This application claims the benefit under 35 U.S.C. § 119(a) of Korean Patent Application No. 2014-0097411, filed on Jul. 30, 2014, the disclosure of which is incorporated by reference in its entirety for all purposes.
1. Field
The present invention relates to a stepless variable auto stroke hydraulic breaker system and, more particularly, to a stepless variable auto stroke hydraulic breaker system capable of reducing impact energy reflected in the event of an idle blow by detecting, via a vibration sensor, a frequency or the number of vibrations generated when a chisel breaks objects such as bedrocks, operating with a short stroke if the frequency or the number of vibrations does not exceed a preset frequency or a preset number, and automatically switching the short stroke into a long stroke if the frequency or the number of vibrations exceeds the preset frequency or the preset number.
2. Description of the Related Art
In general, hydraulic breakers are used to break up rocks. Such a hydraulic breaker includes a housing that has a reciprocating piston controlled by a distribution valve and a cylinder bore, and a pressure accumulator. While the hydraulic breaker is in operation, the pressure accumulator is preliminarily pressurized to a pre-load pressure in order to prevent the hydraulic breaker from being damaged by a fluid cavity and a pressure gradient and increase performance of the hydraulic breaker, and transmits a blow to a chisel from the piston. Thereby, a chisel tip supplied with kinetic energy of the piston breaks a rock.
In the case of a rock composed of soft substances, energy remaining after the rock is broken is applied to components of the hydraulic breaker.
Therefore, a process in which applied kinetic energy is greater than energy required to break the rock is not desirable, because high stress occurs at the hydraulic breaker due to the energy remaining after the rock is broken. Thus, applying a rapid change in the kinetic energy to all operating conditions prolongs a life of the hydraulic breaker and is simultaneously an important requirement for optimal material breaking.
However, the conventional hydraulic breakers are driven before a supplied hydraulic pressure reaches a level higher than or equal to the pre-load pressure of the pressure accumulator, or are continuously driven after the supplied hydraulic pressure is reduced below the pre-load pressure of the pressure accumulator. That is, the pressure accumulator cannot be operated with precision. In detail, the pressure accumulator cannot absorb an undesired pressure gradient, cannot prevent a cavity in a hydraulic fluid, and cannot increase a flow of the fluid during an operating stroke of the piston. Therefore, there is a serious risk of certain portions of the impact mechanism being damaged.
To solve this problem, Korean Patent No. 10-1285062 has been proposed.
The preceding patent includes a housing 10 with a cylinder bore 11, a forward working chamber 23 and a rear working chamber 18, a hydraulic fluid supply passage 26 continuously connected to the forward working chamber 23 and a drain passage 33 connected to the rear working chamber 18, a hammer piston 12 reciprocally guided in the cylinder bore 11 in order to deliver hammer blows to a working implement 14 attached to the housing 10, a pressure accumulator 27 pre-loaded to a certain pressure level, and a distribution valve 30 for alternatingly connecting the rear working chamber 18 to the drain passage 33 and the supply passage 26 to thereby reciprocate the hammer piston 12, wherein a sequence valve 34 is provided in the drain passage 33 for the purpose of keeping the pressure in the rear working chamber 18 at such a level that the resulting forward directed force will prevent the piston 12 from being moved backward in the cylinder bore 11 at pressure levels in the supply passage 26 below the pre-load pressure level of the accumulator 27. Thereby, impact energy according to an idle blow is reduced.
However, the preceding patent has a problem in that it is still insufficient to reduce the reflected impact energy according to the idle blow.
[Patent Document 1] Korean Patent No. 10-1285062 titled “HYDRAULIC IMPACT MECHANISM” (registered on Jul. 4, 2013).
Accordingly, an object of the present invention is to provide a stepless variable auto stroke hydraulic breaker system in which a vibration sensor detects vibrations generated when a chisel breaks rocks and converts the detected vibrations into signals, a counter counts a frequency or the number of the vibrations corresponding to the generated signals, and thereby, according to the frequency or the number of the vibrations counted for a predetermined time, a stroke of a piston can be automatically adjusted from a short stroke to a long stroke, and vice versa.
In order to achieve the above object, according to an aspect of the present invention, there is provided a stepless variable auto stroke hydraulic breaker system, which includes: a vibration sensor configured to detect vibrations generated when a chisel breaks rocks; a transmitter provided with the vibration sensor and configured to transmit signals generated from the vibration sensor; a receiver configured to receive the signals transmitted from the transmitter; and a stepless variable auto stroke hydraulic breaker controlled by a reception micro controller unit (MCU) of the receiver.
