SU1200256A1 - Multicomponent proportioning device - Google Patents

Abstract

one; A DEVICE FOR MULTICOMPONENT DOSING, containing also metering devices by the number of channels, multiplication units, a maximum determination unit and an adder, and a liter. In order to improve the accuracy and speed of the device, it contains controllers, a memory unit, switches, an AND element, a comparison element, the first key elements, controllers, a delay element, and a second key element, and in each channel the metering input is connected with the first output of the regulator, and the output with the first input of the regulator and with the first input of the first key element connected with the input to the first multiplication unit, the output of the setpoint generator of each channel is connected to the first input of the switch, the second input which is connected to the output of the second multiplication unit, and the output - to the second input of the regulator, and the outputs of the setters of all channels are connected to the corresponding inputs of the adder, the output of which is connected to the first input of the comparison element connected to the second input to the output of the maximum determination unit and to the first input the second key element, and the output to the third inputs of the switches and controllers of all channels, the first outputs of the element I are connected to the corresponding second inputs of the first key elements of all channels, the second the output is with the input of the delay element, and the inputs are with the corresponding second outputs of the regulators, the output of the delay element is connected to the second input of the Hex key element connected by the output with the input of the memory block whose output is connected to the inputs of the second multiplication blocks, the outputs of the first blocks the multiplications are connected to the corresponding IsD inputs of the maximum determination unit. 2. A device according to claim 1, characterized in that each QPS controller contains an exact mass fixing unit and a coarse mass fixing unit, an IL block, a pulse width former and a logic block, the second input of which is associated with the output of the exact mass fixing unit, the third input — with the output of the fixing unit of the coarse mass and the second regulator output, the fourth input — with the second input of the OR element and the third regulator input, and the output — with the first regulator output, the first fixation input coarse mass podkve chen to the first input of the block fixations

Description

exact mass and k l torus, and the second second input of the regulator input block fixing the exact mass input to the second and to the first input of the regulator. 1200256

one

This invention relates to systems.

controlling the ratio of the components in mixtures of different materials and can be used in the construction, metallurgical, chemical and other industries.

The purpose of the invention is to improve the accuracy and speed of the device.

FIG. 1 shows a block diagram of the proposed device; 2 a connection diagram for one of the regulators.

A device for a multicomponent dose 1 | ro ni contains n according to the number of channels of the dispensers 1 multicomponent. mixtures, stabilizing controllers 2, n first key elements 3, n first multiplication blocks 4, maximum determining block 5, memory block 6, n second multiplicating blocks 7, n dials 8, n switches 9, logical gate 10, adder 11 , comparison element 12, key element 13, and delay element 14.

Each of the automated 1 x, dispensers 1 contains the inlet 15, the hopper with the weighting mechanism 1.6. And weight sensor 17.

In addition, each stabilizing regulator 2 contains an exact weight fixing unit 18, a gross weight fixing unit 19, a pulse width imaging unit 20, a logic unit 21, and an OR element 26.

In turn, the exact weight fixing unit 18 comprises a shift repeater 22 and a reference element 23.

The coarse weight fixing unit 19 contains a shear repeater 24 and a reference element 25.

The pulse width former 20 has two adjustable resistances 27 and 28, a switch 29, a limit switch 30, a capacitance 31, and a relay 32.

Logic block 21 contains two inverters 33 and 34, two logical elements And 35 and 36, the key element 37 and the logical element OR 38.

