KR20160004892A - PBD complex equipment installed beforehand boring structure with vibratory-hammer/breaker and system/method thereof - Google Patents

Abstract

The present invention relates to a PBD combined device with a preliminary boring structure at one side of a leader of an ordinary PBD device including a PBD structure. After a preliminary borehole is preliminarily formed in an underground composite stratum, where a rock stratum and a hard sand stratum are mixed, by utilizing the PBD combined device, a PBD draining member is tamped into the preliminary borehole. In this regard, the preliminary borehole is bored by the preliminary boring structure, and the PBD draining member is tamped by an ordinary PBD structure. Also, the preliminary boring structure is formed by a hitting rod, a hitting means, and a shock control drawing wire, the intrusion of the hitting rod is conducted by the hitting means, and the drawing of the hitting rod is conducted by the upward force of the shock control drawing wire. In addition, the preliminary borehole is formed with the drawing of the hitting rod, and the hitting rod and a mandrel of the PBD structure are formed to have almost the same diameter so that a spaced distance is minimized and verticality is improved. Furthermore, since the preliminary borehole is formed in the way of pushing rock of a rock stratum, which is a discontinuum, to a movement space on left and right sides by a sharp front end of the hitting rod, rock is not fallen to a lower weak stratum so that the draining member is not cut by fallen rock when the PBD draining member is tamped, and skin friction force is minimized by a vibratory hammer, thereby facilitating drawing at a depth. Also, the PBD draining member may be efficiently tamped in an underground composite stratum by a single PBD combined device.

Description

PBD-type composite equipment with line-perforated structure and PBD-type system in underground composite layer and PBD-type construction method with PBD type equipment thereof}

The present invention relates to a PBD composite apparatus equipped with a line perforation structure, a PBD type system in an underground composite layer using the same, and a PBD type construction method in an underground composite layer using the PBD type system. The PBD is a composite device equipped with a PBD, and thus a line hole is first formed in an underground composite layer in which a sandstone layer or a hard sand layer is mixed. Then, a PBD drainage material is used for line perforation, The type is made by a conventional PBD structure.

The line perforation structure is formed by the hitting rod, the hitting means and the impact suppression drawing wire, the penetration of the hitting rod by the hitting means, and the drawing of the hitting rod by the upward force of the impact suppressing drawing wire. The line perforation is formed with the drawing of the penetrating impact rod.

In addition, since the tip of the striking rod has a pointed shape with a minimum grounding area, the stones of the discontinuous chain of stones are pushed to the left and right moving spaces to form a line perforation, so that the diameter of the line perforations and the diameter of the mandrel But also the verticality is improved. Moreover, since the stones do not fall into the soft layer below, the drainage material is not cut off due to the broken stones in the type of the PBD drainage material. As a result, although the length of the soft layer in the underground multiple layer is long, the drilling operation is efficient and economical.

In addition, it is possible to minimize the frictional force applied by the vibro hammer, so that it is easy to pull out the long depth of the impact rod, and it is a useful invention that enables the type of PBD drainage material in the underground multiple layer by efficiently using one PBD combined equipment.

In general, improvement of soft ground such as roads, harbors, and complexes is accomplished by a consolidation method that dehydrates pore water contained in the ground and increases soil bearing capacity. The most commonly used method is PBD (Plastic Board Drain) method.

The outline of the PBD method is shown in Figs. 1A and 1B. 1A and 1B are prior art-1 described in Patent Registration No. 10-0950067.

As shown in FIG. 1A, the PBD equipment 103 includes a reeder 105 and a PBD casing (mandrel) 104. The PBD 106, which is a drainage material, is inserted into the mandrel 104 (Fig. 1B). Underground penetration and withdrawal of the mandrel 104 is typically accomplished by hydraulic devices. The PBD 106 is induced to the ground by the underground penetration of the mandrel 104 and the PBD 106 is left in the ground when the mandrel 104 is again introduced.

Since the mandrel 104 of FIG. 1A is penetrated into the ground by the hydraulic device, the ground surface embedded in the ground at a certain thickness by the gravel, slag, sand or the like, The penetration of the mandrel 104 is practically impossible.

Especially in the case of an underground multiple layer, this is more difficult to penetrate. Here, the underground composite layer is a layer in which a sandstone layer, a hard sand layer or a sandstone layer and a sandstone layer are mixed with each other (see FIG. 1C). The underground multiple layer is formed between the sandstone layer and the hard sand layer, And in such a layer there is a weak layer such as a soil layer or a moss layer in between.

When the mandrel 104 meets the underground composite layer, there is a problem that the mandrel 104 is warped or intrusive.

A conventional technique for allowing mandrel penetration into the slag layer is shown in Figs. 2 and 3. Fig.

In both the prior art of FIGS. 2 and 3, drilling of the slag layer is accomplished by a screw rotating auger equipped with a rotating bit having a large ground surface area. Since such a rotating bit is a method of drilling and grinding, it is advantageous for drilling a rock bed having a continuous structure. Since the rotary bit presses the rock and the reaction force of the rock corresponding thereto is transmitted to the rotary bit, wear piercing is efficient. If the number of revolutions is the same, the efficiency of wear is proportional to the magnitude of the ground area of the rotating bit.

On the other hand, since the slag layer is a discontinuous structure in which a moving space is formed as a separate entity having a certain size between the slag and the slag, wear puncturing due to the pressing of the rotating bit is inefficient. This is because the reaction force of the rotary bit is not transmitted to the rotating bit because the rock layer is moved toward the moving space due to the pressing of the rotary bit. When the rotating bit reaches the end of the slag layer, the slag is pushed into the soft layer (mud layer or soil layer) by the pressure of the rotating bit. In addition to the difficulty of mandrel penetration, the sandstone that has fallen to the bottom has a problem that the PBD drainage material is cut when the mandrel is pulled out.

First, a description will be given of a prior art 10-1337223 (hereinafter referred to as " prior art 2 ") of FIG.

The dual casing vertical drainage type device 300 of the prior art-2 allows the mandrel 60 to be penetrated into the slag layer or the hard sand layer 150. Is formed into a double casing structure having a central passage along the inner central axis of the screw rotary auger 50 for penetration of the mandrel 60 of the rigid layer 150 so that the mandrel 60 is passed through the inner central passage. That is, the perforations of the slag layer are inserted by the screw rotating auger 50 and the mandrel 60 is inserted into the inner central passage of the screw rotating auger 50. A drill bit 81 is attached to the bottom of the screw rotating auger 50.

