JPH06173567A - Regenerating method for old well and doughnut drill bit used for the method and cutter for existing casing pipe - Google Patents

Abstract

PURPOSE:To regenerate an old well by a method wherein the periphery of the casing pipe of the old well is dug down by a pressure muddy-water circula tion type doughnut drill bit, the casing pipe is cut in proper length and extracted, and a casing pipe is constructed in the same method as a new well. CONSTITUTION:A filled gravel layer 21 in the periphery of the casing pipe 6 of an old well and a part of a bedrock are dug down by a doughnut drill bit 1 conducting excavation by infecting pressure muddy water. The dug-up casing pipe 6 is cut in proper length by a cutter, and extracted. The operation is repeated successively, and the casing pipes 6 are extracted in succession. Excavation is performed by a diameter expander, and a casing pipe is constructed in the same method as a new well, thus regenerating the old well. Accordingly, a groundwater intake right need not be gained anew, thus reducing the cost of construction.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for remanufacturing an old well in which a desired amount of pumped water cannot be maintained, and a donut drill bit and an apparatus for cutting an existing casing pipe used in this method.

[0002]

2. Description of the Related Art Tap water plays an extremely important role which is indispensable for people's lives. Rivers are mainly used for tap water sources, but groundwater is often used throughout Japan. Generally, the most common method of collecting groundwater is from deep wells, and the well diameter is 1
From 50mm to 500mm, the depth varies from country to country depending on the stratum conditions, but the water source wells of municipalities are from 60m to 35mm.
It is about 0m. Similarly, the amount of pumped water varies depending on the region, but there are large-scale ones with daily production capacity of 1,000 m ³ to large-capacity of 10,000 m ³ / day. On average, it seems to be 3,000 m ³ / day.

When pumping well water, the water level in the well drops, but if the well capacity, that is, within the range of appropriate pumping volume, the groundwater is discharged from the aquifer through the well screen (water intake pipe). It is possible to draw a fixed amount of water continuously at a fixed water level by being guided into a well.

However, calcium, magnesium and iron contained in groundwater which has been dissolved in the form of bicarbonate are precipitated due to changes in temperature and pressure, and a well screen and pump for taking in water from the well over time. As a scale of carbonate or the like adheres to the strainer portion, the inside of the pumping pipe, etc., a so-called clogging phenomenon occurs.
As a result, the water level gradually decreases, and the amount of pumped water decreases. If the groundwater is corrosive, the water intake of the well screen gradually expands, and gravel flows into the well from the surrounding aquifer. If the amount of gravel is large, the well becomes unusable.

In order to keep the well in good condition, the well is rehabilitated once every 3 to 5 years, and the scale adhering to the inner surface is brushed, treated with chemicals, stirred, and drenched in the well. It is necessary to take measures such as work and corrosion.

Since there are few components that corrode metals in groundwater components and few components that easily form scale,
Although some have maintained the same performance as when they were dug without performing maintenance for 60 years, such wells are extremely rare.

When the nature of groundwater tends to generate scale, as the number of well repairs increases, the degree of aging corrosion of well screens and casing pipes also progresses, and scale adheres to the gravel filling the outer periphery of well screens. . In this case, it becomes gradually difficult to completely restore the original state by the maintenance work. So 2
If maintenance is not carried out once every three to three years, the amount of pumped water cannot be maintained and the cost cannot be ridiculous.

Since the area where the water supply population is increasing is being urbanized, it is extremely difficult to acquire a new tap water source well site and the cost is enormous. If an abandoned well that owns groundwater intake rights or a well with significantly degraded performance can be regenerated into a new well, the immeasurable cost savings of more than two birds with one stone will be saved, and it will be appreciated by well-known well users all over the world. Will greatly contribute to

However, there is a common sense that a pipe of a deep well of 100 m to 350 m cannot be pulled out even if the well is about 10 m deep. For example, in order to pull out a pipe of a well with a diameter of 30 cm and a depth of 300 m, a load of 500 to 600 tons or more is necessary even if the conditions are assumed to be good.
It is common sense to think that it is impossible considering the pressure resistance of the ground.

The earth and sand surrounding the casing are
If it can be removed without collapsing the holes, the structure of the well,
That is, all of the casing pipe and the well screen can be replaced with new ones, but the work difficulty is extremely high and the possibility of success could not be expected, so there has been no previous attempt.

