RU2763123C1 - System providing testing and verification of a weight measurement apparatus, method for testing and verification of a weight measurement apparatus - Google Patents

Abstract

FIELD: testing.

SUBSTANCE: invention relates to the field of weight measuring equipment and can be used for testing and verification (calibration) of conveyor scales. The system includes a container for placing the material, equipped with tools for dosed supply and tools for measuring the weight of the contents, at least one transportation tool containing a closed belt with weight measuring tools installed thereon. The system is therein configured to provide multiple cyclic circulation of the material supplied from the container for placing the material to the transportation tools, and is equipped with measuring tools, including tools for determining the speed of movement of the closed belt, transportation tools, calculation and control tools configured to convert the digital signals received from the weight measuring tools to the physical units of mass and/or weight, as well as ensure operation of the system.

EFFECT: possibility of conducting verification of the conveyor scales with a preset accuracy at high speed, providing a possibility of working on most types of measuring equipment, as well as transmitting a unit of mass with high accuracy in a short period of work.

12 cl, 1 dwg

Description

The proposed group of inventions relates to the field of weighing technology. The proposed technical solutions are intended to ensure testing and verification (calibration) of conveyor scales, as well as for reproduction and transmission of linear density units.

From the technical field, solutions are known for verifying, in particular, conveyor scales, for example, a method and device according to the USSR inventor's certificate for invention No. 1654672 "Method for dynamic calibration and verification of conveyor scales and a device for its implementation" (IPC G01G 11/00, NPO SNIIM, USSR, z. No. 4402428, 04.04.1988, publ. 07.06.1991). According to the description of the technical solution, the invention relates to measuring technology and can be used for dynamic calibration and verification of continuous weighing devices. The load-receiving section of the weighing device is loaded with a variable verification load, and the signal of the weighing device is fed to the input of the first adder, the output of which is connected to the summing input of the second adder directly, and to the subtractive input through a delay element, the output of the second adder is connected through the forming unit and the functional conversion unit to the second input of the first adder, the device registers the transient response of the weighing device.

The disadvantages of this solution include the lack of a description of the technical solution of the process of calibration and verification of continuous weighing devices. Lack of taking into account the speed of the conveyor belt in the calculations. Lack of description of specific operations required for verification and calibration.

Some disadvantages of the previous technical solution are overcome by the technical solution under the US patent for invention No. 3899915 "Conveyor scale calibration" (IPC G01G11 / 006; Reliance Electric Co, USA, z. No. 41365773, 07.11.1973, publ. 19.08.1975). , intended for use in conjunction with a conveyor, consisting, in the aggregate, of means for generating an electrical speed signal corresponding to the speed of the conveyor belt, means for generating an electrical weight signal corresponding to the weight of the material in the weighing section, means for multiplying said signals of speed and weight to generate an electrical signal , which serves as a measure of the conveyor performance and means for calibrating said measuring device, including means for applying to said means for multiplying a weight signal corresponding to a given weight, means for generating an electrical signal to simulate said speed signal at a given p constant conveyor speed, switching means for selectively applying said simulated speed signal to said multiplier instead of said conveyor speed signal, whereby said load speed signal is generated in response to said simulated speed signal and said predetermined weight signal, and means for adjusting said a measuring device for eliminating any deviation of said signal of the speed of movement of the load from the true signal of the speed of movement of the load for such a predetermined constant speed of the conveyor and a predetermined weight in the weighing section.

At the same time, the specified technical solution is not without drawbacks, in particular, there is no description of the operations performed for verification and calibration.

Thus, the systems and methods disclosed in the prior art do not provide a solution to a number of technical problems, in particular, a technical problem to be solved by a group of technical solutions is the creation of a system and a method that provides verification and calibration of weight measuring instruments with a given accuracy at high speed, providing the ability to carry out work on most measuring instruments, as well as the transfer of a unit of mass with high accuracy in a short time of work.

