CS209667B1 - Power hammer with counter-running movement of the ram and anvil - Google Patents

Description

(54) Hammer with normal movement of ram and anvil

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for pressure deformation of metals, and basically relates to hammers with counter-rotating movement of the ram and anvil - the upper ram and the lower ram.

Hammers with an opposing movement of the ram and anvil are known, in which a working frame carrying an anvil - the lower tool to which the workpiece is placed and a working cylinder whose cavity under the piston is filled with pressurized gas, is mounted in the guides of the stationary frame. in order to guide and hold the piston in an upward position, and whose cavity above the piston serves as a gas chamber, the ram with the upper tool mounted on the piston rod of the piston. These hammers are provided with a device for starting the working frame with a force equal to or exceeding the predetermined value of the working frame.

In the known hammers, the device consists of a pneumatic cylinder provided on the heater stand, the piston rod of the cylinder resting on the lower surface of the working frame.

The counter-rotating movement of the ram and anvil and of the respective structural elements on which the ram and anvil are mounted is effected by the pressure of the compressed gas which is simultaneously fed from the compressed air line into the gas chamber and into the cavity below the pneumatic cylinder piston.

Counter-rotating movement of components must be made to avoid the transmission of shock loads equal to the product of the mass of these parts and its velocity to the hammer rack at such proportions of motion quantities of the parts that the working frame stops after impacting the workpiece again smoothly returns to its initial position as soon as the compressed gas is discharged from the pneumatic cylinder.

In order to meet these conditions, the ratio of the momentum of the lower tool working frame to that of the piston rod, ram and upper tool at the moment of impact shall be equal to one if absolutely plastic blanks are to be formed. or it must exceed one by a certain value, which value is determined by the impact elasticity factor in the reshaping of the elastic-plastic blanks where the impact elasticity factor does not equal zero after the impact.

For known hammers to achieve the same momentum of the striking members, the force of the pneumatic cylinder must be equal to the weight of the working frame, and for the momentum of the working frame to exceed the momentum of the piston with pis.tnj.ci, ram and upper tool. the own weight of the working frame.

Since the force of the pneumatic cylinder is equal to the product of the cross-sectional area of the piston and the height of the pressure of the gas, and the working frame weight is constant for each particular hammer, it must be higher for known hammers with a certain cross sectional area of the pneumatic cylinder. pressure of a pressure gas quite a certain value.

If the gas pressure exceeds this value, the anvil working frame will continue to move upwards upon impact with the stock to accumulate potential energy, which then turns into kinetic energy and is transmitted to the hammer rack as a dynamic stress.

If the gas pressure level does not reach a predetermined value, the working frame begins to move downwards and thereby transmit the dynamic load to the ram stand.

Since this dynamic load is transmitted from the stand and through the hammer base to its surroundings as a seismic wave, such a load must not reach any high value and therefore the pressure of the gas below which it is fed into the gas chamber as well as into the cavity below the pneumatic piston. rollers must not significantly differ from the specified value.

Since the hammer impact energy is determined by the height of the gas pressure in the gas chamber, and the impact energy of known hammers can only be varied to a relatively limited extent, the technological possibilities of these hammers are accordingly limited.

In known hammers, the discharge of the compressed working frame of the hammers to the lower starting position during each countercurrent movement of the ram and anvil must pass to the lower starting position when the compressed gas is discharged from the cavity below the piston of the pneumatic cylinder.

The purpose of the invention is to extend the range of technological possibilities of a hammer with counter-rotating movement of the ram and anvil.

It is an object of the present invention to provide a hammer with an opposing movement of the ram and anvil of such a design as to provide a predetermined momentum ratio for the hammer members colliding at substantially different impact energy values as well as increasing the hammer economy.

This object is solved by providing a buttress with a counter-rotating movement of the ram and anvil, comprising in the guides of the rigid stand mounted working frame with the possibility of vertical adjustment and carrying an anvil for gripping the workpiece, as well as a working cylinder with cavity below the piston. to retract and retain the piston in its initial position, as well as a cavity above the piston which constitutes the gas chamber and where the ram with the upper tool is attached to the piston rod, a working frame starting device with a force corresponding to its gravity this value exceeds that according to the invention it is provided with cavities provided in the lower part of the working frame which are filled with fluid and connected to the cavity below the working cylinder piston and into both cavities in the lower part of the frame with vertical plungers mounted on the hammer rack; C The plunger cross-sectional area to the cross-sectional area of the cavity below the working cylinder piston is 1.5 to 2 times the ratio of the mass of all moving parts of the hammer to the mass of the piston with the piston rod, the ram and the upper tool.

A technical solution of this type ensures that constant forces are applied to the working frame and the piston of the hammer working cylinder, the values of which are correspondingly equal to the weight of the working frame with the lower tool and 1.5 to 2 times the weight of the piston with piston rod, ram and upper tool. as a result, the momentum ratio of the hitting hammers remains constant, is determined solely by the elasticity of the fluid, and is independent of the pressure level below which the compressed gas is fed into the hamme's gas chamber. with varying energy impact, which significantly expanded the technological possibilities of the hammer's usability.