The screw rotating auger 50 of the prior art-2 with the excavating bit 81 attached is generally the same in bit perforation and perforation method by the T4 drilling equipment. However, the perforation by the prior art-2 is larger than the perforation diameter by the T4 perforation equipment as a large diameter. This is because there is no space for inserting the double casing structure having the central passage along the inner central axis of the screw rotating auger 50 unless the prior art-2 is a large diameter.

T4 drilling equipment is equipped with a bit on the bottom of the rotary drill and auger with a spiral steel plate attached to the outside of the circular casing. The perforation diameter is equal to or greater than 440 mm. Particularly, since the prior art-2 has a double casing structure, the perforation diameter is 700 to 800 mm. Since the diameter of the mandrel of the PBD is usually 150 to 160 mm, there is a problem that it is difficult to vertically maintain the mandrel of the PBD unless the fastening hole is formed by the screw rotating auger 50 of the prior art-2.

In addition, since the method of drilling the slag layer while pressing the screw rotating auger 50 equipped with the rotary bit having a large ground area, there is a problem of drilling of the discontinuous slag layer in which the moving space exists (the PBM is inefficient, Cutting, etc.) will remain intact, as described above.

Next, a description will be given of a conventional technique disclosed in Fig. 3 (hereinafter referred to as " Prior Art 3 ").

Conventionally, the large-diameter perforation hole is formed in the slag layer by using a rotating bit having a large ground contact area as in the prior art-3. However, it is intended to prevent the flow of PBD vertical drainage material by filling filling material (sand) in the space of the large diameter perforation hole.

In the prior art-3, the problem of the flow to the spaced-apart space of the unfilled large-diameter perforation hole of the prior art-2 is pointed out, and the large-diameter perforation hole is filled with the filler to prevent this.

However, even if the problem of the flow of the PBD drainage material is solved by filling the filling space in the space, the drilling method of the prior art-3 is also a method of drilling the slit layer while pressing the rotating bit having a large ground area as shown in FIG. The problem of perforation of the discontinuous chain of discontinuous chains (inefficiency of perforation, cutting of PBD drainage, etc.) remains intact.

The drilling of the slag layer of the prior art-3 and the PBD installation process are shown in Fig.

Conventional technique 3 is a process of extracting a crushed stone (ST 1), filling a filler (ST 2), penetrating a vertical drainage (ST 3), pulling a mandrel (ST 4) .

The ST1 step is a process in which the casing 12 is introduced into the slag layer 2 by the T-4 drilling rig 10 with the rock excavation bit 11 attached thereto.

The diameter of the casing 12 is a large diameter (at least = 440 mm) as in the prior art-2 because the T-4 drilling equipment 10 is pierced by the rock excavation bit 11 having a large grounding area. Since the PBD mandrel (= 150 to 160 mm) passes through the inside of the large-diameter casing 12, a space is inevitably generated between the large-diameter casing 12 and the mandrel.

The < filler filling > (ST 2) process is a process of filling the sand 13 to prevent the flow of the spacing space generated in the process of (ST 1).

(ST 3)) is a process in which a mandrel is penetrated through a filler inside a large-diameter casing (12). The vertical drainage member 21 is inserted into the mandrel.

In the process of the mandrel drawing (ST 4), the vertical drainage material 21 is put into the ground.

The < casing drawing > (ST 5) process is a process of drawing the casing 12 by the T-4 punching machine 10.

Next, the problems of the prior arts 2 and 3 will be described.

As shown in FIG. 2 and FIG. 3, the slag layer does not exist only near the ground surface. Usually, there is an underground multiple layer. When the underground composite layer is drilled by rock rotation bit having a large ground area of the prior arts 2 and 3, the drilling operation is inefficient and uneconomical because large diameter drilling must be performed up to the soft layer between the slag layer and the slag layer. The longer the length of the softened layer, the larger the perforation of the large diameter, so the inefficient and noneconomical weight increases.

Problems of Prior Art-2 and 3 are summarized as follows.

In the prior art-2 and 3, since the abrasion hole is drilled by the rock rotation bit having a large ground area in the discontinuous chain of discontinuous chain having the moving space, the large hole in the large diameter hole is inevitable and a large separation space is formed between the large diameter hole and the mandrel There is a problem in the prior art-2 that the PBD drainage material can not maintain the vertical state due to the flow of the PBD drainage material at the mandrel drawing. In the prior art-3, the filling material is filled in the spacing space of the large- The perforations of the prior arts 2 and 3 are perforated while pushing the slag layer with a large ground contact area, so that the reaction force of the slag layer corresponding to the pressing of the rotary bit is not transmitted to the rotary bit, , So many stones are pushed into the soft layer (mud layer or soil layer). As a result, when the mandrel is drawn out, the stones fallen into the soft layer have a problem of blocking the passage of the PBD drainage material and cutting it. In addition, in the case of the underground composite layer, the perforation structure of the prior art-2 and 3 having the rock rotation bit has an inevitable uneconomical problem because the drilling operation is inevitable until the soft layer. The longer the length of the weakened layer, the more inefficiency and non-economicity.

The present invention relates to a PBD composite apparatus having a line hole structure on one side of a leader of a conventional PBD apparatus equipped with a PBD structure, wherein a line hole is first formed in an underground composite layer in which a sandstone layer or a hard sand layer is mixed, The line perforation is made by the line perforation structure of the PBD combined equipment, and the PBD drainage type is formed by the ordinary PBD structure of the PBD combined equipment. The line perforation structure and the turn of the PBD structure are formed by the swing The penetration of the striking rod is effected by the striking means and the drawing of the striking rod is by the upward force of the striking suppression drawing wire, At this time, a line perforation is formed along with the drawing of the intruding rod, and the diameter of the striking rod is formed to be substantially equal to the mandrel diameter of the PBD structure Not only the spacing space is minimized but also the verticality is improved, the line drilling operation and the mandrel penetration operation are efficient, and the sharp conical tip of the hitting rod pushes the discontinuity of the discontinuous chain slag into the left and right moving spaces, The PBD drainage material is prevented from being cut down due to the fact that the stones fall into the below-mentioned soft layer, and the type of PBD drainage material is efficiently and economically applied to the underground composite layer in which the sandstone layer or the hard sand layer is mixed by a simple PBD- There is a purpose in that,

PBD composite equipment has a conventional PBD structure on one side and a line perforation structure on the other side, and a hammering means of a line perforation structure uses a conventional breaker and / or a vibrating hammer, Another object of the present invention is to maximize the input of the hitting rod to the underground composite layer in which the slag layer or the hard sand layer is mixed by suppressing the upward repulsive force due to the impact of the hitting means by the impact suppression drawing wire.

