KR20210102656A - Split wedge for reducing friction - Google Patents

Abstract

The present invention relates to a split wedge for reducing a frictional force. More specifically, a plurality of optical fiber rod friction parts having a low frictional force while having excellent durability are installed on both sides of a split wedge body producing friction with a pair of semi-split bodies installed in the center of a rock cracking head to be liftable to be placed tightly on both sides, and the pair of semi-split bodies producing friction with the plurality of optical fiber rod friction parts on both sides of the split wedge body producing the friction have parts of different materials producing friction with each other to make a considerable reduction in the frictional force, and, as a result, the ascending and descending of the split wedge is made to be smooth and a hydraulic force for lifting the split wedge is fully consumed by the descending of the split wedge to generate a large rock cracking force, which can lead to the efficient use of the rock cracking head, and also, since the frictional force is reduced during operation, the split wedge and the pair of semi-split bodies are prevented from being attached to each other, and, as a result, the split wedge can be used without repairing work, which can lead to fast construction and a low maintenance cost.

Description

Split wedge for reducing friction

The present invention relates to a split wedge for reducing friction, and more specifically, it is installed in the center of the head for rock cracking and rubs against a pair of half-shaped split bodies arranged in close contact with both sides of the split wedge body. A pair of split-type split bodies rubbing against a plurality of fiber optic rod friction parts on both sides of the split wedge body where friction is generated by installing a plurality of fiber optic rod friction parts with low frictional force and excellent durability on both sides is the material of the rubbing part Since the frictional force is significantly reduced because of these differences, the lowering and ascending of the split wedge becomes smooth, and the hydraulic force for raising and lowering the split wedge is used for the lowering of the split wedge as it is. The head can be used and the frictional force is reduced during operation, so the adhesion between the split wedge and the pair of split splits is prevented. It relates to a split wedge for reducing friction.

In general, in rock destruction work to construct a tunnel in a rock zone for stone production in a quarry or to construct a road or railroad, conventionally, a method of breaking the rock to be destroyed with a rock drill or a chisel, or a mechanized cracker A non-blasting method is used, such as smashing small wedges and breaking them by hitting them alternately, or a blasting method in which explosives are loaded and detonated to break a hole in the bedrock with a crusher.

The non-blasting method generates a lot of dust even when a lot of effort is put into it, and the noise is also very large enough to make life uncomfortable, so it is inefficient and inefficient such as acting as a very loud noise to the workers or surrounding residents and causing disputes. There was a problem in that an inefficiency problem was generated, and the risk of injury to the worker during the operation was increased.

In addition, although the blasting method has the advantage that the rock demolition work can be carried out in a short time, the explosion, vibration, and impact of the explosives are large, so the shock is applied to the buildings installed nearby, and the cracks of the nearby buildings are generated. In case of blasting, stone fragments blown away at the time of blasting have a very high risk of causing injury to people living nearby, so use them carefully. There was a problem being

In order to solve this problem, as shown in FIG. 1 , the hydraulically operated head 10 and the head 10 are formed to be divided into two equal parts and tapered to become smaller in the longitudinal direction and installed at the lower end of the head 10 . It is inserted between a pair of split-type split body 20 and the pair of split-type split body 20 and is fixed to a wedge movable shaft 11a installed in the head 10 and operated so as to move up and down. A rock cracking head (B) is proposed, which is composed of a split wedge (30) tapered downward and taper, and the split wedge (30) has a fixed part (31) on its upper part of the hydraulic part (11). ) is inserted between the split-type split body 20 in a state of being fixed by a fixing pin 11d to the lower part of the wedge movable shaft 11a accommodated in the inside, so that the wedge movable shaft 11a is lowered by hydraulic pressure. When the wedge-shaped split body 20 is opened while descending simultaneously with the movable shaft 11a, a crack S2 is generated in the split hole S1 of the rock S by the force of the force, and on the contrary, the hydraulic pressure When sucked in, the wedge movable shaft 11a is raised and lowered and the split wedge 30 is also raised and lowered, so that the split split body can be separated from the split hole S1, but the split wedge 30 is the split split Since it is formed of the same metal material as the main body 20, frictional force is generated with the neighboring divided body 20 when the dividing wedge 30 is operated, so the hydraulic force to operate the dividing wedge 30 by the frictional force Since more than half is consumed, there is a problem in that it takes more than half of the force to open the split-type divided body 20, so that a large force cannot be exerted. And, when the split wedge 30 is completely lowered or a large frictional force is generated during the descent and a lot of frictional heat is generated, the portion where the frictional force between the splitting wedge 30 and the splitting body 20, which are metal components, is generated is high in frictional heat. In order to separate the split wedge 30 and the split body 20 that are adhered to each other, first stop the operation of the rock cracking head (A) and split the fused split wedge 30 and the split Since the fusion surface of the main body 20 is separated and the head (B) for rock cracking is re-processed again after separation, there is a problem that a lot of time and effort is required.

