DE3424505A1 - VIBRATION DEVICE - Google Patents

Description

description

The present invention relates to, and particularly relates to, laboratory dynamic machines Vibration devices.

The invention can be applied in metallurgy, which allows the similarity of the structure of molten metals and ingots made from them to increase considerably «It is also expedient the application of the vibration device according to the invention in the chemical industry and in microbiology for Intensification of running processes.

At present, a new direction is being explored in the field of vibration exposure to various technological ones Processes, especially structure formation of metals During their melting, the course of chemical reactions in the production of nitrogen fertilizers middle in, the formation of microbiological structures and on a number of other processes.

A vibration device is known (see the USSR copyright certificate ITr, 876427, Int. Kl., B 28 B 1/08), which contains a number of Rutte! devices that operate over Pipelines are connected to a compressed air control valve which iet connected to a compressed air line. That Compressed air control valve is made with the help of an electric motor driven. The rod devices are mounted on a foundation with the help of elastic supports.

The presence of the electric drive of the compressed air control valve makes it impossible to do this To use equipment for work in an explosive medium.

A vibration device is known (see the USSR copyright certificate No. 1085828, Int. Zl. B 28 B 1/08), which contains a housing, on the outer end face of which a working element is attached, while inside the Housing coaxially with it housed a socket with channels that can be pushed back and forth along the housing which connect the cavity of the socket with the main source of compressed air and with the atmosphere, wherein

from the end faces of the socket, the inner end faces of the housing and from elastic ones arranged between them Elements two working chambers are formed, while equiaxed with her in the cavity of the socket Air distribution system is arranged.

The air distribution system is designed in the known device in the form of electromagnetic valves, which connect the working chambers to the compressed air source and the atmosphere. The system is with provided an electrical phase distributor to which the electromagnetic valves are connected in such a way that one of the working chambers with the compressed air source and the other is connected to the atmosphere.

The presence of the electromagnetic valves in the The air distribution system of the vibration device does not allow this in an explosive medium to use.

The invention is based on the object of a vibration device to create in which the structural design of the air distribution system would allow to work in an explosive medium.

This is achieved in that in the vibration device, which has a housing on its outer end face a working element is attached, while inside the housing equiaxed with it one along the Housing reciprocating version is arranged with channels that the cavity of the socket with the Connect the main compressed air source and the atmosphere, being of the end faces of the socket, the inner end faces of the housing and of between them elastic elements formed two working chambers are, while an air distribution system is arranged coaxially with it in the cavity of the socket, according to the invention the air distribution system represents a sleeve with a cover, with which a hollow shaft is arranged coaxially is, which has a transverse partition and η "openings, which on the circumference of the hollow shaft to both sides

tea the transverse partition wall are evenly distributed, and on the hollow shaft itself is a gate direction for rotating the hollow shaft by means of compressed air attached, which of a additional source is supplied, wherein the sleeve is designed with channels and annular turns, to one of those in the arrangement zone of the device for rotation the hollow shaft has channels for the supply of compressed air from the additional source and to the other channels for connect the outlet of the exhaust air into the atmosphere, as well as with slots, which are arranged in rows along the axis of the sleeve are arranged uniformly on the circumference of the sleeve in the region of the openings of the hollow shaft, in each of which Row η slots are executed and the slots of the adjacent rows one against the other around one Angles CX = -— are offset ·

The vibration device according to the invention is simply constructed and reliable, and its presence a pneumatically controlled air distribution system enables the device to work in one explosive medium

In the following, the essence of the invention through a specific execution variant of the same and based on from accompanying drawings explains it

demonstrate:

Fig. 1 is a longitudinal section of the vibration device according to the invention;