The configuration of the PBD composite apparatus 100 equipped with the line perforation structure S of the present invention will be described as follows.

In a conventional PBD equipment 110 equipped with a PBD structure P

A conventional PBD structure P is mounted on one side of the reader 120 of the PBD equipment 110 and a line perforation structure S is mounted on the other side of the leader 120. The PBD structure P includes a mandrel 130 And a PBD drainage member 132. The linear perforation structure S comprises a hitting means 150 and a hitting rod 160. The hitting means 150 and the hitting rod 160 are mounted coaxially The pulling out of the impact rod 160 is carried out by the impact suppression pulling wire 170 while the impact restraining pulling wire 170 is wound on the punching wire drum 172 rotated by the forward and reverse hydraulic motors MW, WB wires are respectively wound on upper and lower ends of the hitting means 150. In this state, the drawing of the striking rod 160 is pulled out while the WB wire is unwound simultaneously with the winding of the WB wire, A line perforation hole 166 is formed along with a line hole 166 and a swing of the PBD equipment 110 to form a conventional PBD structure P, The PBD mandrel 130 is introduced into the line perforation hole 166 while the PBD mandrel 130 of the PBD mandrel 130 is aligned with the PBD mandrel 130 of the PBD mandrel 130, L in a line perforation hole 166. The PBD composite device is equipped with a line perforation structure.

First, the hitting means 150 of the line perforation structure S is made of a breaker B, the impact suppressing drawing wire 170 is fixed to the upper and lower ends of the breaker B, , And a PBD composite device equipped with a line perforation structure characterized by compression at the bottom dead center along with a gas expansion force.

Second, the hitting means 150 of the line perforation structure S is characterized in that strike vibration is performed by the vibrohammer H while the impact suppressing drawing wire 170 is fixed to the upper and lower ends of the vibrohammer H, It is PBD composite equipment equipped with perforated structure.

The hitting means 150 of the line perforation structure S is composed of a vibrohammer H and a breaker B while the impact suppression drawing wire 170 is disposed on the upper portion of the vibrohammer H and the breaker B and the breaker B is mounted on the coaxial shaft with the hitting rod 160 while the breaker B is fixed to the lower end of the piston B by gas compression at the top dead center of the piston, This is a PBD composite equipment equipped with a line perforation structure, which is characterized by the blowing at the bottom dead center along with the inflated gas pressure.

Fourth, the impact suppression drawing wire 170 in which the WA and WB wires are respectively wound on the circular punched wire drum 172 rotated by the normal and reverse hydraulic motor M is fixed to the upper and lower ends of the hitting means 150 When the WA wire is wound, the WB wire is loosened and vice versa. When the striking rod 160 is in the underground composite layer L, the WA wire is wound and the hitting means 150 is vertically downward The upward repulsive force due to the striking means 150 is suppressed and conversely the WB wire is wound and the striking rod 160 is pulled out while the wire of the WA starting from the perforator wire drum 172 is wound on the lower roller R3 And the wires of the WB starting from the perforator wire drum 172 are connected to the rollers R1 and R2 fixed to the support fixing member 174 provided at the middle upper portion of the leader 120. [ From horizontal to vertical again The PBD is a compound device is perforated line structure characterized by a fixed mounting at the top of the striking means (150).

The PBD composite apparatus 100 equipped with the line perforation structure S of the present invention is basically a PBD composite apparatus 100 based on a conventional PBD apparatus 110 because it uses a conventional PBD apparatus 110. [

The PBD composite apparatus 100 is a single apparatus composed of a line perforation structure (S) and a conventional PBD structure (P).

The PBD composite equipment 100 of the present invention is an equipment for forming a PBD drainage material 132 into a slag layer and an underground composite layer L as one equipment. The PBD drainage material 132 of the PBD composite equipment 100 is formed by drilling a line perforation hole 166 in a line perforation structure S in a), brittle layer and underground composite layer L, The PBD drainage material 132 is inserted through the penetration and drawing process of the mandrel of the PBD structure P into the line perforation hole 166 of the slag layer and the underground composite layer L. [ Here, it is a common practice that the PBD drainage material 132 is formed into the slag layer and the underground composite layer L by penetration and drawing of the mandrel 130 of b. However, the PBD structure P and the line perforation structure S in FIG. 1 are mounted on one PBD reader 120, thereby making the PBD composite apparatus 100 a simple structure.

The matching of the line perforation hole 166 with the mandrel 130 is achieved by a simple swing of the PBD composite apparatus 100. [

The configuration of the PBD complex equipment 100 will be described in more detail as follows.

A) First, a conventional PBD structure (P) of the PBD complex device 100 and a configuration related thereto will be described.

The PBD structure P of the PBD composite apparatus 100 generally comprises a mandrel 130 and a PBD drain 132.

The PBD structure P is a structure in which the PBD drainage material 132 is applied to the soft ground so that the intrusion of the sandstone layer and the underground composite layer L of the mandrel 130 is impossible.

The first drilling of the slag layer and the underground composite layer (L) is to enable penetration of the mandrel (130).

The PBD structure P is pre-drilled in the slag layer and the underground composite layer L by the pre-drilled structure S and then the PBD drainage material 132 is applied to the slag layer and the underground composite layer L in a conventional manner The PBD drainage material 132 can be efficiently and economically advantageously introduced.

(B) Next, the line perforation structure (S) of the PBD complex device 100 and the related structures will be described.

The line perforation structure S is a structure composed of a hitting rod 160, a hitting means 150, and an impact suppressing drawing wire 170.

