RU2625042C1 - Conveyor scales of forward and reverse travel - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: device contains a weight roller support, two mounting units of weight sensors, wherein both mounting units are connected in a counter-way to each other and are attached to the conveyor belt from above. Both weight sensors and a belt displacement sensor are connected to the information processing unit. The information processing unit (IPU) receives a signal from two weight sensors and a displacement sensor and converts the conveyor capacity, the total flow of the transferred material, the density of the material on the belt, and the speed of the belt movement into the digital output. The information from the IPU is transferred to the operator's console (OC) and the personal computer, remote from the conveyor.

EFFECT: simplified design, increased accuracy, reliability of measurements, reduction of structure metal content to a minimum.

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Description

The invention relates to a weighing technique and can be used for weighing bulk materials on belt conveyors of direct and reverse motion in various industries and energy when accounting or dosage.

The prior art various designs of conveyor scales, which are used for weighing bulk materials located on conveyor belts. Known conveyor scales of the type of VNK CJSC "Tenzo-M Weighting Company" (Kraskovo, Moscow Region), in which weight roller bearings transfer the load to one or two weight sensors with end fastening of the T70, T100 type, middle and side rollers are located above the sensors weight. The disadvantage is the low accuracy of weighing when the load deviates from the value at which the balance was calibrated due to the additional moment loads arising from this, created by the horizontal components of the total load on the roller support (resistance forces to the movement of the belt, dynamic loads, etc.). The disadvantage of the scale is that you want to use many console weight sensors, at least two rollers. Also, scales are difficult to install on a conveyor belt.

Known conveyor scales (patent RU 2193759), containing two articulated suspended two-arm weight platforms with grooved weight rollers, located on opposite sides of the stationary roller bearings and installed opposite to the location of the weight rollers relative to the hinges, the outer shoulders of the platforms are supported by weight sensors and equipped with counterweights for balancing " containers ", and the inner shoulders - prisms for the suspension of exemplary loads. Such a kinematic scheme minimizes the influence on the accuracy of the horizontal components of the load (resistance to the movement of the belt, material dynamics, etc.), asymmetric deformation of the belt on inclined conveyors and provides the possibility of using an indirect method of verification by alternately loading the platforms with standard weights when the conveyor is working under load. The disadvantages of the scale is that you want to use many console weight sensors, at least two rollers. Also, scales are difficult to install on a conveyor belt.

Known conveyor scales (RU 2289797), which contain weight sensors, two grooved roller bearings located on opposite sides of one stationary roller bearing, each weight roller bearing is supported on the free ends of two cantilever weight sensors, and the weight roller bearings being installed opposite each other relative to the pinched ends of the weight sensors, the axes of the middle rollers of the weight rollers are located below the axes of the weight sensors, with an angle of inclination of the side rollers of 20 ° at a distance of h = 0.15S or with an angle of inclination of the side rollers of 30 ° at a distance of h = 0.157 S, where S is the height of the gutter tape, which uses at least four cantilever weight sensors and at least two rollers. The disadvantages of this invention is that you want to use many console weight sensors, at least two rollers. It is also difficult to install the scales on a conveyor belt, it is even more difficult to calibrate these conveyor scales in an indirect way by alternately loading the weight roller bearings with standard weights when the conveyor is operating under load.

The closest analogue is the conveyor scales according to patent RU 129225, which have one weight roller support based on two cantilever weight sensors installed in two modules of the mounting units, both weight sensors connected to a terminal box mounted on a conveyor stand connected to the weight controller, whose function is to receive a signal from weight sensors and convert to a digital result.

The disadvantages of this device are that the weight roller support is not protected from side impacts of the transported cargo, which reduces the accuracy and reliability of the scales, as well as the complexity of installation on the conveyor, while the sensor mounting units are installed so that there is no possibility of a reverse stroke.

The technical result of the claimed conveyor scales of conveyors direct and reverse stroke is to simplify the design, improve the accuracy and reliability of measurements; reversing capabilities; reducing the metal consumption of the structure to a minimum, i.e. only the manufacture of two sensor mounting units; simplification of installation and setup time due to the exclusion of linkage platforms, zoom lever and counterweights; the ability to calibrate and verify the balance without the use of suspended material, if the company does not have a carriage or automobile scale of the middle class, using a calibration device for conveyor scales (VHF).

Improving accuracy is achieved by:

- the ability to take into account the flow of material across the entire width of the belt due to the location of two weight sensors located on both sides of the conveyor;

- compensation of the influence of the horizontal components of the load due to the oncoming installation of two nodes of the sensors;

- summing not of an analog, but of a digital signal from weight sensors.

