阅读说明：本技术 基于bim的穿溶洞处锚索的施工方法 (BIM-based construction method for anchor cable penetrating karst cave ) 是由 林细桃 莫凡 彭伯伦 张祖宏 郭东超 钟真盛 卢世维 于 2021-08-03 设计创作，主要内容包括：本发明涉及一种基于BIM的穿溶洞处锚索的施工方法,包括如下步骤：创建施工区域的三维地质模型；获取锚索的布设方案,将所获取的锚索的布设方案组合在所述三维地质模型中,并找出需穿设所述三维地质模型中的溶洞的锚索；对需穿设溶洞的锚索进行加强处理以提高锚索的锚固力。本发明通过创建三维地质模型而精确的模拟地质中溶洞的位置,将三维地质模型与锚索的布设方案相组合,快速识别遇溶洞的锚索并指导现场施工,能够提前采取防范措施,提高钻孔施工的成型效率,减少重新钻孔施工的现象,从而确保施工进度,还减少了对地层的扰动,避免了安全事故的发生。(The invention relates to a construction method of an anchor cable at a karst cave penetration position based on BIM, which comprises the following steps: creating a three-dimensional geological model of a construction area; acquiring a layout scheme of the anchor cables, combining the acquired layout scheme of the anchor cables in the three-dimensional geological model, and finding out the anchor cables needing to penetrate through a karst cave in the three-dimensional geological model; and (4) reinforcing the anchor cable needing to penetrate through the karst cave so as to improve the anchoring force of the anchor cable. The invention accurately simulates the position of the karst cave in the geology by establishing the three-dimensional geological model, combines the three-dimensional geological model with the layout scheme of the anchor cables, quickly identifies the anchor cables meeting the karst cave and guides the site construction, can take precautionary measures in advance, improves the forming efficiency of the drilling construction, reduces the phenomenon of re-drilling construction, thereby ensuring the construction progress, also reducing the disturbance to the stratum and avoiding the occurrence of safety accidents.)

1. A construction method of an anchor cable at a karst cave penetration position based on BIM is characterized by comprising the following steps:

creating a three-dimensional geological model of a construction area;

acquiring a layout scheme of the anchor cables, combining the acquired layout scheme of the anchor cables in the three-dimensional geological model, and finding out the anchor cables needing to penetrate through a karst cave in the three-dimensional geological model; and

and (4) reinforcing the anchor cable needing to penetrate through the karst cave so as to improve the anchoring force of the anchor cable.

2. The BIM-based construction method of the anchor cable at the karst cave penetration position, according to claim 1, wherein the step of reinforcing the anchor cable needing to be subjected to the karst cave penetration comprises the following steps:

and (4) lengthening the anchor cable needing to be penetrated with the karst cave so as to enable the end part of the anchor cable to be partially anchored into the rock stratum.

3. The BIM-based construction method of the anchor cable at the karst cave penetration position, according to claim 1, wherein the step of reinforcing the anchor cable needing to be subjected to the karst cave penetration comprises the following steps:

configuring a steel sleeve for an anchor cable needing to penetrate through the karst cave;

during drilling construction, a steel sleeve follow-up method is used for forming holes;

and after hole forming, inserting the steel strand for anchor cable construction into the steel sleeve, and grouting into the steel sleeve to complete the construction of the anchor cable.

4. The BIM-based construction method of the anchor cable at the karst cave penetration position, according to claim 1, wherein after the anchor cable needing to be penetrated by the karst cave is found out, the size of the karst cave is judged:

if the size of the karst cave is smaller than a lower limit value, adjusting the setting position and/or the setting direction of the anchor cable to enable the anchor cable to avoid the corresponding karst cave;

and if the size of the karst cave is larger than a high limit value, filling the karst cave.

5. The BIM-based construction method of the anchor cable at the karst cave penetration position, according to claim 1, wherein when the anchor cable is constructed, a wire erecting ring is provided, and a bayonet matched with a steel strand for construction of the anchor cable is arranged on the wire erecting ring;

clamping the end part of the steel strand into the corresponding bayonet;

fixedly connecting the overhead line ring to a tray through a supporting leg;

and pushing the tray by using a drill rod to send the stringing ring and the steel strand into a drill hole.