In order to solve this problem, as shown in Fig. 2, the wedge body 31 extending in the longitudinal direction and having a synthetic resin attachment space 31v to which the synthetic resin plate body is to be attached is formed on the contact surfaces 31b of both front and rear surfaces. provided, and in the synthetic resin attachment space 31v of the wedge body 31, a divided wedge 30 having a synthetic resin plate body 32 fixed has been proposed, but the divided wedge 30 has a reduced frictional force at the beginning of use. Although it works smoothly, since a lot of vibration and friction are generated during use, when it is used for about 3 months, the synthetic resin plate body 32 is separated from the surface of the wedge body 31 due to the generated vibration and frictional force. There was a problem that expensive equipment could not be used because the entire head (B) for rock cracking could not be used.

Registered Patent 10-1613043

An object of the present invention is to solve this problem, and frictional force is provided on both sides of the split wedge main body in friction with a pair of semi-split-type split bodies that are installed in the center of the rock cracking head to be lifted and disposed in close contact with both sides. A pair of split-type split bodies that rub against the fiber optic rod friction parts on both sides of the split wedge body where friction is generated by installing a large number of small and durable fiber optic rod friction parts have significant frictional force due to the different materials of the parts rubbed against each other The lowering and ascending operation of the split wedge becomes smooth, and hydraulic force is used for the lowering of the split wedge as it is, so a large rock cracking force is generated and the head for rock cracking can be used efficiently, and the friction force is reduced during operation. Therefore, since the adhesion between the split wedge and the pair of half split body is prevented, it can be used without repair, so that the construction proceeds quickly and the maintenance cost is low to provide a split wedge for reducing friction.

It is an object of the present invention to provide a plurality of optical fiber rods on both sides of the split wedge body, where a plurality of optical fiber rod friction parts with excellent durability and low frictional force due to the inclusion of glass material on both sides of the split wedge body are installed to generate friction. A pair of halves rubbing against the friction part is achieved by the split wedge for reducing friction according to the present invention, in which the materials of the parts rubbed with each other are different from each other and the friction force is significantly reduced by the glass component of the friction part of the optical fiber rod.

In the split wedge for reducing friction according to the present invention, a plurality of optical fiber rod friction parts with low frictional force and excellent durability are installed on both sides of the split wedge body, and a pair of halves rubbed against both sides of the split wedge body where friction is generated The split body has different materials rubbing against each other and is slippery due to the glass component of the fiber optic rod friction part, so the friction force is greatly reduced. Since it is required for the lowering of the multi-split wedge, a large rock-cracking force is generated so that the head for rock-cracking can be efficiently used. Since this is prevented, it can be used without repair, which has an excellent effect of speeding up construction and reducing maintenance costs.