[0011]

The present invention makes it possible to extract the casing pipe even in a deep well, and widens the aquifer part for taking in water as in the case of a newly dug well. Then, by constructing a new casing pipe and well screen and filling it with gravel, a method of regenerating an old well such as an abandoned well or a well with poor performance into a completely new well, and a donut drill bit used for this method. It is intended to provide a cutting device for casing pipes. The present invention is a conventional technique (Japanese Patent Publication No. 63-27).
No. 515 and Japanese Examined Patent Publication No. 59-31609), with some improvements and new elements added.

[0012]

The method for recycling old wells according to the present invention includes first, second, third and fourth steps. The first step is to dig a part of the gravel layer and ground around the casing pipe of the old well with a circulating pressure mud of sufficient amount to be injected from the lower end of the donut bit suspended in the old well. By excavating the gravel layer that has been dug up to a predetermined depth, it is levitated to the ground by keeping the rising velocity of this muddy water sufficiently higher than the sedimentation velocity of the gravel and discharging it to the ground. The second step is to sequentially cut out the casing pipe with a cutting device and extract the casing pipe, and to extract the casing pipe to a predetermined depth by alternately performing the cutting with the first step. Further, the third step is to scrape and discharge the agglomerated region of the aquifer of the hole wall of the old well to an appropriate thickness with a widening machine and discharge. Then, the fourth step is to perform the steps from installation of the conventional casing pipe and well screen to finishing.

Further, the donut drill bit used in the regenerating method according to the present invention has a cylindrical portion, a connecting portion, a muddy water receiver, and a nozzle pipe. The inner diameter of the tubular portion is larger than the outer diameter of the casing pipe of the old well. The connecting portion is for connecting the tubular portion to the drill pipe, is tubular, and its lower end is concentrically attached to the tubular portion via a mounting plate.

Further, the muddy water receiver is formed between the mounting plate and the bottom plate mounted on the inner peripheral surface of the cylindrical portion and communicates with the connecting portion. The nozzle pipe is provided radially on the outer surface of the tubular portion and substantially parallel to the axis thereof over substantially the entire length thereof, and communicates with the aforementioned muddy water receiver at its upper end portion through a through port.
A nozzle is arranged at the lower end.

The donut drill bit described above is constructed by connecting the upper end and the lower end, which are independent from each other, to the inner part of the cylindrical part and the nozzle pipe by means of the connecting means. The donut drill bit described above is configured such that the upper end portion, the lower end portion, and one or more intermediate portions that are independent of each other are electrically connected to each other by the connecting means so that the inner portion of the cylindrical body portion and the nozzle pipe are electrically connected to each other. .

The nozzle described above is provided with a ring-shaped cover for preventing the flow toward the wall surface of the hole. The previously mentioned nozzle is
It includes those whose axis lines form an angle with each other on a cylindrical surface concentric with the cylindrical portion.

The casing pipe cutting apparatus used in the method for regenerating old wells of the present invention has an inside slip, an electric motor, and a cutting nozzle. The inside slip is a wedge body attached to the lower end of a rod suspended on a drill line, a sleeve loosely fitted to the rod, a swing arm radially bonded to the outer peripheral surface of the sleeve, and a free end of the swing arm. It is a known structure having a slip which is connected to and disengages from the conical surface portion of the wedge body on the inner surface and has a tooth portion provided on the outer surface to engage with the inner wall surface of the casing pipe. The electric motor is supported by a fixed arm extending downward from the inside slip, and its rotation shaft projects downward to support the nozzle fixed arm. The cutting nozzle described above is attached to the end of the nozzle fixing arm so that the injection axis of the cutting nozzle is perpendicular to the inner wall surface of the casing pipe, and is rotated together with the rotating shaft to cut the casing pipe. .

The aforementioned cutting nozzle integrally has a guide roller having a vertical axis, and when the aforementioned nozzle fixing arm advances, this guide roller abuts the inner wall surface of the casing pipe, and the aforementioned cutting nozzle and casing pipe. The distance between the inner wall surfaces is kept at a predetermined value.

[0019]

First, the first step is started. The donut drill bit is connected to a drill pipe and suspended above an old well, and the lower end of the tubular portion is fitted outside the casing pipe of the old well. The pressure muddy water flowing down the drill pipe enters the muddy water receiver of the donut drill bit, is distributed to each nozzle pipe, and is ejected from the nozzle to dig up gravel. Gravel that rises with mud flows into the mud bits above the ground and accumulates.