6. The BIM-based construction method of the anchor cable at the karst cave penetration position, according to claim 5, wherein after the steel strand is fed into the corresponding drill hole, grouting is performed into the drill hole to anchor the steel strand, and the grouting is performed in two times, wherein the first time is normal pressure grouting, and the second time is high pressure grouting.

7. The BIM-based construction method of the anchor cable at the karst cave penetration position, according to claim 1, wherein a steel sleeve is arranged for the anchor cable needing karst cave penetration, and a plurality of grout spraying holes are arranged on the steel sleeve, and the plurality of grout spraying holes are spirally arranged on the outer surface of the steel sleeve.

8. The BIM-based construction method of anchor cables at karst caves, according to claim 1, wherein the step of creating a three-dimensional geological model of the construction area comprises:

acquiring geological data;

drawing a horizontal stratum section diagram and a vertical stratum section diagram by using the geological data;

and importing the drawn stratum transverse section diagram and the drawn stratum longitudinal section diagram into a Revit platform, and generating a three-dimensional geological model by using the Revit platform.

Technical Field

The invention relates to the technical field of anchor cable construction, in particular to a construction method of an anchor cable at a karst cave penetration position based on BMI.

Background

Due to the characteristics of safety and economy, the pile-anchor supporting structure is widely applied to deep foundation pit supporting engineering, and in southern karst landforms, karst development and local karst cave, crack, broken zone and fault exist, so that the anchor cable hole forming often has the characteristics of difficult drilling such as hole blocking, hole collapse or slurry leakage, and the like, and the anchor cable construction difficulty is high and the efficiency is low.

In the traditional anchor cable construction, after an anchoring drilling machine drills into a hole, an anchor rod of the anchoring drilling machine is withdrawn, and then the anchor cable is installed, but the construction method cannot be applied to a complex karst area. Because the half-filling karst cave and the full-filling karst cave contain the flow-plastic clay, after the anchor rod of the anchoring drilling machine is withdrawn, the flow-plastic clay rapidly flows into the drilled hole, and the drilled hole can not be formed.

Southern karsh features show a karst form with irregular fluctuation in three-dimensional space, the existing anchor cable layout scheme is designed by a design unit, but the design unit is carried out based on geological exploration data during design, namely, the karst cave ratio under the geological condition is estimated based on analysis of the geological exploration data, and then the position and the angle of the laid anchor cable are designed to ensure the reinforcing and supporting strength of the anchor cable. Therefore, during site construction, the anchor cable is very easy to form a drilled hole due to the fact that the anchor cable is subjected to karst cave during drilling construction, so that the anchor cable is newly constructed beside the designed position, the frequent hole collapse phenomenon influences the construction progress, the stratum is greatly disturbed, and safety accidents are easily caused.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, provides a construction method for penetrating an anchor cable at a karst cave based on BMI, and solves the problems that anchor cable drilling cannot be formed easily and drilling construction is carried out again to influence the construction progress, disturbance on the stratum is large, safety accidents are easily caused and the like during construction according to the existing anchor cable laying scheme.

The technical scheme for realizing the purpose is as follows:

the invention provides a construction method of an anchor cable at a karst cave penetration position based on BIM, which comprises the following steps:

creating a three-dimensional geological model of a construction area;

acquiring a layout scheme of the anchor cables, combining the acquired layout scheme of the anchor cables in the three-dimensional geological model, and finding out the anchor cables needing to penetrate through a karst cave in the three-dimensional geological model; and

and (4) reinforcing the anchor cable needing to penetrate through the karst cave so as to improve the anchoring force of the anchor cable.