Technical problems are solved as follows. The present group of inventions proposes, firstly, a system that provides testing and verification of a weight measuring device, including a container for placing material, equipped with means for dispensing and means for measuring the weight of the contents, at least one means of transportation containing a closed belt, with installed on it by means of measuring weight. The system is configured to provide cyclic circulation of the material coming from the container for placing the material on the means for transportation and is equipped with measuring means, including means for determining the speed of movement of the closed belt of the transportation means, means of calculation and control, made with the possibility of converting digital signals received from the means of measurement weights in physical units of mass and / or weight, as well as ensuring the operation of the system.

In the first particular case, the system is additionally characterized in that the system contains means that reproduce the set value of the linear density, made with the possibility of installation on the means for transportation in the area of the location of the weight measuring means.

In the second particular system, the system is additionally characterized in that the means for dispensing material are made in the form of a metering flap, which allows the material contained in the container for accommodating the material to be supplied to the means for transportation.

In the third particular case, the system is characterized in that it contains three means for transporting, mutually placed in such a way that the material coming from the container for storing the material, after passing through the means for transporting, goes back to the container for storing the material.

In the fourth particular case, the system differs in that the calculation means are made with the possibility of receiving and processing readings from the weight measuring means with which the container for placing the material is equipped, the weight measuring means installed on the transportation means and the means for determining the speed of the closed belt.

The container for accommodating the material makes it possible to place, for example, a free-flowing body inside a reservoir, while determining its weight with a sufficient degree of reliability by means of measuring the weight of the contents with which the specified reservoir is equipped. The means for transportation makes it possible to create conditions for the movement of the material contained in the container, and allows weighing the material coming from the container by means of weight measuring installed on the means for transportation. Essentially, the means for transportation provides a cyclic circulation of the material coming from the container, allowing a certain amount of material to be repeatedly passed through the means for measuring installed on the means for transportation within a certain period of time. A known and constant amount of material in the system reduces the amount of measurement error, allowing for more accurate instrument readings. The means of transportation also ensure the reloading of the incoming material back into the container for its storage. The speed of movement of the closed belt of the means for transportation is determined by means of measuring the speed and allows it to be controlled, providing a uniform movement of the tape at a set speed, allowing per unit time to ensure the passage of a certain amount of material, essentially over the means for measuring weight installed on the means for transportation. The means of calculation and control make it possible to convert, according to a predetermined mathematical algorithm, digital signals received by them from the means of measuring weight into physical units of mass and / or weight.

Supplementing the system with means that reproduce the specified linear density value allows them to transfer reference linear density values to other weighing devices, which makes it possible to verify / calibrate the latter.

The supply of a part of the container, namely the means for dispensing material with a metering gate, makes it possible to ensure that a substantially equal amount of material is supplied to the means for transporting at regular intervals. This allows you to increase the readings from the measuring instruments with higher accuracy, creating an even flow of material from the container.

The cyclic circulation of the material coming from the container back to the container allows reading the measuring instruments multiple times over a set period of time.

The supply of the system with means of calculations that collect the incoming readings from the means of computing, which are or are equipped with the components of the system, allows converting and comparing the readings obtained to calculate, in particular, the conversion factors, errors of weight measuring instruments.

The claimed group of inventions is, secondly, a method for testing and verifying a device for measuring weight, consisting of determining the conversion factor of a digital signal received from a weighing device into physical units, through a metered supply of material from a container for placing material on a transportation means, obtaining readings from the means for measuring the weight of the contents of the container for placing the material, means for measuring weight installed on the means of transportation and means for determining the speed of movement of the closed belt, with the assignment of the error calculated using the readings to the means for measuring weight installed on the means for transportation. Consisting of calculating the average linear density of the means for reproducing the set linear density value by placing the means for reproducing the linear density value substantially over the means for measuring weight mounted on the transport means, obtaining readings from the weight measuring means installed on the means of transport and means determining the speed of the closed belt, calculating the average linear density of the means reproducing the set linear density value using the obtained readings and the calculated error of the weight measuring instruments installed on the transportation means. Consisting of calculating the error of the weight measuring device through the installation of means that reproduces the set linear density value substantially above the weight measuring device, obtaining readings from the weight measuring device and means for determining the speed of movement of the closed belt of another means for transportation, calculating the device error for weight measurements using the readings obtained and the calculated average linear density of the means that reproduces the specified linear density value.