As described above, in the stepless variable auto stroke hydraulic breaker system according to the present invention, according to the number of blows of the chisel, the piston is freely switched between a short stroke and a long stroke. Thus, due to the switching of the strokes, work efficiency is improved.
Further, as the stroke is shortened in the event of an idle blow, the remaining impact energy is reduced, and a life of the hydraulic breaker is increased.
The above and other features of the present invention will be described in reference to specific exemplary embodiments thereof with reference to the attached drawings in which:
Hereinafter, a stepless variable auto stroke hydraulic breaker system according to an embodiment of the present invention will be described in greater detail with reference to the accompanying drawings. When the detailed descriptions of known functions and configurations are determined as unnecessarily obscuring the subject matter of the present invention, they will be omitted. Technical terms, as will be described below, are terms defined in consideration of their functions in the present invention, which may be varied according to the intention or usual practice of a client, an operator, or a user, or the like, so that the terms should be defined based on the overall content of this specification.
Throughout the drawings, the same reference numerals are used to indicate the same components.
As illustrated in
Here, the transmitter 100 is made up of the vibration sensor 110, a transmission signal processor 120 for processing the signal generated by the vibration sensor 110 into a transmission signal, a transmission antenna 130 for transmitting the transmission signal processed by the transmission signal processor 120, and a transmission MCU 140 for controlling an operation of the transmission signal processor 120 and an operation of the transmission antenna 130.
In an operation of the transmitter 100 configured in this way, the signal generated by the vibration sensor 110 is processed into the transmission signal at the transmission signal processor 120, and the transmission antenna 130 transmits the processed transmission signal to the receiver 200 to be described below. At this time, the transmission MCU 140 controls the operations of the transmission signal processor 120 and the transmission antenna 130. The situation controlled in this way is transmitted to the receiver 200 (to be described below) to the transmission antenna 130. The transmitter 100 is mounted on an attachment, and is operated by a battery or a solar cell.
Further, the vibration sensor 110 is made up of a housing 111 that is formed of a metal, a protrusion 112 that is formed at an upper end of the housing 111, a pair of iron-magnet bias elements 113 that are mounted under the protrusion 112 and provide an electronic element with a predetermined operating point, a metal cap 114 that covers an upper portion of the housing 111, a ceramic insulator 115 that is mounted under the metal cap 114 and adjusts a magnetic field between a magnetic sphere 117 and the metal cap 114, a metal electrode 116 that passes through the metal cap 114 and the ceramic insulator 115 to be housed in the housing 111, and the magnetic sphere 117 that is contacted with or separated from the metal electrode 116 to thereby generate a signal and has magnetism.
When a vibration is generated by an operation of the chisel 308, the vibration sensor 110 configured in this way generates a signal in such a manner that the magnetic sphere 117 attached to the ceramic insulator 115 mounted under the metal cap 114 by the magnetic field between the metal cap 114 and the magnetic sphere 117 is detached from the ceramic insulator 115 by the vibration and is contacted with the metal electrode 116 housed in the housing 111. That is, when the magnetic sphere 117 is connected to the metal electrode 116, the signal is generated. When the magnetic sphere 117 is disconnected from the metal electrode 116, no signal is generated. Therefore, the magnetic sphere 117 is connected to or disconnected from the metal electrode 116 according to the vibration caused by the operation of the chisel 308, and thereby serves as a switch that generates signals at certain intervals. As a result, a frequency or the number of working strokes of a piston 302 of the stepless variable auto stroke hydraulic breaker 300 can be measured. The signals generated in this way are transmitted to the receiver 200 through the transmission antenna 130 via the transmission signal processor 120 of the transmitter 100 under the control of the transmission MCU 140.
Further, the receiver 200 is made up of a reception antenna 210 that receives the transmission signal transmitted by the transmission antenna 130 of the transmitter 100, a reception signal processor 220 that processes the transmission signal received by the reception antenna 210 into a reception signal, a reception controller 230 that transmits the signal processed by the reception signal processor 220 to a reception MCU 240, a light-emitting diode (LED) 250 that emits light to inform an operator of the stepless variable auto stroke hydraulic breaker 300 of the situation received by the reception controller 230, a counter 260 that counts the vibrations of the vibration sensor 110 under the control of the reception MCU 240, and the reception MCU 240 that controls operations of the reception antenna 210, the reception signal processor 220, the reception controller 230, the LED 250, and the counter 260 and controls a hydraulic impact mechanism of the stepless variable auto stroke hydraulic breaker 300.
