RU2438824C1 - Counterblow hammer - Google Patents

Abstract

FIELD: process engineering. ^ SUBSTANCE: invention relates to metal forming and may be used in hammer shop. Proposed counterblow hammer comprises vertical bed accommodating top and bottom supports. Vertical bed top work zone accommodates system of pneumatic communication with channels and cylinders, top head drive, air pipelines and drives. Bottom work zone accommodates system of hydraulic communication with channels, bottom head drive and other drives. Heads drives are made up of central and lateral rods. Bottom head central rod incorporates piston to divided central hydraulic communication cylinder chamber into top and bottom work zones. Proposed hammer incorporates bottom head braking device made up of a barrel. Said barrel is arranged in central hydraulic communication channel bottom work zone and may reciprocate related thereto. Bottom head piston has at least one opening equipped with check valve. Said valve is made up of washer arranged between bottom head piston bottom face and brake bottom. ^ EFFECT: higher reliability. ^ 2 dwg

Description

The invention relates to the field of metal forming and can be used in forge shops.

The closest solution from the prior art, in technical essence, is a careless hammer containing a vertical bed, in the guides of which the upper and lower women are mounted with the possibility of reciprocating movement, a pneumatic communication system with a channel, upper woman's moving means made in the form of a gas-phase medium, pneumatic pipelines and drives, installed in the upper working area of the bed system of means of hydraulic communication with channels, means for moving the lower woman, made in the form of a liquid-phase medium and drives installed in the lower working area of the bed, which functionally provide movement of the upper and lower women, respectively, and the women’s drives are made in the form of central and side rods with the ability to interact with one end face with the end surfaces of these women, and the other end faces with liquid-phase and gas-phase means displacement, while the central rod of the lower head is made with a piston that functionally separates the cavity of the central hydraulic communication channel into two upper and lower technological zones (Yu.A. Bocharo . "Forging and stamping equipment." M., "Academy". 2008, p. 415-416).

However, such a technical solution of a vertical hammerless hammer does not exclude repeated repeated strokes of the central rod along the lower plane of the additional (lower) head when bouncing after impact with the main head, which reduces the reliability of the hammer.

The technical task of this invention is to increase the reliability of the work of the free hammer by eliminating the collision of its structural elements, in particular repeated strokes of the central rod on the lower plane of the additional headstock when bouncing after impacting with the main headstock.

The stated technical problem is solved by the fact that a careless hammer containing a vertical bed, in the guides of which the upper and lower women are mounted with the possibility of reciprocating movement, a pneumatic communication system with a channel, upper woman's moving means made in the form of a gas-phase medium, pneumatic pipelines and drives installed in the upper working area of the bed system of means of hydraulic communication with channels, means for moving the lower woman, made in the form of a liquid-phase medium, and a drive installed in the lower working area of the bed, functionally providing movement of the upper and lower women respectively, and the women’s drives are made in the form of central and lateral rods with the possibility of interaction with one end with the end surfaces of these women, and with the other ends with liquid-phase and gas-phase moving means, wherein the central rod of the lower head is made with a piston functionally dividing the cavity of the central hydraulic communication channel into two upper and lower technological zones, according to the invention The y is additionally equipped with a braking tool for the lower head, made in the form of a cup, installed in the lower technological zone of the central hydraulic communication channel with the possibility of grasping the piston of the central rod of the lower head and reciprocating relative to it, while the piston of the lower head is made with at least one a hole equipped with a check valve, made in the form of a washer installed between the lower end of the piston of the lower headstock and the bottom of the braking means.

The invention is illustrated by drawings, where

- figure 1 schematically shows a longitudinal section of a dieless hammer;

- figure 2 is an increase in figure 1.

