This application claims priority to Chinese Patent Application No. 202110448905.5 filed Apr. 25, 2021 and Chinese Patent Application No. 202110450374.3 filed Apr. 25, 2021, the disclosures of which are incorporated herein by reference in their entireties.
The present application relates to the technical field of electric power iron tower foundation construction, for example, a drilling device and a drilling construction method for an electric power iron tower foundation.
The construction of an electric power iron tower foundation is usually carried out in mountainous and hilly areas. Firstly, drilling platforms are built, and then holes are drilled on the drilling platforms.
In the related art, a drilling construction device for a rock and soil foundation is large in volume and weight, and a drilling process requires the transfer among multiple drilling platforms and the transfer among multiple hole positions of the drilling platforms, resulting in low drilling efficiency, and the transfer of the drilling device requires a large manual labor cost and a large manual labor intensity.
The present application provides a drilling device and a drilling construction method, so as to solve problems of low drilling construction efficiency and high manual labor intensity.
An embodiment of the present application provides a drilling device. The drilling device includes a hydraulic drilling unit, a multi-way connector, a compressed air conduit, a plurality of air compressor units, an air duct, a dust removal unit and an operation bench. The hydraulic drilling unit is capable of moving among a plurality of drilling platforms and among a plurality of hole positions on the plurality of drilling platforms, and performing a drilling operation. The plurality of air compressor units are disposed in a fixing and mounting region that is between the plurality of drilling platforms, where compressed air outputted by the plurality of air compressor units flows jointly through the multi-way connector and then is transmitted to the hydraulic drilling unit through the compressed air conduit. The dust removal unit includes a dust collection cover and a dust remover, where the dust collection cover is disposed at ground apertures of the plurality of hole positions, the dust remover is disposed in the fixing and mounting region, and the dust collection cover and the dust remover are connected through the air duct. The operation bench is separately connected to the hydraulic drilling unit, the plurality of air compressor units and the dust remover for communication and control.
An embodiment of the present application provides a drilling construction method for an electric power iron tower foundation. The method includes the steps described below.
A fixing and mounting region among a plurality of drilling platforms is determined according to a layout of the plurality of drilling platforms of the electric power iron tower foundation, and a moving route of a hydraulic drilling unit is determined according to distribution of a plurality of drilling hole positions on the plurality of drilling platforms.
A plurality of air compressor units and a dust remover are arranged in the fixing and mounting region, and the hydraulic drilling unit is provided on any one of the plurality of drilling platforms.
An operation bench is placed according to a sight line requirement, where the operation bench is separately communicatively connected to the hydraulic drilling unit, the plurality of air compressor units and the dust remover.
A dust collection cover is provided at an aperture position of a first one of the plurality of hole positions on the plurality of drilling platforms, and the dust collection cover is connected to the dust remover through an air duct.
Drilling is performed on the first one of the plurality of hole positions through the hydraulic drilling unit and drilling is completed on all the plurality of hole positions on the plurality of drilling platforms in sequence according to the moving route.
Whether it is a last one of the plurality of drilling platforms is determined, and based on a result that it is not the last one of the plurality of drilling platforms, the hydraulic drilling unit moves to a next one of the plurality of drilling platforms, and a step in which the dust collection cover is provided at the aperture position of the first one of the plurality of hole positions on the plurality of drilling platforms, and the dust collection cover is connected to the dust remover through the air duct is returned to, until drilling at all the plurality of hole positions on all the plurality of drilling platforms are completed.
100 drilling platform
200 hole position
300 fixing and mounting region
1 hydraulic drilling unit
101 track mechanism
102 bridge
1021 beam
1022 stringer
1023 reinforcing plate
1024 taper pin
1025 taper shoe
1026 first connector
103 swivel assembly
1031 fixed portion
1032 rotating portion
1033 locking mechanism
104 chassis
105 drill boom
106 adjustment lever
107 telescopic rod
108 drive mechanism
109 drill rod
110 hydraulic system module
111 power system module
2 air compressor unit
201 multi-way connector
2011 main input interface
2012 main output interface
2013 secondary input interface
2014 mixing chamber
2015 oil mist interface
2016 secondary input channel
202 compressed air conduit
203 air compressor module
204 air compressor power module
3 dust removal unit
301 dust collection cover
302 dust remover
303 air duct
4 operation bench
5 oil mist lubricator
6 three-way joint
601 air intake interface
7 support leg
In the description of the present application, terms “joined”, “connected” and “secured” are to be understood in a broad sense unless otherwise expressly specified and limited. For example, the term “connected” may refer to “securely connected”, “detachably connected” or “integrated”, may refer to “mechanically connected” or “electrically connected” or may refer to “connected directly”, “connected indirectly through an intermediary” or “connected inside two components” or “interaction relations between two components”. For those of ordinary skill in the art, specific meanings of the preceding terms in the present application may be construed according to specific circumstances.
