SU1368650A1 - Method and apparatus for digital weight metering of loose materials - Google Patents

Abstract

This invention relates to a weight measuring technique. The purpose of the invention is to improve accuracy. With the start of weight gain, feeder 1 is turned on at a high feed rate. The material enters the ladle of the mass measuring device 2, the output signal of which is fed to the inputs of the comparators 3 and 4 and the analyzer 5 of the material flow. If the flow rate of the supplied material is uniform during the mass acquisition cycle, the control unit 3 gives a command to block the precursor weight selection blocks 9, 15 and select the feed speed in the same state. If the unevenness of the flow exceeds the permissible limit, then the control unit 13 gives the command to change the state of the setting unit blocks 9, 15 and the selection of the feeder speed. The dosing is continued at a low material feed rate and ends at the moment when the control unit 16 turns off the feeder for 1..2 s and 1 hp. f-ly, 3 Il. & (L

Description

Source material

i unload

ten

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This invention relates to a weight-related rhythmic technique.

The purpose of the invention is to improve accuracy.

A method for discrete weight dosing of materials is as follows.

With a large consumption of material, a set of the main part of the portion (dose) is made. During the set of the main part of the portion, the integral characteristic of the material consumption uniformity is analyzed, and after dialing this part of the portion, the value of the integral characteristic of the flow is compared with its limit set value and, if this value is exceeded, a dozen is produced at a low flow rate; if the target value is not equal or equal to the target value, the dozen is produced with the same material consumption as when recruiting the main portion of the batch. In addition, the mass of the main portion of the batch is set not 25 less than the value of the maximum ejection of the output signal of the mass meter, which is possible when the material is fed.

Fig. 1 shows a block diagram of a device realizing a method of discrete weight dosing of bulk materials; 2 is a block diagram of a material flow analyzer; fig.Z - block diagram of the logical part of the device. The device contains a two-speed feeder 1, a mass measuring device 2, a first comparator 3, a second comparator 4, a material flow analyzer 5, a setpoint generator, 6 batches of material, a rough setpoint generator, 7 (additional) lead weight, precision setpoint meter of lead weight, block 9 lead preselection selectors, subtractor 10, limit value setter 11 45, third comparator 12, shunt unit 13, transfer weight setter 14, feeder speed selection unit 15, feeder control unit 16.

To the inputs of the two-speed feeder 1 are connected the codes of the feeder speed selection unit 15 and the feeder control unit 16. Output mass meter 2 is connected to the first inputs of the first 3 and second 4 comparators and to the input of the analyzer 5. material flow. A subtractor output is connected to the second input of the first comparator 3

13686502

10, and the output of the first comparator 3 is connected to the input of the control unit 16 of the feeder.

The outputs of the dials 7 and 8 are connected to the first and second inputs of the unit 9 for the selection of the lead presetter, to the third input of which the first output of the control unit 13 is connected. The output of the setpoint selector unit 9 is connected to the input of the Subtracable subtractor 10, the Reduced input of which is connected to the output of the unit 6 of the portion.

The transition mass setting device 14 is connected to the second headhole of the second comparator 4, the output of which is connected to one of the inputs of the control unit 13, to the other input of which the output of the third comparator 12 is connected.

The output of the analyzer 5 thread is connected to the first input of the third comparator 12, to the second input of which is connected the setting device 11.

The second output of the control unit 13 is connected to the power supply speed selector 15.

The analyzer 5 of the flow of material must, within the time of hinge, given by the mass of the transition M, give a quantitative characteristic of the irregularity of the sweat of the material entering the ladle. Such an analyzer can be implemented in various ways and devices. For example, a quantitative characteristic of flow irregularity can be obtained using a device whose block diagram is shown in FIG. 2. The latter includes a scaling unit 17, a smoother 18, a subtractor 19, a quad 20 and an integrator 21.

The analyzer 5 operates as follows.

The mass analyzer 2 receives the analyzer signal m (t), which is a monotonically increasing signal modulated by a random component caused by a random, in general, material flow entering the mass measuring device.

Skipping the scaled signal m (t) through smoother 18 get gg averaging monotonously increasing signal m (t), subtracting in subtractor 19 from the signal m (t) signal m (t), get a random process (t), which, being skipped through the quad 20,

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gives a process (t) containing a component of only one polarity. Process 6 (t), when fed to the integrator 21, produces at the integrator output an increasing signal, the average growth rate of which and thus the final integrator output depends only on the unevenness of the material flow entering the bucket.