Next, the second step is carried out. The casing pipe cutting device is suspended in the well, and the cutting nozzle and inside slip are put in place in the casing pipe.
Here, the drill rope is raised and the slip is moved upward by the wedge body to engage the slip with the inner surface of the casing pipe. The stability of the inside slip stabilizes and stabilizes the entire casing cutting device with the casing axis, so that pressure water is sent from the ground to the cutting nozzle to start the electric motor and rotate the rotary shaft. Due to the rotation of the rotating shaft, the arm also rotates, and the cutting nozzle also rotates on a horizontal plane to collide the jet water flow with the inner wall surface of the casing pipe and cut it. After the cutting is completed, the cutting device is lifted out of the well together with the cut pipe portion by a drill line. Reverse this work and the work of paragraph [0019], and remove all the parts of the old well casing pipe that should be extracted.

Next is the third step. By installing a widening machine (expansion type expansion wing bit) at the tip of the conventional direct rotary chiseling machine and suspending it in the well, the wall surface of the aquifer and its back part are shaved off to remove muddy water. It is discharged to the outside with.

The final step is the fourth step. In the conventional process for a new well, a new casing pipe is suspended and installed in the well, and the outer periphery of the well screen is filled with gravel of an appropriate grain size. Then, the finishing work that is generally performed is performed to complete the series of steps.

If the above-mentioned nozzle is provided with a ring-shaped cover for blocking running water toward the wall surface of the hole, it is possible to prevent the hole wall from being unnecessarily dug. Further, when the nozzle described above includes the nozzles whose axes form an angle with each other, the gravel digging work becomes effective.

If the above-mentioned donut drill bit is constructed by connecting the upper end and the lower end, which are independent of each other, to the inner part of the cylindrical part and the nozzle pipe by the connecting means, the donut drill bit described above It doesn't need to be long and is easy to handle.

The above-mentioned donut drill bit is constructed by connecting the upper end portion, the lower end portion and one or more intermediate portions, which are independent from each other, to the inside of the cylindrical portion and the nozzle pipe by means of connecting means. If there is a deep well,
The number of intermediate parts can be selected appropriately and the work can be done easily.

The casing pipe cutting device is suspended from a drill line and suspended inside the casing pipe. When the cutting nozzle descends to a predetermined position, it is fixed to the casing pipe by inside slip. When the electric motor is started, the cutting nozzle rotates on a horizontal plane, and when the muddy water is pumped to the cutting nozzle through the pressure muddy water supply pipe, the muddy water cuts the casing pipe.

The cutting nozzle described above integrally has a guide roller having a vertical axis, and when the nozzle fixing arm advances, the guide roller abuts the inner wall surface of the casing pipe, so that the cutting nozzle and the casing pipe are separated from each other. The distance between the inner wall surfaces is kept at a predetermined value. In this case, the distance between the cutting nozzle and the casing pipe becomes constant, and the cutting work is ensured.

[0028]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT FIG. 1 shows the first step of digging the filling gravel of an old well using a donut drill bit, with half the donut drill bit cut. 2 is an enlarged sectional view taken along line 2-2 of FIG. 1, and FIG. 3 is an upper end portion and a lower end portion of the donut drill bit, an upper end portion and an intermediate portion,
An enlarged half sectional view of a connecting portion common to each of the intermediate portions and each connecting portion of the intermediate portion and the lower end portion, and FIG. 4 is a sectional view taken along line 4-4 of FIG.
FIG. 5 is an enlarged bottom view of the donut drill bit, FIG. 6 is a detailed cross-sectional view of the nozzle portion, and FIG. 7 is a bottom view of an embodiment using a nozzle in which the jet direction of the nozzle is inclined.

The donut drill bit 1 has a cylindrical portion 2
It has a connection part 3, a muddy water receiver 4, and a nozzle pipe 5. The donut drill bit 1 may be divided into an upper end portion 1T, an intermediate portion 1M, and a lower end portion 1B which are independent from each other, and these may be connected by a connecting means 1C. As an example of the connecting means 1C, as shown in FIGS. 3 and 4, an inner thread ring R1 and an outer thread ring R2 are attached to the ends of the respective parts so as to cover the nozzle pipe 5, and the tubular body part 2 is also fitted in a watertight manner. There is a method in which the inner ring Q1 and the outer ring Q2 to be mated are attached and connected by screwing the inner and outer threaded rings R1 and R2.