The free hammer contains a hydraulic communication system 1, in particular, with two side cylinders 2, connected by channels 3 to one central cylinder, the lower technological zone in the form of a cavity 4 and the upper technological zone in the form of a cavity 5 which are separated by means of braking the lower head, made in the form cup 6. Also contains a lower woman’s drive in the form of a central rod 7 with a check valve in the form of a washer 8, a piston 9 of the central lower woman’s rod with holes 10. A rod 12 s is installed in the channels 11 of the hydraulic communication system 1 13, separating the channel 11 and the cavity 2 of the cylinder from the pneumatic cavity 14 of the compensator 15. The cavity 14 of the compensator 15 is connected through an opening 16 to the pneumatic pipe 17. On the central rod 7 is installed lower woman 18 with the possibility of vertical reciprocating movement along the vertical struts of the frame 19 its guides 20. The lower parts of the side rods 2 are located on a sliding fit of the side cylinders 2 of the system 1. The upper ends of the rods 21 are rigidly fixed on the upper head 22, and installed on the upper ends of the struts of the frame 19 to the pneumatic communication system 23 of the pneumatic actuator with the cavity 24, which is connected through the hole 25 and the pneumatic pipe 17 to the pneumatic cavity 14 of the compensator 15, and through the hole 26 is connected to the pneumatic cavity 27, in which the drive is installed in the form of a central rod along the sliding landing with the possibility of reciprocating movement 28.

In addition, in the upper technological zone 5 of system 1, a valve 30 is provided through the channel 29, by means of which the upper technological zone 5 is connected to means for moving the lower woman 22, made in the form of a liquid-phase medium, or for returning the women 18 and 22 to their initial position, or with a drain to effect their dispersal to strike. On facing each other surfaces of the women 18 and 22 are fixed dies 31.

The work of the hammerless hammer is as follows.

The lower woman 18 and the upper woman 22 are respectively in the extreme lower and upper positions. Side cylinders 2, cavities 4 and 5, channels 3, 11, 29 are filled with liquid-phase medium (liquid) under high pressure, and cavities 14, 25, 27 and pneumatic pipe 17 are filled with gas-phase medium (air) also under high pressure. To perform acceleration of the lower and upper women 18 and 22 before impact, the cavity 5 is connected by a channel 29 and a valve 30 with a drain. The pressure of the liquid in the cavity 5 drops and the glass 6 moves upward by the force of the pressure of the liquid in the cavity 4. The volume of the cavity 4 increases, thereby decreasing the pressure of the liquid in the cavity itself, as well as in the cylinders 2, channels 3 and 11 and the force of the liquid pressure on the lower end lateral rod 21. Under the influence of air pressure in the cavity 27 on the central rod 28 and gravity of the upper woman 22 and rods 21, the latter move downward, compressing the liquid in the cylinders 2, cavities 4 and channels 3, 11 to the pressure under which the glass 6 moves the central stock 7 and the lower woman 18 up. Oncoming movement of the upper and lower women 18 and 22.

On a given path of acceleration of the lower woman 18, the cup 6 brakes and stops in the brake cavity, which is functionally formed in the cavity 5 of the system 1 when moving the upper end of the cup 6 above the channel 29. Since the braking of the cup 6, the rod 7 with the washer 8 and the piston 9 with holes 10 move up by inertia together with the lower woman 18, until it collides with the upper woman 22. In this case, the piston 9 moves relative to the stationary cup 6.

From the moment of braking of the cup 6, the lateral rods 21 move downward under the action of drive forces and gravity, compressing the fluid in the cylinders 2, cavities 4 and channels 3 and 11 to a pressure whose pressure force on the rod 12 becomes greater than the pressure force of the compressed air of the pneumatic actuator on the piston 13 in cavity 14 of the compensator 15. This force will move the rod 12 and the piston 13 to the left in the direction opposite to the longitudinal axis of the hammer, displace the fluid from the cylinder 2 into the cavity 11, thereby reducing the volume of the cavity 14. Since the volume of the cavity 14 is negligible compared to the volume of air in the cavity 24 system 23, then the change in air pressure in the pneumatic actuator will be insignificant, and, as a result, there will be an insignificant change in the fluid pressure in the cylinder 2, channel 3, cavity 4, the value of which can be considered constant.

At the stage of the working stroke, the women 18 and 22 collide and bounce from each other in the direction opposite to acceleration. When bouncing side rods 21, a woman 22 and a rod 28 bounce up. Their upward displacement reduces the fluid pressure in the cylinders 2 and cavity 4 to a pressure lower than the fluid pressure in the cavities of the hydraulic communication system 1 created by the gravity of the upper woman 22 and the air pressure on the rod 28 in the initial position of the hammer.