The method accurately simulates the position of the karst cave in the geology by creating the three-dimensional geological model, combines the three-dimensional geological model with the layout scheme of the anchor cables, further finds out the anchor cables which need to penetrate through the karst cave in the three-dimensional geological model and guides the construction, knows the distribution of the karst cave when the anchor cables are drilled, can take precautionary measures in advance, improves the forming efficiency of drilling construction, reduces the phenomenon of re-drilling construction, ensures the construction progress, reduces the disturbance to the stratum and avoids the occurrence of safety accidents. The anchor cable which needs to be penetrated through the karst cave is further subjected to strengthening treatment, and the anchoring force of the anchor cable is improved, so that the anchor cable which is penetrated through the karst cave can have strong anchoring force, and the supporting strength and the supporting effect of the anchor cable are improved.

The construction method of the anchor cable at the karst cave penetration position based on the BIM is further improved in that the step of strengthening the anchor cable needing to penetrate the karst cave comprises the following steps:

and (4) lengthening the anchor cable needing to be penetrated with the karst cave so as to enable the end part of the anchor cable to be partially anchored into the rock stratum.

The construction method of the anchor cable at the karst cave penetration position based on the BIM is further improved in that the step of strengthening the anchor cable needing to penetrate the karst cave comprises the following steps:

configuring a steel sleeve for an anchor cable needing to penetrate through the karst cave;

during drilling construction, a steel sleeve follow-up method is used for forming holes;

and after hole forming, inserting the steel strand for anchor cable construction into the steel sleeve, and grouting into the steel sleeve to complete the construction of the anchor cable.

The construction method of the anchor cable at the karst cave penetrating position based on the BIM is further improved in that after the anchor cable needing to penetrate the karst cave is found out, the size of the karst cave is judged:

if the size of the karst cave is smaller than a lower limit value, adjusting the setting position and/or the setting direction of the anchor cable to enable the anchor cable to avoid the corresponding karst cave;

and if the size of the karst cave is larger than a high limit value, filling the karst cave.

The construction method of the anchor cable at the karst cave penetration position based on the BIM is further improved in that when the anchor cable is constructed, a wire erecting ring is provided, and a bayonet matched with a steel strand for anchor cable construction is arranged on the wire erecting ring;

clamping the end part of the steel strand into the corresponding bayonet;

fixedly connecting the overhead line ring to a tray through a supporting leg;

and pushing the tray by using a drill rod to send the stringing ring and the steel strand into a drill hole.

The BIM-based construction method of the anchor cable at the karst cave penetration position is further improved in that after the steel strand is sent into the corresponding drill hole, grouting is performed in two times, wherein normal pressure grouting is adopted for the first time, and high pressure grouting is adopted for the second time, so as to anchor the anchor cable.

The BIM-based construction method of the anchor cable at the karst cave penetration position is further improved in that a steel sleeve is configured for the anchor cable needing to be penetrated with the karst cave, a plurality of grout spraying holes are formed in the steel sleeve, and the plurality of grout spraying holes are spirally arranged on the outer surface of the steel sleeve.

The construction method of the anchor cable at the karst cave penetration position based on the BIM is further improved in that the step of creating the three-dimensional geological model of the construction area comprises the following steps:

acquiring geological data;

drawing a horizontal stratum section diagram and a vertical stratum section diagram by using the geological data;

and importing the drawn stratum transverse section diagram and the drawn stratum longitudinal section diagram into a Revit platform, and generating a three-dimensional geological model by using the Revit platform.

Drawings

FIG. 1 is a flow chart of a construction method of an anchor cable at a karst cave penetration position based on BIM.

FIG. 2 is a cross sectional view of the anchor cable layout scheme and the three-dimensional geological model in the BIM-based karst cave penetration anchor cable construction method.

FIG. 3 is a cross-sectional view of an anchor cable in the construction method of the anchor cable at the karst cave penetration position based on BIM.

FIG. 4 is a schematic structural diagram of the anchor cable after the connection of the wire loop and the anchor cable in the construction method of the anchor cable at the karst cave penetration position based on the BIM.

FIG. 5 is a schematic structural diagram of a drilling pushing tray and a stringing ring in the construction method of the anchor cable at the karst cave based on BIM.