In addition, since the fluid permanently fills the cavity below the working cylinder piston, as well as the cavities formed at the bottom of the working frame, and the potential energy accumulated in the working frame during the opposing movement, it is used to raise the piston with the piston rod. this technical solution allows an additional increase in the hammer economy.

It is expedient if a gas-liquid mixture is used as the fluid.

A technical solution of this kind enables the elasticity of the fluid to be changed to provide the momentum ratio of the hammers that are needed to stop the work frame in the upper position after impact on the workpiece and which is determined by the impact elasticity factor value for the workpiece. , which also extends the hammer's technological capabilities.

In the following, the hammer and anvil counter-rotating hammer made according to the invention will be described in detail using a drawing which schematically shows the hammer and anvil counter-rotating hammer in vertical section.

The ram with an opposing movement of the ram and the anvil comprises a stationary frame 1, a working frame 2, a working cylinder 3 and a device for starting the working frame 2 with a force equal to or greater than its weight.

The working frame 2 is guided in the rack guides 4 with the possibility of vertical adjustment and carries the anvil 5 - the lower tool for holding the workpiece 6. Working cylinder 3.

is located 7 below the piston.

and has a cavity which is pressurized with fluid to introduce and hold the piston in its initial position, as well as a cavity above the piston which forms the gas chamber.

A ram 11 with an upper tool 12 is mounted on the piston rod of the piston 8 of the working cylinder 3. The housing 13 of the working cylinder 3 is in the form of a sleeve and is arranged in the working frame 2 upside down with adjustable axial movement. An annular collar 14 is provided on the outer surface of the housing 13 of the working cylinder 3. The annular collar 14 divides the annular recess 15 into two cavities 16 and 17 in which there is fluid, for example liquid, to effect adjustable movements of the working cylinder housing 3.

In the upper part of the working frame 2, two nozzles 18 and 19 are built in at the height of the cavities 16 and 17 for the successive joining of these cavities 16 and 17 correspondingly to the high or low pressure pipes 20 and 2Ί,

A socket 22 is built into the bottom of the housing 13 of the working cylinder 3 for successively connecting the gas chamber 9 with the pneumatic high-pressure line 23, or via the compressed air line 24 to the outside atmosphere.

To control the consumption of compressed gas when it is discharged from the gas chamber into the ambient air, the compressed air line 24 is provided with a throttle valve 25.

The device for starting the working frame 2 is designed in the form of cavities 26 in the lower part of the working frame 2, which are filled with fluid and connected to the cavity 7 under the piston of the working cylinder 3. so that when the working frame 2 is adjusted, these plungers 27 partially enter or exit the cavities 26, whereby their space volume is varied accordingly.

To connect the cavities 26 with the cavity 7 below the piston, a lower beam 28 is provided in the lower part of the housing 13 of the working cylinder 3, which is provided with channels 29 and carries vertically bars 30 in each of which a channel 31 is connected to the channel. 2 9 in the crossbeam 28, wherein in the housing 13 at the height of the channel 29 are provided openings 32, which open into the cavity 7 below the piston of the working cylinder 3.

With their upper end, the bars 30 extend into the openings 33 which are formed in the upper part of the working frame 2, and with their lower end they extend into the cavities 26; whereby the channels 31 of these rods are connected by 8 cavities 26.

The cavity 7 beneath the piston of the cavity 26, the channels 29 and 31 and the openings 32 are filled with a fluid, which may consist, for example, of a gas-liquid mixture whose volume is selected under a condition as well as maintaining a certain momentum ratio of the hammers hitting each other were ensured during the work.

In the working frame starting device 2, the ratio of the sum S of the plunger cross-sectional areas 27 to the cross-sectional area Sj of the cavity 7 under the working cylinder piston 3 is 1.5 to 2 times greater than the mass ratio of all moving parts of the hammer - working frame 2 with anvil. The housing 13 of the working cylinder 3, its piston 8 with the piston rod 10, the ram 11 with the upper tool 12, the rod 30 and the crossbar 28 to the mass of the piston 8 with the piston rod 10, the ram 11 and the upper tool 12.

The hammers according to the invention with the counter-rotating movement of the ram and anvil work as follows.

In the initial position, the gas chamber is connected to the outside atmosphere via the sleeve 22 and the compressed air line 24.

Under the action of the fluid that fills the cavities 26 and cavities 7 below the piston, the working frame 2 is raised to a limit height above the stand 11, while the piston 8 with the piston rod 10, the ram and the upper tool 12 assume the extreme upper position. In this case, the fluid is compressed to a given pressure level by the action of the movable parts of the hammer, so that the use of other additional devices is unnecessary.

The force of the fluid on the piston 8 is 1.5 to 2 times greater than its weight along with the piston rod 10, the ram with the upper tool 12, which is sufficient to return and securely hold the piston in its initial position.

