KR20230174979A - Pipe drilling apparatus - Google Patents

Abstract

The pipe body drilling device is started.
This pipe drilling device is a pipe drilling device used for pipe drilling to connect and form branch pipes by an uninterrupted method on the side of underground pipes such as water pipes or sewer pipes,
A base support having a wheel, a housing disposed on the base support, a drilling portion having a drill bit for drilling connected to the housing side to enable drilling of a pipe body, and a drill for drilling in the drilling portion. A drilling operation unit having an operation tool formed on the outside of the housing in a state in which the blade side can be operated in a forward and backward direction, and the operation of the operation tool of the punching operation unit can be remotely guided and controlled. It includes a wireless control unit that is formed.

Description

Pipe drilling device {PIPE DRILLING APPARATUS}

The present invention relates to a tubular drilling device.

In general, pipe (e.g. water and sewage) facilities constructed underground may require the construction of a branch pipe from the main pipe after construction.

Among the work methods for branch pipe construction, the uninterrupted water method, which carries out branch processing work without blocking the fluid pressure and flow inside the main pipe, is widely known.

The uninterrupted water method is a method of drilling one side of the circumference of the pipe body at the point where branching is required while maintaining the fluid pressure and flow within the underground main pipe section, and then connecting the branch pipe body to the perforated area. The work proceeds with .

This continuous water interruption method has the advantage of minimizing civil complaints or inconveniences due to water interruption in the main pipe when constructing branch pipes. However, due to the construction method, the work is done while maintaining the fluid pressure and flow on the main pipe side. Since this process is being carried out, it is important to ensure work efficiency and work stability, especially when drilling pipe bodies.

(Patent Document 0001) Registered Patent Publication No. 10-0983640.

The present invention was devised to solve the conventional problems described above,

The purpose of the present invention is to provide a pipe drilling device that can easily perform pipe drilling work on various underground pipes, such as water pipes or sewer pipes, in a state consistent with the formation of branch pipes by an uninterrupted water pipe method.

In order to realize the purpose of the present invention as described above,

A pipe drilling device used for pipe drilling to connect and form branch pipes using an uninterrupted method on the side of underground pipes such as water pipes or sewer pipes,

base support with wheels;

a housing disposed on the pedestal support, and a drilling portion provided with a drill bit for drilling connected to the housing to enable drilling of a tubular body;

a drilling operation unit having an operating tool formed on the outside of the housing to enable drilling operations on the drill bit side of the drilling unit in forward and backward directions; and

a wireless control unit configured to remotely guide and control the operation of the drilling unit;

It provides a tubular drilling device comprising a.

The present invention provides an integrated device structure that includes a drilling unit, a drilling operation unit, and a wireless control unit for drilling the pipe body of an underground pipe, and whose main components are installed on a base support with wheels, allowing for movement and Convenience in transportation can be further improved.

In addition, the present invention provides a structure that can remotely guide and control the operation of the drilling operation unit using a wireless control unit, thereby ensuring further improved operating convenience during drilling work.

Therefore, the present invention can be expected to have satisfactory device efficiency and work efficiency when performing pipe perforation processing for forming branch pipe connections by an uninterrupted method on various underground pipes such as water pipes or sewer pipes.

Figure 1 is a diagram schematically showing the overall structure of a tubular drilling device according to an embodiment of the present invention.
Figures 2 to 9 are drawings for explaining the detailed structure and operation of a tubular drilling device according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the attached drawings.

Embodiments of the present invention are described within the scope of enabling those with average knowledge in the art to practice the present invention. Accordingly, since the embodiments of the present invention can be modified into various different forms, the scope of the claims of the present invention is not limited to the embodiments described below.

Figure 1 is a diagram schematically showing the overall structure of a tubular drilling device according to an embodiment of the present invention, and Figures 2 to 9 are diagrams for explaining the detailed structure and operation. Referring to Figures 1 to 7, The pipe drilling device according to an embodiment of the present invention includes a supporter 10, a drilling unit 20, a drilling operation unit 30, and a wireless control unit 40, and includes an underground pipe (e.g., a water pipe or a sewer pipe). ) is formed to have a device structure that can perforate the pipe body (P) side by an uninterrupted method.

As shown in FIGS. 1 and 2, the base support 10 has a wheel 12 at the bottom, and is formed to have a structure that can be moved on the ground by the wheel 12.

The base support 10 may be formed in the form of a frame capable of stably supporting the perforated portion 20, which will be described later. For example, a plurality of metal pipes or metal bars may be connected by welding or bolting. It can be formed to have the same frame shape as in 1.