1 is a schematic longitudinal cross-sectional view of a conventional rock cracking head;
Figure 2 is a schematic longitudinal cross-sectional view of the split wedge of the head for rock cracking provided with another conventional split wedge reduced frictional force;
3 is a perspective view of a split wedge for reducing friction according to a first embodiment of the present invention;
4 is a schematic longitudinal sectional view of a split wedge for reducing friction according to a first embodiment of the present invention;
5A and 5B are a partially cut perspective view of a rock crack head installed with a split wedge for reducing friction according to the first embodiment of the present invention, and an enlarged cross-sectional view of a crushed state of the fiber optic rod friction part and the half split body;

The split wedge A for reducing friction according to the first embodiment of the present invention is, as shown in FIGS. 3 and 4, a plurality of optical fiber rods with low friction and excellent durability on both sides of the split wedge body 31. A friction part 4 is provided.

The split wedge body 31 of the split wedge A for reducing friction has the same structure as in the prior art that the upper part is wide and the lower part is formed in a tapered shape with a narrow width, and a plurality of fixing grooves 32 are formed on both sides. However, the present invention is not limited thereto, and it will be natural that a plurality of fixing holes to be penetrated may be formed instead of the fixing groove 32 .

An adhesive 41 is applied in the fixing groove 32 and a diameter slightly larger than the diameter of the fixing groove 32, for example, when the diameter of the fixing groove 32 is 15 mm, a diameter of about 15.5 mm The fiber optic rod friction part 4 having a

The height of the fiber optic rod friction part 4 is formed to be higher than the depth of the fixing groove 32 to protrude from the surface of the split wedge body 31, for example, to protrude about 1 mm. Thus, the fiber optic rod friction part 4 is rubbed while in contact with the inner surface 20a of the half-shaped divided body 20 of the rock crack head (B).

In addition, the optical fiber rod used as the optical fiber rod friction part 4 is an aggregate of optical fibers, and optical communication is widely used in long-distance high-speed wired communication, and recently, it is also widely used in subscriber network communication through FTTH (fiber to the home) technology, Optical fiber is widely used as a physical transmission medium of such optical communication. The commonly used silica optical fiber has an advantage in that it is easy to connect light sources, detectors, or optical fibers because the diameter is very large compared to single-mode optical fibers with a core diameter of about 8 microns. It has the disadvantage that a large amount of data cannot be transmitted due to the modal dispersion phenomenon caused by the difference in propagation speed. As an optical fiber that minimizes dispersion, a graded index silica optical fiber has been proposed. Recently, a graded index type plastic optical fiber that is easier to handle than silica optical fiber and has a wider transmission bandwidth has been developed for short-distance optical communication and home networks. , The optical fiber rod in which the optical fiber is formed into a rod shape can be used as the optical fiber rod friction part used in the present invention.

In the fiber optic rod friction part 4, when combustion gases such as H2 and O2 generated by the burner and reaction gases such as SiCl4 and GeCl4 are supplied at a predetermined flow rate, a high temperature state is induced by the combustion reaction of the combustion gas, Accordingly, material particles such as SiO2 and GeO2 are generated from the reaction gas, the generated particles are deposited to a predetermined thickness on the surface of the rotating parent rod, and the material particles such as SiO2 and GeO2 are H2O in which the reaction gas is a combustion product. It is produced by direct oxidation reaction with O2, which is a carrier gas, in a high temperature environment of 1100℃ or higher formed by the burner, and fine particles such as SiO2 and GeO2 are produced through processes such as first stone, agglomeration, etc. to 02μm in diameter. A rod-shaped optical fiber rod, which becomes particles of a certain degree, is deposited on the surface of the rotating parent rod in that state and cooled to a certain length, for example, when the diameter of the optical fiber rod is 15 mm, it is cut to a length of 7 mm and used. will be. And, the fiber optic rod friction part 4, for example, has been mentioned as an optical fiber rod used for optical communication, but it is not only an optical fiber rod, but also contains quartz or silica sand, which is slippery and has excellent wear resistance, or a glass fiber component and fine holes are formed. It will be said that other materials can also be used.

The fiber optic rod friction part 4 used in this way was found to withstand a press pressure of 25 ton/cm 2 based on a diameter of 15 mm, and the fiber optic rod friction part 4 hardly wears after this test. appeared to be Therefore, in this embodiment, since 114 fiber optic rod friction parts 4 are installed only on one side of the split wedge A for reducing friction, it is possible to withstand a pressure of 2,850 tons. , it was confirmed that it can withstand a pressure of 5,700 tons, and almost no wear of the fiber optic rod friction part 4 occurs.