The inner diameter of the tubular portion 2 is larger than the outer diameter of the casing pipe 6 of the old well. Also, the connecting portion 3
Is for connecting the tubular body portion 2 to the donut drill joint 7 and has a cylindrical shape, and the lower end portion thereof is concentrically attached to the tubular body portion 2 via a mounting plate 8.

The muddy water receiver 4 is formed between the mounting plate 8 and the bottom plate 9 mounted on the inner peripheral surface of the tubular portion 2, and communicates with the connecting portion 3 at the upper end. The nozzle pipes 5 are provided radially on the outer surface of the tubular portion 2 and parallel to the axis of the tubular portion over substantially the entire length of the tubular portion 2. The nozzle pipe 5 communicates with the muddy water receiver 4 through the through hole 10 at the upper end and the nozzle at the lower end. 11 are provided.

A ring-shaped cover 12 is attached to the nozzle 11.
Is provided to prevent the mud flow from heading to the bore wall 13. A blade tip 12 ′ is provided at the lower end of the cover 12, and the filled gravel layer 21
You can also use it to break through. The nozzle 11 also includes nozzles 11 that are at an angle to each other.

The donut drill bit 1 is attached to the donut drill joint 7 and suspended in an old well. Then, the lower end of the tubular portion 2 is attached to the casing pipe 6
When it reaches the filling gravel layer 21, the mud pump 22 is driven, and the mud water in the mud tank 23 is pressure-fed from the donut drill joint 7 to the donut drill bit 1 through the water swivel 24. . The muddy water enters the muddy water receiver 4 and the entrance 1
It evenly flows into each nozzle pipe 5 through 0, and is jetted from the nozzle 11 at the lower end to excavate gravel.

The gravel dug up is the cylindrical portion 2 and the hole wall 13.
It is carried by the flow velocity of the muddy water that rises between the two, flows into the mud bit 25 above the ground, and accumulates there. When the digging of the filled gravel layer 21 is completed, the donut drill joint 7 is pulled up and the donut drill bit 1 is taken out of the well.

In the drawings, 26 is a sand pump, 27 is a rotary table, 28 is a drive unit, and 29 is a conductor pipe.

FIG. 8 shows a second step of cutting the casing pipe 6 of the old well by the cutting device 31, and FIG. 9 is a detailed view of the cutting device. The cutting device 31 is a known inside slip 32 in which an electric motor 33 and a cutting nozzle 34 are integrally provided.

The inside slip 32 includes a wedge body 37 attached to the lower end of a rod 36 suspended from a drill rope 35, and the rod 3
6 has a sleeve 38 loosely fitted therein. A swing arm 39 is pivotally attached to the outer peripheral surface of the sleeve 38 in a radial manner, and a slip 40 is connected to the free end of the swing arm. This slip has an inner surface that is engageable with and disengages from the conical surface portion 41 of the wedge body 37, and has an outer surface that has a tooth portion 42 that engages with the inner wall surface of the casing pipe 7.

The electric motor 33 is suspended and supported by a fixed arm 43 extending downward from the inside slip 32. The rotation shaft 44 extends downward and the nozzle fixing arm 4 is attached to the side surface.
Supports 5. A cutting nozzle 34, which is electrically connected to a high-pressure water generator 46, is installed at the lower end of the rotary shaft 44 so as to be movable back and forth in a direction perpendicular to the cutting nozzle 34, and a guide roller 47 having a vertical axis line integrally with the cutting nozzle 34 is provided. It is provided.

The pins 48 on both sides of the cutting nozzle 34 are fitted into the long holes 49 of the nozzle fixing arm 45, and the pushing mechanism 51 provided on the rotary shaft 44 is connected to the nozzle fixing arm 45 and driven by the electric motor 33. It This pushing mechanism 51
When the nozzle fixing arm 45 is pushed by, the guide roller 47 and the cutting nozzle 34 move in parallel, and the guide roller 4
7 contacts the inner wall surface of the casing pipe 6, and the axis of the cutting nozzle 34 is perpendicular to the inner wall surface of the casing pipe 6. A plurality of cutting nozzles 34 may be provided radially. In the drawing, 52 is a sand reel, 53
Is a reel for drill cords.

