BR202016006521Y1 - CONSTRUCTIVE PROVISION APPLIED TO HYDROMECHANICAL HAMMER - Google Patents

Abstract

CONSTRUCTIVE ARRANGEMENTS APPLIED TO HYDROMECHANICAL HAMMER This utility model describes the development of a hydromechanical hammer that uses a driving spiral spring (7) to fire blows on the pointer (3), and to arm the hammer (4) for a new one blow, employs a hydraulic motor (19) with a connecting rod (12), where said connecting rod compresses the spring (7) and when the hammer escapes, it is accelerated against the tip.

Description

TECHNICAL FIELD

[001] The following descriptive report for utility model is intended to describe a constructive disposition applied in hydromechanical hammer and carried out the appraisal of patent documents and others, to determine used in excavators, tractor with mechanical arm or similar equipment, with direct application in mining, rock demolition, construction, concrete, asphalt.

STATE OF ART

[002] Many types of impact tools for mining and breaking concrete and the like are known. These devices essentially have an energy storage medium, such as a coil spring or gas chamber, a hammer, and a work tool. The energy storage mode, when compressed, causes the hammer to accelerate to the work tool to deliver a blow.

[003] The document US 2559478 discloses a hydromechanical hammer whose operation is based on some of the types of internal valves and a solid piston. However, this requires the piston to push the fluid chamber into an exhaust opening on the downward stroke. Appreciable drag can result. Other types of internal valves prevent this, as there is a piston made up of two separate components.

[004] A percussion assembly for use with a mechanically actuated hammer, including the percussion mount is described in US 3881554. The percussion assembly is constructed to include percussion and a plurality of toroidal springs mounted to provide reactive lateral forces in response to the lateral movement of the percussion.

[005] Document US 3792738 describes a hydraulic hammer, using an oil pressure, the attenuation of the impact given to the machine body, in order to avoid its damage, as well as damage to the portion of the rod that couples the piston integrally to the hammer head and smoothing the action of said hammer head, are both accomplished by providing: a bush mounted on the dividing wall that defines the upper cylinder of the lower cylinder and provided with a conical recess, to receive a part of the oil that is used for controlling the movement of said piston, said piston having, at its end portion, a conical portion, which can be freely received in the conical cavity of said bush; said stem portion having an intermediate portion whose diameter is smaller than that of the remaining portions thereof; and said hammer head slidably mounted within the lower cylinder and having a portion capable of sliding over the inner circumference of the lower cylinder, said portion having a length that is at least 1.3 times the inner diameter of the said lower cylinder, said hammer head being slidably mounted on said lower cylinder, through a liner provided on said hammer head.

[006] The document US 4256187 describes an impact tool for mining, demolitions and the like. An energy storage device such as a coil spring, when compressed, accelerates a hammer to deliver an impact to a work tool. The hydraulic cocking mechanism has a compression chamber and an inclined chamber. The shaft has an annular stop attached to it and reciprocally carries a compression bushing above the annular stop. A slanted member extends into the slanted chamber. The hydraulic pressure input urges the angled members to press the compression sleeve into contact with the annular stop to define a piston. Hydraulic inlet pressure acting at the same time below the piston and urges the shaft upward to cock the spring. At the top of the stroke, ports and passages reduce the pressure difference above and below the plunger to allow the spring to force the rod down for impact. On the downward stroke, the compression sleeve and the annular stop are separated. Doors urge the sleeve back into tight contact with the annular stop after impact. A resilient member cooperating with the sleeve and annular stop reduces damage to the sealing surface.

DISCUSSION

[007] The state of the art shows that the use of hydromechanical hammers that employ springs to accumulate energy and release at once to produce the impact of mars against the pointer, is a common knowledge of the art.

[008] The fact of employing a propeller spring of a new hammer blow is not new, as this is provided for in previous patent documents. As, for example, in patent document US 4256187, which discloses an energy storage device such as a coil spring, when compressed, accelerates a hammer to provide an impact to a work tool. This patent uses the energy accumulated in the spring to drive the hammer to strike the tip. It is quite clear that the coil spring serves as an energy storage means to accelerate the hammer to deliver a blow to the work tool when the coil spring is compressed and the hammer released.

[009] What does not exist is the connecting rod system used to accumulate energy in the spring and release it suddenly, through the exhaust system.

SUMMARY

[010] Thus, due to considerations pertinent to the state of the art discussed above, one of the objectives of this utility model is the development of a hydromechanical hammer that employs a driving spiral spring to fire blows on the tool (the pointer). To arm the hammer for a new blow, it employs a hydraulic motor with a connecting rod. This connecting rod compresses the spring and when the spring escapes, the hammer is accelerated against the tip. This mechanical construction is different from the previous ones found.

DESCRIPTION

[011] The characterization of this document as a utility model is made through representative drawings of the constructive disposition applied to a hydromechanical hammer, in such a way that the equipment can be fully reproduced by appropriate technique, allowing full characterization of the functionality of the claimed object.

