DE440789C - Drive of shaker channels by means of a mass that can swing and is spring-mounted - Google Patents

Description

Drive of the slide channels by means of a swingable and resilient stored Igasse. With the shaking chutes, the control of the shaking process self-induced forces to be transmitted to the support of the gutter considerable difficulties. These disadvantages increase, on the one hand, with higher Vibration numbers of the channel, which, however, are very desirable to protect the conveyed material are, on the other hand, especially when the support of the gutter to accommodate larger Forces is unsuitable, for example when the gutter is high in factory buildings is arranged so that the building walls are relieved of impermissibly high mass pressures Need to become.

All these difficulties are then completely eliminated and vibrational numbers of practically any height, i.e. vibrations of the channel, even with a light inner foundation feasible if according to the invention on the vibrating chute under spring action in a mass is mounted so that it can oscillate in the conveying direction; caused by periodic impulses, which with the natural frequency of the from the internal mass, the suspension and the vibrating mass existing system, is put into vibrations, the the channel vibrates under the mediation of the spring back pressure that arises offset with the same number of cycles. As a result, the new channel keeps up to a certain extent the drive mass itself the equilibrium, so that to the outside only proportionally weak forces are to be transmitted that are not significantly greater than their own weight the gutter. The resilient, z. B. inclined, known per se supports of the channel therefore need to be dimensioned so weakly according to the invention that they are straight the gutter is to be led sufficiently, but at least compared to the usual Schnell swinging channels necessary, extraordinarily powerful, technically hardly feasible Springs only cushion the channel so little that the natural frequency of the channel is significantly lower than the number of vibrations attached to the channel cushioned drive mass.

Another big advantage of the new drive is that the gutter through it as good as completely insensitive to fluctuations in the Feeding the chute is. This is for gutters that are supposed to work in resonance, very important. Such a channel is itself designed as a vibratory system, and therefore, an increase in the load becomes its natural frequency substantial while relieving the trough an increase in the natural frequency equals. If the drive motor is now running at a constant speed, how If this is usually the case in the company, it will be very difficult, if not impossible be to keep the gutter in resonance. This disadvantage does not apply in the present case away, since the channel only forms the basic mass, so to speak, which the oscillating in resonance, for example ljlo to 1 / "o of the internal mass Propulsion mass supports. It now influences the natural frequency of the drive mass only very insignificant and practically negligible, whether the internal mass twenty or forty times as large as. the drive mass itself.

This drive mass can in itself in any way in back and forth walking movement can be offset by the desired number of vibrations. A very simple one Operation results when, according to the invention, the pulses by centrifugal forces of Balancing masses are generated whose axis of rotation in the oscillating: mass is firmly mounted is. If compressed air, steam or a similar propellant is available for the drive, so the momentum on the oscillating mass according to the invention can still be always in the correct number of units, even if the operating pressure of the propellant fluctuates, occur when the vibrating mass is dependent on its own position Control always receives the impulse of the propellant at the right moment, in which they stand out from the opposite wall of the one surrounding the propellant Seeks to remove space while the propellant is exhausted any later, z. B. on the declining stroke of the vibrating mass takes place.

Some embodiments of the inventive concept are shown in the drawing schematically illustrated, namely Fig. i is a drawing of the overall arrangement the new channel and a drive by the centrifugal force of balancing masses while the Fig. - The self-control of the oscillating mass with compressed air o. the like. As Drive means illustrated. 1) The ritual u- can in an bich as is known, rest on inclined guide supports b or on pendulum rods or the like. In any case, these supports b or the like are dimensioned so weak that that they are essentially sufficient to support and guide the gutter without a significant one Own suspension.

At any suitable point on the channel a there is a the conveying direction extending guide c- attached for a mass d. This mass is opposite to channel a by suitably selected, optionally adjustable springs e supported, Berat. that the swingable: mass d with the suspension c and the channel mass forms a vibration system with a pronounced natural frequency.

If this oscillating mass d is now set to oscillate in this natural oscillation number in any way, the supporting pressure of the springs e also brings the channel a. even in oscillations with the same number of cycles. Here, the forces caused by the vibrations are essentially canceled out to the outside, in such a way that only relatively weak forces need to be transmitted to the outside. For this reason, the otherwise necessary strong support springs, especially in the case of heavy channels that work in resonance, and the load-bearing forces acting on the foundation are eliminated. There can be gutters of a thousand and more tons. Weight can be built and operated without the foundation and its support having to take into account other forces than the dead weight of the channel and its conveying load.

