SU861207A1 - Vibratory feeder - Google Patents

Description

The vibrating feeder (see Fig. 1 and 2) contains a bowl 1 with a spiral tray, driven in oscillatory motion from an electromagnetic actuator 2, the electromagnet of which is attached to a reactive plate 3 connected to the bowl 1 by means of an elastic system 4.

The vibrating feeder contains a compressor, made in the form of chambers of variable volume, for example bellows 5 and 6.

Brackets 7 are attached to the bottom of the bowl 1 of the feeder, in which there are cavities

8 and discharge valves are located

9 and 10, and brackets 11 and 12 are attached to the reaction plate 3, in which suction valves 13 and 14 are placed and channels 15 and 16 are located.

Chambers of variable volume (bellows) 5 and 6 are placed between the brackets 11, 12 and 7 and attached to them with their ends. The cavity 8 communicates with the outlet channels of the chambers 5 and 6 and is connected to the nozzle 17 via a flexible hose 18.

The device works as follows.

During operation of the vibropitel, the bowl 1 and the reactive plate 3 perform oscillatory movements, and since the bellows 5 and 6 are fixed with their ends to the brackets 11, .12 and 7, the volumes of the bellows 5 and 6 change. In the first half-period, the volume of the bellows 5 decreases, and the bellows 6 is increased. Valves 13 and 10 are closed, and valves 14 and 9 are open. Air from the atmosphere through the channel 16 is sucked into the bellows B, since vacuum is created in it, and from the bellows 5, as a result of its compression, compressed air is forced out into the cavity 8, from which it is fed through a flexible hose 18 to the nozzle 17.

Over the next half-period, the air is supplied to the nozzle 17 from the bellows 6, and a new portion of the air from the atmosphere is sucked into the bellows 5 through the open valve 13 and the channel 15.

The vibrating feeder shown in FIG. 3 and 4, comprises a bowl 1, an electromagnetic actuator 2, a reaction plate 3, connected by means of an elastic system 4, and chambers of variable volume 5 and 6, which are bellows.

Brackets 7 are installed on the jet plate along the axis of the feeder, in which there are CAVES 8 and pressure valves 9 and 10 are located. Suction valves 13 and 14 are placed in channels 15 and 16. The cavity 8 is connected to the nozzle 17 by means of a flexible hose 18. On the periphery of the reactive plate flat springs 19 are fastened, at the ends of which there are loads 20. To balance the feeder, the chambers are installed in pairs, at equal distances from the axis of the feeder.

The device works as follows.

The pulses excited by the electromagnetic drive 2 are converted by the elastic 5 system 4 of the feeder into torsional vibrations of the bowl 1 and the reaction plate 3. Thanks to the fact that the loads 20 are attached to the reaction plate 3 by means of springs 19, and the natural frequencies of the systems

0, load 20 — spring 19 is chosen close to the oscillation frequency of the feeder (near-resonant tuning), oscillations of the reaction plate 3 due to kinematic excitation will be transmitted to loads 20, and the amplitude of oscillations of the loads will be much greater than the amplitude of oscillations of the reactive mass at the points of spring attachment, i.e. :

1 ppm V;

  -Ply

where Af is the amplitude of oscillations of the goods; rm is the amplitude of oscillations of the reactive mass at the points of attachment of the springs;

C - the coefficient of dynamism equal to from 10 to 20, depending on the proximity settings to the resonance, and the quality factor in the system.

In addition, due to the fact that the frequency of natural oscillations of the systems of the load - spring, located on one side of the chambers of variable volume, more, and located on the other side less

oscillation frequencies of the feeder, loads placed on one side will oscillate in phase with a reactive plate, and weights placed on the other side will oscillate in antiphase with a reactive plate, i.e. they will either converge, then move away from each other .

As a result of cargo oscillations in antiphase during the first half period of oscillation

of the reaction plate, the volume of the bellows increases and air is sucked from the atmosphere through the suction valves, and during the second half period the volume of the bellows decreases, the suction valves

are closed, and compressed air is forced through the injection valves into the cavity 8 of the bracket 7, from where it is supplied to the nozzle 17 by means of the hose 18. Thus, appropriate installation of variable volume chambers between the out-of-phase oscillating masses of the feeder allows creating this type of vibratory feeders in the shops of enterprises where there is no pneumatic network, and also to increase the reliability of the device as a whole.

In addition, in the vibrating feeder of the proposed con: puck (Fig. 3 and 4) when choosing

the corresponding parameters of the oscillating system provides an increase in compressor performance.

Claims (3)

1. A vibrating feeder comprising a bowl with a spiral tray, driven in an oscillatory motion from a drive, a reaction plate connected to the bowl by means of an elastic system, a compressor connected to a nozzle, characterized in that, in order to increase reliability, the compressor is made in the form of alternating chambers volume, such as bellows having suction and discharge valves, the walls of the chambers are connected to the moving masses of the feeder, while the inlet channels of the chambers communicate with the atmosphere, and the weekend with the nozzle. 2. The vibrating feeder according to claim 1, characterized in that one of the walls of each chamber is connected to the bottom of the thicket, and the other to the reaction plate. 3. Vibrating feeder according to claim 1, characterized in that the feeder is provided with additional weights fixed by means of flat springs on the reactive plate, one of the walls of each chamber being rigidly connected to the reactive plate and the other with the load. Sources of information taken into account in the examination 1. USSR author's certificate No. 372138, cl. In 65G 27/04, 1969. 2. Preuss V.F. Automation of loading presses with piece blanks, M., “Mashinostroenie, 1975, p. 257-259.