A sleeve 38 is loosely fitted to the rod 36, the sleeve is hung on the sand reel 52, the rod 36 is hung on the drill cable 35, and the cutting device is lowered into the well while the sleeve 38 is floating. Put in the pipe 6. When the cutting nozzle 34 reaches a predetermined position, the sleeve 38 is lowered and the rod 36 is pulled up, and the slip 40 moves in parallel in the radial direction and presses against the inner wall surface of the casing pipe 6.
Next, when the nozzle fixing arm 45 is pushed out by the pushing mechanism 51 by the electric motor, the guide roller 47 abuts on the inner wall surface of the casing pipe 6, and the cutting nozzle 34 comes close to the inner wall surface of the casing pipe 6 and is oriented perpendicularly thereto.

Here, when high-pressure water is sent from the high-pressure water generator 46 and the electric motor 33 is started, the rotary shaft 44 rotates,
The cutting nozzle 34 also rotates to cut the casing pipe 6 by the water jet. When the cutting is completed, the drill rope 35 is wound up. Then inside slip 3
Since 2 remains in the cut casing pipe, this casing pipe is pulled out together with the cutting device 31. It is also possible to connect the rod 36 and the sleeve 38 via a cylinder, and send hydraulic pressure from the ground to engage and disengage the wedge body 37 and the slip 40.

FIG. 10 illustrates the third step. The widening machine 61 is a conventionally known type, and is a type having a bit 65 which is attached to the lower end of a fixed arm 62 and is expanded and contracted in a radial direction by a cylinder 63 via a link 64. A stabilizer 66 is provided in the middle of the fixed arm 62. The bit 65 is lowered to the surface of the aquifer 67 in the well, the bit 65 is extended, the bit is lowered while rotating, the hole wall portion is scraped off, and the bit wall 65 is carried out to the outside by muddy water.

Since the fourth step is the same as the method for a normal new well, the description with the drawings is omitted. That is, a casing pipe is installed, gravel is filled, and finishing with muddy water is performed. Thus, the old well is regenerated.

[0044]

According to the present invention, since it is possible to remove the casing pipe in a deep well, which has been considered impossible in the past, it is possible to remove an old well such as an abandoned well or a well whose pumping capacity is lowered while retaining the right to pump. Wells can be regenerated as well as newly constructed.

According to the second aspect of the present invention, excavation of the filled gravel and discharge of the excavated gravel from the floating can be automatically and efficiently performed according to the relationship between the flow velocity of the muddy water and the gravity of the gravel. According to the third and fourth aspects, the donut drill bit can be connected and configured according to the depth of the well, and the handling becomes easy.

According to claims 5 and 6, unnecessary excavation of the hole wall can be prevented, and the effect of excavating gravel can be increased.
According to the seventh aspect, it is possible to provide a cutting device capable of cutting the casing pipe by merely suspending and fixing it inside the casing pipe and rotating the cutting nozzle. According to claim 8, the distance between the tip of the cutting nozzle and the inner wall surface of the casing pipe can be kept constant, and effective cutting can be performed.

[Brief description of drawings]

FIG. 1 is a partially cut side view showing a specific example of a first step of a method for recycling an old well according to the present invention.

FIG. 2 is a sectional view taken along line 2-2 of FIG.

FIG. 3 is an enlarged half cutaway view of a connection portion when a donut drill bit has a connection configuration.

FIG. 4 is a sectional view taken along line 4-4 of FIG.

FIG. 5 is an enlarged bottom view of the donut drill bit.

FIG. 6 is a detailed cross-sectional view of a nozzle portion.

FIG. 7 is a bottom view of an example in which nozzles in which the ejection direction of a nozzle is inclined are used in combination.

FIG. 8 is an explanatory diagram of a second step.

FIG. 9 is a detailed view of the inside slip and casing pipe cutting device used in the second step.

FIG. 10 is an explanatory diagram of a third step.

[Explanation of symbols]

 1 Donut drill bit 2 Cylindrical part 3 Connection part 4 Muddy water receiver 5 Nozzle pipe 1T Upper end part 1M Middle part 1B Lower end part 1C Connecting means 6 Casing pipe 7 Donut drill joint 8 Mounting plate 9 Bottom plate 10 Through hole 11 Nozzle 12 Cover 13 hole Wall 31 Cutting device 32 Inside slip 33 Electric motor 34 Cutting nozzle 35 Drill rope 36 Rod 37 Wedge body 38 Sleeve 39 Shaking arm 40 Slip 41 Cone face 42 Teeth 43 Fixed arm 44 Rotation shaft 45 Nozzle fixed arm 47 Guide roller 48 Pin 49 Length Hole 51 Extrusion mechanism 61 Widening machine

Claims (8)