Detailed Description

The invention is further described with reference to the following figures and specific examples.

Referring to fig. 1, the invention provides a construction method of an anchor cable at a karst cave penetration position based on BIM, which is used for rapidly identifying the anchor cable encountering the karst cave to guide field construction, and solves the problems that in the prior art, when a hole collapse occurs, the karst cave is known to occur and then the hole needs to be drilled again, and the collapsed hole disturbs the stratum to easily cause potential safety hazards. The construction method provided by the invention creates a three-dimensional geological model of the karst area, and can perform visual analysis and accurate prejudgment on karst caves, cracks, broken zones and faults, so that the site construction of the anchor cable is effectively guided. The construction method of the invention carries out reinforcement treatment on the anchor cable needing to be penetrated with the karst cave, improves the anchoring force of the anchor cable, and further improves the support strength and the support effect of the anchor cable. The construction method of the anchor cable at the karst cave penetration position based on the BIM is described below with reference to the accompanying drawings.

Referring to fig. 1, a construction method of an anchor cable at a karst cave penetration position based on BIM is shown. The construction method of the anchor cable at the karst cave penetration position based on the BIM of the invention is explained with reference to FIG. 1.

As shown in FIG. 1, the construction method of the anchor cable at the karst cave penetration position based on the BIM comprises the following steps:

executing the step S101, and creating a three-dimensional geological model of the construction area; then, step S102 is executed;

executing the step S102, obtaining a layout scheme of the anchor cables, combining the obtained layout scheme of the anchor cables in the three-dimensional geological model, and finding out the anchor cables needing to penetrate through the karst caves in the three-dimensional geological model; then, step S103 is executed;

and step S103, reinforcing the anchor cable needing to be penetrated with the karst cave so as to improve the anchoring force of the anchor cable.

The method and the device provided by the invention have the advantages that the three-dimensional geological model is created for the construction area, the geological condition of the construction area is accurately simulated, the position and the size of the karst cave can be quickly identified, the three-dimensional geological model and the layout scheme of the anchor cable are combined, the anchor cable needing to penetrate through the karst cave can be quickly obtained, the anchor cable is subjected to reinforcement treatment to improve the anchoring force of the anchor cable, the anchor cable needing to penetrate through the karst cave can be known in advance to guide the site construction, the hole collapse phenomenon during the drilling of the anchor cable can be avoided, the anchor cable can be formed at one time during the construction, and the construction efficiency is improved.

In a specific embodiment of the present invention, the step of performing reinforcement processing on the anchor cable to be drilled with the karst cave includes:

and (4) lengthening the anchor cable needing to be penetrated with the karst cave so as to enable the end part of the anchor cable to be partially anchored into the rock stratum.

As shown in fig. 2, the end portions of two anchor cables 21 are located at the bottom of the karst cave 10, the two anchor cables 21 need to pass through the karst cave 10 during construction, if construction is performed according to the original anchor cable layout scheme, the existence of the karst cave 10 makes the anchoring force at the end portions of the anchor cables 21 weaker, and when the stratum changes, the anchor cables 21 cannot provide firm support, so that potential safety hazards are easily generated, and the length of the anchor cables 21 needs to be increased for the anchor cables 21 at the end portions of the anchor cables 21 to be anchored into the rock stratum more, so as to improve the anchoring force of the anchor cables. Preferably, as shown in fig. 3, the anchor cable 21 includes a free section located at the upper portion and an anchoring section located at the lower portion, the free section and the anchoring section at the normal soil layer are determined according to a layout scheme, the length of the free section is designed to be 7 meters, the length of the anchoring section is 13 meters, when the anchor cable 21 is lengthened, the length of the portion of the anchor cable 21 located in the karst cave is obtained according to the three-dimensional geological model, and then the lengthened length of the anchor cable 21 is set according to the length.

