SU701709A1 - Apparatus for controlling the content of coarse fraction in a stream of lump product - Google Patents

Description

(54) DEVICE FOR CONTROLLING THE CONTENT OF A LARGE CLASS IN A FLOW OF LAP MATERIAL

I

The invention relates to the field of crushing and grinding of building materials, ore and non-metallic minerals and can be used for the operational control and management of technological processes of crushing and grinding.

A device is known for determining the size of a material by measuring the average frequency of vibration amplitudes exceeding a predetermined level of limitation occurring in a body under the action of a shock.

ore 1.

However, this device does not provide the required measurement accuracy.

The closest. The invention is a device for monitoring the content of a large class in a stream of bulk material, comprising a sensing element in the form of a beam fixed in shock-absorbing supports, installed in a falling stream and equipped with a vibration sensor, an amplifier, a dividing unit and a secondary device 2. In this device, parallel to the forming unit measuring the frequency of the signal emission of the vibration sensor beyond the limitation threshold, a second forming

The unit measures the average frequency of outliers for the zero level, and the outputs of these blocks are connected to the dividing unit.

However, this device does not provide the required accuracy when changing the physicomechanical properties of the flow material, which are expressed in changing the shape, hardness and moisture of the particles, the content of clay and other viscous, wetting and bonding substances leading to a change in the impact forces at a constant size. Thus, with an increase in hardness and other properties that increase the forces of an impact, some of the small particles can strike such a force that would cause an excess of. the threshold is limited by a signal, and then all these particles will be recorded as large, which will lead to a false increase in the measured value of the content of a large class. And vice versa - changes in material properties causing a decrease in impact forces (decrease in hardness, increase in humidity, etc.) will result in signals from the blows of some large particles not being able to overcome the limitation threshold and all these particles will lock in

i.a small ones, t, e, there will be a false decrease in the measured value containing I5, a cool class.

The Lie.Uiio of the invention is to exclude the effects of controlling the changes in the physicomechanical properties of the flow of bulk segregated material.

This goal is achieved by the fact that the device for monitoring the content of a large p; lass in a stream of bulk material, comprising a sensing element in the form of a beam fixed in the shock absorbing supports, installed in a downstream stream and equipped with a vibration sensor, an amplifier, a dividing unit and a secondary device, additionally contains a block square root extraction, multiplication unit, frequency converter, differentiating unit, switchboard, adders, sensor of perceiving element, time delay unit, memory unit, relay Name and function of the sensing element, the vibration sensor through the amplifier and the square root extraction unit is connected to one input of the multiplication unit, to the other input of which the output of the amplifier is connected, the output of the multiplication unit is connected to the input of the frequency converter, the output of which is connected to one input of the first adder and one input of the switch, the other input of which is connected to the output by amplifying the alternating block; (the output of the switch is connected to one input of the second totalizer a, the outputs of the adders are connected to the inputs of the dividing unit, the output of which is connected to one input of the memory unit, the other input of which is connected to the output of the sensor of the sensing element and the output to the secondary device, the other inputs of the adders are connected to the output of the sensor of the sensing element through the block time delay, and the output of the time relay is connected to the actuator displacement of the sensing element, kinematically connected with the position sensor. the impoverished element and the receptive element.

The device is shown in the drawing-and: ON; vibro-platform 1, conveying conveyor 2, vibration sensor 3, sensory element 4, amplifier 5, square root extraction unit 6, b. 1k multiplication 7, frequency converter 8, differentiating unit 9, adder iO of lump material mass, adder 11 total mass, movable frame 12, blocking unit 13, time relay 14, memory unit 15, secondary device b, time delay unit 17, actuator 18 for moving the sensing element, switch 19, position sensor 20 for the sensing element and pulls 21.

The sensing element 4 is made in the form of a rectangular cross-section beam, mounted in shock-absorbing mode (x supports under the head of the transport conveyor 2 parallel to the cylinder forming the drum co-generator 2 and an edge to the incident flow of the lumpy segregated material. On one side of the beam there is a vibration sensor 3. Length beams between supports exceed the maximum

the possible width of the flow of the controlled material. A. The damping beams of the beam are fixed on the horizontal frame 12, which is kinematically connected with the rod 21 of the actuator of the translational movement 18. The stroke of the actuator 18 and the movable frame 12 is set larger than 5axial-1. material.

The device works as follows. M, the material supplied by the transporting conveyor 2, contains pieces of various sizes ,,. When the tape passes through the roller supports, the material is shaken, as a result of which small pieces are sifted to the lower layers, and the larger ones are squeezed up, i.e., segregation occurs. When moving along a long conveyor belt, there is an almost complete separation of the material, as a result of which the coarse material is located at the top of the stream, and the shallow interior:. For the purpose of the material separation process, a vibroplatform 1 was used, accelerating the passage of segregation processes due to the intensive shaking of the material at the helix above it.

When a command from the time relay 14 arrives at the beginning of the measuring cycle, an additional mechanism 12 is activated, moving through the jaws 21 a movable frame 12 with the sensing element 4. The last one is introduced into the incident flow from the side of the large pieces of the series. Its movement through the flow is accompanied by the dynamic effects of pieces of material striking the beam. Moreover, the movement of the beam is set in terms of the wide angle of its wide face, which ensures the intersection during the measurement of the cross-sectional area of the entire flow. As a consequence, the pieces passing through each point of the flow cross section ,. will hit the sensing element. The impact force of each piece is determined by its dimensions, the physicomechanical properties of the impacting materials, and the speed of movement of the piece at the moment of impact.

