KR19980072547A - Quarry Water Jet Slotter - Google Patents

Abstract

An object of the present invention relates to a water jet throttle for quarrying to collect and cut stone resources such as granite, marble, etc. more efficiently, and in particular, rock cutting using high pressure water generated through a water jet system. The present invention relates to a water jet slotter for quarrying which allows for the formation of slots in rock.

The configuration of the present invention is that when the rotational movement of the nozzle vibration motor 1 is applied to the motive roller 3a mounted on the eccentric shaft 2 and transmitted to the chuck assembly 5 through the driven roller 3b engaged therewith. The force exerted by the chuck assembly 5 is applied to the vibration cushion urethane 4, and the vibration cushion urethane 4 generates a restoring force upon receiving the force, and conversely, applies the force in the opposite direction to the chuck assembly 5. Repeatedly, the jet lance 6 coupled to the chuck assembly 5 is vibrated, and the high pressure water generated by the high pressure pump is injected into the target rock through the jet lance 6 and the injection nozzle 7 through the high pressure pipe. .

Description

Quarrying, water jet slotters

The present invention relates to a water jet slotter for quarrying to collect and cut stone resources such as granite and marble more efficiently. Particularly, the present invention relates to a rock for cutting rocks using high pressure water generated through a water jet system. The present invention relates to a water jet slotter for quarrying which allows for the formation of slots in the.

In general, a water jet system is a system for cutting and removing various materials by compressing a fluid by using a high pressure pump and spraying it through a nozzle. The maximum jetting pressure is about 400 MPa, and the speed of jet flow is Is supersonic at Mach 3 or so.

Since the water jet system was first introduced in 1968, the development and application of the equipment has been rapidly expanding. Typical applications for the use of the Hanjae water jet system include: 1) cutting, drilling, and milling various materials such as rock, metal, and plastic. Cutting and processing applications such as 2) removal of coding, cleaning of metal surfaces such as ships, removal of rust or deposits, etc. 3) mining and tunnel applications such as coal mining, mining, and auxiliary means for tunneling.

In particular, attempts to apply water jet equipment to quarrying have been a trend that has been developed around technological propaganda countries.

Quarrying applications of conventional water jet systems should be able to cut slots with the depth and direction needed in the rock to collect raw stones or form large blocks. As the separation distance increases gradually, the depth of cut decreases gradually, and when the separation distance increases beyond a certain threshold level, the material is no longer cut. In this case, even if the multi-administration method is adopted, the same phenomenon occurs because the number of strokes reaches a limit where the depth of cut no longer increases.

Therefore, in order to cut a deep slot in a rock by using a water jet, it should be possible to maintain a constant separation distance at any depth. If only a constant separation distance is maintained, it is possible to cut a slot of any depth necessary early on. Will be.

In order to maintain a constant separation distance, the injection nozzle must be able to enter a slot formed in the target material, and therefore, a device that can cut a slot having a width sufficient to enter the nozzle is required. In order to cut the slot, it is necessary to implement a mechanism for causing the rotational motion, the rotary vibration motion or the vibration motion of the injection nozzle. In the case of rotational movement, the leakage problem inherent in the high-pressure swivel is expected, which may deteriorate the practicality and economical efficiency of the device. In the case of rotary vibration, there is no leakage problem, but since the torsion of the high pressure hose equipped with the injection nozzle is expected, there is a need for procuring suitable high pressure parts.

And most of the quarry in Korea is producing raw stones mainly in quarrying method using jet burner, drilling and blasting, diamond wire, etc.Blast blasting method can be seen as the most influential method with its simplicity and economic efficiency. However, when using long blasting to form large blocks, there is a disadvantage in that cracks are generated in the rock. In the case of jet burners, there are problems such as environmental constraints due to high noise levels exceeding l40 dB, loss of gemstones due to a wide cutting width of about 100 mm, and thermal deformation of the rock due to generated heat.

The present invention has been made in consideration of the above circumstances, and a first object thereof is to provide a water jet slotter for quarrying employing a vibrating motion mechanism that does not need to separately manufacture a leakage problem and a high-pressure part.

It is a second object of the present invention to provide a quarrying water jet slotter capable of realizing vibratory motion with a simple and stable mechanical mechanism in consideration of field applicability.