(A) The impact load 160 will be examined.

The top 162 of the striking rod 160 is pointed conical and the top of the striking rod 160 is securely fastened to the striking means 150.

Through the penetration and drawing of the striking rod 160, a perforation hole 166 is drilled in the slag layer and the underground composite layer (L).

The striking rod 160 is penetrated into the slag layer and the underground composite layer L by the striking of the striking means 150. [

The pull of the striking rod 160 is pulled by the upward force of the striking wire 170 that is fixed to the top of the striking means 150. Along with the drawing of the striking rod 160, a perforation hole 166 of a line perforation is formed in the slag layer and the underground composite layer L. [

The diameter of the striking rod 160 is approximately the same as the diameter of the mandrel 130 of the PBD structure P. The diameter of the striking rod 160 is the diameter of the line perforation hole 166, Since the mandrel 130 is penetrated into the perforation hole 166, not only the spacing space is minimized but also the effect of the earth pressure is reduced as well as the verticality is improved. In this case, since the line perforation is small in diameter, unlike the case of the conventional method, the perforating operation is efficient and economical. The diameter of the striking rod 160 is preferably several tens mm larger than the diameter of the mandrel 130.

First, the relationship between the striking rod 160 with the pointed end 162 and the intrusion of the stony layer will be described as follows.

Unlike the rock mass, which is a continuum, the rock mass is a discontinuous structure in which there is a moving space between the rock and the rock. When the rocks of discontinuous structure are pierced by the rock excavation bit having a large ground area, the rocks are crushed while pushing the rocks down. Therefore, the rocks do not move to the moving spaces on the left and right sides, It will fall out. The PBD drainage material 132 is not cut or vertically formed in the course of the type of the PBD drainage material 132 due to the broken stone which is pushed by the soft layer.

The present invention is a method in which the front end 162 of the hitting rod 160 is pointed to minimize the ground contact area with the stave so that the stave is moved to the left and right of the moving space. By the tip 162 whose grounding area is minimized, the stones are pushed to the right and left of the moving space, but are not pushed downwardly. Even if the tip 162 of the striking rod 160 pushes the slag layer, it moves to the left and right moving spaces before falling downward.

The vertical position of the striking rod 160 is maintained by the moving bracket 164 moving along the guide 152 and the fixed brackle 164 fixed to the guide 152 when the striking rod 160 penetrates the striking rod 160.

Next, the drawing of the striking rod 160 intruded into the stony layer is pulled out by the upward force of the striking wire 170 fixed on the top of the striking means 150.

(B) The impact suppression drawing wire 170 will be described.

The impact suppression drawing wire 170 performs two functions, i.e., a draw function and a suppression function of an upward repulsion force.

And serves to pull out the striking rod 160 by the upward force of the impact restraining drawing wire 170 fixed to the upper portion of the striking means 150. The downward force of the impact restraining drawing wire 170 fixed to the lower portion of the hitting means 150 functions to suppress the upward repulsive force due to the impact of the hitting means 150. [

First, the flow of the shock suppression drawing wire 170 is as follows.

The impact restraining drawing wire 170 is wound around a perforator wire drum 172, which is a cylindrical shape rotated by a normal rotation motor. When the WA wire is wound, the WA and WB wires are wound in such a manner that the WB wire is unwound and vice versa. The other end of the WB wire is vertically moved through the lower roller 3 and fixed to the lower end of the striking means 150. The other end of the WB wire rises vertically, As shown in FIG.

The downward force of the impact restraining pulling wire 170 fixed to the lower portion of the hitting means 150 suppresses the upward repulsive force and the upward force of the impact restraining pulling wire 170 fixed to the upper portion of the hitting means 150 The pulling function of the hitting rod 160 by the force will be described.

The function of suppressing the upward repulsive force due to the downward force of the impact restraining drawing wire 170 fixed to the lower portion of the hitting means 150 can be suppressed only by the process of penetrating the hitting rod 160 into the slag layer by the hitting means 150 .

The downward force of the suppression function is activated when the WA wire is wound. At the same time, the WB wire is released.

The reinforcement of the downward force is to reinforce the tension of the WA wire. The tension cylinder 173 mounted on the lower roller 3 directly reinforces the tension of the WA wire.

When the hitting means 150 is the breaker B, when the hitting rod 160 is hit by the operation of the breaker B, an upward repulsive force corresponding to the impact of the tip 162 of the hitting rod 160 is generated. When the stover and the tip end 162 of the striking rod 160 come into contact with each other, the stones are moved to the left and right moving spaces while breaking the small stones. When the upward force is applied to the hitting rod 160, the input of the hitting rod 160 is lost. The downward force of the shock suppression drawing wire 170 suppresses the upward repulsive force.

Secondly, the drawing function of the hitting rod 160 by the upward force of the impact restraining drawing wire 170 fixed to the upper portion of the hitting means 150 is operated only in the process in which the intruding hitting rod 160 is pulled out from the slag layer .

When the intrusion of the striking rod 160 into the stony layer is completed, the striking rod 160 is pulled out. A line perforation is formed in the slag layer together with the drawing.

In the drawing process, the WB wire is wound and the upward force is actuated. At this time, the WA wire is released from the perforator wire drum 172.

(C) Explain the hitting means of the hitting rod.

The striking means 150 of the striking rod 160 used in the PBD combined equipment 100 of the present invention is a breaker B and a vibratory hammer H. [

The breaker (B) and the vibratory hammer (H) are generally used as hitting means, but they are applied to the line perforation structure of the PBD composite apparatus 100 of the present invention. The line perforation structure is intended for an underground composite layer (L) composed of a sandstone layer, a hard sand layer or a soil layer and a combination thereof.

First, a breaker (B) will be described.

The breaker B is generally attached to a backhoe or the like so that the rocker 1 is lifted up and down by the upward and downward movements of the hitting rod 1 (here, the reference numerals of FIGS. 4A and 4B are used to describe FIGS. 4A and 4B) It is used for crushing. If it is a shallow ground, it can be drilled and drawn. It is pointed out that if the depth is deepened, it is possible to perforate, but it is difficult to draw due to the friction force of the sand and the adhesion force of the clay.

Among the various types of breaker breaker (B), the hydraulic + gas blowing method will be described.