Setting a specific value for the transition mass, M ,, determines the value of the integration limit. A massaging unit 17 is used to coordinate the analyzer with other units of the proposed discrete dosing device.

The logical part of the device provides the following modes.

If m (t) Mn, then the hitch is carried out at a high feed rate, and the feedthrough is fed from the coarse unit.

If at time m (t) eM, d. (M) In, blocks 9 and 15 should remain in the initial states that ensure the end of the hinge at a high material feed rate and feed in advance from the coarse sensor 7.

If at time m (t) is 5-M, a (M),

 Fri

BUT, even before the end of the sample, the sign changes, i.e. becomes C1 (Mn) B, then the work should be the same as in the first case.

When reaching m (t) 2 (when giving a lead from a coarse setting device) or m (t) 5Mg-Mp (when giving an information at the moment mCt) 5: M, and (M) B, - the setting from the exact setting device) a change in the states of blocks 9 and 15 occurs, which ensures the end of the hinge at a low feed rate of the material and a feed forward from the exact setpoint generator.

The implementation of the logical part of the device can be performed on various elements. An example of implementation using relay-contact elements is shown in Fig. 3, where the electrical circuit diagram is shown. Here, the setpoint selector unit 9, the control unit 13, the unit are deployed.

15 choice of speed feeder and unit

16 seeder.

B GFG circuit. The following elements are included: change-over contact 22, sources 23 and 24 signals of different levels, change-over contact 25, amplifier 26, relay 27, double contact 28, except that To enter, belonging to the control unit 13, contacts 29 -34, relay 35, time relay 36, and relay 37 and 38. In the indicated second, contact 39 of the first comparator 3 tracks, which triggers the relay 27 and its contacts 28 to open the feeder 1.

40 The device operates as follows.

At the outputs of the setters 6-8, 14 and 11, the predetermined values of M, M, M, M, B are set. In addition to

45 in addition, the units for selecting the setting device 9 and selecting the speed of the power supply 15 are in the states in which the feeder operates at high speed, and a coarse setpoint 7 of the advance mass is connected to the subtractor 10.

From the beginning of the load (weight gain), feeder 1 is switched on at a high feed rate. The material enters the mass measurement gauge 2, which leads

gg to increase its output signal m (t). The output signal of the mass meter is fed to the inputs of the first 3 and second 4 comparators and the analyzer 5 of the material flow.

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In the fourth and fourth modes, the logical part of the device operates as follows.

In the second and third modes, when closing the contact 29 of the second rator 4, the contact 30 is open (Q (Mr,)). At the same time, a time relay 36 having a small delay (approximately 0.5 s) triggers, and its normally closed contacts 31 and 33 open, which ensures locking in the initial states of relays 35, 37 and 38, i.e. blocks 9 and 15 also remain in their initial states. If in the course of further weighting, the signal at the analyzer output (M,) exceeds the limit value B (the second mode), i.e. if contact 30 of the third comparator 12 is closed, this does not affect the change of state of the other circuit elements.

In the fourth mode, when closing the contact 29 of the second comparator 4, the contact 30 of the third comparator 12 is already closed. In this case, the relay 35 trips, which, by its normally closed contact 32, breaks the power supply circuit of the time relay 36 and, by contact 34, switches on the relays 37 and 38, which causes the switching of the states of blocks 9 and 15.

When m (t) 2 is reached (when forwarding from a coarse setting device) or m (t) 5Mg-Mp (when supplying control from an accurate setting device) is reached from the exact setting device, contact 39 of the first comparator 3 closes, which causes the relay 27 to operate and its contacts 28, disconnecting the feeder 1.

The device works as follows.

At the outputs of the setters 6-8, 14 and 11, the predetermined values of M, M, M, M, B are set. In addition to

In addition, the unit selector unit 9 and the power supply speed selector 15 are in the states in which the feeder operates at high speed, and a coarse output control unit 7 is connected to the subtractor 10.

From the beginning of the load (weight gain), feeder 1 is switched on at a high feed rate. The material enters the mass measurement gauge 2, which leads

to an increase in its output signal m (t). The output signal of the mass meter is fed to the inputs of the first 3 and second 4 comparators and the analyzer 5 of the material flow.

The supply of material at high speed continues until the mass mass 2 in the bucket mass m (t) 5-M ", at the moment m (t) M" at the output of the analyzer 5 there is a signal; x (M,), which is compared in the third comparator 12 with a signal B, which sets the limit value 11.