In the present application, unless otherwise expressly specified and limited, when a first feature is described as “on” or “below” a second feature, the first feature and the second feature may be in direct contact or be in contact via another feature between the two features instead of being in direct contact. Moreover, when the first feature is described as “on”, “above” or “over” the second feature, the first feature is right on, above or over the second feature, or the first feature is obliquely on, above or over the second feature, or the first feature is simply at a higher level than the second feature. When the first feature is described as “under”, “below”, or “underneath” the second feature, the first feature is right under, below, or underneath the second feature, or the first feature is obliquely under, below, or underneath the second feature, or the first feature is simply at a lower level than the second feature.
In the description of the present application, it should be noted that orientations or position relations indicated by terms such as “above”, “below”, “right” and the like are based on orientations or position relations shown in the drawings. These orientations or position relations are intended only to facilitate and simplify the operation, and not to indicate or imply that a device or element referred to must have such specific orientations or must be configured or operated in such specific orientations. Thus, these orientations or position relations are not to be construed as limiting the present application. In addition, the terms “first” and “second” are used only to distinguish between descriptions and have no special meaning.
First, this embodiment provides a drilling device. The drilling device is a self-moving modular drilling device. As shown in
The self-moving modular drilling device provided in the present application is configured with the dust removal unit 3 so that the drilling construction site is free from dust pollution, thereby improving the working environment of staff. The dust remover 302 may be a cyclone dust remover and include a cyclone barrel mounted on a dust removal bracket, a filter element, a blower, a hydraulic motor and the like, where the hydraulic motor is configured to drive the blower.
The present application provides the self-moving modular drilling device. The drilling device is modularly arranged. The hydraulic drilling unit 1 separately disposed on the drilling platform 100 performs independent moving and drilling. The air compressor units 2 and the dust remover 302 are disposed among multiple drilling platforms 100. When the hydraulic drilling unit 1 moves and performs drilling, after positions of the air compressor units 2 and the dust remover 302 are reasonably arranged in advance, the air compressor units 2 and the dust remover 302 keep stationary, thereby reducing the number of unit modules that need to be moved and transferred for each time of drilling. Compared with the case where the whole drilling device is disposed on the drilling platform 100 in the related art, the modular drilling device in the present application is transported to mountainous areas or other drilling construction sites with a rock foundation and poor traffic in the form of modularization or split components, and modules after split and transportation are mounted on the site, arranged at pre-planned positions, and connected through the air duct 303 or a cable manner or a wireless manner so as to construct the drilling device so that quick assembly can be achieved, thereby greatly improving the drilling efficiency and reducing the manual labor intensity, especially accelerating the movement efficiency among the drilling platforms 100. In this embodiment, the hydraulic drilling unit 1 is connected to the air compressor units 2 through the compressed air conduit 202, and the dust collection cover 301 and the dust remover 302 in the dust removal unit 3 are connected through the air duct 303. The operation bench 4 is individually wired or wirelessly connected to the hydraulic drilling unit 1, the air compressor units 2 and the dust remover 302 separately, and positions are not limited so that each unit module can be individually hoisted and transported, and each unit module of the drilling device can be quickly disassembled and assembled at the construction site, thereby solving the problem that the drilling device is inconvenient to transport due to its large volume and weight.
As shown in
As shown in
In an embodiment, each air compressor unit 2 includes at least one air compressor module 203 and at least one air compressor power module 204, where the air compressor power module 204 is configured to drive the air compressor module 203 to generate and output the compressed air.