In each channel (Fig. 1), the inlet of the dispenser 1 is connected to the first input of the regulator 2, and the output to the first input of the regulator 2 and the first input of the first key element 3 connected with its output to the input of the first multiplication unit 4. The output of the setpoint 8 of each channel is connected to the first input of the switch 9, the second input

0 which is connected to the output of the second multiplication unit 7, and the output to the second input of the controller 2, and the outputs of the setters 8 of all channels are connected to the corresponding inputs of the adder 11, the output of which is connected to the first input of the comparison element 12 connected to the second input 5 determine the maximum and to the first input of the second key element 13, and the output to the third control inputs of the switches 9 and the controllers 2 of all channels, the first outputs of the element And 10 are connected to the corresponding second control inputs of the first to The key elements 3 are all channels, the second output is the input of the delay element 14, and the inputs are with the corresponding second outputs of the regulators 2, the output

the delay element 14 is connected to the second input of the second key element 13 connected to the input of the memory unit 6, the output of which is connected to the inputs of the second multiplication units 7, the outputs of the first multiplication units 4 are connected to the corresponding inputs of the maximum determining unit 5.

In addition, in each controller 2, the exact weight fixing unit 18, the gross weight fixing unit 19, the OR element 26, the pulse width former 20 and the logic unit 21, the second input are sequentially connected.

which is associated with the output of the exact weight fixing unit 18, the third input with the output of the coarse weight fixing unit 19 and the second regulator output, the fourth input with the second input

the element OR 26 to the third input of the regulator, and the output to the first output of the regulator; the first input of the coarse weight fixing unit 19 is connected to the first input of the exact weight fixing unit 18 and to the second input of the regulator, and the second input to the second input of the unit 18 fixing the exact weight and to the first input of the regulator. The output of the switch 9 is connected to the inputs of the repeaters 22 and 24 with a shift, the outputs of which are connected to the inputs of the respective comparison elements 23 and 25, the second outputs of which are connected to the weight sensor 17, and the output of the first comparison element 23 is connected to the input of the first inverter 33, the output of which is connected with the first input of the first element AND 35, the output of which is connected to the first input of the first element OR 38, the output of which is connected to the input of the inlet gate 15, and the output of the second comparison element 25 is connected to the corresponding input of the element 10 s , the first input of the second element OR 26 and the input of the second inverter 34, the output of which is connected to the input of the key element 33 whose second input is connected to the output of the system comparison element 12 and the second input of the second element OR 26, and the output of the second key element 37 is connected to the first input the second element And 36, the output of which is connected to the second input of the first element OR 38, the output of the second element. OR 26 is connected to the input of the first adjustable resistance 27, the output of which is connected to the input of the switch 29, the first output of which is connected to the second adjustable resistance 28, and the second output to the input of the capacitance 31, the output of which is connected to the input of the relay 32, c. which is connected to the main input of the first element And 35, and the control input of the switch 29 is connected to the limit switch 30.

Theoretical justification of the device.

For a mixture consisting of n components, their fraction of content, established according to technological standards, is equal to

and 7V pt, .. ", p)

U1

where and. - the dose value of the component x, corresponding to the position of the setting device 8, the i-th component is dosed with the appropriate metering device.

First, all the components are dosed simultaneously in the Gryuo mode, followed by weighing. Due to the fact that the dosing process is often accompanied by mass ejections (overdose) in a rough mode in relation to the nominal value of the exact dosing mode, the device performs a correction of the dosage for filling

in each dosing cycle so that the proportion of each component in the mixture remains set.

I.

In this case, the leading component is selected, and therefore the normalized masses V of the mixture, i.e. such masses of the mixture at which the metering error of component i is zero. This is the value of the normalized mass for component x; equally

V.2iiyj). c, 2p),

„; where and. - the measured value of the i-dose mass.

The outcome of the value of the normalized. masses V,. . .V. | , ... Vf ,, determine the maximum value of c. according to the maximum function

mx MdncVi 2. i nJ

V

The signal is then transmitted to all channels and multiplied by the corresponding specified proportions of the components.

, K.cri

The obtained values of the adjusted tasks are supplied as new tasks to the stabilizing controllers and they are added in the mode of accurate dosing.

simultaneously on all channels.

The device works as follows.