[Claims] 1. A first, a second, a third and a fourth step are included, wherein the first step comprises a packed gravel layer (21) around the casing pipe (6) of an old well and a ground ( A part of (Jiyama) is blasted from the lower end of the donut drill bit (1) suspended in the old well, and is crushed by circulating pressure mud with a sufficient amount of water. By keeping it large, the excavated gravel is floated and discharged to the ground, and the filled gravel layer (21) is excavated to a predetermined depth, the second step is excavated in the first step. Filled gravel layer (2
A device for cutting the casing pipe (6) near the upper surface of 1)
Cut out by (31) and extract on the ground, and by alternating execution with the first step, the casing pipe to a predetermined depth
(6) is extracted, the third step is to use the widening machine (61) to open the hole wall (13) of the old well.
The agglomerated region of the aquifer (66) is scraped to an appropriate thickness and discharged. The fourth step is to newly add casing pipes and wells as in the conventional deep well method. A method of remanufacturing an old well, which is characterized by carrying out the steps from installation of the screen to finishing. 2. A cylindrical portion (2), a connecting portion (3), and a muddy water receiver.
(4) and a nozzle pipe (5), the inner diameter of the tubular portion (2) is larger than the outer diameter of the casing pipe (6) of the old well, and the connecting portion (3) is a donut drill joint ( 7) for connecting the tubular portion (2) to the tubular portion, the lower end of which is concentrically attached to the tubular portion (2) via a mounting plate (8), 4) is formed between the attachment plate (8) and the bottom plate (9) attached to the inner peripheral surface of the cylindrical body portion (2) and communicates with the connection portion (3). 5) is provided radially on the outer surface of the tubular portion (2) and substantially parallel to the axis thereof over substantially the entire length thereof, and communicates with the above-mentioned muddy water receiver (4) at its upper end through a through port (10),
A donut drill bit used in a method of regenerating an old well, characterized in that a nozzle (11) is arranged at the lower end.
(1). 3. An upper end portion (1T) and a lower end portion (1B) which are independent from each other are electrically connected to each other inside the cylindrical portion (2) and the nozzle pipe (5) by a connecting means (1C). The donut drill bit (1) used in the method for regenerating an old well according to claim 2, which is configured as follows. 4. The inside of the tubular part (2) is connected to the upper end (1T), the lower end (1B) and one or more intermediate parts (1M), which are independent of each other, by connecting means (1C). Comrade and nozzle pipe
(5) The donut drill bit used in the method for regenerating an old well according to claim 2, wherein the donut drill bits are configured to be electrically connected to each other.
(1). 5. The donut drill used in the method for regenerating an old well according to claim 2, wherein the nozzle (11) is provided with a ring-shaped cover (12) for blocking a flow toward the wall surface of the hole. Bit (1). 6. The donut drill bit for use in the method of regenerating an old well according to claim 2, wherein the nozzles (11) include those whose axes are at an angle to each other.
(1). 7. An inside slip (32) and an electric motor (33).
And a cutting nozzle (34), the inside slip (32) being a rod suspended on a drill rope (35).
The wedge body (37) attached to the lower end of (36), the sleeve (38) loosely fitted to this rod (36), the swing arm (39) radially pivotally attached to the outer peripheral surface of this sleeve, and this swing Slip that is connected to the free end of the arm and can be engaged and disengaged with the conical surface portion (41) of the wedge body (37) on the inner surface and the tooth portion (42) that engages with the inner wall surface of the casing pipe (6) on the outer surface
(40), the electric motor (33) is supported by a fixed arm (43) extending downward from the inside slip (32), the rotary shaft (44) thereof projects downward, and the nozzle is fixed to the rotary shaft. The cutting nozzle (34) that supports the arm (45) is movable in parallel so that its injection axis is perpendicular to the inner wall surface of the casing pipe (6), and the nozzle fixing arm (45) is Attached to the end, the rotary shaft (44)
A casing pipe cutting device for use in a method of regenerating an old well, characterized in that the casing pipe (6) is rotated together with the casing pipe (6). 8. The cutting nozzle (34) integrally has a guide roller (47) having a vertical axis, and when the nozzle fixing arm (45) advances, the guide roller (47) causes the casing pipe (47) to move. The method for regenerating an old well according to claim 7, wherein the distance between the cutting nozzle (34) and the inner wall surface of the casing pipe (6) is maintained at a predetermined size by contacting the inner wall surface of 6). A casing pipe cutting device to be used.