the fracturing fluid.
In Dafosi mine field, the closure pressure of coalbed was low, and so was the loading strength of propping agent. From the points of reducing costs and convenient for the transportation of fracturing fluid, the economical quartz sand was suggested as the propping agent, since its strength could meet the requirements of fracturing construction.
2) Displacement
Based on former statistics, the displacement of high average daily gas production CBM wells in the Dafosi mine field was among 8 to 9 m3/min. In the real
construction process, the sand plugging occurred frequently. To improve the efficiency and fracturing effect, the displacement was set at 8 - 10 m3/min. In the study area, the coal seam was characterized by high permeability, induced great loss in fracturing field. Therefore, 1 - 2 fine sand plugs were added during preflush stage to reduce the loss and improve the efficiency of fracturing and sand carrying.
3) The total volume of fluid
The total volume of fluid included the volume of preflush fluid, the sand carrying fluid and displacement fluid. According to the construction data and the fracturing results, the construction effect was better when the displacement was between 950 and 1100 m3. Generally, the volume of preflush fluid accounted for 25% - 40% of the total volume of fluid. The volume of sand carrying fluid was determined by the quality of sand and the sand ratio. The displacement fluid was used to squash the residual sand carrying fluid in the wellbore into the stratum fractures. The volume of the displacement fluid could be calculated from the structure of the inlet pipe of the wellbore. In this study, the value was 6 - 7 m3.
4) The quality of sand and sand ratio
Based on the analyzed fracturing construction data above and considering the thickness and high permeability in No.4 coalbed in Dafosi mine field, the quality of sand was designed as following. If the coalbed was thicker than 12 m, the quality of sand was set 5 - 7 m3/m; otherwise, the value was set 8 - 9 m3/m. The coal seam was thicker in Dafosi mine field and was difficult to fracturing. In this study, the sand ratio was suggested between 10% - 11%, and the medium/coarse sand ratio in propping agents was set at 2 - 3.
1) In the 24 vertical CBM wells that performed fracturing construction in Dafosi mine field, most of them are increasing in production, and part of them showed good potential.
2) The main fracturing parameters that influenced the gas production of CBM wells in Dafosi mine wells included displacement, the total volume of fracturing fluid, the quality of sand, sand ratio and the volume of propping agent.
3) Based on statistical analysis of fracturing construction parameters, an optimization design of fracturing parameters was proposed as follows: the displacement was suggested to be 8 - 10 m3/min; 1 or 2 fine sand plugs were added in preflush stage; the total volume of fracturing fluid was set between 950 and 1100 m3 (with 25% - 40% preflush fluid); the quality of sand was suggested to be 5 - 7 m3/m when coal seam thickness excesses 12 m or 8 - 9 m3/m when coal seam thickness was less than 12 m; the medium/coarse sand ratio in propping agents was set 2 - 3.
Wang, C.T., Ma, D.M., He, Q., Li, Q. and Liu, P.C. (2017) Optimization Design of Fracturing Parameters for Coalbed Methane Wells in Dafosi Mine Field. Journal of Power and Energy Engineering, 5, 121-131. https://doi.org/10.4236/jpee.2017.59010