The wheels 12 are composed of a plurality of wheels, and can be fixedly installed to enable normal rolling movement while being supported on the ground at the lower side of the base support 10.

The wheel 12 may be, for example, in the form of a roller caster, and may be selected from among various types of wheels that satisfy the purpose of the present invention.

In addition, the wheel 12 is installed to enable rolling movement while grounded on the ground on the side of the base support 10, but has a structure that can be operated in a protruding or non-protruding (retracted) state, for example, by folding or lifting. may be provided.

The perforation part 20 is formed to have a structure capable of perforating one side of the outer surface of the pipe body (P) of the underground pipe through a drilling drive.

As shown in FIG. 1, the drilling portion 20 includes a housing 22 and a drill bit 24 for drilling installed on the housing 22 side, and is installed on the base support 10 side.

That is, the housing 22 is formed in a cylindrical shape and is placed on the upper side of the base support 10, and can be fixedly installed in a horizontal position.

At one end of the housing 22 in the longitudinal direction, a flange-shaped connection portion (A) is formed, as shown in FIG. 1 .

As shown in FIG. 2, the connection portion (A) is formed so that it can be detachably connected and fixed to the side of the normal drilling holder device (M), which is installed in a state of holding the circumference of the pipe during drilling of the pipe body (P). .

The holder device (M) for drilling is provided with a holder (M1) that surrounds and holds the circumferential side of the pipe body (P), and an opening/closing valve (M2) and an adapter (M3) formed in connection with the holder (M1) side. And, the connection portion (A) side of the housing 22 is detachably connected and fixed to the adapter M3 side using a bolt and nut fastening method.

A drive source (B) is installed on the housing 22 side to generate and transmit power for drilling the drill bit 24.

The drive source (B) can, for example, use an electric motor, and the rotational force of the motor shaft can be transmitted to the drill bit 24 side for drilling through a normal gear-meshing power transmission method. can be installed in

The drive source (B) can be electrically set to be controlled to be driven in an on or off state by manipulating the switch (B1), and the switch (B1) can be installed at a point adjacent to the drive source (B) on the outside of the housing (22). there is.

The drill bit 24 for drilling is connected to the housing 22 and set to perform drilling operation by driving the drive source B.

As shown in FIG. 1, the drill bit 24 for drilling is protruding from both ends of the housing 22 in the longitudinal direction on the connection portion (A) side, and performs a drilling operation while being rotated around the axis when the drive source (B) is driven. It is set as possible.

The drill bit 24 for drilling is formed to have a drill bit structure that matches the drilling process on the outer surface of the pipe body P.

For example, the drill bit 24 for drilling may be formed in the form of a metal hole saw (HOLE SAW) having a peripheral portion corresponding to the size (diameter) of the hole for drilling the pipe body (P).

As shown in FIG. 3, the hole saw-type drill bit 24 has a groove C1 with one side open on the inner side of the peripheral portion, and a guide blade C2 is provided in a coaxial state on the groove C1 side. It may be composed of this formed structure.

The drill bit 24 for drilling may be provided with a collection port 26 as shown in FIG. 3 .

The collection port 26 is formed and set so that it can be detachably attached to the groove C1 side of the drill bit 24, and a permanent magnet can be used.

This collection port 26 can induce cutting foreign substances (e.g., iron powder) generated during the drilling operation of the pipe body (P) to be collected in a state where they stick to the pipe body (P), and as a result, cutting foreign substances are collected through the perforation portion of the pipe body ( P) The inflow phenomenon can be suppressed.

Referring to Figures 4 and 5, a fixture 28 may be formed on the side of the collection port 26.

The fixture 28 has a locking portion D1 and a protrusion D2. The locking portion D1 is disposed on the side of the guide groove D3 formed inside the circumference of the collection port 26, and the protrusion D2 Can be set to protrude from one side of the collection port 26 while being connected to the catching portion D1.

The locking portion (D1) is disposed inside the guide groove (D3), and when rotated at a certain angle as shown in FIG. 4, it is located on the locking groove (C3) formed on the inner peripheral surface of the groove (C1) of the drill bit for drilling (24). It is formed to have a protrusion structure that can be detachably hung.

The protrusion D2 is disposed in a protruding state on one surface of the collection port 26, and is set to function as a kind of lever for latching or unlatching the latching portion D1.

When installing the collector 26 on the groove C1 side of the drill bit 24 for drilling, this fixture 28 is used to lock the groove C1 by manipulating the protrusion D2. The collection port 26 on the side can be fixed more stably.