In the example in Fig. z a balancing mass f, which rotates around the axis g, which is fixedly mounted in the mass d. For example, an electric motor can be built into the oscillating mass d to drive it be that in any way, e.g. B. radially adjustable, the mass f carries. A Drive of this type is particularly simple and, as mentioned, also remains the same Motor speed can therefore be used for the new conveyor trough because the natural frequency of the structure is almost independent of the size of the conveying load.

As is usually the case in mines, for example, compressed air or a If similar operating power is available to drive the chute, the implementation would be such a force then turns into energy with a rotating motion to drive the chute Difficulty when, as is almost always the case with compressed air in mines is the case, the pressure and thus also the drive speed within very large limits fluctuates. In such cases, the drive is expediently carried out in that the directly Compressed air acting on the oscillating mass d - preferably through movement the mass d itself is controlled in such a way that its force is always only correct Number of cycles as a drive on the vibrating mass can be asserted. An example Fig. z.

In a housing h which is firmly connected to the vibrating chute, the mass d is able to oscillate between the springs e in such a way that its natural frequency corresponds to the operational frequency of the chute. Into the interior of the housing h protrudes a projection i which is firmly connected to the housing and which, acting as a piston, is encompassed with a good sealing effect by a cylindrical piece k which is connected to the mass d. On this mass there is also a tube 1, which slides well sealing in a bore i, of the extension i acting as a piston and has control slots at 11 through which the compressed air flowing in at i n can penetrate into the cylinder chamber k1 when these slots 1, meet with similar slots i, of the piston body i , which continue in channels i, to the cylinder chamber k. The compressed air is exhausted through the slots k2 of the cylinder wall k, which are controlled by the piston body i, and through which the calls can escape into the open after flowing through the openings k2 of the housing. Inside the main control slide 1 there is a protruding slide n consisting of a short piece of pipe, which slides in the main slide 1 with relatively high friction: this pilot slide ya has two stops "n o can meet.

The operation of this device is as follows: As long as no compressed air flows in, the mass d is held in its central position by the springs e, in which the inlet slots 1 :, i2 are fully open. If air now flows in, it penetrates the slots 11, i, and the channel i, into the cylinder chamber k through the bore i ″ and pushes the mass d to the right joins this movement to the right and with its wall closes off the inlet slits i2. Depending on whether the compressed air is to be expanded with greater or lesser extent, the exhaust duct k opens later or earlier incoming compressed air is thrown to the right under compression of the corresponding spring e. During this movement, the outlet channels k2 remain fully open. They are "only closed again when the mass d - on its return movement to the left - comes into position; - in which the outlet slots had opened. If the inlet slots 1 ″ i @ were to open again as the mass d moved to the left, the mass d would immediately be thrown back to the right and only very small oscillations would occur . Procedure: it the pilot spool is entrained l by its friction from the inner wall of the main spool, if n his device, za allow Approximately in - the moment in which the inlet slits h, 1, d in the movement of the mass.. close to the right, the left stop za. of the pilot spool iz hits against the fixed disc o,. the rod o. This holds it in place while parts d and L move to the right so that the auxiliary spool is now in the bore of the Main slide l slides. If the mass d reverses its movement in its right dead center, the pilot spool n is carried along in the bore of the main slide l by friction as long as until the space between its stops n1, ra, is traversed - and the right stop n, _ against the stationary disk o ,. meets. Now the pilot valve remains. stand while the main slide l moves with the mass d further to the left. In this position, however, the pilot slide it closes the inlet slots h of the main slide 1 when these are positioned in front of the slots i2 of the piston during the longitudinal movement. Despite the coincidence of the slots 1,. and i. so when the mass d moves to the left, no compressed air can flow into the cylinder space h ..

After passing through the middle position, the mass d will be longer keep moving to the left until their kinetic energy is in suspension and useful work has transformed. Since in the example shown, the exhaust ports on this Paths remain closed, the air trapped in room h, _ will condense, which, however, has no harmful effect, but only increases the effect of the springs e. If necessary, however, this can be ensured by attaching suitable exhaust slots that this compression does not take place in the space k i.

During this left movement of the mass d, the stop is supported -n, _ of the pilot spool against .the fixed disc o1, so that the main spool 1 slides over the pilot valve. But as soon as the mass d and you Slide 1 moved to the right again after passing through the left dead center, the pilot valve n is on the short piece between its two stops taken from the inner wall of the main slide L until there is a left stop n2 against the disk o, supports. As a result, the pilot valve has its original one Position taken again, so that shortly before reaching the central position of the mass d the Slots 1 "i2 again give the compressed air access to the cylinder space h, and with a new compressed air impact on the vibrating mass d the game begins again. .