In a specific embodiment of the present invention, the step of performing reinforcement processing on the anchor cable to be drilled with the karst cave includes:

as shown in fig. 3, a steel sleeve 22 is configured for the anchor cable needing to be provided with the karst cave;

during drilling construction, holes are formed by utilizing a steel sleeve 22 follow-up method;

after the hole is formed, the steel strand 211 for anchor cable construction is inserted into the steel sleeve 22, and grouting is performed into the steel sleeve 22 to complete the construction of the anchor cable.

The constructed anchor cable 21 and the steel sleeve 22 are anchored in the soil body together, and the arrangement of the steel sleeve 22 improves the hole forming rate of drilling construction, prevents hole collapse and ensures the efficiency of anchor cable construction. The steel sleeve 22 also enhances the anchoring force of the anchor cable 21 and improves the strength of the supporting structure.

Furthermore, the drilling construction adopts a water-working steel sleeve follow-up hole forming process, a steel sleeve 22 is arranged on the outer side of a drill rod during the construction, a hole is formed in the steel sleeve 22, the drilled mud is washed by water and then is cleared, the steel sleeve with the hole is fixed in the drill hole after the hole is formed, the drill rod is withdrawn, a steel strand is sent into the steel sleeve, and then grouting and anchoring are carried out, so that the construction of the anchor cable is completed. The whole anchor cable is constructed in the karst cave: drilling, deslagging, hole forming, steel strand laying and grouting, wherein the whole process is completed at one time, hole collapse can be prevented, and residual soil is not left. When the drilling construction meets karst caves, cracks, broken zones and faults, the steel sleeve is utilized to protect the wall, hole collapse can be effectively avoided, and the hole forming efficiency is greatly improved. And by adopting the water operation construction process, after the drill rod is withdrawn, the water operation slurry retaining wall is still arranged, and the problem that the holes cannot be formed by the flowing plastic clay in the karst cave can be solved by combining the steel sleeve retaining wall.

Further, as shown in fig. 4 and 5, when constructing the anchor cable, a wire loop 23 is provided, and a bayonet matched with the steel strand 211 for constructing the anchor cable is provided on the wire loop 23; the end part of the steel strand 211 is clamped into the bayonet; then the overhead wire ring 23 is fixedly connected to a tray 25 through the supporting leg 24, and the drill rod 32 pushes the tray 25 to send the overhead wire ring 23 and the steel strand 211 into the drilled hole. An anchor rope 21 includes a plurality of steel strand wires 211, for ensureing transferring smoothly of steel strand wires 211, set up overhead wire ring 23, utilize overhead wire ring 23 and many steel strand wires 211 fixed connection, overhead wire ring 23 plays fixed and guide effect to steel strand wires 211, can let smooth the transferring of steel strand wires 211 in the drilling hole, the in-process of transferring has realized the accurate location of steel strand wires, directional propulsion, ensure the installation of steel strand wires and the construction one shot forming of anchor rope, the efficiency of construction of anchor rope is improved.

Preferably, the stringing ring 23 is an annular plate, a through hole is formed in the middle of the stringing ring, the through hole in the middle of the stringing ring is used for installing grouting pipes so as to facilitate subsequent grouting construction, a plurality of inward sunken bayonets are arranged on the edge of the annular plate, steel strands are clamped at the corresponding bayonets, one bayonets are clamped with the other grouting pipe, and two grouting pipes are arranged to achieve batch grouting. When a bayonet fixing traction rope 26 is selected, the traction rope 26 is used for positioning the stringing ring 23, and the stringing ring 23 is ensured to be in a stable state in the process of lowering.

And further, after the steel strand is conveyed into the corresponding drill hole, grouting is performed in the drill hole to anchor the steel strand, and grouting is performed in two times, wherein normal pressure grouting is adopted for the first time, and high pressure grouting is adopted for the second time. The grouting pipe adopted by normal pressure grouting is a grouting pipe clamped at a bayonet, the grouting pipe is arranged close to the inner wall of the steel sleeve, the normal pressure grouting allows the grout to fill the steel sleeve, the high pressure grouting adopts the grouting pipe arranged at a through hole at the middle part of the stringing ring, the high pressure grouting presses the grout into the grouting pipe at set pressure, the grout extrudes the surrounding grout outwards under the action of the set pressure, the steel sleeve is provided with holes, the grout is sprayed outwards from the holes at high pressure, the sprayed grout impacts the soil body and concretes the soil body around the steel sleeve, and part of the grout fills the solution cavity, cracks, broken zones and broken layers, so that the anchoring force of the anchor cable is greatly improved, and the construction safety is guaranteed.