Hydraulic-gas is described in detail in Patent Publication No. 1994-0005811 (hereinafter referred to as "hydraulic-gas method"). Are shown in Figs. 4A and 4B.

The basic concepts of the hydraulic-gas system are examined.

The hydraulic-gas system is a system for crushing a rock mass by a striking force of a hitting rod 1 to which a chisel is attached.

The striking force of the striking rod 1 is an inflating force that is pressed while the compressed gas in the gas chamber 60 installed on the cylinder 20 is expanded. The pressurized expansion force hits the hitting rod 1 downward. The state in which the piston (40) is pressed to the maximum immediately before descending is a state in which the piston (40) reaches the top dead center.

The striking by the pressurized expansion force occurs between the top dead center and bottom dead center of the piston (40).

In order for the pressurized expansion force to have the maximum impact force, there should be no pressure in the cylinder 20 that resists the piston 40 being lowered.

The operation of the piston 40 between the top dead center and the bottom dead center is achieved by valve conversion.

Valve conversion is accomplished by a spool (90). The conversion operation of the spool 90 is interlocked with the descent and the upward movement of the piston 40.

For example, when the piston 40 is lowered, a valve change is made in a direction in which there is no pressure resistant against the descent of the piston 40, that is, in a direction in which there is no pressure in the cylinder 20. When the piston 40 is lifted up, the valve switching valve of the spool 90 is switched in the direction in which the piston 40 is pressed in the upward direction. As a result, the valve 70 is opened and closed by the valve change of the spool 90 by the movement of the spool 90 which is linked with the reciprocating movement of the piston 40.

Therefore, the basic principle of the hydraulic-gas system is that the gas compression at the top dead center of the piston 40 and the blow at the bottom dead center together with the compressed gas expansion force are achieved.

In the hydraulic-gas system, the spool 90 in the valve interlocked with the reciprocating movement of the piston 40 is automatically moved, and the hydraulic pressure in the third chamber 44 on the upper portion of the piston 40 is changed In this process, the gas compression is performed at the top dead center, and the blow is carried out at the bottom dead center together with the compressed gas expansive force.

Since the hydraulic-gas method is a striking method of a compressed gas expansion force, it is easy to penetrate the underground composite layer (L) such as a slag layer because the striking force is good.

Since the striking force is good, when the tip of the striking rod and the striking rod meet in front, the upward repulsive force due to the striking is large. The upward repulsive force damages the tube input of the hitting rod. In addition, there is a limit in the penetration depth of the perforated casing due to the difficulty of drawing due to the large adhesion force and surface friction between the perforated casing and the ground layer.

In the present invention, breakers (B) and vibrohamers (H) are installed by intruding and drawing of single core degree only by a breaker (B), intruders by a breaker (B) and drawers by a vibrator ) Is operated to minimize the frictional force.

Next, the vibratory hammer (H) (vibratory hammer) will be described.

The perforation of the Vibro hammer (H) is achieved by the vertical vibration and the weight of the hammer. The weight of the Vibro hammer (H) is usually 45 to 50 kgw.

The Vibro hammer (H) is advantageous for casing drawing that is intruded into the sand layer of single degree of depth or long depth. This is because the main surface friction force with the casing is greatly reduced by the vibration.

In the PBD composite equipment of the present invention, a linear perforation structure is additionally attached to one side of a reader of a conventional PBD equipment, so that the structure is simple, and a line hole Since the mandrel is penetrated into the line hole, the mandrel penetration is easy in the slag layer, and the diameter of the line hole and the diameter of the mandrel penetrated are almost the same. Therefore, the spacing space is minimized and the vertical degree is improved As a result, although the length of the soft layer in the underground composite layer is long, the drilling operation is efficient and economical.

Due to the pointed conical tip of the striking rod, the stones of the discontinuous chain of stones are pushed into the left and right moving spaces to form line perforations, so that the stones do not fall into the soft layer below. It is possible to maintain the vertical state and improve the quality.

In addition, if the breaker (B) and the vibrohammer (H) are used in combination, it is easy to intrude and pull out the long-depth impact rod as well as single core. Intrusion of the hitting rod can be achieved by operation of the breaker B having good striking force and by drawing the hitting rod by the operation of the vibrohammer H which minimizes the frictional force of the main surface, .

In addition, there is an advantage that the downward force of the impact restraining drawing wire suppresses the upward repulsive force generated due to the strong impact of the breaker (B) when the impact rod is penetrated, thereby further increasing the tube input of the impact rod.

Since the PBD composite equipment uses the conventional PBD equipment as it is, it is equipped with the line hole structure, so that the type of PBD drainage material is made easy in the underground composite layer in which the sandstone layer and the hard sand layer are mixed by one composite equipment. Therefore, Construction is a useful invention with an efficient and economical advantage.

FIG. 1a is a cross-sectional perspective view of a typical PBD method using conventional PBD equipment;
1B is a sectional view showing a state in which a PBD drainage material is embedded in the mandrel of FIG. 1A
Figure 1c is an exemplary cross-sectional view illustrating an underground composite layer;
2 is a cross-sectional perspective view showing a state where a PBD drainage material is applied to a slag layer according to Prior Art-1
3 is a cross-sectional perspective view showing a process of applying a PBD drainage material to a slag layer according to Prior Art-2
4a is a structural cross-sectional view of a breaker in which gas compression at the top dead center of the piston and blow at the bottom dead center together with the compressed gas expansion force
FIG. 4B is a detailed sectional view of FIG.
5a is a cross-sectional perspective view of the PBD composite equipment equipped with the line perforation structure of the present invention
5b is a rear view of the PBD composite equipment equipped with the line perforation structure of the present invention
5c is a plan view of the PBD composite equipment equipped with the line perforation structure of the present invention
6a and 6b are cross-sectional perspective views showing the relationship between the hitting means of the line perforation structure, the hitting rod, and the impact suppressing drawing wire.
7a is a sectional view showing preparation steps for line perforation of an underground composite layer by a PBD composite equipment equipped with a line perforation structure of the present invention
FIG. 7b is a cross-sectional view showing a penetration step of the batting rod by the line perforation structure of the present invention in the underground composite layer
FIG. 7c is a cross-sectional view showing a step in which a puncture is formed in an underground multiple layer by pulling out a strike rod having a line perforation structure penetrated into an underground multiple layer
FIG. 7d is a cross-sectional view showing a preparation step of mandrel penetration of the PBD structure in the perforated line hole in FIG. 7c
[Fig. 7e] Cross-sectional view showing the ground type step of the PBD drainage material by the mandrel penetration drawing of the PBD structure in the line perforation hole

First, a PBD type system in the underground composite layer L by the PBD composite equipment 100 equipped with the line perforation structure S will be described in detail with reference to the accompanying drawings.

