The present invention relates to an engineering machine, in particular to an engineering breaking device.
At present, the hydraulic breaking hammers used in engineering projects have the power source from excavators, loaders or pumping stations. The working principles for the driving include full-hydraulic type, hydraulic-pneumatic combination type, nitrogen explosion type and so on, in which steel chisels are driven by the piston motion to generate on rocks the impact force by which the rocks are broken. For example, the above technologies can be seen in Chinese patent publication number CN2688815, the title of which is “Hydraulic Breaking Hammers for Engineering Trucks”, and Chinese patent publication number CN3481445, the title of which is “Hydraulic Breaking Hammers”, and so on. The above technologies have the advantages of applications in a wide range and easy operation; however, they have shortages, such as low efficiency, high noise, serious damages to the driving excavator caused by the reaction of the impact force and incapability of breaking large rocks.
The purpose of the present invention is to provide a hydraulic resonant breaking hammer, to solve the problems of the existing engineering breaking devices, such as low efficiency, high noise, serious damages to the driving excavator caused by the reaction of the impact force and incapability of breaking large rocks.
The present invention solves the above technical problems by the following technical solution: a hydraulic resonant breaking hammer of the present invention comprising a hydraulic driving system, a vibration exciter 2, a control system, a linkage mechanism and a breaking hammer head 3.
The hydraulic driving system consists of a hydraulic motor 1, an electric-control hydraulic distributing valve 12, a hydraulic pump 13 and an engine 14. The output end of the engine 14 is connected to the hydraulic pump 13, the output end of the hydraulic pump 13 is connected to the electric-control hydraulic distributing valve 12, and the output end of the electric-control hydraulic distributing valve 12 is connected to the hydraulic motor 1. The engine 14 drives the hydraulic pump 13 to generate pressure oil, which is regulated by the electric-control hydraulic distributing valve 12 and output to the hydraulic motor 1, therefore to drive the hydraulic motor 1 to rotate.
The vibration exciter 2 consists of a box 4 and at least one group of eccentric wheels consisting of two eccentric wheels which are arranged symmetrically on left and right sides and installed in the box and the rotating shafts of which are provided with a pair of gears 11 engaged with each other, in which the rotating shaft of one of the eccentric wheels is connected to the hydraulic motor 1. The hydraulic motor drives the rotating shaft of said one of the eccentric wheels to rotate, via the gears that are engaged with each other, to achieve reverse synchronous rotation of the two eccentric wheels.
The control system consists of a sensor 16, a microcomputer controller 17 and the electric-control hydraulic distributing valve 12. The sensor 16 is installed on a machine frame 7, the output end of the sensor 16 is connected to the microcomputer controller 17, and the output end of the microcomputer controller 17 is connected to the electric-control hydraulic distributing valve 12. The sensor 16 senses the vibration feedback of rocks being broken and inputs feedback signals to the microcomputer controller 17, the microcomputer controller 17 analyzes the vibration situation of rocks to find out the natural frequency of the rocks being broken, the microcomputer controller 17 outputs corresponding control signals to the electric-control hydraulic distributing valve 12. The electric-control hydraulic distributing valve 12 can adjust the flow rate output to the hydraulic motor 1, and control the rotation speed of the hydraulic motor 1 by controlling the flow rate output to the hydraulic motor 1, thus to control the vibration frequency of the vibration exciter 2.
The linkage mechanism consists of the machine frame 7, a guide rail 9 and a damper spring 8. The machine frame 7 is installed on a fore arm 10 of an excavator, the guide rail 9 is arranged on the machine frame 7, the box 4 of the vibration exciter 2 is arranged on the guide rail 9 and forms an up-and-down sliding fit with the guide rail 9, and the damper spring 8 is connected between the upper part of the box 4 and the machine frame 7.
The breaking hammer head 3 is arranged at the lower part of the box 4.
The breaking hammer head 3 is of a tapered structure.
The hydraulic resonant breaking hammer according to the present invention is a breaking machine that has high efficiency, low noise, capability of breaking large rocks and slight damages to the main mechanism. The machine breaks rocks by means of resonant vibration instead of impact force.
The hydraulic resonant breaking hammer according to the present invention has the advantages of high working efficiency, low noise, no damages to the driving excavator and capability of breaking larger rocks.
In the drawings: hydraulic motor 1, vibration exciter 2, breaking hammer head 3, box 4, eccentric wheel A 5, second eccentric wheel B 6, machine frame 7, damper spring 8, guide rail 9, fore arm 10 of an excavator, gears 11, electric-control hydraulic distributing valve 12, hydraulic pump 13, engine 14, pulley 15, sensor 16, microcomputer controller 17.
The present invention will be described in details below by means of an optimal embodiment in conjunction with the drawings.
With reference to
The function of the control system lies in: the sensor 16 senses the vibration feedback of rocks being broken and inputs feedback signals to the microcomputer controller 17, the microcomputer controller 17 analyzes the vibration situation of rocks to find out the natural frequency of the rocks being broken, the microcomputer controller 17 outputs corresponding control signals to the electric-control hydraulic distributing valve 12. The electric-control hydraulic distributing valve 12 can adjust flow rate output to the hydraulic motor 1, and control the rotation speed of the hydraulic motor 1 by controlling the flow rate output to the hydraulic motor 1, thus to control the vibration frequency of the vibration exciter 2, and finally automatically adjusting the vibration frequency of the breaking hammer head 3, such that the vibration frequency approximates to the natural frequency of the rocks being broken. As a result, the rocks being broken generate the resonance within the local area under the breaking hammer head 3, to reduce the internal friction force in rocks quickly, thus to break the rocks easily.
The function of the hydraulic driving system lies in: the engine 14 drives the hydraulic pump 13 to generate pressure oil, which is regulated by the electric-control hydraulic distributing valve 12 and output to the hydraulic motor 1, therefore to drive the hydraulic motor 1 to rotate.
The function of the vibration exciter 2 lies in: the hydraulic motor 1 drives the rotating shaft of the eccentric wheel B 6 to rotate, via a pair of gears 11 that are engaged with each other, to bring the rotating shaft of the eccentric wheel A 5 to rotate at the same time, thus to achieve reverse synchronous rotation of the eccentric wheel A 5 and the eccentric wheel B 6. When in operation, the two eccentric wheels generate centrifugal forces, components of which in the direction of the central line connecting the centers of the rotating shafts counteract with each other at the same time, while components of which in the direction perpendicular to the central line of the rotating shafts are added up to form an excitation force. The excitation force is transferred to the breaking hammer head 3 through the box 4, and the breaking hammer head 3 is in contact with the rocks being broken, to transfer the energy to the rocks.
The number of the groups of eccentric wheels of the vibration exciter 2 is not limited to one; and there may be two or more groups of eccentric wheels.
The main function of the linkage mechanism lies in that the vibration exciter 2 is linked to the fore arm 10 of the excavator. The box 4 of the vibration exciter 2 can slide up and down on the guide rail 9 through the pulley 15, and the top part of the box is connected to the machine frame 7 through the damper spring 8. In this way, when the hydraulic resonant breaking hammer is in operation, it can be avoided that the impact energy is transferred to the excavator through the machine frame 7.
The present invention is not limited to the above embodiment. Various improvements and modifications can be made within the principle of the present invention, and those improvements and modifications should be covered by the protection scope of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
201010135284.7 | Mar 2010 | CN | national |
201020144576.2 | Mar 2010 | CN | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/CN2010/002229 | 12/31/2010 | WO | 00 | 11/23/2011 |