In the receiver 200 configured in this way, the reception antenna 210 of the receiver 200 receives the transmission signal transmitted through the transmission antenna 130 of the transmitter 100, and the reception signal processor 220 processes the received transmission signal into a reception signal. The reception controller 230 transmits the processed reception signal to the reception MCU 240, and the reception MCU 240 informs the operator of the stepless variable auto stroke hydraulic breaker 300 of this situation using the light emitted from the LED 250. Thereby, the operator recognizes a present state of the working stroke. The receiver 200 is mounted on a cabin (not shown), is supplied with power, and is operated.
Hereinafter, the hydraulic impact mechanism of the stepless variable auto stroke hydraulic breaker 300 will be described in detail.
The stepless variable auto stroke hydraulic breaker 300 is provided with a hollow cylinder 301 and a piston 302 that is housed in the cylinder 301 and axially reciprocates in the cylinder 301. The piston 302 is provided with rear guide 304 and front guide 305 that are separated from each other by a circumferential recess 303. First piston face 302a and second piston face 302b directed to the outside of the circumferential recess 303 define rear cylinder chamber 306 and front cylinder chamber 307, respectively. Here, the first piston face 302a has a smaller area than the second piston face 302b. Movement of the piston 302 in a forward stroke direction is as indicated by a downward arrow shown in
The vibration sensor 110 is mounted at one side of an exterior of the cylinder 301. The working mechanism such as the chisel 308 is located at the exterior of the cylinder 301 and is mounted on an end of the piston 302. When a normal operation is performed, i.e., when the chisel 308 does not penetrate a rock to be broken, the piston 302 assumes a typical impact position.
A controller for movement switching of the piston 302 includes a control plunger 309a movable in a control valve 309. The control plunger 309a is provided with a small control plunger face 309b and a large control plunger face 309c. The small control plunger face 309b is continuously exposed to a working pressure by a resetting conduit 310. The working pressure is generated by a hydraulic pump 311. The first piston face 302a is also continuously exposed to the working pressure by a pressure conduit 312 communicating with the resetting conduit 310. An outlet 312a of the pressure conduit 312 is disposed at the cylinder 301 such that it is always located in the front cylinder chamber 307.
The large control plunger face 309c of the control plunger 309a is connected to the cylinder 301 by a switching conduit 313 such that an outlet 313a is connected to a reduced pressure return conduit 317 through the circumferential recess 303 in a normal operation state.
One side of the control valve 309 is connected to the pressure conduit 312 by a control conduit 314, and the other side of the control valve 309 is connected to a tank 316 through a return conduit 315. The control valve 309 is connected to the reduced pressure return conduit 317 whose outlet 317a is connected to the return conduit 315 through the circumferential recess 303. Therefore, the outlet 317a of the reduced pressure return conduit 317 and the outlet 313a of the switching conduit 313 are located a distance shorter than an axial length of the circumferential recess 303 away from each other.
Further, the control valve 309 is connected to the rear cylinder chamber 306 by an alternating pressure conduit 318. The second piston face 302b is adapted to be exposed to the working pressure that can be supplied to the rear cylinder chamber 306 by the alternating pressure conduit 318.
The control valve 309 can assume two valve positions. That is, the second piston face 302b can assume a return stroke position (right side) at which a pressure is reduced through the alternating pressure conduit 318 and the return conduit 315, and a working stroke position (left side) at which the working pressure is applied to the rear cylinder chamber 306 by the pressure conduit 312, the control conduit 314 connected to the pressure conduit 312, and the alternating pressure conduit 318 (left side). As a result of this operation, the piston 302 conducts the working stroke against a resetting force applied to the first piston face 302a in a direction of the downward arrow.
Meanwhile, the stepless variable auto stroke hydraulic breaker 300 according to the present invention includes a stroke valve 329 assuming a long stroke position and a short stroke position.
The stroke valve 319 is decided by a pressure applied by a flow rate control valve 320 such as an electric proportional pressure reducing (EPPR) valve or a solenoid valve operated under the control of the reception MCU 240.
An input side of the stroke valve 319 is connected to the pressure conduit 312 by a stroke control pressure conduit 321, and an output side of the stroke valve 319 is connected to the switching conduit 313 for the control valve 309 by an additional conduit 322.