The speed of movement of the pieces at the moment of impact is constant due to the constant height of the fall and the constant speed of the conveyor 2. Material properties

in the flow, during the measurement time remains constant.

The content of a large class in the stream of bulk material can be determined by the ratio of the mass of the large material in the stream under study to the total mass of the material. However, it is known that the mass of a piece is proportional to the third degree of its linear dimensions, and the impact force is second. This determined the following sequence of signals passing through the device and actions on them.

The dynamic impact of the impact of each piece causes a corresponding oscillation of the beam, perceived by the sensor, of vibrations 3, the electrical signal of which is supplied through amplifier 5, square root extraction unit 6 and multiplication unit 7 to the input of frequency converter 8. In addition, the output signal of amplifier 5 also enters the second input of multiplier 7. The output signal of block 6 is proportional to the linear dimensions of the struck piece, and the second input of multiplier 7 receives a signal proportional to the square of these sizes, p result after multiplication by the output of block 7 there is a signal proportional to the cube of the linear dimensions of the piece or mass. Frequency converter 8 converts it into a proportional frequency signal supplied to the input of the adder 11 directly, and to the input of the adder 10 - through the switch 19. Therefore, the mass of each piece will correspond to a certain number of pulses accumulated in these adders.

When a sensing element is moved in a layer of coarse material, a signal is accumulated in both adders that is proportional to the mass of the pieces that hit the perceiving element during its movement. The transition of the sensing element 4 from the coarse-sized layer into the small-sized layer is accompanied by a sharp change in the dynamic effects transmitted to the vibration sensor 3. Differential unit 9 triggers and a signal is sent from it to the switch 19, which disconnects the input of the adder 10 from the output of the converter 8. Consequently, after the transition of the sensing element in the small-layer layer, the accumulation of the signal occurs only in the adder 11. After the flow has completely crossed the sensing element. 4, the reverse occurs and additionally mechanism 18 and its movement in the opposite direction. At the same time, only the adder P. is still connected. When the sensing element transitions into the lumpy layer of material, a new actuation of the differentiating unit 9, the switch 19, the connection of the adder 10 and fixing the results of the interaction with both adders,

up to the exit of the receiving element from the flow and stopping the actuator 18.

Thus, for the period and the ::. 1 cycle, the control of the entire flow occurs twice in the forward and reverse direction, which ensures averaging of the results obtained. During this time, SIGAL accumulated in the adder 10, proportional to the mass of large-volume material that came into contact with the sensing element 4, and in the adder 11 —signal proportional to the mass of the material in contact. These signals are fed to the inputs of the dividing unit 13, the signal at the output of which is proportional to the content of a large class in the material under study.

After you, the sensor of the sensing element from the flow position sensor 20 issues a signal indicating the end of the measuring cycle. On this signal, the memory unit 15 memorizes the output signal of the division unit 13 and transmits it to the secondary device 16. At the same time, the time delay unit L7 is turned on and, after the time required for memorization in unit 15, sends a command to the control inputs of adders 10 and 11 on erasing the signals accumulated in them. After that, the device is ready to start the next measurement. cycle, which occurs after a pause determined by the required interval in obtaining information, set by setting the time relay 14.

Increasing the content of a large class, with postO) 1nn total material consumption leads to an increase in the coarse layer in the stream and a corresponding reduction in the fine. Accordingly, the output signal of the block 10 will increase, and the block I will remain constant, as a result of which, after dividing the signals in block 13, the signal at its output and at the input of the secondary device 16 will increase.

5 Excessing or increasing the total consumption of material with a constant content of a large class will lead to a corresponding change; signals from both its large-scale part and the entire stream, and the result of dividing and reading the secondary instrument will remain constant.

A change in the physicomechanical properties of the controlled flow will result in a change in the same degree of force by the impact of the large-sized and small-sized parts of it and will not affect the measurement results.

Claims (2)

. Invention Formula A device for controlling the content (corpse class in a stream of baked material, including a sensing element in the form of a beam fixed in shock-absorbing bearings, fixed in a falling stream and equipped with a vibration sensor, amplifier, de-block unit; n secondary device, different -tQ i, which is eliminating the influence of the results of monitoring changes in the physicomechanical characteristics of the flow of lumpy segregated material; it contains, additionally, a square root extraction unit, a multiplication unit, a frequency converter, differentiating unit, switchboard, adders, sensor position sensor, time delay unit, memory unit, time relay and actuator for moving the sensing element, the vibration sensor through the amplifier n the square root extractor connected to one input of the multiplication unit to another the input of which is connected to the output of the amplifier, the output of the multiplication unit is connected to the input of the frequency converter, the output of which is connected to one input of the first adder and to one input of the switch, the other second input of which through differentiator the unit is connected to the output of the amplifier, the output of the switch is connected to one input of the second adder, the outputs of the adders are connected to the inputs of the division unit, the output of which is connected to one input of the memory unit, the other input of which is connected to the output of the sensor of the sensing element, and the output to the secondary device , the other inputs of the adders are connected to the output of the sensor of the sensing temperature through a time delay unit, and the output of the time relay is connected to the actuator of the movement of the sensing element kinematically associated with the sensor position of the sensing element and the sensing element. , Sources of information taken into account during the examination 1. USSR author's certificate No. 353741, cl. B 02 C 25/00, 1973. 2. USSR author's certificate number 377171, cl. B 02 C 25/00, 1973 (prototype).