Before the start of dosing with the aid of the setting devices 8, the level of the analog signal C (nominal) is set, which is proportional to the set value. Dispensers 1 controlled by their own

stabilizing regulators 2,

In accordance with the nominal values given on switches 9 through the switches 9, all p components of the mixture are dosed in the coarse mode. After the end of coarse metering in all metering devices 1, the coarse clocking signal (TSH) formed in AND 10 opens the keys 3, and the signals of the gained coarse weight of the mixture component arrive through multiplication units 4 (where they are divided by their given weight fractions) into block 5 maximum selection, (where the maximum value of the normalized weight V is chosen. In the event of overload, with the introduction of the adjusted nominal value, the signal TS G can become equal to zero. Therefore, the value of the maximum normalized value after passing through the key element Step 13, opened by a TSG signal with a time delay (determined by the delay element 14), is stored in a block, 6 am. Then the VM "KC signal is multiplied in blocks. 7 multiplied by y, where the value of the adjusted UV UV What it goes to the second input of the switch 9. With the output of the setting devices 8, the signals go to the adder 11, where the value of the specified mass of the batch is formed. This value of the specified mass simultaneously with the signal is fed to the comparison element 12. The signal Z formed in element 12 is equal to logical O in the absence of overload with coarse dosing and equal to logical; in case of overload (the signal to the output of the switch 9 passes the setpoint signal U. from the setpoint 8. When the output of the switch 9 passes the signal of the adjusted setpoint U-, and the regulator-2 performs its value. The stabilizing regulator works as follows. Before dosing , while the gross weight is not dialed,, at the output of the comparison element 25 of the fixation block 19, a coarse weight of logical O remains, which is then inverted in the element 34 and through the key element 37 enters the first input of the AND 36 element. To the logical unit 21, namely, to the second inputs of the And 35 and 36 elements (Fig. 2), a start signal is given, which is maintained until the end of the dosing cycle, i.e., a set of accurate weights on the dispensers. during unloading, the material was not filled in. The first input of the element 36 comes from the inverter 34 through the key element 37, a logical signal 1. At the output of the element ILY 38 of logic unit 21, a signal of logical 1 appears and the gate 15 opens. The material to be dosed begins to flow through the open gate 15 into the hopper 16 of the weighing system, and the weight is picked up in it by the sensor 17, which generates an analog signal P (parameter), which is proportional to the weight of the material being metered. A repeater 24 with a shift of the coarse weight fixing unit 19 gives the output signal H of the setter 8 a negative shift C, the value of which determines the coarse metering zone. After dialing the coarse weigher at П7Н-С1, the comparison element 25 forms a discrete logical 1 at the output, which passes through the inverter 34 and the key element 37 to the output of the AND 36 element. The inverted signal enters the input of the OR element 38 of the logic unit 21 and turns off the IM signal ( the actuator) and the shutter 15 is closed. At the output of block 25, logical 1 appears and dosing begins. When at the end of the coarse dosing mode at the outputs of the comparison elements 25 of the coarse weight fixing unit 19, the logical 1 signals appear on all channels, the TGG signal equal to logical 1, forming the coarse dosing in all channel a, is formed in the logical And 10 element. .x The exact dosage can not go on in two modes. In the event that (overdosing does not occur), the switch 9 is in the first position, at which the nominal signal from the setting device 8 passes through it. The key element 37 is open. The logical 1 signal, which appeared at the output of element 25, arrives at element OR 26. After the shutter 15 is closed, the limit switch 26 from the duration generator 20 generates a signal that arrives at the control input of the switch 29.

7

The latter closes its normally open contact, and the signal from element 26, passage through adjustable resistance 27, switch 29 and capacitance 31, turns on relay 32 with a time delay (equal to the time for complete restraint of dynamic perturbations of the weighing system)

Then, the output signal from relay 32 is supplied through element 35 and element 38 of logic block 21, which generates an MI signal, to open gate 15. The gate 15, moving, releases the lever of limit switch 30, the signal from which disappears, and switch 29 closes its normally closed contact.

The capacitance 31 through the normally closed contact of the switch 29 and the adjustable resistance 28 is discharged, and after a specified time the signals from the relay 32 and, accordingly, the MI from the OR 38 element of the control unit 21 disappear, after which the shutter 15 closes.