As illustrated, when the flow rate control valve 320 is opened under the control of the reception MCU 240, a large quantity of flow rate is fed to the stroke valve 319 by the hydraulic pump 311, and the piston 302 is operated at a short stroke. When the flow rate control valve 320 is closed under the control of the reception MCU 240, the flow rate fed by the hydraulic pump 311 is interrupted, and the piston 302 is operated at a long stroke.
Here, a reference numeral 323 indicates a spring installed on an upper surface 319a of the stroke valve 319. The spring 323 provides a mechanical resetting function according to a change in hydraulic pressure.
Now, an operation of the aforementioned stepless variable auto stroke hydraulic breaker system according to the present invention will be described.
First, it is assumed that, when the reception MCU 240 of the receiver 200 installed in the cabin receives signals of the predetermined number of times, for instance, of 18 times or less, from the vibration sensor 110 for a predetermined time according to a model of the stepless variable auto stroke hydraulic breaker 300, the piston 302 is set to be operated at a short stroke.
When the chisel 208 does not penetrate a rock to be broken after the stepless variable auto stroke hydraulic breaker 300 is activated for work, the stroke of the piston is long, and thus a signal generated from the vibration sensor 110 attached to the transmitter 100 mounted on the attachment does not exceed the predetermined number of times for a predetermined time. This situation is transmitted to the reception antenna 210 of the receiver 200 through the transmission antenna 130 via the transmission signal processor 120 under the control of the transmission MCU 140. The situation received through the reception antenna 210 of the receiver 200 is transmitted to the reception MCU 240 through the reception signal processor 220 for processing it into a reception signal and the reception controller 230 for transmitting the received signal to the reception MCU 240. According to this situation, the reception MCU 240 sends the signal to the flow rate control valve 320 such that the flow rate control valve 320 is opened, and a large quantity of flow rate is fed from the hydraulic pump 311 to the stroke valve 319 and pressurizes a lower side of the stroke valve 319. Thereby, since an area of the lower side of the stroke valve 319 becomes greater than that of an upper side of the stroke valve 319, the stroke valve 319 is switched into an open position (first position), and the piston 302 continues to be operated at a short stroke.
In contrast, when the chisel 208 penetrates a rock to be broken after the stepless variable auto stroke hydraulic breaker 300 is activated for work, the stroke of the piston is short, and thus a signal generated from the vibration sensor 110 attached to the transmitter 100 mounted on the attachment exceeds the predetermined number of times for a predetermined time. The situation is transmitted to the reception antenna 210 of the receiver 200 through transmission antenna 130 via the transmission signal processor 120 under the control of the transmission MCU 140. The situation received through the reception antenna 210 of the receiver 200 is transmitted to the reception MCU 240 through the reception signal processor 220 for processing it into a reception signal and the reception controller 230 for transmitting the received signal to the reception MCU 240. According to this situation, the reception MCU 240 sends the signal to the flow rate control valve 320 such that the flow rate control valve 320 is closed, no flow rate is fed from the hydraulic pump 311 to the stroke valve 319, and the lower side of the stroke valve 319 is not pressurized. Thereby, since the area of the upper side of the stroke valve 319 becomes greater than the area of the lower side of the stroke valve 319, the stroke valve 319 is switched into a closed position (second position), and the piston 302 continues to be operated at a long stroke.
As described above, in the stepless variable auto stroke hydraulic breaker system according to the present invention, the counter 260 of the receiver 200 counts the signals which the vibration sensor 110 attached to the attachment transmits for a predetermined time. If the counted signals do not exceed a predetermined number, the piston 302 is operated at a short stroke. In contrast, if the counted signals exceed a predetermined number, the piston 302 is operated at a long stroke. According to the counted signals, the short stroke is automatically switched into the long stroke, and vice versa.
In the stepless variable auto stroke hydraulic breaker system according to the present invention, according to the number of blows of the chisel, the piston is freely switched between the short stroke and the long stroke. Thus, due to the switching of the strokes, work efficiency is improved. Further, as the stroke is shortened in the event of the idle blow, the remaining impact energy is reduced, and the life of the hydraulic breaker is increased.
Although a preferred embodiment of the present invention has been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. The disclosed embodiments should be taken into consideration not from a limitative point of view but from a descriptive point of view. The scope of the present invention is shown not in the above description but in the claims, and all differences within the range equivalent thereto will be understood to be incorporated in the present invention.
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