The operation of the split wedge (A) for reducing friction according to the present invention having such a structure will be described in detail below.

In a state where a pair of split-type split bodies 20 of the head for rock cracking (B) are inserted into the split hole (S1) of the rock (S) excavated to the depth required for cracking the rock, In this case, the split wedge (A) is operated to be lowered (same as shown in FIG. 1).

The split wedge (A) has a plurality of fiber optic rod friction parts 4 fixed on both sides of the split wedge body 31, so that when the split wedge A is lowered, the fiber optic rod friction part 4 and When the inner surface 20a of the pair of semi-divided body 20 in contact with each other is in close contact and the split wedge A is further lowered, since the upper side is formed in a wide wedge shape, it becomes wider on the same plane. The optical fiber rod of the split wedge (A) in contact with the inner surface 20a of the pair of halved divided bodies 20, which is operated to crack the rock while the pair of split-shaped divided bodies 20 is spread apart, is rubbed against each other The friction part 4 is made of different materials, and the fiber optic rod friction part 4 has a structure in which silica sand and glass fiber and fine through-holes are formed. The hydraulic force for lowering A) is required for the lowering of the split wedge (A) as it is.

That is, the plurality of fiber optic rod friction parts 4 fixed on both sides of the split wedge A are made of a slippery material containing a lot of silica sand and glass fiber, whereas the split split body 20 is metal, so each other Since the materials in contact are different from each other and almost no frictional force is generated, the power consumption due to friction is greatly reduced.

Therefore, in the split wedge (A) for reducing friction according to the present invention, the friction force is significantly reduced, so that the lowering and ascending operations of the split wedge (A) are smoothed, so that the hydraulic force is required for the lowering of the multi-split wedge (A) as it is. Therefore, a large rock cracking force is generated, and even if it has a small hydraulic force, it can be used efficiently for rock cracking work.

In addition, the head (B) for rock cracking provided with the split wedge (A) for reducing friction according to the present invention reduces frictional force during operation, so that the split wedge (A) and the pair of half split body (20) Since fusion is prevented, it is possible to perform rock cracking work throughout the rock cracking operation time, so it is possible to use workers efficiently, resulting in a lower cost of rock cracking work.

As described above, in the split wedge (A) for reducing friction according to the present invention, a plurality of optical fiber rod friction parts with low frictional force and excellent durability are installed on both sides of the split wedge body, and friction is generated on both sides of the split wedge body and friction A pair of split-type split bodies to be used have different materials for the parts rubbed against each other, and in particular, the friction force of the split wedge body is significantly reduced, so the lowering and raising of the split wedge becomes smooth, so that the hydraulic force is applied to the lowering of the split wedge as it is. As a result, a large rock cracking force is generated so that the head for rock cracking can be used efficiently, and the friction force is reduced during operation, so the adhesion between the split wedge and the pair of half split parts is prevented, so it can be used without repair. This allows for faster construction and lower maintenance costs.

The split wedge for reducing friction according to the present invention will be said to be an invention with industrial applicability because it will be possible to repeatedly manufacture the same product in the industry for manufacturing a general rock cracking head.

A: Split wedge 4: Fiber optic rod friction part
31: split wedge body 32: fixed groove

Claims (2)

In the split wedge (A) for reducing friction,
The split wedge (A) for reducing friction force, the split wedge body (31) of the split wedge (A) for reducing friction is formed in a tapered shape in which the upper part is wide and the lower part is narrow,
A plurality of fixing grooves 32 are formed on both sides of the divided wedge body 31,
A split wedge for reducing friction, characterized in that the fiber rod friction part (4) is fixed in each of the fixing grooves (32).
According to claim 1,
The height of the fiber optic rod friction part (4) is formed higher than the depth of the fixing groove (32), so that it is formed to protrude from the surface (31a) of the split wedge body (31). wedge.

Images