JPS61207790A - Excavation of geothermal production well - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for drilling a geothermal production well for effectively producing and utilizing geothermal heat.

[Conventional technology]

Fig. 3 is a diagram for explaining a general method of drilling a production well, in which 11 is a mud water pump, 12 is a stand pipe, 1
3 is rotary hose, 14 is swivel, 15 is kelly, 16 is drill pipe, 17 is drill collar, 1
8 is a bit, 19 is a petit gutter, 20 is a mud screen, 21 is a saxilan tank, 22 is a rotary table, and 23 is a cellar.

In drilling a production well by mud drilling, first, the drill collar 17 and the kelly 15 are connected to the bit 18, the drill collar 17 and the kelly 15 are lowered, and drilling is started from the bottom of the cellar 23. Drilling is performed by gradually applying the weight of the drill collar 17 to the bit 18 while rotating the rotary table 22 and rotating the focus 18 through the kelly 15. At the same time, on the other hand, the mud pump 11 is operated from the sacsidine tank 2.
It is sucked in from 1 and pumped through the ground vibrator to stand pipe 12, rotary hose 13, and swivel 1.
4, Kelly 15, and is injected from the nozzle of the bit 18 through the inside of the drill collar 17. And this muddy water
The cuttings (cuttings) cut by the blade of the bit 18 rise between the outside of the drill pipe 16 and the mine wall (annulus), pass from the vertical pipe and the horizontal conduit, pass through the putsch gutter 19, and enter the mud screen 20. The cutting is removed and returned to the suction tank 21. This creates a continuous circulation system between the muddy surface and the inside and outside of the mine.

In addition, when drilling with fresh water, fresh water is circulated instead of muddy water.

When excavation is carried out to a predetermined depth as described above, the excavation is stopped and muddy water continues to circulate for a while to bring up the cuffing contained in the muddy water inside the mine to the surface of the ground.Afterwards, when the inside of the mine is clean, the pipe is lifted. . The casing is then lowered and cemented.

[Problem that the invention seeks to solve]

In the conventional drilling of production wells mentioned above, small heat sources are overlooked due to mud drilling, small heat sources in the fracture zone or empty wells are crushed and unused, and the entire length of each casing stage is drilled. Casing insertion and cementing cannot be performed until the pipe is pulled up. As a result, there were problems such as excavation being constrained by planned casing programs and the overall effective use of geothermal energy not being achieved.

The present invention aims to solve the above-mentioned problems, and aims to provide a method for drilling a geothermal production well that can retain all the heat sources in the fracture zone and use them effectively for production. be.

Means for Solving Problem C] Therefore, the geothermal production well drilling method of the present invention is a geothermal production well drilling method for drilling a well for effective production and utilization of geothermal energy. Detect the fracture zone while excavating with a diameter larger than the casing pipe, create a step in each fracture zone, and insert smaller diameter casing pipes one after another to excavate to a predetermined depth, and after excavation, detect the thermal energy in each fracture zone. It is characterized by analyzing.

[Effect]

In the method of drilling a geothermal production well of the present invention, a hole expansion bit is used to drill with a diameter larger than the casing pipe, so the well wall is not collapsed, and in each fracture zone, a step is created and the small diameter casing pipe is sequentially drilled. Since it is inserted, all the heat sources of the fracture zone can be retained.

Therefore, while searching for the target heat source, it is possible to consider how to utilize all the heat sources in the fracture zone along the way, and to link the most effective form of utilization as a production well.

〔Example〕

Examples will be described below with reference to the drawings.

FIG. 1 is a diagram for explaining the method for drilling a geothermal production well according to the present invention, and FIG. 2 is a diagram showing a hole expansion bit used in the method for drilling a geothermal production well according to the present invention. In the figure, 1 is a casing pipe, 2 is a small diameter casing pipe, 3 is a drill pipe, 4 is a drill collar, 5 is a hole expansion bit, 6 is a fracture zone, -, 9 is a bit, and 10 is a threaded part are shown respectively.

In FIG. 1, a hole expansion bit 5 is used to perform excavation with a diameter larger than that of the casing pipe 1.

In the method for drilling a shallow geothermal production well of the present invention, the well expansion bit 5 is used to prevent the wall of the well from collapsing, and the casing pipe 1 is inserted immediately after drilling to protect the well. When it comes into contact with the crushing zone 6, the casing pipe is switched to one with a smaller diameter to provide a step and the excavation continues w1. In other words, in the past, the fracture zone 6 was crushed by continuing to excavate to the initially targeted heat source or heat source depth, but in the present invention, the fracture zone 6 is protected by the casing pipe 1 to prevent it from being crushed. Continue excavation, inserting perforated tubes as casing pipes if necessary. In this way, excavation proceeds to the initially targeted heat source or heat source depth, and then, by analyzing the form and capacity of energy in each fracture zone, the most effective form of utilization is pursued.

FIG. 2 shows a specific example of the drilling bit 5 used in the present invention. The hole expansion bit 5 has a protruding blade 8 in addition to a general bit 9, as shown in FIG. - It has a structure in which the collar 4 and the bit 9 are screwed together with threaded portions 10, respectively.

Then, as shown in the AA' cross section in FIG. 2(b), the excavation is performed by protruding by rotating in the direction of arrow F, and the excavation is performed by rotating in the direction of arrow R.

〔Effect of the invention〕

As is clear from the above description, according to the present invention, all the heat sources of the drilled production well can be comprehensively utilized. In other words, in geothermal power generation, it is possible to determine power generation capacity by comprehensively utilizing all of these heat sources. In addition, by using a hole expansion bit, casing and cementing can be performed at any depth without being restricted by planned casing programs, and furthermore, it is possible to perform excavation deeper than the casing and with the same diameter as the upper part, making it possible to perform geothermal It is possible to improve energy productivity.

[Brief explanation of drawings]

Fig. 1 is a diagram for explaining the method for drilling a geothermal production well according to the present invention, Fig. 2 is a diagram showing a hole expansion bit used in the method for drilling a geothermal production well according to the present invention, and Fig. 3 is a diagram for explaining the drilling method for a geothermal production well according to the present invention. FIG. 2 is a diagram for explaining a method of drilling a production well. 1...Casing pipe, 2...Small diameter casing pipe, 3...Drill pipe, 4...Drill
Collar, 5... Hole expansion bit, 6... Fracture zone, 7...
- Stratum, 8... Protruding blade, 8-1... Protruding blade support collar, 9... Bit, 10... Thread part, 11... Mud water pump, 12... Stand pipe, 13. ... Rotary hose, 14 ... Swivel, 15 ... Kelly, 16 ... Drill pipe, 17 ... Drill collar, 18 ... Bit, 19 ... Petit gutter, 20 ...
...Mud Screen, 21...Saxicon Tank, 22...Rotary Table, 23...Cellar. Patent applicant Ryukichi Abe, patent attorney representing Shimizu Corporation Figure 2 (a)

Claims (2)

[Claims] (1) A geothermal production well drilling method for drilling wells for effective production use of geothermal energy, in which fracture zones are detected while drilling with a diameter larger than the casing pipe using a well-expansion bit. A method for drilling a geothermal production well, which is characterized by creating steps in a fracture zone and sequentially inserting small-diameter casing pipes to excavate to a predetermined depth, and analyzing the thermal energy in each fracture zone after drilling. (2) The well-expanding bit is characterized by having a support collar provided at the rear of the bit that is provided with a protruding blade that protrudes when rotated in one direction and is retracted when rotated in the opposite direction. Method of drilling geothermal production wells as described.