The ratio of the fluid components is determined in a known manner by calculation, possibly experimentally with respect to the elastic-plastic properties, shape and dimensions of the workpiece to be processed.

For blanks whose deformation is effected by an impact elasticity factor of zero, the maximum gas volume shall be used. The volume of gas is correspondingly increased when the blanks are formed with an impact elasticity factor not equal to zero.

If it is necessary to lift the housing 3 of the working cylinder 3 in order to increase the length of the stroke of the piston 8 to the required distance between the upper tool 12 and the anvil 5, the cavities 16 and 17 are connected to the low pressure line as well as the high pressure line 21 and 22. If the stroke height of the piston 8 has to be reduced, the cavities 16 and 17 are connected to the high and low pressure lines 20 and 21 respectively.

The upward or downward movement of the housing 13 of the working cylinder 3 is respectively connected to the protrusion of the rod 30 from the cavities 26, which increases their space volume, possibly with a submerged surface.

Claims (2)

P £ E M Mí T 1. A ram with an opposing movement of the ram and anvil, comprising in the guides of a rigid stand with the possibility of vertically projecting the bars 30 into cavities 26, the space volume of which is thereby reduced accordingly. The working frame 2 is correspondingly lowered or raised relative to the hammer stand. The blank 6 is placed on the anvil The gas chamber 9 is connected via a sleeve 22 to a pneumatic high-pressure line 23. Under the influence of the compressed gas coming from the pneumatic high-pressure line into the gas chamber 9, the piston 8 of the working cylinder 2 moves downward ^{with the} piston rod 10, the ram 11 and the upper tool 12 and the working frame 2 with the working cylinder housing 13. As the piston 8 moves, the fluid filling the cavity 7 below the piston is forced out of the cavity through the apertures 32 through the cavity. channels 29 and 31 into cavities 26, the space volume of which increases due to the upward movement of the working frame. For a ratio of the total cross-sectional area of the plungers 27 to the cross-sectional area of the cavity 7 below the piston according to the invention, which exceeds 1.5 to 2 times the ratio of all movable hammers to piston mass 8 with piston rod 10, ram 11 and upper tool 12, by the piston 8 from the cavity 7 below the piston an average of 1.5 to 2 times the value by which the volume of the cavity 26 increases by adjusting the working frame 21 in the case of the same momentum of these members. Therefore, with low fluid compressibility, the relative volume of gas is small - the countercurrent movement of the piston 8 and the working frame 2 is accompanied by an increase in pressure of the fluid, thereby increasing the force that prevents the piston 8 from accelerating. . In this case, the momentum ratio of the working frame 2 with the working cylinder housing 13 and the anvil 5 to the momentum of the piston 50 with the piston rod 10, the ram 11 and the upper tool 12 will be greater than one and after impacting the plastic-elastic blank 6 with impact factor. elasticity not equal to zero, the working frame 2 stops in the up position. With considerable compressibility of the fluid - the relative volume of gas is large - the fluid pressure remains virtually unchanged when the piston 8 and the working frame 2 are moved countercurrently, so the momentum of the impacting members will be approximately one, and upon impact on the plastic the work frame 2 is also melted again. After the workpiece 6 has been deformed due to the counteracting impact of the ram 11 and the anvil 5, the gas chamber is connected to the ambient air via the nozzle 22 and the compressed air line 24 with the throttle valve 25. The compressed gas is discharged from the gas chamber 9, thereby raising the piston 8 to the upper position due to the fluid pressure on the circular surface of the piston. As a result of the piston 8, the volume of the cavity 7 is increased. it becomes smaller and is not impeded by the lowering of the working frame 2 by the lower starting position at which the force of the applied fluid on the working frame 2 is equal to its weight. The reshaped blank 6 is now removed from the anvil. This completes one hammer duty cycle. The next cycle is repeated as described above. BACKGROUND OF THE INVENTION a supported working frame supporting an anvil for receiving a workpiece, and further comprising a working cylinder with a cavity below the piston, the cavity being filled with pressurized fluid to return and hold the piston in its initial position, and a cavity above the piston forming the gas chamber wherein a ram with an upper tool is mounted on the piston rod, further comprising a device for starting the working frame with a force corresponding to or exceeding the weight of the working frame, characterized by having cavities (26) provided at the bottom of the working frame of the frame (2), which cavities (26) are filled with fluid and are connected to the cavity (7) below the working cylinder piston (3), and vertical plungers (27) extending into the cavities (26) and supported on the frame (1). wherein the ratio of the total cross-sectional area of the plungers (27) to the cross-sectional area of the cavity (7) is 1.5 to 2 times greater than p measuring the sum of the weights of the working frame (2) with the anvil and the working cylinder (3) with the piston (8), the piston rod (10), the ram (11) and the upper tool (12) to the sum of the weights a ram (11) and an upper tool (12). 2. The hammers of claim 1, wherein the fluid is a gas-liquid mixture.