In some embodiments, the at least one air compressor module 203 and the at least one air compressor power module 204 in each air compressor unit 2 may be connected in a one-to-one correspondence, or one air compressor module 203 may be connected to at least two air compressor power modules 204. or one air compressor power module 204 may drive multiple air compressor modules 203 to work. To facilitate hoisting and transferring, in the first case, the air compressor module 203 and the air compressor power module 204 are separately fixedly mounted on two different fixed frames that are detachably connected. In an embodiment, a plug-in positioning mechanical locking connection manner is used between the two fixed frames. In the second and third cases, at least two air compressor power modules 204 are separately assembled and mounted on one fixed frarne, and multiple air compressor modules 203 are assembled and mounted on one fixed frame; after separately transported to the construction site, the fixed frames are assembled and mounted through corresponding driving objects, thereby improving the installation efficiency and hoisting efficiency. In an embodiment, generally, the total weight of each fixed frame does not exceed 200 KG, and hoisting members are separately provided at the tops of the fixed frames, so as to be better compatible with a variety of different hoisting manners, such as manual hoisting, livestock, cableway and/or small-sized rotor wing unmanned aerial vehicle handling. In an embodiment, the air compressor module 203 uses a screw air compressor, and the air compressor power module 204 uses a V-type double-cylinder diesel engine and a small-sized high-speed diesel engine as a prime mover so that the power efficiency is higher and the fuel safety is better, which is suitable for field forest operation and is not easy to cause mountain fire. During the drilling construction, multiple air compressor modules 203 are placed on a flat ground in the fixing and mounting region 300, arranged side by side, and connected in parallel. The number of air compressor modules 203 may be determined according to the drilling size and the drilling device power required for construction.
In an embodiment, the self-moving modular drilling device provided in the present application further includes an oil mist lubricator 5 and a three-way joint 6. A first port of the three-way joint 6 communicates with the multi-way connector 201, a second port of the three-way joint 6 communicates with an output end of the air compressor module 203, and a third port of the three-way joint 6 is used as an air intake interface 601. The oil mist lubricator 5 communicates between the air intake interface 601, and an oil mist interface 2015 that is disposed on the multi-way connector 201.
Referring to
One of the first mounting portion or the second mounting portion is provided with a taper pin 1024, and the other one of the first mounting portion or the second mounting portion is provided with a taper shoe 1025, where the taper pin 1024 and the taper shoe 1025 are separately provided with central connecting holes, the taper pin 1024 is inserted into the taper shoe 1025, and a first connecting member 1026 is mounted in the two central connecting holes.
In some embodiments, to enhance the strength of the bridge 102 and reduce the weight of a single split component, as shown in
In an embodiment, as shown in
In an embodiment, the drill boom assembly module includes a chassis 104, a drill boom 105, an adjustment rod 106, a telescopic rod 107 and a drive mechanism 108. The chassis 104 is fixedly connected to the swivel assembly 103 and rotatable with the swivel assembly 103. A first end of the drill boom 105 is a fixed end, a second end of the drill boom 105 is an adjustment end, the fixed end is hinged with the chassis 104, a top end of the adjustment rod 106 is hinged with the adjustment end, a bottom end of the adjustment rod 106 is slidably connected to the chassis 104, a top end of the telescopic rod 107 is hinged with the adjustment end, a bottom end of the telescopic rod 107 is hinged with the chassis 104, and the drive mechanism 108 can drive the telescopic rod 107 to move telescopically.
In conjunction with
In an embodiment, the hydraulic drive module is provided with at least three hydraulic output interfaces, where each hydraulic output interface is provided with a quick-plug joint, at least one hydraulic output interface is connected to the two track mechanisms 101 to drive the two track mechanisms 101 to move, at least one hydraulic output interface is connected to the drill boom assembly module to drive the drill hit connected to the drill boom 105 to perform drilling, and at least one hydraulic output interface is connected to the dust remover 302.
As shown in
In an embodiment, the swivel assembly 103 includes a fixed portion 1031, a rotating portion 1032 and a locking mechanism 1033, where the rotating portion 1032 is rotatably disposed on the fixed portion 1031, the locking mechanism 1033 is capable of unlocking or locking the rotating portion 1032 relative to the fixed portion 1031, the fixed portion 1031 is fixed on the bridge 102, and the rotating portion 1032 is fixedly connected to the chassis 104. At a ±180 rotational position of the chassis 104, the locking mechanism 1033 is configured to lock and unlock the position of the chassis 104 after the chassis 104 rotates into position.
In an embodiment, a swivel center of the swivel assembly 103 is arranged at a center of the bridge 102, the chassis 104 may be separated from the swivel assembly 103, and the swivel assembly 103 may drive the chassis 104 to rotate continuously by any angle. In the present embodiment, the fixed portion 1031 is fixed on the bridge 102, the rotating portion 1032 rotates relative to the fixed portion 1031, and the locking mechanism 1033 performs locking when rotating by ±180° and ±90°, thereby facilitating the alignment of the drill bit with the hole position 200, reducing the floor area to a certain extent, and reducing the workload of early excavation and leveling on the construction site. The locking mechanism 1033 can ensure the stability during drilling.