Preferably, the steel sleeve 22 is configured for the anchor cable to be inserted into the karst cave, and a plurality of grout spraying holes are formed in the steel sleeve 22, and the plurality of grout spraying holes are spirally arranged on the outer surface of the steel sleeve. By utilizing the slurry spraying holes which are distributed spirally, slurry sprayed from the slurry spraying holes is also ejected outwards spirally, high-pressure splitting grouting is formed, and the anchoring force is improved. And the grout spraying holes which are spirally arranged enable the directions of all the grout spraying holes to be different, so that the condition that the soil body outside the steel sleeve enters the steel sleeve to influence the grouting construction inside the steel sleeve can be avoided.

In a specific embodiment of the present invention, after finding out the anchor cable that needs to be penetrated with the cavern, the size of the cavern is determined:

if the size of the karst cave is smaller than a lower limit value, adjusting the setting position and/or the setting direction of the anchor cable to enable the anchor cable to avoid the corresponding karst cave;

if the size of the karst cave is larger than a high limit value, filling the karst cave.

After the layout scheme of the anchor cable is combined with the three-dimensional geological model, the position relation between the karst caves in the anchor cable and the three-dimensional geological model can be rapidly identified, the specific shape and the size of the karst cave are displayed in the three-dimensional geological model, when the size of the karst cave is relatively small, the anchor cable can be adjusted to the position avoiding the karst cave, when the size of the karst cave is relatively large, the position of the karst cave difficult to avoid by the anchor cable is arranged, the anchor cable needs to be reinforced, when the size of the karst cave is relatively large, the firmness of the anchor cable is influenced to a certain degree, in order to ensure the construction safety, the karst cave with relatively large size is filled, grouting is performed into the karst cave to compact the karst cave, the stability of strata and the anchor cable is further improved, and the supporting strength is ensured. Preferably, the lower limit value and the upper limit value in the invention are selected according to the sectional area of the designed anchor cable according to a certain proportion, and when the size of the karst cave is between the lower limit value and the upper limit value, the karst cave can be half-filled, that is, the filled concrete is half of the karst cave. Preferably, the size of the cavern is the cross-sectional area of the cavern.

The size of the karst cave is judged, the type of the karst cave can be identified, such as a clustered karst cave, a bead string type karst cave and an ultra-long type karst cave, and corresponding processing modes can be provided for different types of the karst caves so as to select targeted measures for construction.

In one embodiment of the present invention, the step of creating a three-dimensional geological model of the construction area comprises:

acquiring geological data;

drawing a horizontal stratum section diagram and a longitudinal stratum section diagram by using geological data;

and importing the drawn stratum transverse section diagram and the drawn stratum longitudinal section diagram into a Revit platform, and generating a three-dimensional geological model by using the Revit platform.

The layout scheme of the anchor cables comes from a design unit, and the design unit provides an anchor cable layout model created by using the Revit platform, which is equivalent to a three-dimensional model of the anchor cables. The arrangement model and the three-dimensional geological model of the anchor cable can be integrated in the Revit platform, the implementation is simple and convenient, and the position relation between the anchor cable and the karst cave can be quickly identified.

The geological data is acquired by adopting two modes of drilling and geophysical prospecting, the geological data acquired by the drilling mode is relatively accurate, the data acquired by the geophysical prospecting mode is comprehensive, and the horizontal section diagram and the longitudinal section diagram of the stratum can be perfected by combining the drilling mode and the geophysical prospecting mode, so that the accuracy of the created three-dimensional geological model is improved. Preferably, the geological data of the drill hole is used for drawing a stratum transverse section diagram and a stratum longitudinal section diagram, data which can be verified with the geological data of the drill hole is found out from the geological data of geophysical prospecting, the stratum transverse section diagram and the stratum longitudinal section diagram are corrected by using the data, and then the stratum transverse section diagram and the stratum longitudinal section diagram are used for building the three-dimensional geological model after correction.