A PBD composite device 100 having a line perforation structure S mounted on one side of a reader 120 of a conventional PBD equipment 110 equipped with a PBD structure P, The line perforation is formed by the line perforation structure S of the PBD composite apparatus 100 and the PBD drainage material 132 by the line perforation structure S, Type is made by the conventional PBD structure P of the PBD composite apparatus 100 and the line perforation structure S and the PBD structure P are made by swinging while the line perforation structure S is made by the swing Wherein the penetration of the striking rod is effected by the striking means 150 and the drawing of the striking rod is performed by the upward force of the striking suppression wire 170 Wherein a line perforation is formed with the pulling of the intruding striking rod, and the diameter of the striking rod is determined by the diameter of the PBD structure (P) The vertical spacing is minimized and the spacing is minimized to improve the verticality and the stiffness of the discontinuous grinding stone is pushed to the left and right moving spaces by the pointed conical tip 162 of the striking rod, And a PBD drainage material (132) is formed in the underground composite layer (L) in the process of penetrating and inserting the PBD mandrel (130) of the PBD structure (P) into the line hole formed together with the drawing of the batting rod It is PBD type system in underground multiple layer using PBD composite equipment equipped with perforated structure.

First, the hitting means 150 of the line perforation structure S is composed of a vibro hammer H and a breaker B, and a vibro hammer H and a breaker B on the same axis as the hitting rod , And the breaker (B) is provided with a PBD composite device equipped with a line perforation structure characterized by gas compression at the top dead center of the piston and blow at the bottom dead center along with the compressed gas expansion force, Type system.

Second, the impact suppression drawing wire 170 is wound on the perforator wire drum 172 in the form of WA, WB wires, the WA, WB wires are started in the perforator wire drum 172, And the WB wire is vertically raised toward the rollers 1 and 2 fixed to the support fixing member 174 installed at the intermediate upper portion of the leader 120 and then vertically descends again through the horizontal And is fixed to the upper end of the hitting means (150). The PBD type system is used in the underground composite layer using the PBD composite equipment equipped with the line perforation structure.

Next, a PBD construction method using the PBD composite equipment 100 equipped with the line perforation structure S of the present invention will be described in detail with reference to the accompanying drawings.

As the first construction method,

A PBD structure P is mounted on one side of the reader 120 of a conventional PBD equipment 110 and a line perforation structure S is mounted on the other side of the reader 120. A conventional PBD structure P is mounted on a mandrel 130 and the PBD drainage material 132. The line perforation structure S comprises a breaker B and a hitting rod and the breaker B is a combination of an underground composite Layer (L);

The impact load of the line perforating structure S of the PBD combined equipment 100 installed on the underground composite layer L is hit by the breaker B and the gas compression is performed at the top dead center of the piston of the breaker B, At this time, the WA wire of the impact suppression drawing wire 170 fixed to the upper and lower ends of the breaker B is wound and the breaker B is wound on the breaker B, The WB wire of the impact-suppressing drawing wire 170 is wound while pulling the striking rod upward so that the striking rod is pulled out, and the striking rod is pulled up by pulling the striking rod up and down to suppress the upward repulsive force due to the striking of the breaker B, Forming a line perforation hole (166) in the underground composite layer (L) together with the drawing of the strike rod;

The PBD composite device 100 is swung so that the mandrel 130 of the conventional PBD structure P is penetrated into the line perforation hole 166 and the PBD drainage material 132 is removed in the process of drawing the mandrel 130 again. Into the underground composite layer (L);

And a plurality of PBD drainage materials (132) in the underground composite layer (L) while repeating the above-described steps. The PBD composite device (100) equipped with the line perforation structure (S) It is PBD type construction method in underground multiple layer.

At this stage, the impact suppression wire 170 is made of WA, WB wires, one end of the WA and WB wires is fixed to the upper and lower ends of the breaker B, and the other end of the WA and WB wires is a circular- The wires of the WA starting from the perforator wire drum 172 are lifted up vertically through the lower roller 3, and the breaker wire drum 172 is wound up on the drum 172. In this way, the WB wire is unwound when the WA wire is wound, The wires of WB starting from the perforator wire drum 172 are fixed to the lower end of the perforator wire drum 172 by the rollers 1 and 2 fixed to the support fixing member 174 provided at the middle upper portion of the reader 120, And forming a line perforation hole (166) in the underground composite layer (L) by being fixed to the upper end of the breaker (B) by using the PBD composite device equipped with the line perforation structure. PBD type construction Method.

As a second construction method,

A PBD structure P is mounted on one side of the reader 120 of a conventional PBD equipment 110 and a line perforation structure S is mounted on the other side of the reader 120. A conventional PBD structure P is mounted on a mandrel 130 and a PBD drainage material 132. The line perforation structure S comprises a vibrohammer H and a hitting rod and the vibrohammer H is composed of a hitting rod and a PBD Installing the equipment (100) on the underground composite layer (L);

The hitting rod of the line perforation structure S of the PBD combined equipment 100 installed on the underground multiple layer L is typed into the underground composite layer L by the vibrohammer H, The WA wire of the impact suppression drawing wire 170 fixed to the upper and lower ends of the vibration suppression drawing wire 170 is wound while pulling the vibro hammer H and the hitting rod vertically downward to suppress the upward repulsive force due to the hitting of the vibrohammer H Conversely, when the WB wire of the shock-suppression drawing wire 170 is wound, the striking rod is pulled up to draw the striking rod, and a line perforation hole 166 is formed in the underground composite layer L together with the drawing of the striking rod;

The PBD composite device 100 is swung so that the mandrel 130 of the conventional PBD structure P is penetrated into the line perforation hole 166 and the PBD drainage material 132 is removed in the process of drawing the mandrel 130 again. Into the underground composite layer (L);

And repeating the above steps to form a plurality of PBD drainage materials (132) in the underground composite layer (L), using the PBD composite equipment equipped with the line perforation structure. It is a construction method.