The shock mass of the lower woman 18, reflected during the rebound, shifts down the central rod 7, the washer 8, the piston 9 relative to the nozzle 6. In this case, the pressure force of the fluid in the cavity between the nozzle 6 and the piston 9 presses the washer 8 against the piston 9, blocking the fluid outflow from it through the holes 10 into the cavity 5. From the cavity between the cup 6 and the piston 9, the rod 7 will displace the fluid into the cavity 5 through the gap that is created between the inner cylindrical surface of the piston 6 and the outer surface of the piston 9, which can be profiled.

The glass 6 is kept from shifting downward relative to the body of the system 1, when the piston 9 moves in it, by the force of the liquid pressure in the cylinders 2, channel 3, cavity 4 created by air through the rod 12, piston 13 of the compensator 15. The pressure of the liquid inside the glass 6, acting on the piston 9 creates a force that inhibits the downward movement of the rod 7 and the lower woman moving, together with it, downward.

The work done by the braking force of the piston 9 is equal to A. The reflection energy of the lower woman 18, which is equal to T _{from the} rebound, will be extinguished by the value of A when it is reflected down and becomes equal to T _m = T _from -A. Thus, there will be a decrease in the kinetic energy of reflection of the lower woman 18 during the rebound, which is transformed into the heat of the liquid flowing from the inner cavity of the glass 6 into the gap between the pistons. If the energy of reflection T _{from the} lower woman 18 is not extinguished by the hydraulic brake generated between the pistons 6 and 9, then the piston 9 will hit the bottom of the piston 6 and shift it down, increasing the pressure in the cavity 4. The pressure will displace the rod 12 and the piston 13 of the compensator 15. There will be air compression in the cavities 14 and 25 of the pneumatic actuator. Due to the work of the pressure forces of the pneumatic actuator, the excess energy T _{t of the} rebound of the lower woman 18 will be extinguished.

At this moment, according to the signal from the sensor that is triggered by moving the lower head down, the valve 30 is switched to a position in which the cavity 5 is connected to the pressure. Under the action of fluid pressure in the cavity 5 and gravity of the lower woman 18, the force of the liquid pressure in the system 1, acting on the side rods 21, the upper woman 22, the rod 28 is moved upward, compressing the air in the cavities 25 of the receiver. When the lower woman 18 descends to her initial position for acceleration, the forces of air pressure and gravity will stop the upper woman 22 in the extreme, upper position. The hammer is ready to strike and the cycle repeats.

The analysis of the claimed technical solution for compliance with the conditions of patentability showed that the characteristics indicated in the independent claim are interrelated with each other with the formation of a stable set of necessary attributes unknown at the priority date from the prior art sufficient to obtain the required synergistic (over-total) technical result.

The properties regulated in the claimed compound by individual features are well known in the art and require no further explanation.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed technical solution:

- the object embodying the claimed technical solution, in its implementation is intended for use in forge shops;

- for the claimed object in the form described in the independent clause of the utility model formula, the possibility of its implementation using the means and methods known from the prior art on the priority date as described in the application materials is confirmed;

- the object embodying the claimed technical solution, when implemented, is able to ensure the achievement of the technical result perceived by the applicant.

Therefore, the claimed object according to the current legislation meets the requirements of patentability conditions “novelty”, “inventive step” and “industrial applicability”.

Claims (1)

A careless hammer containing a vertical bed, in the guides of which the upper and lower women are mounted with the possibility of reciprocating movement, a pneumatic communication system with channels and cylinders installed in the upper working area of the bed, with means for moving the upper woman, made in the form of a gas-phase medium, with pneumatic pipelines and drives, installed in the lower working area of the bed, a system of means of hydraulic communication with channels, with means for moving the lower head, made in the form of a liquid-phase medium, and with water, functionally providing movement of the upper and lower women, respectively, and the women’s drives are made in the form of central and side rods that can interact with one end with the end surfaces of these women, and with the other ends with liquid-phase and gas-phase media, while the central rod of the lower woman is made with a piston functionally separating the cavity of the central hydraulic communication cylinder into upper and lower technological zones, characterized in that it is additionally equipped with a brake for lower a woman, made in the form of a glass installed in the lower technological zone of the central channel of hydraulic communication with the coverage of the piston of the central rod of the lower woman and with the possibility of reciprocating movement relative to it, while the piston of the lower woman is made with at least one hole equipped with a check valve, made in the form of a washer installed between the lower end face of the lower woman's piston and the bottom of the braking means.

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