In accordance with the first particular case of the technical solution, the method is additionally characterized in that the readings from the measuring means are recorded at fixed time intervals within a certain time interval.

According to the second special case, the method is additionally characterized in that the speed of movement of the closed belt of the transportation means is substantially equal to the speed of movement of the closed belt of the other means for transportation.

In clarifying the specified special case, the method is additionally characterized in that essentially equal values of the speed of the indicated closed belts of the indicated means for transportation are set using the determination of the speed.

In accordance with the third particular case, the method is additionally characterized in that the algorithm for determining the conversion factor of the digital signal received from the means for measuring weight into physical units comprises determining the value of the mass and / or weight of the material in the container for placing the material using the means for measuring the weight of its contents ; setting in motion means for transportation; obtaining readings from the means for measuring weight installed on the means for transportation; setting the speed of movement of the closed belt of the means for transportation and determining the target value of the linear density of the material supplied to the means for transportation; supplying material from the container for holding the material to the transport means in accordance with the determined target linear density value; obtaining substantially synchronous readings from the means for measuring the weight, installed on the means for transporting, means for measuring the weight of the contents of the container for holding the material; calculation of the coefficient of the digital signal received from the means for measuring weight in physical units using the readings from the measuring instruments.

In specifying the specified special case, the method is additionally characterized in that the receipt of indications from the means for measuring the weight installed on the means for transportation, means for measuring the weight of the contents of the container for placing the material is performed within a certain finite time interval with a set frequency.

In the fourth particular case, the method is additionally characterized in that the material placed in the container for accommodating the material is a free-flowing body.

Determination of the conversion factor of the digital signal from the weighing instruments installed on the means for transportation, including when the means of transportation with material from the bunker or without it in physical units of mass, makes it possible to compare the readings of the weight measuring instruments installed on the material container for the purpose of calculating errors of weight measuring instruments. Accordingly, taking readings from the weight measuring devices installed both on the container for the material, the means for transportation, as well as monitoring the speed of the closed tape, based on the data obtained, calculate the error of the weight measuring means installed on the means for transportation.

The calculation of the average linear density of the means that reproduces the set linear density value makes it possible to transfer, taking into account a certain error of the weight measuring instrument, over which the means that reproduce the specified linear density value are installed, to the indicated means the linear density value for their subsequent use to verify the device for measuring weight. At the same time, it is necessary to control the speed of movement of the closed belt in order to obtain reliable and accurate readings from the means of measuring weight.

When using the means that reproduces the set linear density value on another means for transportation when verifying the device for measuring the weight installed on the other means for transportation. For verification, it is necessary to obtain readings from a device for measuring the weight and speed of movement of a closed belt of another means of transportation. Since the average linear density is known from the previous step, the error of the weight measuring device mounted on the other transport means is calculated.

To obtain the most approximate values of readings from measuring instruments, it is necessary to carry out a series of measurements within a predetermined period of time. The values are recorded by the means of calculation and control, essentially synchronously with a set frequency, for example, once a second. The time interval during which the readings are recorded can be selected in accordance with the admitted reliability of the results and be, for example, from 5 to 15 minutes.

The speeds of movement of the closed belts of the conveying means and other means for conveying are substantially equal, since the readings obtained from the measuring means, in particular the means for measuring weight, depend on the speed of movement of the closed belts. Consequently, by synchronizing the speed of movement of the conveyor belts, relevant results are obtained during subsequent verification. For such synchronization, a speed measuring means is used, which, in connection with the means of calculation and control, sets the speeds of movement of the means of transportation.