Pig. 2 shows a section along the line H-II in FIG. 1,

Fig. 3 shows a section along the line IH-III in JO Fig. 1,

Fig. 4 is a section along the line IV-IV in Fig. 1,

FIG. 5 shows a longitudinal section along the line V-V (a partial cutout) in FIG. The vibration device contains a housing 1 (Fig. 1), on the outer end face 2 of which a working element 3 is attached, which is used for fastening a (in

the drawing) shovel-like or plate-like .working organ is determined, which in a medium exposed to vibration processing, for example in a molten metal, is immersed. In the variant discussed here, the housing 1 is in several parts and with With the help of screw bolts 4 assembled. in the Inside the housing 1 is coaxially with it a holder 5 which can be pushed back and forth along the housing housed. Springs 6 are coaxially arranged with the screw bolts 4 and for installing the socket 5 in the Housing 1 determined. In the version 5 are a channel 7 (Fig. 2), the cavity 8 (Fig. 1) of the version 5 with the Main compressed air source connects, which is under a pressure p- (the direction of entry of the compressed air is indicated in Fig. 2 by an arrow), and channels (Fig. 2), 10 (Fig. 5), which the cavity 8 (Fig. 1) to connect the version 5 with the atmosphere «) From the end faces 11, 12 of the socket 5> the inner end faces 13, 14 of the housing 1 and from between the housing 1 and the ring-shaped elastic elements 15, 16 located on the mount 5 are two working chambers 17, 18 educated. In the cavity 8 of the socket, an air distribution system 19 is arranged coaxially with it, the one Sleeve 20 contains which has a cover 21 and ring indentations which form annular spaces 22, 23, 24, 25 with the inner walls of the mount 5.

The annular space 22 is connected to the main compressed air source via the channel 7 (Fig. 2), the annular spaces 23, 24 (Fig. 1) are connected to the atmosphere via the channels 9 (Fig. 2), IO (Fig. 3) while the annular space 25 (Fig. 1) is connected via a channel 26 (Fig. 4, 5) to an additional compressed air source which is under a pressure of P ₂ (the direction of the entry of the compressed air is indicated by an arrow in Fig . 5 indicated). Inside the sleeve 20 (FIG. 1), a hollow shaft 27 (FIG. 1) is mounted in bearings coaxially with it, which has a transverse partition 28 and "n"'openings 29, 30 on both sides of the transverse partition 28. In the training dealt with here

management variant of the facility are on the one hand (the upper side) of the transverse partition wall 28 four openings and on the other side (the lower side) four openings 30 executed. The number "n" of the openings 29, 30 can be arbitrary and is chosen based on design considerations. On the hollow shaft 27 itself is in Cavity 31 of the sleeve 30 a device 32 for rotation the hollow shaft 27 is attached by means of the compressed air which is supplied from the additional source via the channel 26 (Fig. 5), the annular space 25 and channels 33 (Fig. 1) for the supply of compressed air is fed.

In the variant discussed here, the device 32 for rotating the hollow shaft 27 is designed as an axial turbine. In other cases, this device 32 can represent a hotation piston engine or a tangential turbine. The cavity 31 of the sleeve 20 is connected to the annular cavity 23 via channels 34 for the exit of the exhaust air into the atmosphere. In the sleeve 20 slots 35, 36, 37, 38 (FIGS. 1-3) are made, which are arranged in rows along the axis of the sleeve 20 in the area of the openings 29, 30 of the hollow shaft 27 evenly on the circumference of the sleeve. In the area of the openings 29 there are two rows of slots 35, 36 of "n" slots 35, 36 in each row (in the variant discussed here, "n">> 4), and in the area of the openings 30 there are two rows of slots 37 , 38 also made to four slots 37, 38 in each row. The adjacent slots 35-38 (Figs. 1-3) along the axis of the sleeve 20 (Fig. 1) are offset from one another by an angle o ( = r -, where "n" means the number of slots in the sleeve 20).

In the variant of the vibration device discussed here, four slots are provided and the angle is oC = 45 °.

The vibration device is mounted on a foundation with the aid of springs 40.

The vibration device proposed according to the invention works as follows.

The compressed air under pressure p. is supplied from the main source via the channel 7 (Fig. 2) to the ring space 22 and from the additional source under the pressure p ₂ via the channel 26 (Fig. 5) to the inlet space 25, from which it is fed via the connected to it it se η the? Channels 33 (FIG. 1) enter the cavity 31 of the sleeve 20. The compressed air under pressure p ₂ hits the blades of the axial turbine and rotates the hollow shaft. Subject to their work performance, the compressed air flows through the channels 34 into the annular space 23 and exits into the atmosphere through the channels 9 (FIG. 2).

