KR20000020172A - Quarrying method of long wall type multiple stairway - Google Patents

Abstract

PURPOSE: A quarrying method of long wall type multiple stairway is provided to maintain quarrying work scene in a large number in one stony mountain developing scene and to minimize a time gap generated while quarrying. CONSTITUTION: A quarrying method contains the steps of: removing a top soil layer and a weathering layer to be appropriate to quarry a rock phase after checking a vertical and a horizontal joint of the rock phase of granite class and constituting the shape of the rock phase to be quarried according to the vertical and horizontal joint checked in a first step. Further, a granite phase constituted in a second step is quarried to be an objective size. This method is proceeding a work by lengthening continuously along a vertical joint direction to maximally use a free face formed once as proceeding the work to fit a frost protection joint of the base phase of granite class by investigating ground to be quarried by drilling as not quarrying granites in reference to naked base rock.

Description

Barrier Multi-Stage Quarrying

The present invention relates to a method for quarrying stone used as a building, civil engineering, and sculpture material. In particular, the present invention utilizes the shape of the rock joint and the rock which are the characteristics of the granite rock which is the object of quarrying. In addition, the present invention relates to a barrier-type multi-stage quarrying method that can minimize the time gap that can occur during the process of quarrying and maintain a large number of quarry workshops at a single quarries development site.

The conventional method of quarrying granite rocks is to find out the outcrops that are exposed to nature mainly as shown in Figs. 1 and 2 when quarrying granite rocks. After forming the free surface through the Jet Burner (1), and then drilling (2) for blasting on the rock, artificially free through the blasting work Quarrying is carried out by increasing the number of faces.

That is to say, mainly to make free surface through the burner work of outburst rock, and to carry out the drilling work (2), it is blasted to quarry stone of the desired size.

Referring to the above-described conventional granite quarrying step by step, the step of removing the topsoil layer and the step of removing the weathering layer, forming a free surface on the rock to form a shape, According to the form consists of the steps of quarrying and quarrying stone in the rock.

However, the conventional quarrying process is based on the concept of cutting out the stone from a huge rock mass by recognizing the granite as a mass or a mass of rock without using the sedimentary joint, which is a characteristic of granite rocks. As the number of workshops is about 1 or 2, the work is progressed, and only the outlying rock is quarryed. Therefore, as the work continues, the form of the workshop is formed in a 'c' shape as shown in FIG. As the width of the workshop is small, it is inevitable for the quarrying and quarrying to make the free surface for the shape formation through the burner work, and the quarrying work based on this, and then through the burner work again. After free-form formation work for shape construction, the difficulty of proceeding quarrying is repeated repeatedly.

In addition, the conventional granite quarrying method takes a step from removing the topsoil layer to form the free surface for the quarrying and form the shape, considering that the quarrying work is affected by the natural climate Since the working time takes more time than the stone quarrying time, in terms of unit time of one year, the time for quarrying is limited. If the quarrying work, from topsoil removal to morphology, If you run out of time, you will inevitably turn over production and shipping to the next year.

In addition, since the basic concept of the conventional granite quarrying method is a quarrying method of cutting out a stone from a huge rock, the utilization rate of difficult free surface is low, which requires a lot of effort and time in the quarrying, which makes it difficult for mass production. The rock quarryed by the method has a problem of low productivity due to the low ratio of the salable stone to the rock, that is, the error rate, and the slope of the mountainous terrain as the quarrying operation approaches the top center of the mountainous terrain. In addition, the time taken from the topsoil removal phase to the shape formation phase becomes longer in proportion to the increase of the work surface, and the psychological anxiety of the workers in the field continues to increase with the increase of the work surface. It is more difficult and takes a lot of time and effort .

The present invention has been made in order to solve the above problems of the prior art, it is not mainly quarrying the granite on the basis of the outcrop rock, but instead of drilling the topography of the object of quarrying, the joint of the granite rock Work to meet the requirements, continue to lengthen along the vertical joint direction in order to make the best use of the free surface formed once, and to extend the distance so that the previous quarrying workshop will not be affected. When the number of workshops is continuously increased along the layers and stages, not only can they be mass-produced, but they also do not carry out unnecessary burners to form free surfaces. The purpose is to provide a quarrying method of granite that saves energy.

1 is a perspective view of a quarry according to the prior art,

2 is a plan view of a quarry according to the prior art,

3 is a front view and a plan view of a mountainous landform in which vertical boreholes are formed by the present invention;

4 is a front view and a plan view of a mountainous landform with horizontal boreholes formed by the present invention;

5 is a cross-sectional view of a typical mountainous terrain,

6 is a perspective view of a part of the quarry according to the present invention,

7 is a perspective view showing the type of quarry according to the present invention.