[012] The descriptive part of the report is based on the elaborated figures that express the best way or preferential way to carry out the product herein, through a detailed and consecutive numbering, where it clarifies aspects that may be implied by the representation adopted, in order to clearly determine the protection sought herein.

[013] These figures are merely illustrative, and may vary, as long as they do not deviate from what was initially claimed.

[014] In this case you have to:

[015] — AFIGURA1 shows the proposed hydromechanical hammer in front view, a longitudinal section A-A revealing the position of arming the blow and a transverse section B-B showing the hydraulic motor;

[016] - AFIGURA2 shows the proposed hydromechanical mars in an internal view, a longitudinal section E-E revealing the blow already delivered on the tip and a transverse section H-H e;

[017] - FIGURE 3 shows a detail of the hydraulic motor driving the hammer.

[018] The proposed utility model comprises an entire body or housing (1), equipped with an internal assembly composed of a hammer (2) and pointer (3), respectively jacketed by the hammer bushing (4) and the pointer bushing ( 5), with a damping piece (6) for empty blows, positioned between the hammer (2) and pointer (3), with a spiral spring (7) being trapped in a cavity (8) in the rear of the hammer (2) on a guide pin (9) existing in the support cover (10) of said spring (7) and the retaining cover (14) of the spring support.

[019] The pointer (3) can move inside the housing (1) in back-and-forth in a course determined by a cavity, where the retaining pin (11) of said pointer (3) is retained.

[020] The hydromechanical hammer is driven by the actuation of a connecting rod (12) attached to a shaft (13), where said connecting rod (12) can rotate freely by this shaft in a cavity (15) provided by a cover (16 ) and which is part of the housing (1). The connecting rod (12) contains rollers (17) at its ends, said rollers (17) coming into contact with the hammer (1) through the recess (18), such that the movement of the connecting rod (12) pushes the hammer (2) compressing the spring (7) and, through said recess (18) allows the escape of the hammer (2) that collides against the pointer (3).

[021] The connecting rod (12) is moved by means of a hydraulic motor (19) that makes it rotate through its axis (20), this rotation allows the hammer to have its back-and-forth movement.

[022] For the operation, the hammer (2) is used together with a driving spiral spring (7) to fire the blows on the tool (the pointer). It uses a hydraulic motor (19) with a connecting rod (12) to arm the hammer (2) against the spring (7) for a new blow.

[023] With the new hydromechanical hammer system, the oil circulates only in the hydraulic motor, in smaller volume and less pressure, dissociated from the extreme impact parts, hammer and pointer. Thus, reducing indirect operating costs in relation to the engine effort of the machine carrying the equipment, fuel consumption, premature wear of the hydraulic fluid that feeds the general system together (machine and hydromechanical hammer).

[024] In general, the hydromechanical hammer system provides a drastic reduction in the risks of oil contamination in the system of the machine carrying the equipment, as the oil circulates only in a hydraulic motor, isolated from the function of the hammer and pointer mechanisms and components of the set that generates mechanical energy of work. The oil circulates only in the hydraulic motor, (coupled on the outside of the hydromechanical hammer) connected to a connecting rod, transmits motor energy to the hammer, driving it against the propulsion spring.

[025] The utility model innovates in using a spring on the hammer to fire blows under the tool (pointer). Use a hydraulic motor with a connecting rod to arm the hammer for a new strike.

Claims (1)

1- CONSTRUCTIVE ARRANGEMENT APPLIED TO HYDROMECHANICAL HAMMER, which comprises an entire body or housing (1), equipped with an internal assembly composed of hammer (2) and pointer (3), characterized in that: - they are, respectively, jacketed by the hammer bushing (4) and by the pointer bushing (5), having a damping piece (6) for empty blows, positioned between the hammer (2) and pointer (3), with a spiral spring (7) being held captive in a cavity (8) on the rear part of the hammer (2) on a guide pin (9) on the support cap (10) of said spring (7) and the retaining cap (14) of the spring support; - the actuation of the hydromechanical hammer occurs by the actuation of a connecting rod (12) attached to a shaft (13), where said connecting rod (12) can rotate freely through this shaft in a cavity (15) provided by a cover (16) and which is part of the housing (1); - the connecting rod (12) contains rollers (17) at its ends, said rollers (17) coming into contact with the hammer (1) through the recess (18), in such a way that the movement of the connecting rod (12) pushes the hammer (2) compressing the spring (7) and, through said recess (18) allows the escape of the hammer (2) which collides against the pointer (3); - if the connecting rod (12) is moved by means of a hydraulic motor (19) that makes it rotate through its axis (20), this rotation allows the hammer to have its back-and-forth movement. - have a propeller spring (7) acting together with the hammer (2) to fire the blows on the tool (the pointer), and use a hydraulic motor (19) with a connecting rod (12) to arm the hammer (2) against the spring (7) for a new blow.

Images