In an embodiment, the self-moving modular drilling device further includes a support mechanism. As shown in
To ensure that the hydraulic drilling unit 1 remains stable during drilling after moved into position, the chassis 104 is configured to be rectangular, and four adjustable support legs 7 are separately provided at four comers for supporting, positioning and leveling. After the modular drilling device is assembled in place at the construction site, the air compressor units 2 and the dust removal unit 3 no longer move, and only the hydraulic drilling unit 1 moves in sequence among positions of the drilling hole positions 200. After drilling is completed at one hole position 200, the drill impactor is retracted and disengaged from the dust collection cover 301. The support legs 7 are retracted, the tracks touch the ground to bear weight, the self-sealing quick-plug joint for driving the hydraulic pipeline of the dust remover 302 is temporarily disconnected, and the hydraulic drilling unit 1 is controlled by the remote control operation bench 4 to advance, retreat and turn. When the next construction hole position 200 is reached, the support legs 7 are lowered, the hydraulic pipeline of the dust remover 302 is reconnected after positioning and hole alignment, and drilling is started.
In some embodiments, four hole positions 200 are distributed in sequence on the drilling platform 100 and distributed at four angular positions of the rectangular drilling platform 100. The hydraulic drilling unit 1 is firstly suspended on the drilling platform 100 and moves to the 1# hole position 200 for drilling. At this time, the support legs 7 are supported on the drilling platform 100. After drilling, the support legs 7 are retracted, the swivel assembly 3 rotates by 180° and is locked. The track mechanism 101 retreats to the 2# hole position 200 at the diagonal position for drilling. After drilling, the support legs 7 are retracted, the track mechanism 101 advances to a center of the drilling platform 100, the support legs 7 support the drilling platform 100, the track mechanism 101 stops after rotating by 90° relative to the swivel assembly 3, the support legs 7 are retracted, and the track mechanism 101 moves to the 3# hole position 200 for drilling. After drilling, the support legs are retracted, and the track mechanism 101 retreats to the 4# hole position 200 for drilling. In the preceding drilling process, through the cooperation between the support legs 7 and the track mechanisms 101, the rotation of the track mechanisms 101 and the rotation of the chassis 104 above the swivel assembly 3 can be achieved separately, thereby solving the problems of large turning area and difficult turning of the track mechanisms 101.
Based on the self-moving modular drilling device provided in embodiment one, this embodiment provides a drilling construction method for an electric power iron tower foundation. In conjunction with flows shown in
In S1, a fixing and mounting region 300 among multiple drilling platforms 100 is determined according to a layout of the multiple drilling platforms 100 of the electric power iron tower foundation and a moving route of a hydraulic drilling unit 1 is determined according to distribution of multiple drilling hole positions 200 on the multiple drilling platforms 100.
In S2, multiple air compressor units 2 and a dust remover 302 are arranged in the fixing and mounting region 300 and the hydraulic drilling unit 1 is provided on any one of the multiple drilling platforms 100; and an operation bench 4 is placed according to a sight line requirement, where the operation bench 4 is communicatively connected to the hydraulic drilling unit 1, the multiple air compressor units 2 and the dust remover 302.
In S3; a dust collection cover 301 is provided at an aperture position of a first one of the multiple hole positions 200 on the multiple drilling platforms 100 and the dust collection cover 301 is connected to the dust remover 302 through an air duct 303.
In S4, drilling is performed at the first one of the multiple hole positions 200 through the hydraulic drilling unit 1 and drilling at all the multiple hole positions 200 on the multiple drilling platforms 100 is completed in sequence according to the moving route.
In S5, whether it is a last one of the multiple drilling platforms is determined, based on a result that it is not the last one of the multiple drilling platforms, the hydraulic drilling unit 1 moves to a next one of the multiple drilling platforms 100, S3 is performed until drilling at all the hole positions 200 on all the drilling platforms 100 is completed, and based on a result that it is the last one of the multiple drilling platforms, drilling at the hole positions on all the drilling platforms is completed.
In an embodiment, in the preceding drilling construction method for an electric power iron tower foundation, the modular drilling device is used and reasonably arranged on the construction site, and only the hydraulic drilling unit 1 is disposed on the drilling platform 100 to perform self-moving and drilling so that the drilling construction flexibility is improved, and the drilling platform 100 is not limited by the drilling device and may be built according to actual requirements, thereby saving construction costs. The remaining modules, such as the dust remover and multiple air compressor units 2, do not move during the drilling construction, and the operation bench 4 may be arranged and moved according to requirements, thereby not only reducing the labor intensity of manual transportation of the device, but also improving the construction efficiency.