<Explanation of symbols on main parts of the drawings>

50: mountainous terrain 51: vertical borehole

51 ': horizontal borehole 52: perforation

61: topsoil layer 62: upper sky weathering layer

63: lower weathering layer 64: deep weathering layer

65: invariant L: L-type workshop

O: O type workshop

According to the present invention, the first process of removing the topsoil layer and the weathering layer to be suitable for quarrying the rock after confirming the vertical and horizontal jointing of the rock phase of the granite, and the rock phase to be quarryed according to the vertical and horizontal jointing identified in the first step A second process constituting the form, and a third process of quarrying the granite phase formed in the second process to fit the desired size.

In addition, the first process is characterized in that the vertical and horizontal jointing by drilling a borehole in the granite rock.

In addition, the third process is characterized in that by using the free surface formed in the second process in the barrier type by constructing the work form in a multi-stage along the soft layer and the stage is quarryed.

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

3 is a front view and a plan view of a mountainous landform with vertical boreholes formed by the present invention, and FIG. 4 is a front view and a plan view of a mountainous terrain with horizontal boreholes formed by the present invention, and FIG. 6 is a perspective view of a part of a quarry according to the present invention, and FIG. 7 is a perspective view showing a kind of quarry according to the present invention.

Granite flow quarrying method according to the present invention, as shown in Figures 3 to 7 by drilling vertically at the site of about nine revisions to the mountain terrain 50, through the vertical borehole 51, weathering layer 62, 63 and 64 and the depth of the invariant 65 is measured. In addition, as shown in FIG. 4, data about the weathering layers 62, 63, and 64 and the invariant 65 are collected in the mountainous terrain 50 to be horizontally drilled by horizontal boreholes 51 ′. In this case, the number and pore size of the boreholes 51 and 51 'may vary according to the shape or work situation of the mountainous terrain 50, but the number of boreholes 51 and 51' is about 3 to 10 balls. The inside and outside are appropriate and can be drilled with some deviation angle. In addition, the reason for drilling the boreholes 51 and 51 'is to obtain data on various states inside the mountainous terrain 50. Therefore, other work may be performed first and drilling may be performed later, if necessary.

Here, the general mountainous topography is a topsoil layer 61 and the top weathering layer 62, the lower weathering layer 63, the deep weathering layer 64 from the top, as shown in FIG. It is composed of invariant (65). And the data measured after drilling the vertical borehole 51 as described above, the thickness of the first weathering layer (62, 63) and the depth to the deep weathering layer (64), the second inclined plane of each horizontal joint on the granite subject to quarrying And the thickness of the rock layer between each horizontal joint, the increase and decrease of the main and sub-components of the third granite rock, the mixing state of impurities, the physical and chemical properties through the sample on the upper deep weathering layer 64, the presence of the fifth black / white spot, and This is to check the state, direction, etc. of stains, quartz veins and cracks, and to identify the sixth granite structure and use it as a data for shaping work.

And the data measured after drilling the horizontal borehole (51 '), the thickness of the first sanbok-myeon weathering zone, the thickness of the rock layer between the vertical joint and the joint in the granite bed, third, the grinding through the fertilizer of each sample between the rock layers Post-optical quality comparison analysis, fourth physical and chemical analysis of each rock layer component, 5th vertical drilling data for increase and decrease of main and subcomponents and impurities, and 6th vertical drilling data to identify rock condition And use as a data when constructing a suitable form of quarrying.

As described above, after performing the drilling operation to check the geological rock structure, the topography layer 61 and the upper awning layer 62 of the mountainous terrain are removed and at the same time, when the upper awning layer 62 is removed. Choose a space that can be used as a road to the top of the mountain and a space that can process waste rocks.

In the above, when the removal of the upper ceiling layer 62 is finished to form the rock to be quarried in accordance with the vertical and horizontal joints, and when the configuration is completed, the full-scale quarrying work is carried out, the quarrying work in any direction convenient It is possible to do as much as possible, but to increase productivity and work effectively, the first direction is south, the next is west, inevitable trends, and northwards are possible, but should be avoided if possible. In this context, the south direction means that the workplace form is made by moving from south to north based on the whole terrain.

In the quarrying method of the present invention, unlike the prior art, the stone is quarryed by blasting by performing the perforation 52 according to the vertical and horizontal joints as shown in FIG. In order to make full use of the free surface, quarrying is continuously extended along the main direction of vertical jointing.

The vertical joints appearing in nature are considered as one stage, and the horizontal joints are considered as one soft layer, but the horizontal joints match the desired stone size. If not, the drilling 52 is carried out at an arbitrary point to proceed with the quarrying.

Next, as shown in FIG. 6, when the quarrying operation is advanced as the first soft layer 71, the second soft layer 72 is spaced apart from the upper soft layer so as not to affect the operation. As the work of the second soft floor 72 is advanced and progressed, the work of the third soft floor continuously proceeds with a distance that does not affect the work between each soft floor.

