Hydraulic breaker without back head

Abstract

A hydraulic breaker without a back head, includes a main control valve, to which fluid is supplied from the outside of the polyhedron, and accommodating a pilot valve for controlling the main control valve, in the interior space of the polyhedron, and in which impact force is obtained by double-acting cylinders, operated by the main control valve, moving modules that are connected to piston rods backwards and forwards, thus moving an integrated impact ram and ram block module forward, and filled compressed gas rapidly pulling back the integrated impact ram and ram block module.

Claims

1. A hydraulic breaker without a back head, comprising: a plate on which a plurality of tabs, bolt holes, gas inlets, and oil inlets are machined, and a pilot passage hole connecting a main control valve and a pilot valve is perforated therein; the main control valve that receives fluid from an outside of a polyhedron; the pilot valve that controls the main control valve in a sealed space inside the polyhedron; an impact ram integrally coupled with a ram block module; a ram cylinder in which the impact ram reciprocates; each double-acting cylinder operated by the main control valve; each module integrally coupled with a piston rod within each double-acting cylinder; a block guide that prevents each module from breaking away when each module moves forward and backward; the impact ram and the ram block module that are moved forward by each module; a linear bearing guide that guides each module and the impact ram and the ram block module in a straight line; and a charged compressed gas that moves the impact ram and the ram block module, which are moved forward, backward to obtain an impact.

2. The hydraulic breaker of claim 1, wherein a plate assembly part of the polyhedron is sealed, and a seal retainer is applied to the ram cylinder to fill the sealed space with the compressed gas.

3. The hydraulic breaker of claim 1, wherein each of the modules includes a linear bearing block, a hinge block, a push rod, and a valve pressing adjustment rod.

4. The hydraulic breaker of claim 1, the pilot valve is repeatedly alternately operated by a seesaw plate whenever two spools in the pilot valve press a protruding spool based on a seesaw plate axis.

Description

DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a partial diagram of the conventional hydraulic breaker.

(2) FIG. 2 is a diagram showing a stroke section of the conventional piston.

(3) FIG. 3 is a side structural diagram of a hydraulic breaker without a back head according to the present invention.

(4) FIG. 4 is a plan view of a hydraulic breaker without a back head according to the present invention.

(5) FIG. 5 is a side structural diagram illustrating a state when a first piston according to the present invention finishes moving backward.

(6) FIG. 6 is a side structural diagram illustrating a state when a first piston according to the present invention moves forward.

(7) FIG. 7 is a side structural diagram illustrating a state before a first piston according to the present invention finishes moving forward.

(8) FIG. 8 is a side structural diagram illustrating a state when a first piston according to the present invention finishes moving forward.

(9) FIG. 9 is a detailed drawing showing an operating method of a spool according to the present invention.

MODES OF THE INVENTION

(10) Hereinafter, a preferred embodiment of a hydraulic breaker without a back head according to the present invention will be described in detail with reference to the attached drawings. For reference, in describing the present invention below, terms referring to the components of the present invention are named in consideration of the function of each component, and should not be understood as limiting the technical components of the present invention.

(11) Referring to FIGS. 1 to 9, a hydraulic breaker without a back head according to the present invention is attached to construction machinery such as an excavator and is used for crushing, compaction, and pile driving and includes an impact ram, a ram cylinder, a ram block module, a double-acting cylinder, a module, a main control valve, a pilot valve, a seal retainer, plates, fastening tabs, a linear bearing block, a linear bearing guide and a block guide.

(12) The hydraulic breaker without the back head includes a plate 100 on which a plurality of fastening tabs 7, bolt holes (not shown), gas inlets, oil inlets, oil outlets (not shown), etc. are processed and an assembly surface of the plate 100 assembled into a polyhedron is sealed and a seal retainer 80 is applied to a ram cylinder 50 to make a sealed space and fill the sealed space with gas.

(13) The filled gas pressure functions to obtain impact force by rapidly moving the advanced impact ram 40 and ram block module 60 backward.

(14) In addition, a plurality of pilot flow holes 6 connecting a main control valve 70 and a pilot valve 71 are perforated in the plate 100 assembled into the polyhedron.

(15) The main control valve 70 receives fluid from the outside and supplies the fluid to the inside of the plate 100 through the pilot flow holes 6, and the interior space of the plate 100 accommodates the pilot valve 71, which controls the main control valve 70 and double-acting cylinders 20 and 21.