In a half cycle of the vibrations, the slots 36 coincide with the openings 29 and the slots 38 coincide with the openings 30 (FIG. 3). In this case the compressed air occurs under pressure p. from the entrance space 22 (FIG. 1) via the slots 36 and the upper part of the hollow shaft 27 divided by the partition 28 into the working chamber 17, and in this the pressure rises. At the same time, the seed escapes from the working chamber 18 into the atmosphere via the lower part of the hollow shaft 27, the openings 30, the slots 38, the inlet space 24 and the channels 10 (FIG. 3), and in the chamber 18 (FIG. 1 ) the Dpuck drops. As a result of the pressure gradient in the working chambers 17 »18, the socket 5 moves downwards together with the sleeve 20, the cover 21, the hollow shaft 27 and the device 32 for rotating the said shaft 27, while the housing 1 with the working element 3 goes up.

In the following half-cycle of the oscillations, after the rotation of the shaft 27 by the angle oC, the slots 35 with the openings 29 (FIG. 2) and the slots 37 with the openings 30 (FIG. 3) coincide. In this case the compressed air flows under the pressure p. from the inlet space 22 (FIG. 3) via the slots 37 and the lower part of the hollow shaft 27 (FIG. 1) into the working chamber 18, and in this the pressure rises. Here, the air exits the working chamber 17 via the upper part of the hollow shaft 27, the openings 29 (Fig. 2), the Schlitr ·

ze 35 and the fiing chamber 23 into the atmosphere, and the Pressure in this chamber 17 (Fig. 1) drops. As a result of the Pressure drop in the working chambers 17 »18 shifts the fit 5 together with the sleeve 20, the Cover 21, the hollow shaft 27 and the device 32 for Rotation of said shaft 27 upwards, while the housing 1 with the working element 3 goes downwards.

The leather 40 isolate the foundation 39 from vibration · ·

Thus, the vibration device represents a two-

mass resonance system, in which one of the masses includes the holder 3 and the air distribution system 19, but the other includes the housing 1 and the working element 3. The vibration device is set to the operating state close to resonance by regulating the pressure p ₂ . The oscillation amplitude is determined by the choice of pressure p. regulated, which directly determines the amplitude of the excitation force. The stiffness of the springs 6 is designed for the near-resonance operating state of the vibration device

The device according to the invention is thus simple constructed and reliable and allows the vibration processing of explosive media to be carried out ο

Claims (1)

VIBKiTIONSSINHICHTIMG PiTMTiITSPEUOH Vibration device, which contains: - a housing (1), - A working element (3) which is attached to the outer end face (2) of the housing (1); - A fitting (5), which is housed inside the housing (1) and can be pushed back and forth along its Ise is; - Channels (7, 9, 10) that run in the fit (5) are and their cavity (8) with a main compressed air source and connect with the atmosphere - two labor chambers (17, 1Ö), which are run by the End faces (II, 12) of the fit (5), the inner end faces (13, 14) of the housing (I) and of between them located elastic elements (15, 16) formed are; - An air distribution system (19) in the cavity (8) the fit (15) is arranged coaxially with it, characterized in that the air distribution system (19) represents: - a hollow shaft ⁽² 7) with a transverse partition (28) and ¹ ^ n "orifices (29, 3o) which are executed in the hollow shaft (27) uniformly on the circumference on both sides of the transverse partition (28), - A device (32) for rotating the hollow shaft (27) by means of compressed air from an additional source is supplied, which device is mounted on the hollow shaft (27) itself and - A sleeve (20) with a cover (21) which is arranged coaxially with the hollow shaft (27) and - one of the channels (33) for the supply of compressed air from the additional source, - the other channels (34-) for the exhaust air to exit into the atmosphere, - the one hinge in rotation, the one in the arrangement zone the device (32) for rotating the hollow shaft (27) is carried out and to which the one channels (33) connect, - the other. Rings in rotation, on which the others Connect channels (34), - Has slots (35, 36, 37, 38) which in rows along the axis of the sleeve (20) in the region of the Openings (29 »30) of the hollow shaft (27) are arranged evenly on the sleeve circumference, with" n "in each row Slots (35, 36, 37, 38) are carried out and the slots (35, 36, 37, 38) of the adjacent rows the / CT one offset from the other by an angle CX = - are.