In addition, as described above, when the first stage 81 is operated in a multi-stage form, the stage is spaced so that each stage does not affect work, and the second stage 82 is similarly operated. Proceed with the work of the third stage (83). Therefore, compared with the prior art, the production is increased in a short time because not only one workplace is quarryed but also several independent places.

As described above, if the mountain terrain 50 is a part of the mountain range, as shown in FIG. 7, the number of working places is continuously increased in the form of a U-type workshop or an L-type workshop (L), and the mountainous terrain ( If 50) is an independent mountain, the quarrying work is carried out by increasing the number of workplaces in the form of O type workshop (O) and proceeding with the top-down stair quarrying method at each workplace. It is most ideal if it adds even quarrying method.

In addition, quarrying can be done along the periphery of the vertical joint, but in order to collect a large amount of homogeneous stone, work should be done in the perpendicular direction of the vertical jointing.

Listed mountainous terrain 50 to which the quarrying work is applied to the present invention as described above, the first is an independent mountainous terrain (mountain) and hills (丘陵地), the second is a mountain with a ridge connected to the mountain range Terrain or hills.

Here, in the case of an independent mountain, the altitude of the contour line is ideally below 100M, but it may be higher than that in some cases. The slope of the mountainous terrain is ideally 10 ° to 15 ° and 22 °. The following is appropriate because it is a terrain that can be used as a road facility where heavy equipment vehicles can pass to the top of the mountain.

The ridges of the mountains are better to be gentle, and the hills are also gentler to the slopes. The slope of the mountains is the average of the slopes of the ridges and the mountain slopes. Ideally, the inclination is between 18 ° and 22 °, and more than that, but there are some difficulties in shaping. There is no big problem in shaping even if there are some cliffs among the mountainous terrain. In addition, in the case of ridges or hills connected to the mountain range, the longer the ridge length is from the tens of meters to the hundreds of meters, the longer the ridge can be. The same is true for one independent mountain.

In addition, the method of applying the present invention can be divided into three types according to the size of the business and capital of the main body, namely, individual or group, which performs the stone production. In the process of removing the strata, we do not cover the entire mountainous terrain, but remove the topsoil and the weathering layer on a small portion of the mountainous terrain on a small scale to the extent allowed by the capital, and then perform the stone production. This is because the production scale is reduced and the production cost is slightly higher as the present invention is applied to only a part of the mountainous terrain, but it is possible to develop quarries even with a small amount of capital. As a result, it is possible to obtain economic profits in a short time by shortening the time to form, form, and stone production. The proceeds can be used again as a reserve fund for the next stone production by investing in the development of stone mountain.

The second method is to perform full-scale stone production after removing topsoil and weathered layers for the entire mountainous terrain when performing topsoil removal and weathered layers after drilling. This is because it requires a long time to remove topsoil layer, weathering layer removal, morphology, and stone production, that is, one to two years, as the present invention is implemented for the whole mountainous terrain. Although it has the disadvantage of requiring large capital in the early stage of development, even in large-scale quarries, many independent quarry sites can be maintained, which has the advantage of significantly lowering the production cost through mass production.

The third method is to produce the intermediate form of the first and second methods listed above, which is a way to trade off the advantages and disadvantages of the first and second methods.

As described above, the barrier multi-stage quarrying method according to the present invention relates to a method of quarrying stone used as a building, civil engineering, and sculpture material. By checking the shape of the rock and the length, spacing, width, and direction of the vertical and horizontal joints, stages and soft layers, and removing the topsoil of the mountainous terrain, The quarrying work is carried out not with the concept of quarrying like a huge granite block, but with the concept that the aggregates of several granite blocks already divided into vertical and horizontal joints are stacked for the purpose and purpose of use. In addition, the quarrying process can be carried out safely, and the process steps for repeated quarrying operations can be reduced to prepare for stone quarrying. It is possible to maintain continuous production activities by minimizing the production downtime, and to maintain a large number of quarrying sites that can work independently in a single mountain, enabling mass production systems. It offers the greatest benefit as well as a significant increase in production per unit time.

Claims (3)

After confirming the vertical and horizontal jointing of the rock phase of granite, the first process of removing the topsoil layer and the weathering layer to be suitable for quarrying the rock phase, and the shape of the rock phase to be quarryed according to the vertical and horizontal jointing identified in the first step Barrier-type multi-stage quarrying method comprising a second process and a third process of quarrying the granite phase formed in the second process to fit the desired size. The method of claim 1, The first step is a barrier type multi-stage quarrying method characterized in that the vertical and horizontal joints are confirmed by drilling boreholes in the granite rocks. The method according to claim 1 or 2, The third process is a barrier-type multi-stage quarrying method characterized in that by using the free surface formed in the second process in the barrier type by constructing a multi-tiered work form along the soft layer and stage.