(16) Referring to FIGS. 3 and 4, by first and second piston rods 10 and 11 that receive fluid from the main control valve 70 and operate alternately forward and backward and are integrated with first and second modules 30 and 31, the impact ram 40 and the ram block module 60, which are integrated, move forward, and the impact ram 40 and the ram block module 60 also rapidly move backward due to gas pressure.

(17) That is, when the integrated first piston rod 10 and first module 30 move forward, the impact ram 40 and the ram block module 60 move forward together. If the advanced impact ram 40 and the ram block module 60 move backward, the integrated second piston rod 11 and second module 31, which are on standby, move forward and move the integrated impact ram 40 and the ram block module 60 forward.

(18) To explain in more detail, referring to FIGS. 5 and 6, the first module and second module 30 and 31 include a hinge block 1, a push rod 2, a valve pressing adjustment rod 5 (the second module 31 also has the same configuration as the first module 30), and are integrated with a linear bearing block 90 and move by a linear bearing guide 91 and a block guide 92 when moving forward and backward.

(19) By the main control valve 70, the first module 30 moves forward together with the first piston rod 10, and the second module 31 moves backward together with the second piston rod 11. When moving backward, the hinge block 1 in the second module 31 is in close contact with a limit rod 3 and stands upright, and the interference with the impact ram 40 and the ram block module 60 is eliminated.

(20) In FIG. 6, when the second piston rod 11 moves forward, the push rod 2 in the second module 31 presses the hinge block 1, so that a locking portion 1a of the hinge block 1 comes into close contact with a protruding portion 60a of the ram block module 60 and thus moves forward with the impact ram 40. In FIGS. 7 to 9, when the advancing hinge block 1 comes into close contact with a limit roller 4, the hinge block 1 stands upright by the limit roller 4 along an inclined surface 1c formed on the hinge block 1 due to the forward movement and also is separated from the protruding portion 60a of the ram block module 60. The impact ram 40 and the ram block module 60, which are integrated, move rapidly backward due to the filled gas pressure to obtain an impact force. When the valve pressing adjustment rod 5 in the continuously advancing second module 31 presses a protruding spool 72 in the pilot valve 71, A and B flow paths in the pilot valve 71 are switched. In addition, the flow path (not shown) of the main control valve 70 is also switched, so that the integrated second piston rod 11 and the second module 31 move backward and the integrated first piston rod 10 and the first module 30, which are on standby, simultaneously move forward. As the first piston rod 10 and the first module 30 move forward, the integrated impact ram 40 and ram block module 60, moved backward by the compressed gas, move forward together in the same way as the second piston rod 11 and the second module 31 did. This sequence repeats automatically by executing the same operation.

(21) Each hinge block 1 stands upright in close contact with each limit rod 3 (one of them is not shown).

(22) In addition, the two spools 72 in the pilot valve 71 are based on a seesaw principle and are alternately operated by a seesaw plate 72b whenever the two valve pressing adjustment rods 5 press the spools from the left and right based on a seesaw plate axis 72a.

(23) As described above, the technical ideas described in the embodiments of the present invention can be implemented independently or in combination with each other. In addition, the present invention is described through embodiments described in the drawings and detailed description of the invention, but these are merely illustrative, and various modifications and other equivalent embodiments can be made by those skilled in the art. Therefore, the technical protection scope of the present invention should be determined by the attached patent claims.

INDUSTRIAL APPLICABILITY

(24) The present invention relates to a hydraulic breaker and more specifically, a hydraulic breaker without a back head and having a cylinder block with a polyhedral assembly structure.

(25) The hydraulic breaker without the back head according to the present invention not only reduces manufacturing costs by manufacturing the cylinder block in a polyhedral shape, which reduces the overall structure, but also allows for easy disassembly and assembly, so the best hydraulic breaker performance can always be maintained by replacing consumables in a timely manner.

(26) By applying a seal retainer to a ram cylinder, which has an assembly structure of a polyhedron, a sealed space is filled with compressed gas to fulfill the function of the excluded back head.

(27) In addition, by changing a structure of an impact piston to an impact ram type without a piston part, a stroke distance is increased and the impact force of a hydraulic breaker is improved, which improves work efficiency and reduces fuel efficiency. Also, by applying a linear bearing block and a linear bearing guide, the length of the impact ram can be significantly reduced, and a seal retainer can be used in only one place on a ram cylinder, reducing manufacturing and management costs.