Conversion of a digital signal into physical units of mass is carried out by means of a certain algorithm, including determining the value of the mass of the material contained in the container, which makes it possible to obtain an accurate value expressed in physical units, which will subsequently be used in calculating the error of the weighing instrument. The supply of material from the container to the transport means enables the weight measuring means to be switched on and received from it a signal, the value of which is proportional to the amount of material passing along the closed belt, essentially over the weight measuring means. This takes into account a given speed of movement of the closed tape, creating, together with the means for dispensing the material, which is equipped with the container for the material, uniform movement of the tape and ensures the passage of a certain amount of material through the section of the closed tape during a certain time interval. Synchronous reading from measuring instruments allows you to track changes in system parameters in real time for subsequent comparison and calculation with their use, in particular, errors of measuring instruments.

The results obtained are used when calculating the error of the measuring instrument installed on the transportation means.

Measurements, namely readings from measuring instruments, are carried out over a certain time interval, which allows you to take many pairs of readings to calculate the error with a sufficient degree of reliability.

Placing a bulk material in a material container allows a uniform and substantially homogeneous layer of material having a substantially stable linear density to be created on the transport means.

The proposed group of inventions is illustrated by the following figures:

FIG. 1 - general view of the system.

The figure shows the following positions:

1 –transportation device in the form of three belt conveyors;

2 - container for placing material in the form of hopper scales;

3 - dosing hopper gate;

4 - means of calculation and control in the form of a personal computer with specialized software installed on it

5 - weight measuring device installed on the belt conveyor;

6 - means for measuring speed.

To understand the principles of operation and features of various implementations of the invention, the following is a description of the figures of the technical solution. Although the text of the description explains in detail the preferred options for implementing the technical solution, it should be understood that other options for implementing the group of inventions are also possible. Accordingly, there is no need to limit the scope of legal protection of a technical solution exclusively to the presented implementations and lists of subsystems, assemblies and components. The group of inventions can be implemented in other ways. At the same time, when describing the preferred variants of the technical solution, in order to clarify the understanding of the basic principles of the invention by a specialist, it is necessary to clarify the terms used in the description.

It should be noted that the units and parts of the device used in the singular in the description and the formula also represent plural forms, unless the opposite is explicitly stated. For example, referring to a component of a device also means referring to a collection (plurality) of such items.

Also, specific terms are used in describing the preferred embodiments for clarity of understanding. The term is intended to be used in the broadest sense in which it can be interpreted by those skilled in the art and includes all technical equivalents used in the same manner and for the same purpose. So, in particular, the term "weight measuring device" is a measuring device installed on the means for transportation in such a way that when passing through the location of said measuring device a certain amount of material in the form of a free-flowing body or the like, which is verified when implementing the proposed method. The term "container for holding material" is understood, in essence, a vessel having a certain internal volume, which can contain a certain amount of material in the form of a free-flowing body, configured to supply the contents to the means for transportation, as well as receive material from the means of transportation after passing by the specified means of transportation. The phrase "means for measuring the weight of the content" refers to the measuring device of the weight of the material contained in its internal volume installed and in direct connection with the container for placing the material. The means can be positioned so that the container rests on the frame through the weight measuring means. The error of these means is a known value. In the case of the present group of inventions, the phrase "transportation means" is understood as means for moving bulk or similar bodies from one point in space to another, provided with a substantially closed belt made with the possibility of moving said belt relative to the stationary parts of the means for transportation. In a particular case, the device can be made in the form of a conveyor with a conveyor belt. By "cyclic material circulation" is meant the property of the system, in particular of its components, in which the material coming from the container for holding the material flows back into the said container. Reloading can be carried out using several means of transportation, in particular, a pair of horizontal conveyors and one inclined conveyor. In the case of this technical solution, "measuring instruments" refers to technical means that allow obtaining normalized values of various quantities that can be used to further calculate the required parameters. The term "means of calculation and control" refers to devices and systems designed to coordinate the components of the system and the functioning of the system as a whole. In the general case, these means are understood as computer systems equipped, inter alia, with a man-machine interface, which are made with the ability to receive data from measuring instruments that are part of the system, to perform, inter alia, mathematical operations on the received data and transfer the parameters entered by the operator to the system components in cases where there is a need for such a transfer. In a particular case, these tools can represent a software and hardware complex based on a personal computer. The term "conversion (conversion factor)" in relation to the conversion of a signal from a weighing device into physical quantities, means a certain set of mathematical transformations that make it possible to match and express in physical units a signal of a certain value coming from the measuring instruments installed on the transportation means. The phrase "means that reproduces the set linear density value" means a device that allows simulating a load from a bulk body having a substantially uniform density and configured to be fixed over the section of the transportation means where the weight measuring means are installed.