According to the preceding moving route, the swivel assembly 103 only needs two rotations of 180°, that is, a forward rotation and a reverse rotation, the number of rotations is small, and locking positioning is performed after the rotations, thereby improving the construction safety and reli ability, and the operation is convenient and easy to control, thereby improving the drilling construction efficiency and reducing the labor intensity of workers.
In an embodiment, as shown in
In an embodiment, the operation bench 4 is arranged between the drilling platform 100 where the hydraulic drilling unit 1 is located and the fixing and mounting region 300. It is convenient for the operation bench 4 to take into account both a working state of the hydraulic drilling unit 1 and working states of the dust remover 302 and the air compressor units 2, thereby facilitating operation control, keeping an operator away from device noise, and facilitating the improvement of a working environment of the operator.
In an embodiment, when the hydraulic drilling unit 1 moves, the hydraulic drilling unit 1 is disconnected from the air compressor units 2 and the dust remover 302, thereby improving the construction safety.
The support legs 7 provided in the preceding embodiment are height-adjustable. When the track mechanisms 101 move, the support legs 7 are in a retracted state and capable of rotating synchronously with the rotating portion 1032; and when the support legs 7 are in a supporting state, the track mechanisms 101 are rotatable with the bridge 102 relative to the rotating portion 1032 so as to achieve turning of the track mechanisms 101.
In an embodiment, the turning of the track mechanisms 101 generally requires a relatively large space, and based on the limited space of the drilling platform 100, in this embodiment, the cooperation between the support legs 7 and the swivel assembly 103 can achieve the rotation of the track mechanisms 101 so as to achieve the turning of the track mechanisms 101, thereby reducing the torque damage of the track mechanisms 101 and improving the turning efficiency. Specifically, during implementation, it is necessary for the support legs 7 and the track mechanisms 101 to be alternately supported onto the ground and achieve the rotation and locking relative to the fixing portion 1031 and the rotating portion 1032 in the swivel assembly 103, and accordingly, at each rotational angular position, the corresponding locking mechanism 1033 is provided to improve the safe operability of the device.
In the preceding embodiments, modules are detachably connected to each other so that quick disassembly and assembly can be achieved. Each individual module is fixed through a frame on which a hoisting member is provided for hoisting. The detachable connection manner specifically includes that the bridge 102 is detachably connected to the track mechanism 101, the drill boom assembly module and the hydraulic drive module are detachably connected to the chassis 104, the chassis 104 is detachably connected to the rotating portion 1032, the dust collection cover 301 is detachably connected to the dust remover 302 through the air duct 303, and multiple air compressor units 2 are detachably connected to the hydraulic drilling unit 1 through the compressed air conduit 202. Specifically, for the detachable connection manner, reference is made to embodiment one.
Based on the self-moving modular drilling device and the drilling construction method provided above, this embodiment provides a construction method for a drilling platform. A drilling process of an anchor rod foundation in the related art is: the drilling platform 100 is excavated firstly, and then the anchor rod drilling construction (including lofting, positioning and drilling) is performed on the drilling platform 100; the anchor rod construction operation is started before the excavation on the drilling platform 100; the drilling platform 100 in mountainous areas needs to be excavated manually, and when large rocks are encountered, the excavation progress is slow and the working efficiency is reduced. After the excavation on the drilling platform 100 is completed, the space of the drilling platform 100 is small, most of the drilling machinery cannot perform construction in the small space, the common down-the-hole drilling machine is difficult to set up, and the hole position adjustment takes a long time.
Based on the self-moving modular drilling device provided in the present application, S4 further includes the construction of the drilling platform, where the construction of the drilling platform includes the steps described below.
Firstly, drilling protection is performed for the anchor rod drilling.
Then, lofting and positioning are performed on the drilling platforms 100 according to a drilling position of an anchor rod.
The hydraulic drilling unit 1 performs drilling construction of the drilling platforms 100, and finally excavation is performed manually so as to form the drilling platforms 100.
In an embodiment, in contrast to a construction method for an anchor rod foundation in the related art, in the present application, after the anchor rod drilling construction is performed for the drilling platform 100, the drilling on the drilling platform 100 is performed, and then the excavation is performed manually so that the mechanization rate is high, the construction efficiency is high, the anchor rod drilling construction positioning is easy, and the drilling accuracy is high. The drilling protection is to protect the drilling hole with a steel pipe or a polyvinyl chloride (PVC) pipe. In the anchor rod drilling construction of the drilling platform 100, a drilling direction is shown by a direction of an arrow in
Number | Date | Country | Kind |
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202110448905.5 | Apr 2021 | CN | national |
202110450374.3 | Apr 2021 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2022/100743 | 6/23/2022 | WO |