Elements 28, 31 and 32 play the role of impulse. Adjustable resistance 28 adjust the duration of the pulse (signal). Impulse dosypka occurs before the full set of weight. The exact weight set is monitored by the exact weight fixing unit 18, in which the analog signal H from setpoint 8 or 0 .. from block 7. multiplying, passing through the repeater 22 with a shift receives a negative shift equal to the signal level proportional to the error introduced by the inertia of the actuator and the error of the reference element 23 plus half the weight of the portion of the doserka in the exact weighing zone.

When the signal from the weight sensor 17 reaches a predetermined value, a discrete signal from element 23 appears.

002568

comparison, which through the inverter 33 enters the element And 35 and forms the logical O at its output. At the same time, the element OR 38 removes the signal

5, and the shutter 15 is closed. The specified weight is recruited, the dosing process ends.

 In the event that (overdose of one of the components occurs in the coarse mode), switch 9 switches over with signal z, and at its output appears the signal of the corrected nominal coming from multiplication unit 7. Further

15 dosing is similar.

So that when applying the corrected nominal to the input of the block 24, there is no secondary switching

20 to the coarse dosing mode (as at Hc7P, the output of element 25 may again have a logical O), the signal Z closes the key element 37, and the output c

25 of block 34, logical 1 does not pass to the input of block 36. At the same time, in order for the system to switch to pulsed mode in time (if the output of block 25 disappears), the second input of block OR 26 is given a signal z, which functionally replaces itself. the output of block 25 logical 1.

The invention allows the dosing process of all components to be carried out simultaneously, which reduces the duration of the dosing cycle. In addition, the ability to correct tasks during each dosing cycle allows

40 to increase the stability of the mixture.

The application of the invention in the production of reinforced concrete mixtures allows to reduce the coefficient of variation of the strength of finished products by 5-7%, which,

45, in turn, makes it possible to reduce the consumption of cement for the manufacture of concrete mix by an average of 5%.

Fmg.1

FIG 2

Claims (2)

1; A DEVICE FOR MULTI-COMPONENT DOSING, which contains dispensers by the number of channels, multiplication units, a maximum determination unit and an adder, characterized in that, in order to increase the accuracy and speed of the device, it contains adjusters, a memory unit, switches, an AND element, a comparison element, the first key elements, regulators, a delay element and a second key element, with the dispenser input connected to the first output of the regulator in each channel, and the output to the first input of the regulator and the first input of the first key element nt associated with the output of the input of the first multiplication unit, the output of the master of each channel is connected to the first input of the switch, the second input of which is connected to the output of the second unit .Z of multiplication, and the output is connected to the second input of the controller, and the outputs of the settings of all channels are connected to the corresponding inputs of the adder whose output is connected to the first input of the comparison element connected by the second input to the output of the maximum determination unit and to the first input of the second key element, and by the output to the third inputs of the switches and adjust tors of all channels, the first outputs of the And element are connected to the corresponding second inputs of the first key elements of all channels, the second output to the input of the delay element, and the inputs to the corresponding second outputs of the regulators, the output of the delay element is connected to the second input of the second key element connected by the output to the input of the memory block, the output of which is connected to the inputs of the second multiplication blocks, the outputs of the first multiplication blocks are connected to the corresponding inputs of the maximum determination block. 2. The device according to π. 1, characterized in that each regulator contains an exact mass fixation unit and a coarse mass fixation unit connected in series, an OR element, a pulse width former and a logic block, the second input of which is connected to the output of the exact mass fixation unit, and the third input is connected to the output of the block fixing the coarse mass and with the second output of the regulator, the fourth input - with the second input of the OR element and the third input of the regulator, and the output - with the first output of the regulator, the first input of the block of fixing the coarse mass is connected to the first input of the unit ka fixations' SU „„ 1200256 of the exact mass and to the second input of the regulator- input of the block for fixing the exact mass of the elter, and the second input to the second ^{and the} first input of the regulator.