The words “consisting”, “containing”, “including” mean that at least the specified component, element, part or step of the method is present in the composition, object or method, but does not exclude the presence of other components, materials, parts, steps of the method, even if such a component, material, part, method step performs the same function as the specified one.

The materials from which the various elements of the present invention are made, indicated below in the description of examples of a specific embodiment of the device, are typical, but not required for use. The materials indicated in the present examples of execution can be replaced by numerous analogs that perform the same function as the examples of materials given in the description.

Let's turn to the attached figures. Structurally, the reference complex consists of large-node modules, measuring instruments and peripheral equipment. The complex includes the following units and parts.

Transportation means in the form of three belt conveyors (1): two horizontal belt conveyors and one inclined belt conveyor containing: a conveyor belt for moving material, a drive drum that drives the conveyor belt with a pulling force, a tension drum that serves to adjust the belt tension, a mechanism to adjust the belt tension.

The means for measuring weight (5) contain a weighing roller support, necessary to transfer the weight load to the weight sensor, stabilizing and dumping rollers necessary for aligning the belt in the same plane with the weight measuring roller support. Means of measurement can be equipped with auxiliary rollers to prevent sagging of the tape. Also, the specified device contains weight sensors that perceive the weight load, a sensor for the speed of movement of the conveyor belt (6), which can be included both in the composition of the weight measuring instruments, and be presented as a separate device. The device is connected (directly or through the means of commutation) to a personal computer.

A container for placing material (2) with means for measuring the weight of the contents and means for feeding material in the form of a loading hopper, including a hopper for placing a bulk body, an automatic metering gate (3), a control system for loading the hopper and feeding bulk material onto the conveyor belt and forming funnel.

The system additionally contains means that reproduce the set value of linear density in the form of linear density measures intended for the formation of scales on the measuring section, i.e. on the conveyor belt within the area of installation of the weight measuring devices and the adjacent section of stabilization of the flow of the distributed verification mass, simulating the linear density of the payload.

The control means (4) contain frequency inverters that generate the supply voltage for gear motors of a given frequency, manual controls for moving parts of conveyors, strain transducers, interface controllers, operator panels, concentrators and other peripheral equipment necessary for collecting and processing measuring signals and a personal computer with specialized software.

The system works as follows:

The conveyor belt is stretched between the drive and tension drums of the KLS-650Zh.9345N conveyor, the shafts of which are installed in the rolling bearing housings. The rotation of the drive drum is carried out by a gear motor, the shaft of which is connected to the shaft of the drive drum. The drive and take-up drums are barrel-shaped for automatic belt centering.

A forming funnel serves to feed the material to be dosed onto the conveyor belt and form a layer of material of the required width and height on the belt. A transition funnel is located above the forming funnel. The forming funnel is equipped with an automatically opening and closing slide.

The weighing roller support as part of the weight measuring device transfers the load of the material transported on the belt to the weight sensor. For the correct operation of the weighing roller supports, stabilizing and dumping rollers are used, which are located respectively in front of and after the weighing roller and form the so-called "weighing section". To minimize the effect of belt tension on the accuracy of measuring the weight load, all three rollers, stabilizing, dumping and weighing, should be located in the same plane. After passing the main conveyor, the material is reloaded back to the bunker using overloading conveyors: horizontal and inclined.