In addition, when separating the collection port 26, not only can the jammed state be easily released by manipulating the externally exposed protrusion D2, but also the protrusion (D2) can be easily removed by the operator's hand or a separate tool (e.g., nippers). The collection port 26 can be more easily separated by pulling the D2) side.

The drilling operation unit 30 is formed to move the drill bit 24 for drilling forward and backward to match the drilling operation of the pipe body P.

The drilling operation unit 30 is provided with an operation tool 32 as shown in FIG. 1, and this control tool 32 can operate the drill bit 24 for drilling forward and backward in the longitudinal direction of the housing 22. is formed.

The operating tool 32 may be formed as a circular handle type and may be formed to protrude on the outer surface of the housing 22.

For example, the operating tool 32 may be installed in a state in which forward and reverse rotation is possible on the circumferential side of the opposite end of the connection portion A among both ends of the housing 22 in the longitudinal direction.

The operating tool 32 may be formed to induce forward and backward movement of the drill bit 24 for drilling by transmitting power through gear engagement during forward and reverse rotation.

The operating tool 32 may be set to transmit power through the inner space of the housing 22 by, for example, a combination of a rack gear and a pinion gear among the power transmission methods by gear engagement.

As shown in FIG. 1, the drilling operation unit 30 uses the drill bit 24 for drilling in a state that corresponds to the drilling operation on the connection part A of the housing 22 by rotating the operation tool 32 forward and backward. It is possible to provide a manipulation structure that can induce movement in the forward and backward directions.

In the above description and drawings, the operating tool 32 is shown as an example of a handle type, but it is not limited thereto. In addition, although not shown in the drawings, it may be of a lever type, for example.

Meanwhile, the wireless control unit 40 is formed to have a structure capable of controlling the operation of the drilling operation unit 30 in a wireless manner.

Referring to FIGS. 6 and 7, the wireless control unit 40 includes a control drive source 42, a control power transmission port 44 for transmitting the power of the control drive source 42 to the operation tool 32, and a control drive source 42. It is provided with a wireless control device (46) for wirelessly controlling the driving of the driving source (42).

The drive source 42 for control may use an electric motor, and is disposed on the housing 22 side in a state corresponding to the operation tool 32 side.

The drive source 42 for control may be, for example, a geared motor that can control rotation in the forward and reverse directions and has a deceleration function among electric motors, and the motor shaft is connected to the operating tool 32. It can be placed on the housing 32 side in an arrangement parallel to the handle axis of each other.

The power transmission tool 44 for control may be composed of, for example, a belt and a pulley, and as shown in FIGS. 6 and 7, power is transmitted between the axes of the control drive source 42 and the operating tool 32 using a belt and pulley combination. It can be set to a connection state where transmission is possible.

The power transmission port 44 for control may be configured and set as, for example, a chain and sprocket combination in addition to a belt and pulley combination.

As shown in FIG. 6, the wireless control unit 46 may be composed of a control remote control (E1) capable of wireless transmission and reception and a control switch (E2), and the control switch (E2) is operated on the control drive source 42 side. The connection is established in a state where a signal can be applied.

That is, the wireless control unit 46 not only controls the on and off of the control drive source 42 by, for example, the control switch E2 that receives the corresponding control signal when operating the function button of the control remote control E1, Control of the direction of rotation can be achieved wirelessly.

Therefore, the wireless control unit 40 can provide a structure that allows remote control of the operation of the drilling operation unit 30 in a wireless manner, so that not only can the convenience of operation of the device be further improved when drilling the pipe body (P), Work safety can also be ensured through remote control.

In addition, the wireless control unit 40 is not shown in the drawing, but for example, a remote control method is provided by additionally installing a wireless control switch to correspond to the drive source (B) side of the drilling unit 20 and operating the control remote control (E1). It may be set and configured to control operation.

Referring to FIG. 8, the tubular drilling device according to an embodiment of the present invention may further include an auxiliary support 50.

The auxiliary support 50 is formed to have a structure capable of supporting the perforated portion 20 side in a state in which the drilling posture can be adjusted in connection with the side support 10.

As shown in FIG. 8, the auxiliary support 50 may be in the form of a plate capable of supporting the housing 22 side of the perforation part 20 in a support state, and is disposed on the upper side of the base support 10.

On the side of the auxiliary support 50, the housing 22 is fixed in a horizontally arranged state, for example, at least one point on the longitudinal circumference of the housing 22 is fastened with a bolt (e.g., a “U” bolt). It can be set in a fastened state.