At this stage, the impact suppression wire 170 is made of WA, WB wires, one end of the WA and WB wires is fixed to the upper and lower ends of the breaker B, and the other end of the WA and WB wires is a circular- And the WA wire starting from the perforator wire drum 172 is lifted up vertically through the lower roller 3 and wound on the drum 172. The WA wire is wound up on the drum 172, The WB wire which is fixed at the lower end of the hammer H and started from the perforator wire drum 172 passes through the rollers 1 and 2 fixed to the support fixing member 174 provided at the middle upper portion of the reader 120, And forming a line perforation hole (166) in the underground composite layer (L) by being fixed to the upper end of the vibro hammer (H) by using the PBD composite equipment equipped with the line perforation structure. Put PBD on multiple layers A construction method.

As described above, according to the present invention, it is possible to penetrate the mandrel 130 into the underground composite layer L in which the sandstone layer or the hard sand layer is mixed by the simple PBD composite equipment 100, .

First, the striking rod of the line perforation structure S is introduced into the underground composite layer L and then drawn out. At the same time, a line perforation is formed in the underground composite layer L. Then, The PBD drainage material 132 is introduced into the underground composite layer L in the process of penetrating the mandrel 130.

Since the diameter of the striking rod is the diameter of the linear perforation hole 166 and the mandrel 130 is introduced into the linear perforation hole 166, the space for the separation is minimized as well as the verticality is improved, There is also an advantage of being small.

In addition, since the leading end 162 of the striking rod has a pointed shape with a minimum grounding area, the stones of the discontinuous stones are pushed to the left and right moving spaces to form a line perforation, so that the diameter of the line perforations and the mandrel 130 Can be made almost the same. As a result, even if the length of the soft layer in the underground composite layer L is long, it is a useful invention having an advantage of efficient and economical punching work.

100; PBD Composite Equipment
110; Conventional PBD equipment
120; leader,
P; PBD structure;
130; Mandrel, 132; PBD drainage,
S; Line perforation structure;
150; Hitting means, H; Vibrohammer, B; Breaker, 152; guide
160; Hitting rod, 162; Conical tip, 164; Braga, 166; Line perforation hole
170; Impact Suppression Wire, M; Hydraulic motor of forward and reverse rotation
172; Perforator wire drum, WA wire, WB wire
173; Tension cylinder, 174; A support fixing member, R; Roller, R1, R2, R3
L; Underground multiple layer

Claims (12)

In a conventional PBD equipment 110 equipped with a PBD structure P
A conventional PBD structure P is mounted on one side of the reader 120 of the PBD equipment 110 and a line perforation structure S is mounted on the other side of the leader 120. The PBD structure P includes a mandrel 130 And a PBD drainage member 132. The linear perforation structure S comprises the hitting means 150 and 150 and the hitting means 150 and the hitting rod 160 are coaxial While the pulling out of the striking rod 160 is carried out by the impact suppression pulling wire 170 while the impact restraining pulling wire 170 is pulled by the punching wire drum 172 rotated by the forward and reverse hydraulic motors M, The WA wire and the WB wire are respectively wound on the upper and lower ends of the hitting means 150. In this state, the drawing of the striking rod 160 is pulled out while the WB wire is unwound simultaneously with the winding of the WB wire, A line perforation hole 166 is formed along with the drawing of the PBD equipment 110 and the line perforation hole 166 and the swing of the PBD equipment 110, The PBD mandrel 130 is penetrated into the line perforation hole 166 while the PBD mandrel 130 of the PBD manifold 130 is aligned with the PBD mandrel 130 of the PBD mandrel 130. When the PBD mandrel 130 is re- And a PBD composite device equipped with a line perforation structure, characterized in that the PBD composite material is molded into a line perforation hole (166) of the composite layer (L)
The method of claim 1, wherein
The striking means 150 of the line perforation structure S is made of a breaker B while the impact suppression drawing wire 170 is fixed to the upper and lower ends of the breaker B while the gas compression is performed at the top dead center of the piston, PBD composite equipment equipped with line perforation structure characterized by blowing at the bottom dead center with the inflated gas force
The method of claim 1, wherein
Wherein the hitting means 150 of the line perforation structure S is configured such that the impact vibration is generated by the vibratory hammer H while the impact suppression drawing wire 170 is fixed to the upper and lower ends of the vibratory hammer H, PBD complex equipment equipped with
The method of claim 1, wherein
The hitting means 150 of the line perforation structure S comprises a vibrohammer H and a breaker B while the impact suppression drawing wire 170 is disposed on the top of the vibrohammer H and the breaker B, While the vibrator H and the breaker B are mounted on the same axis as the striking rod 160 while the breaker B is fixed to the lower end of the piston 160 and the gas compression is performed at the top dead center of the piston, PBD composite equipment equipped with a line perforation structure characterized by blowing at the bottom dead center with inflating force
The method of claim 1, wherein
The impact suppression drawing wire 170 wound with the WA and WB wires in the columnar perforator wire drum 172 rotated by the normal and reverse hydraulic motor M is fixed to the upper and lower ends of the hitting means 150, When the wire rod is wound, the WB wire is loosened and vice-versa. When the striking rod 160 is inserted into the underground composite layer L, the WA wire is wound to pull the hitting means 150 vertically downward The upward force of repulsion due to the hitting means 150 is suppressed and conversely the WB wire is wound and the striking rod 160 is pulled out while the wire of WA starting from the perforator wire drum 172 passes through the lower roller R3 And the wires of the WB starting from the perforator wire drum 172 are passed through the rollers R1 and R2 fixed to the support fixing member 174 provided at the middle upper portion of the leader 120, It goes down from level to level again. PBD composite equipment with a perforated line structure, characterized by fixed to the upper end of the case means 150 mounted
A PBD composite device 100 having a line perforation structure S mounted on one side of a reader 120 of a conventional PBD equipment 110 equipped with a PBD structure P, The line perforation is formed by the line perforation structure S of the PBD composite apparatus 100 and the PBD drainage material 132 by the line perforation structure S, Type is made by the conventional PBD structure P of the PBD composite apparatus 100 and the line perforation structure S and the PBD structure P are made by swinging while the line perforation structure S is made by the swing Wherein the penetration of the striking rod is effected by the striking means 150 and the drawing of the striking rod is performed by the upward force of the striking suppression wire 170 Wherein a line perforation is formed with the pulling of the intruding striking rod, and the diameter of the striking rod is determined by the diameter of the PBD structure (P) The vertical spacing is minimized and the spacing is minimized to improve the verticality and the stiffness of the discontinuous grinding stone is pushed to the left and right moving spaces by the pointed conical tip 162 of the striking rod, And a PBD drainage material (132) is formed in the underground composite layer (L) in the process of penetrating and inserting the PBD mandrel (130) of the PBD structure (P) into the line hole formed together with the drawing of the batting rod PBD type system in underground multi-layer system using PBD composite equipment equipped with perforated structure
The method of claim 6, wherein
The hitting means 150 of the line perforation structure S is composed of a vibratory hammer H and a breaker B mounted with a vibratory hammer H and a breaker B on the same axis as the hammer rod, (B) is a PBD type system using a PBD combined equipment equipped with a line perforation structure characterized by gas compression at the top dead center of the piston, and blow at the bottom dead center along with the compressed gas expansion force.
The method of claim 6, wherein
The impact suppression drawing wire 170 is wound on the perforator wire drum 172 in the form of WA, WB wire, the WA, WB wire is started in the perforator wire drum 172 and the WA wire is vertically moved up through the lower roller 3 Is fixed to the lower end of the striking means 150 and the WB wire vertically ascends toward the rollers 1 and 2 fixed to the support fixing member 174 installed at the intermediate upper portion of the leader 120 and then vertically descends again horizontally, The PBD type system having the line perforation structure is mounted on the upper part of the bottom plate 150,
A PBD structure P is mounted on one side of the reader 120 of a conventional PBD equipment 110 and a line perforation structure S is mounted on the other side of the reader 120. A conventional PBD structure P is mounted on a mandrel 130 and the PBD drainage material 132. The line perforation structure S comprises a breaker B and a hitting rod and the breaker B is a combination of an underground composite Layer (L);