Adjustment of the belt speed, direction of movement, start / stop acceleration and attenuation, and other parameters of the conveyor operation is regulated by a block of frequency converters, which are connected to the control PC via an Ethernet interface.

The signals from the weight sensors of the conveyor scales go to the controller, which processes them and sends them to the control PC.

The signals from the weighing cells of the hopper scales are digitized by strain gauges and are continuously sent to the data collection unit, which is connected to the control PC.

The work of the reference complex can be described as follows: the material to be dosed is fed to the belt conveyor (1) of the reference complex through the forming funnel (3), which also forms the height and width of the material layer on the belt. The quality of the accuracy of the transfer of the unit of mass depends on the uniformity of the material layer, the more constant the height and width of the material layer, the higher the accuracy of the transfer of the unit. As the belt moves, the material passes over the weighing roller and creates a load on the weight sensor (5), which generates an electrical signal proportional to the weight load. Also, when the belt is moving, the speed sensor (6) generates a pulse signal with a frequency proportional to the speed of the belt. The signals from the weight and speed sensors, through the intermediate terminal box, go to the control unit's measuring transducer (4). In the converter, these signals are converted into digital normalized values of linear load kg / m and belt speed m / s. The obtained values of load and speed are mathematically multiplied, and as a result, the value of the current productivity of the reference complex is obtained, kg / s (t / h).

The reference complex can be controlled either locally, using the control unit buttons, or remotely, via the Ethernet interface and specialized software.

The verification of the device for measuring weight is carried out as follows. A test load in the form of a free-flowing body of a known weight is loaded into a bunker equipped with scales with an already known weighing error, three belt conveyors are launched: two horizontal, mutually located at a substantially right angle and one inclined, loading the material back into bunker. The readings of the signal of the measuring instruments are taken on the unloaded conveyor belt, the target linear density in kg / m and the speed of the calibrated (verified) device for weight measurement are set. Means for metering the material, which is equipped with the hopper, for example, in the form of a hopper valve, create a material flow, which in linear density kg / m is close to the target linear density. The speed of the conveyor belt of the conveyor, on which the means for measuring the weight are installed, is set according to the known target speed. The magnitude of the speed depends on the speed of the means of transportation, on which the device under test for measuring weight is installed.

Synchronous readings are taken every second from conveyor (weight measuring devices installed on a transport vehicle) and hopper scales and a speed sensor and a conversion factor for the conveyor scales in grams is calculated, and the error of the conveyor scales themselves is assigned, since the mass in the bunker is known exactly. The measurement cycle is carried out for 10-15 minutes, resulting in 600-800 measurement points.

Further, a measure of linear density is placed above the conveyor scales, which is fixed in such a way that when the belt moves, the linear density measure does not move in relation to the means for measuring the weight. After that, the conveyor is started, on which the specified linear density measure is installed with the target speed, and readings are taken from the weight measuring instruments and the speed sensor for 10-15 minutes with an interval of one second. Converting the readings of the conveyor scales into physical units of mass, taking into account the above-defined error of the indicated measuring instrument, and taking into account the time, mass and speed, the average linear density of the linear density measure in kg / m is determined according to known algorithms.

Next, the above-mentioned linear density measure is installed above the weight measuring device installed on the other transportation means in a known manner, and the speed sensor is installed. Another means of transportation (conveyor) is launched for a period of 10 to 15 minutes, with a target speed, readings of speed, average load of the weight measuring device in kg / m are taken, it is compared with the readings obtained at the previous stage when calculating the average linear density of the measure linear density and calculate the error / uncertainty of the device for measuring the weight.

The embodiments of the present invention are not limited to the above specific examples. Other forms of implementation of the technical solution can be proposed without departing from the meaning of the invention.

The above examples of execution are given in order to show the industrial applicability of the device and to give a general impression of the possibilities of the system and method. The scope of legal protection of a technical solution is determined by the claims, and not by the description presented, and all changes made using equivalent features fall under the legal protection of the present invention.