In addition, the auxiliary support 50 is disposed on the upper side of the support support 10, and is set so that the position of the support can be adjusted by the adjustment connector 52.

The adjustment connector 52 may be in the form of a ball joint (BALL JOINT), and can be set to connect the upper side of the pedestal support 10 to the lower side of the auxiliary support 50 in a ball joint manner to enable pedestal support. there is.

The adjustment connector 52 can be formed to limit the angle adjustment movement of the ball joint joint by pressing or releasing the pressure by rotating the fixing member (F, e.g., set screw).

This auxiliary support 50 can provide a structure that can variously adjust and set the drilling posture of the housing 22 disposed on the base support 10 to a state that matches the working conditions, thereby providing further Improved work efficiency can be ensured.

Referring to FIG. 9, the tubular drilling device according to an embodiment of the present invention may further include a protective cover portion 60.

The protective cover portion 60 includes a cover 62, and the cover 62 is preferably made of a material that is transparent and can secure waterproofness (eg, urethane).

As shown in FIG. 9, the cover 62 can be installed so that it can be stored and withdrawn with one side connected and fixed to the storage box 64 disposed on one end of the housing 22 of the perforated portion 20. there is.

The cover 62 has an area that can cover the top and sides of the housing 22 from the outside, and is pulled out from the storage box 64 and then wrapped around the top and sides of the housing 22 by unfolding. It is formed so that it can be covered.

Additionally, a string member (G, for example, a rubber band) having elasticity may be installed along the circumference of the cover 62.

The string member G can induce the circumferential side of the cover 62 to elastically contract, thereby improving installation convenience and stability when installing the cover 62 in a state surrounding the housing 22 side.

This protective cover portion 60 can protect the outer surface of the housing 22 from rainwater or various foreign substances by installing the cover 62 in a state that surrounds the outer surface of the housing 22.

Therefore, in the present invention, as shown in FIG. 2, when drilling for branch pipe construction is performed on the pipe body (P) side of the underground pipe by an uninterrupted method, the end of the housing 22 of the perforation portion 20 and the pipe body (P) It is possible to provide a device structure that can easily drill one side of the pipe body (P) by drilling the drill bit (24) in a state where the drilling holder device (M) is connected and installed between the drilling points of the pipe. there is.

In particular, the present invention provides a device structure in which the perforation portion 20 is fixedly installed on the pedestal support 10 in a stable pedestal support state, thereby making it possible to not only transport the device but also further increase the mobility of the device within the workplace. there is.

In addition, the present invention can be expected to improve work convenience and work efficiency during drilling work by providing a device structure that can remotely and wirelessly control drilling drive and operation for drilling processing.

10: Base support 20: Perforated portion
30: perforation control unit 40: wireless control unit

Claims (6)

A pipe drilling device used for pipe drilling to connect and form branch pipes using an uninterrupted method on the side of underground pipes such as water pipes or sewer pipes,
base support with wheels;
a housing disposed on the pedestal support, and a drilling portion provided with a drill bit for drilling connected to the housing to enable drilling of a tubular body;
a drilling operation unit having an operating tool formed on the outside of the housing to enable drilling operations on the drill bit side of the drilling unit in forward and backward directions; and
a wireless control unit configured to remotely guide and control the operation of the drilling unit;
A tubular drilling device comprising a. In claim 1,
The base support is,
A tubular drilling device in the form of a metal frame with metal pipes or metal bars connected to each other. In claim 1,
The wireless control unit,
A tube body drilling device comprising a control drive source, a control power transmission tool for transmitting the power of the control drive source to the operation tool side of the drilling operation unit, and a wireless control tool for wirelessly controlling the operation of the control drive source. In claim 3,
The wireless control device is,
It consists of a control remote control capable of wireless transmission and reception and a control switch, and the control switch is set to enable control of the on/off and rotation direction of the control drive source by a control signal from the control remote control. In claim 1,
The tube body drilling device further includes an auxiliary support,
The auxiliary support is,
A tube body drilling device, characterized in that it is disposed on the upper side of the pedestal support in a state in which the housing side of the perforation part is supported by a pedestal, and is set on the side of the pedestal support in a state in which the pedestal support posture can be adjusted by an adjustment connector. In claim 1,
The pipe body drilling device further includes a protective cover,
The protective cover part,
Equipped with a cover, the cover has an area that can be covered by surrounding the housing side of the perforated portion, and is set to be stored and withdrawn with one side connected to a storage box disposed on one side of the outer surface of the housing. A pipe perforation device that uses

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