The geophysical prospecting mode comprises one or more of a wave velocity prospecting mode, a resistivity prospecting mode, a ground temperature testing prospecting mode and an electrical prospecting method.

The number of the drilled holes is limited, the obtained geological data have partial deletion, and the geophysical prospecting mode can well supplement the deleted part, so that comprehensive geological data of a construction area are obtained, and a three-dimensional geological model with accuracy can be built.

Further, after the stratum transverse section diagram and the stratum longitudinal section diagram are corrected, karst caves, cracks, fault fracture zones and boundary lines in the stratum transverse section diagram and the stratum longitudinal section diagram are refined. And refining the spatial information, boundary lines, trends and development trends of karst caves, fractures and fault fracture zones in the horizontal cross-section diagram and the longitudinal cross-section diagram of the stratum by using geological data obtained by geophysical prospecting, so that the precision of the horizontal cross-section diagram and the longitudinal cross-section diagram of the stratum is improved, and the precision of a three-dimensional geological model can be further improved.

And when the stratum transverse section diagram and the stratum longitudinal section diagram are drawn, the CAD is adopted for drawing so as to conveniently adjust, correct and refine the boundary line.

And further, based on a Revit platform, establishing a volume family, respectively importing the drawn horizontal section diagram and the drawn longitudinal section diagram of the stratum, automatically picking up boundary vector lines of the horizontal section diagram and the longitudinal section diagram of the stratum by the Revit platform, and applying a volume stretching function to generate a three-dimensional geological model.

And then, correcting and refining the karst cave in the generated three-dimensional address model by using a Revit platform, so that the accuracy of the karst cave position can be improved. Comprehensive geological data of a construction area can be obtained by utilizing geophysical prospecting geological data and drilling geological data, boundary line parameters of karst caves, including complete plane distribution and elevation distribution parameters of the karst caves, are contained in the comprehensive geological data, and the boundary line of a karst cave model in a three-dimensional geological model is corrected and refined by utilizing the complete plane distribution and elevation distribution parameters, so that the position of the karst caves is truly reflected, and an accurate guide basis is provided for anchor cable construction.

The construction method of the anchor cable at the karst cave penetration position based on the BIM has the following beneficial effects:

and (4) rapidly identifying the anchor cable meeting the karst cave and guiding field construction. The three-dimensional geological model is used for accurately pre-judging the position of the karst cave, the nearby anchor cables are rapidly identified, and the success rate and the construction efficiency of anchor cable construction can be improved when the site construction is guided.

The construction porosity of the karst geological anchor cable is greatly improved, and the anchor cable is formed in one step. Contain the karst water in the solution cavity, adopt water works and steel casing pipe to follow up the pore-forming, can prevent during the construction hole that collapses, insert the steel strand wires after the drilling rod withdraws from, carry out the secondary slip casting for the anchor rope construction can one shot forming, and is efficient.

The invention solves the difficult problem that the cluster karst cave, the bead string type karst cave and the ultra-long type karst cave anchor cable cannot be installed, judges the size of the karst cave, fills the karst cave with larger size, improves the anchoring force of the anchor cable, ensures the supporting strength and ensures the construction safety.

Effectively promote karst geology anchor rope tension, safe and reliable. When the anchor rope that is located the solution cavity department is under construction, set up the steel casing, still lengthened the length of anchor rope for the anchor rope can have partial anchor to go into in the stratum, has improved the anchoring power of anchor rope, has promoted the withdrawal resistance of anchor rope.

While the present invention has been described in detail and with reference to the embodiments thereof as illustrated in the accompanying drawings, it will be apparent to one skilled in the art that various changes and modifications can be made therein. Therefore, certain details of the embodiments are not to be interpreted as limiting, and the scope of the invention is to be determined by the appended claims.