According to the present invention, when the rotary motion of the nozzle vibrating motor is applied to the driving roller mounted on the eccentric shaft and transmitted to the chuck assembly through the driven roller engaged therewith, the force received by the chuck assembly is a vibration cushion. It is also applied to urethane, and this vibration cushion urethane generates a restoring force under the force, causing the jet lance coupled to the chuck assembly to vibrate while repeating the application of the opposite force to the chuck assembly. This is accomplished by providing a quarry water jet slotter that is jetted through the high pressure pipe through the jet lance and the spray nozzle into the target rock.

1 is a front view of the present invention,

2 is a perspective view of a nozzle vibration device according to the present invention,

3 is a trajectory diagram of the injection water according to the present invention,

Figure 4 is a schematic diagram showing the movement of the nozzle according to the present invention.

* Explanation of symbols for the main parts of the drawings

1: Nozzle Vibration Motor 2: Pin Core Shaft

3a, 3b: Roller 6: Jet Lance

7: injection nozzle 8: horizontal feed motor

9: guide rail 10: vertical feed motor

11: helical gear 12: support frame

14: anchor bolt 16: rock

A: amplitude a: vibration angle

b: injection angle s: separation distance

w: cutting width

Next, embodiments of the present invention will be described in detail with reference to the drawings.

Figures 1 and 2 show a water jet slotter for quarrying according to the present invention, the water jet slotter for quarrying, as shown in Fig. 1, the slotter itself is simply a conveying system as shown in Fig. ) Is moved in the vertical and horizontal directions.

The nozzle vibrator 18 is installed on the support frame 12 and is moved in the horizontal direction along the guide rail 9 by the rotation of the horizontal feed motor 8.

The vertical feed motor 10 moves the support frame 12 in the vertical direction through the helical gear 11, and thus the nozzle vibration device 18 installed in the frame 12 moves vertically.

On the other hand, the high pressure water generated by the high pressure pump (not shown) is transported along the high pressure pipe (not shown) and passes through the jet lance 6 and the injection nozzle 7 in turn to the target rock 16. Is injected into, and the slot of the wide width is cut by the vibrating movement of the nozzle vibrator 18.

The nozzle vibrator 18 is the core of the slotter developed as a part causing the vibrating movement of the nozzle 7 as shown in FIG.

The nozzle vibrator 18 is located on the guide rail 9, mounts a jet lance 6 with the injection nozzle 7, and is a part that is responsible for vibration and horizontal movement of the injection nozzle 7.

The horizontal movement of the nozzle 7 moves the vibrating device part itself on the guide rail 9 by the rotation of the horizontal feed motor 8.

The mechanism used to implement the vibrating motion of the nozzle 7 is as follows.

First, the rotational movement of the nozzle vibration motor 1 is converted into an intermittent force in one direction by the eccentric shaft 2, which is applied to the driving roller 3a mounted on the eccentric shaft 2, again. It is transmitted to the chuck assembly 5 through the driven roller 3b.

The force received by the chuck assembly 5 is also applied to the lower vibration cushion urethane 4 at the same time, and the urethane 4 generates a restoring force upon receiving the force, thereby inversely applying a force in the opposite direction to the chuck assembly 5. As the process is repeated, the jet lance 6 held in the chuck assembly 5 vibrates.

The driving roller (3a) and the driven roller (3b) is to minimize the wear of the components generated in the process of transmitting the force, to evenly transfer the force, the chuck assembly (5) is a high pressure jet lance (6) It also performs the function of fastening and tightening properly so as not to cause wear or deformation.

On the other hand, in the slotter according to the present invention, since the vibrating motion of the lower part of the jet lance 6 relative to the driven roller 3b hardly restrains the upper part of the jet lance 6, the high-pressure water input hose is provided at the upper end of the jet lance 6. Can be mounted freely.

The vibration frequency of this injection nozzle 7 is up to 30 Hz (cycle / sec).

The transfer motors 8 and 10 perform the function of moving the nozzle vibrator 18 in the vertical and horizontal directions, and use compressed air or electricity as a power source according to the conditions of the quarries.

In terms of cutting performance, the feed motor 8 is economical only at feed rates of up to several hundred mm / sec in the horizontal direction.

In these slotters, the electric motor is used to adjust the maximum feed speed in the horizontal direction to 300 mm / sec. You can do it.

The control system controls the horizontal and vertical movement of the nozzle vibrator 18 and the vibratory movement of the nozzle 7 and is capable of operating in automatic and manual modes.