Claims (22)

1. A system that provides testing and verification of a weight measuring device, including a container for placing a material, equipped with means for dispensing and measuring the weight of the contents, at least one means of transportation, containing a closed tape, with weight measuring devices installed on it, and the system is configured to provide multiple cyclic circulation of the material coming from the container for placing the material on the means for transportation, and is equipped with measuring means, including means for determining the speed of the closed belt, transportation means, calculation and control means, made with the possibility of converting digital signals received from means of measuring weight, into physical units of mass and / or weight, as well as ensuring the operation of the system. 2. The system according to claim 1, further characterized in that the system contains means that reproduce the set value of the linear density, made with the possibility of installation on the means for transportation in the area of the location of the means for measuring the weight. 3. The system of claim. 1, further characterized in that the means for dispensing material are made in the form of a metering flap, which allows the material contained in the container for placing the material to be fed to the means for transportation. 4. The system of claim. 1, further characterized in that it contains three means for transportation, mutually placed in such a way that the material coming from the container for holding the material, after passing through the means for transportation, goes back to the container for holding the material. 5. The system according to claim 1, additionally characterized in that the means of calculation are made with the possibility of receiving and processing readings from the means for measuring the weight, which is equipped with the container for placing the material, means for measuring the weight installed on the means for transportation, and means for determining the speed of movement of the closed ribbons. 6. Method of testing and verification of a device for measuring weight, consisting of the following operations: determination of the conversion factor of the digital signal received from the weighing means into physical units through the dosed supply of material from the container for placing the material on the transportation means, obtaining readings from the means for measuring the weight of the contents of the container for placing the material, weight measuring means installed on the transportation means, and means for determining the speed of movement of the closed belt, assigning the calculated using the readings of the error to the means for measuring the weight, installed on the means for transportation; calculating the average linear density of the means for reproducing the set linear density value by installing the means for reproducing the linear density value substantially over the means for measuring weight installed on the transport means, obtaining readings from the weight measuring means installed on the transport means and means for determining the speed of the closed belt, calculating the average linear density of the means that reproduces the set linear density value, using the readings obtained and the calculated error of the weight measuring means installed on the transportation means; calculating the error of the weight measuring device by installing means that reproduce the set linear density value substantially above the weight measuring device, obtaining readings from the weight measuring device and means for determining the speed of movement of a closed belt of another means for transportation, calculating the error of the weight measuring device using the readings obtained and the calculated average linear density of the means that reproduces the specified linear density value. 7. The method according to claim 6, further characterized in that the readings from the measuring means are recorded at fixed time intervals within a certain time interval. 8. The method according to claim 6, further characterized in that the speed of movement of the closed belt of the transport means is substantially equal to the speed of movement of the closed belt of the other means for transportation. 9. The method according to claim 8, further characterized in that substantially equal values of the speed of said closed belts of said means for transportation are set using the speed determination. 10. The method according to claim 6, further characterized in that the algorithm for determining the conversion factor of the digital signal received from the means for measuring weight into physical units comprises the following actions: determining the value of the mass and / or weight of the material in the container for placing the material using means for measuring the weight of its contents; setting in motion means for transportation; obtaining readings from the means for measuring weight installed on the means for transportation; setting the speed of movement of the closed belt of the means for transportation and determining the target value of the linear density of the material supplied to the means for transportation; supplying the material from the container for placing the material on the means for transportation in accordance with the determined target value of the linear density; receiving substantially time-synchronous readings from the means for measuring weight installed on the means for transporting means for measuring the weight of the contents of the container for placing the material; calculating the conversion of the coefficient of the digital signal received from the means for measuring weight into physical units using the readings from the measuring instruments. 11. The method according to claim 10, further characterized in that the acquisition of readings from the means for measuring weight installed on the means for transportation, means for measuring the weight of the contents of the container for placing the material is performed within a certain finite time interval with a set frequency. 12. The method according to claim 6, further characterized in that the material placed in the container for accommodating the material is a free-flowing body.

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