 IF a (Mn) in, i.e. The flow rate of the supplied material during this hinge cycle is fairly uniform, then the control unit 13 gives a command that blocks the selector unit 9 and select the speed of the feeder 15 in the same state.

In this case, the dosing of the material ends at a high feed rate at the time t (s), when the feeder control unit 16 turns off the feeder 1,

If a (M p) B, i.e. the uneven flow rate of the supplied material exceeds the allowable limit B, then the control unit 13 gives a command to change the state (switch) of the unit selector unit 9 and select the speed of the feeder 15. At the same time, dosing continues at a low material feed rate and ends at time m (t) r (), when the feeder control unit 16 shuts down the feeder 1, and the corresponding circuit elements return to their original state.

 the invention

one . The method of discrete weight dosing of bulk materials, which consists in the recruitment of the main part of a given portion with a large consumption of material and the transition, when recruiting it, to the filling of the material, so that, in order to improve the accuracy, during the set of the main part of the portion, the integral characteristic of the material consumption uniformity is determined, and after dialing this part of the portion, the value of the integral characteristic of the uniformity is compared with its limit set value and, if this value is exceeded, have carried out at a small material consumption, and in case of failure or equal to the limit specified value t dosypki derivatives with the same consumption of material, and that at a set main body portion.

2. The POP.1 method, which is also distinguished by the fact that the mass of the main portion of the portion is set to be not less than the value of the maximum ejection of the output signal of the mass measuring device, possible when the material is fed.

3. A discrete weight dosing device for bulk materials, containing a two-speed feeder, the inputs of which are connected to the outputs of the speed selector unit and the control unit of the feeder, the mass measuring device, the output of which is connected to the first inputs of the first and second comparators, the setting unit of the portion connected to the input Reduced subtractor, output

which is connected to the second input of the first comparator, the output of which is connected to the input of the control unit of the feeder, the mass setting device for switching to the dosshka mode, the output of which is connected to the second input of the second comparator, and the setting mass of the forward signal, in order to improve the accuracy, it includes a material flow analyzer, a limit value setting device, a third comparator, a control unit, a pre-mass master preselection unit and an additional pre-mass master unit, with the pre-mass preassignors The first and second inputs of the advance selector selector unit, to the third input of which the first output of the control unit is connected, and to the output - input of the Subtracted subtractor, the input of the analyzer of the material flow are connected to the output of the mass meter, and the output to the first input of the third comparator, to the second input where the limit value setpoint control device is connected, the outputs of the second and third comparators are connected to the inputs of the control unit, the second output of which is connected to the input of the speed selector unit of the feeder.

Claims (3)

Claim 1 . The method of discrete weight dosing of bulk materials, which consists in the collection of the main part of a given portion at a high consumption of material and the transition when it is recruited to fill up the material, which requires that, in order to increase accuracy, during the collection of the main part of the portion determine the integral characteristic of the uniformity of material flow, and after collecting this portion of the portion, compare the value of the integral characteristic of uniformity with its limit set value and, if this value is exceeded, the filling is carried out they are achieved at a low consumption of material, and in case of failure to achieve or equal to the limit set value, the filling is carried out with the same material consumption as in the collection of the main part of the portion. 2. The method according to claim 1, characterized in that the mass of the main portion of the portion is set not less than the value of the maximum ejection of the output signal of the mass meter, possible when feeding the material. 3. A device for discrete weight dosing of bulk materials, containing a two-speed feeder, the inputs of which are connected to the outputs of the speed selection unit and the control unit of the feeder, a mass meter, the output of which is connected to the first inputs of the first and second comparators, a portion controller connected to the input of the Reducing subtractor, the output of which connected to the second input of the first comparator, the output of which is connected to the input of the control unit of the feeder, the mass regulator of the transition to the filling mode, the output of which is connected to the second the input of the second comparator, and the lead mass controller, characterized in that., in order to improve accuracy, it includes a material flow analyzer, limit value adjuster, a third comparator, a control unit, a lead mass selector selection block and an additional lead mass adjuster, moreover, the lead-in mass detectors are connected to the first and second inputs of the lead-in selector selection block, to the third input of which the first output of the control unit is connected, and the output is the input of the Subtracted subtractor, the input of the sweat analyzer Single material massoizmeritelya connected to the output, and the output - to the first input of the third comparator, to the second input of which is connected setpoint limiting value, the outputs of the second and third comparators are connected to inputs of the control unit, the second output of which is connected to the input feeder speed selection unit. FIG. 2 'Fig. 3