The device just described can be arranged on both sides of the mass d so that it is driven in a double-acting manner. Likewise, instead of the 'any' just described, another equally effective control can be attached so that the propellant is always driven in only one direction of oscillation - the mass d, while the influx of the propellant is shut off during the reverse oscillation . For example, if the pilot spool is omitted, the main spool l shortly before reaching its two dead points could be given a: small rotation or reverse rotation with respect to the mass d, whereby the control slots 11 fall in the longitudinal direction of the slots i2 in one direction of movement, in the other direction of movement, however, due to the rotation of the slide L with respect to the mass d , they are offset from the slots i2. Any other control devices of the same type can also be provided. For example, a cock can also be provided in the air supply line itself, which is rotated back and forth and thus opened and closed by appropriate attachments of the oscillating mass d before the control slots 1, can the oscillating mass d; - similar to a Wagner hammer, only move in its natural oscillation: It controls the energy supply itself so that the drive pulse always occurs at the right moment. The oscillating mass can only work in resonance; B. in a drive by means of a conventional Pr eßluftmotor with revolving crankshaft whose speed and thus the momentum of the channel very significantly through the. Pressure fluctuations would be affected. The new device, however, can never fall out of step. The pressure fluctuations bind at most to influence the oscillation amplitude to a minor extent.

The control, suspension, etc., d. H. Everyone Factors that affect energy absorption, vibration magnitude, natural vibration number and the like of the oscillating system have an influence, adjustable set up. The oscillation amplitude, which reaches the mass d depends on the ratio of the input work to the damping resistances, which remove work from the mass. These dampening Resistances partly consist of harmful damping, i.e. H. the friction in Pistons and control slide, the internal friction of the springs and the like, on the other hand and larger part in the useful attenuation, d. H. in work that of the vibrating mass d is withdrawn and converted into movement of the conveyed material.

Claims (7)

PATENT CLAIMS: i. Drive of vibrating chutes by means of swingable arranged and resiliently mounted mass, characterized in that this mass is supported resiliently and swingably in the conveying direction on the channel, and that the periodic impulses, which set the channel in oscillation, in the natural oscillation number the system consisting of the channel mass, the suspension and the oscillating mass take place and with the mediation of the resulting spring back pressure the channel set in oscillations with the same number of cycles. 2. Drive of vibrating chutes after Claim i, characterized in that the oscillating drive mass is only one Fraction of the channel mass, so that the natural frequency of the channel mass, the suspension and the oscillating mass existing oscillation @ system practical remains the same, even if the load weight fluctuates within wide limits keep the system permanently in resonance by means of a power source with the same number of pulses to be able to. 3. Drive according to claim i, characterized in that the resilient Supports o. The like. Are so weak that they are just sufficient for the gutter to lead, but in any case cushion the channel so little that the natural frequency the channel compared to the foundation is significantly lower than the natural vibration number the cushioned mass sitting on the gutter. . 4. Drive according to claim i to 3, characterized in that balancing masses, which in a known manner by their centrifugal forces generate the impulses, rotatable freely in the conveying direction vibrating mass are mounted. 5. Drive according to claim i or subclaims by means of an electric motor, characterized in that the electric motor is in the oscillating mass is built in and the balancing masses sit on its shaft. 6. Drive according to claim i or dependent claims, characterized in that the pulses exerted on the vibrating mass are generated in that a cylinder (or piston) is attached to the vibrating mass, in which a piston (or cylinder) is fixedly connected to the channel ) is driven by compressed air, steam _ or a similar propellant in such a way that the propellant's drive impulse always occurs only in one direction of oscillation - the mass, while the propellant flow is shut off during the return oscillation. 7. Drive according to claim i or subclaims, characterized in that in the area the central position of the oscillating mass takes place drive impulses after a short distance the mass from the central position cease and the movement under opening the exhaust vents continues. B. Drive according to claim 6, characterized in that that the flow to the control slots by means of a pilot valve or the like is only open during the drive oscillation, during the back oscillation however, remains closed. G. Drive according to claim 8, characterized in that that the pilot valve is designed as a drag valve of the main control valve and its stroke is limited by stops. ok Drive according to claim i or Dependent claims, characterized in that the control, suspension and the like. Factors, -which affects the energy absorption, oscillation magnitude, natural oscillation number and the like. of the vibrating system have an influence, are set up adjustable.