In the automatic mode, when the nozzle vibrator 18 reaches the end of the stroke, the movement direction is changed by the stop switch, and the nozzle vibrator 18 descends according to the step-by-step falling value input, and automatically starts the next stroke.

In manual mode, the vertical and horizontal movements are directly controlled at the end of each stroke. In one system, the number of strokes cannot be controlled, but in the manual mode, the next stroke can be implemented by not giving a fall value arbitrarily.

The diameter of the jet lance 6 is 14 mm but can vary in diameter and length depending on site conditions or needs.

The slotter according to the present invention causes the vibration of the injection nozzle 7 to cut a slot wide enough to allow the nozzle 7 to fully enter. It is possible to completely remove the constituent rock material.

Figure 3 schematically shows the trajectory of the nozzle having two sprayed water formed on the surface of the material as shown in Figure 3, the dotted line is the First Angled Jet, the solid line is the Second Angled Jet, Vf is Traverse Velocity (mm / sec), Vt is Linear (Traverse) Velocity of Jet (mm / sec).

Meanwhile, FIG. 4 three-dimensionally expresses the concept of the vibrating motion of the nozzle 7, and includes the vibration direction, the moving direction, the vibration angle (a), the injection angle (b), the separation distance (s), and the full width of the nozzle 7. (A) is shown.

Here, although the vibration direction of the nozzle 7 is perpendicular to the moving direction, the vibration direction of the nozzle 7 may have an arbitrary angle with respect to the moving direction. In particular, the vibrating nozzle may be spaced apart. If the distance is short, the full width becomes smaller than the diameter of the nozzle, and in this case the entry of the nozzle becomes impossible.

Therefore, in the case of a vibrating nozzle, an appropriate minimum separation distance is required. Although wide slots are required for the entry of the nozzle, cutting too wide a slot can result in excessive energy consumption and loss of gemstones. By setting the spray angle and the separation distance, a slot wider than the width of the nozzle is created.

Therefore, the nozzle should be as small as possible and it is preferable to use a nozzle having an appropriate injection angle, it is preferable to adopt a nozzle having a jet angle of about 45 °.

In other words, when the rotational motion of the nozzle vibration motor 1 is applied to the motive roller 3a mounted on the eccentric shaft 2 and transmitted to the chuck assembly 5 through the driven roller 3b engaged therewith, the chuck The force exerted by the assembly 5 is also applied to the vibration cushion urethane 4, and the vibration cushion urethane 4 generates a restoring force upon receiving the force and conversely repeats applying the force in the opposite direction to the chuck assembly 5 while being reversed. The jet lance 6 coupled to the chuck assembly 5 is vibrated, and the high pressure water generated in the high pressure pump is sprayed to the target rock through the jet lance 6 and the injection nozzle 7 through the high pressure pipe.

In the accompanying drawings, reference numeral 14 denotes a component that functions to secure the slotter to the rock surface as an anchor bolt.

I will explain the effects.

When the present invention is introduced into the quarrying method, the cutting width may vary depending on the diameter of the nozzle and the depth of the slot to cut, that is, the size of the raw stone to be collected. Compared to the 0.8-1m ² / h of the jet burner, the cutting performance is lower than the noise level and the cutting capacity is 1 to 3 m ² / h.

In addition, the cutting operation can be performed regardless of the direction of the target rock surface to be cut or the cutting position on the rock surface.

In addition, noise and dust are less likely to occur in a situation where various environmental conditions are increasing in recent years, and since the spray water itself functions as a coolant, there is no fear of thermal deformation on the rock to be cut. It can be produced in a natural state without compromising quality.

Therefore, it is an excellent invention which can improve the productivity of natural stone extraction and quarrying operations.

Claims (1)

When the rotational movement of the nozzle vibration motor is applied to the driving roller mounted on the eccentric shaft and transmitted to the chuck assembly through the driven roller engaged therewith, the force applied to the chuck assembly is also applied to the vibration cushion urethane, which is the vibration cushion urethane. When it is received, it generates a restoring force and reversely applies the force in the opposite direction to the chuck assembly, causing the jet lance coupled to the chuck assembly to vibrate, and the high-pressure water generated from the high pressure pump passes through the jet lance and the spray nozzle A quarry water jet slotter, characterized in that the sprayed rock to the target rock.