The impact load of the line perforating structure S of the PBD combined equipment 100 installed on the underground composite layer L is hit by the breaker B and the gas compression is performed at the top dead center of the piston of the breaker B, At this time, the WA wire of the impact suppression drawing wire 170 fixed to the upper and lower ends of the breaker B is wound and the breaker B is wound on the breaker B, The WB wire of the impact-suppressing drawing wire 170 is wound while pulling the striking rod upward so that the striking rod is pulled out, and the striking rod is pulled up by pulling the striking rod up and down to suppress the upward repulsive force due to the striking of the breaker B, Forming a line perforation hole (166) in the underground composite layer (L) together with the drawing of the strike rod;

The PBD composite device 100 is swung so that the mandrel 130 of the conventional PBD structure P is penetrated into the line perforation hole 166 and the PBD drainage material 132 is removed in the process of drawing the mandrel 130 again. Into the underground composite layer (L);

And repeating the above steps to form a plurality of PBD drainage materials (132) in the underground composite layer (L), using the PBD composite equipment equipped with the line perforation structure. Construction method
The method of claim 9, wherein
In this step, the impact restraining drawing wire 170 is made of WA, WB wires, one end of the WA and WB wires is fixed to the upper and lower ends of the breaker B, and the other end of the WA and WB wires is a circular- 172, respectively, the WB wire is unwound when the WA wire is wound, and vice versa, and the wire of the WA starting from the perforator wire drum 172 vertically rises through the lower roller 3, And the wire of the WB starting from the perforator wire drum 172 is vertically lowered again from the horizontal through the rollers 1 and 2 fixed to the support fixing member 174 provided at the middle upper portion of the leader 120 And a step of forming a line perforation hole (166) in the underground composite layer (L) by being fixed to the upper end of the breaker (B). The PBD composite device equipped with the line perforation structure, Type construction method
A PBD structure P is mounted on one side of a reader 120 of a conventional PBD device and a line hole structure S is mounted on the other side of the reader 120. A conventional PBD structure P is mounted on a mandrel 130 And a PBD water discharger 132. The line perforation structure S is composed of a vibratory hammer H and a hitting rod and the vibrohammer H is connected to the PBD combined equipment 100 ) On the underground composite layer (L);

The hitting rod of the line perforation structure S of the PBD combined equipment 100 installed on the underground multiple layer L is typed into the underground composite layer L by the vibrohammer H, The WA wire of the impact suppression drawing wire 170 fixed to the upper and lower ends of the vibration suppression drawing wire 170 is wound while pulling the vibro hammer H and the hitting rod vertically downward to suppress the upward repulsive force due to the hitting of the vibrohammer H Conversely, when the WB wire of the shock-suppression drawing wire 170 is wound, the striking rod is pulled up to draw the striking rod, and a line perforation hole 166 is formed in the underground composite layer L together with the drawing of the striking rod;

The PBD composite device 100 is swung so that the mandrel 130 of the conventional PBD structure P is penetrated into the line perforation hole 166 and the PBD drainage material 132 is removed in the process of drawing the mandrel 130 again. Into the underground composite layer (L);

And repeating the above steps to form a plurality of PBD drainage materials (132) in the underground composite layer (L), using the PBD composite equipment equipped with the line perforation structure. Construction method
The method of claim 11, wherein
In the step (b), the impact restraining drawing wire 170 is made of WA, WB wires, one end of the WA and WB wires is fixed to the upper and lower ends of the breaker B, The WA wire starting from the perforator wire drum 172 is vertically moved up through the lower roller 3 and is wound around the vibe 172. The WA wire is wound up on the wire drum 172, And the WB wire starting from the perforator wire drum 172 is fixed at the lower end of the hammer H via the rollers 1 and 2 fixed to the support fixing member 174 installed at the intermediate upper portion of the reader 120, And forming a line perforation hole (166) in the underground composite layer (L) by fixing vertically down to the upper end of the vibro hammer (H), and using the PBD composite device equipped with the line perforation structure PBD type workshop in underground multiple layer method

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