Improving reliability is achieved due to the maximum simplification of the design.

Reduction of metal consumption compared to the previous design, depending on the width of the conveyor belt (500-1000 mm) 3-10 times.

A conveyor scale is disclosed comprising a weight roller support, two weight sensor mounting nodes connected to a weight controller, characterized in that platform weight sensors are integrated in the weight sensor mounting nodes, the weight sensor mounting nodes are installed opposite each other, and an analog signal from each weight sensor arrives at the weight controller of the information processing unit separately and is summarized in digital form, while the device is configured to linearize the scale and calibrate without weighted material using the power of a conveyor belt calibration device.

In FIG. 1 shows the device of the inventive conveyor scales (side view), where:

1 - weight roller support; 2 - node embed sensors; 3 - becoming a conveyor; 4 - platform weight sensors; 5 - conveyor belt.

In FIG. 2 shows the device of the inventive conveyor scales (top view), where:

6 - tape movement sensor; 7 - lower branch of the conveyor belt: 8 - information processing unit; 9 - operator panel; 10 - block circuit breaker; 11 - a personal computer.

In FIG. 3 shows a top view of a cargo receiving device (GU), where: 1 - weight roller support; 2 - two nodes embed sensors; 3 - becoming a conveyor; 12 - weight zone (section); 13 - measuring section; 14 - fixed weight rollers.

In FIG. 4 shows the installation of a calibration device over the inventive conveyor scales, where 15 is a calibration trolley; 16 - roller (wheel) of the calibration trolley; 17 - calibration weights; 18 - hinge assembly; 19 - chain; 20 - rack; 21 - the upper branch of the conveyor belt; 3 - becoming a conveyor; 14 - fixed weight rollers; 1 - weight roller support; 22 - full-time roller bearings.

The design of the inventive conveyor scales (hereinafter - the scales) allows you to install them on any conveyor belt, regardless of the width of the conveyor belt and use without any alteration only one standard full-time roller support installed on two sensor mounting units. Unlike the closest analogue, the sensor mounting units are connected counter-to each other, have an original design and are attached to the conveyor stand from above. Both weight sensors and the tape displacement sensor are connected to the information processing unit (BOI) without a terminal box, since it is located nearby. The BOI receives a signal from two weight sensors and a displacement sensor and converts the conveyor productivity, the total consumption of the transported material, the density of the material on the tape, the speed of the tape into a digital result. Information from the BOI is sent to the operator’s console (software) and personal computer, which are located up to 1000 m from the conveyor.

In the inventive device of the conveyor scales, the weight roller support 1 is mounted on two sensor mounting units 2, which, in turn, are attached to the conveyor 3 using two bolted connections. Platform weight sensors 4 and the belt movement sensor 6 are connected to the information processing unit (BOI) 8, which is installed within 10 meters from the nodes of the sensors 2. The sensor for moving the tape 6 is installed on the lower branch of the tape 7. The operator panel 9 and the personal computer 11 can be removed up to 1000 meters. Power BOI 8 is carried out from the unit of the circuit breaker 10. The inventive device of the conveyor scales with the opposite inclusion of the nodes of the sensors 2 allows you to use them in the reverse movement of the conveyor belt 5.

The nodes of the sensors 2 are mounted on the conveyor 3, after which the weight of the roller support 1 is installed on the nodes of the sensors 2. In FIG. 3. The counter inclusion of the sensors 2 mounting nodes is shown, which allows to compensate for errors arising from the horizontal component of the shock effects of the transported cargo.

The weight zone (section) 12 has a length of 2000 mm, and the measuring section 13 is a length of 1000 mm (Fig. 3). The weight zone (section) 12 is the distance between two stationary weight rollers 14, equal to 2000 mm, which is necessary for calibration using a device for calibrating conveyor scales (UKKV) [RU 2284483]. The measuring section 13 is half the weight zone (section) 12 and is equal to the sum of half the distance between the fixed weight roller support 14 on the left and the weight roller 1 and half the distance between the fixed weight roller 14 on the right and the weight roller 1.

Using the string (tape) set the height of the Central and side rollers on the weight (movable and stationary) roller bearings and two full-time roller bearings, limiting the weight section 12 (Fig. 4). The rollers on these weight and standard roller bearings, limiting the weight section, should have a radial runout in the range of 0.5-1 mm.

The design of the load-bearing device of the GU conveyor scales in the form of one weight roller support 1 and two sensor mounting units 2 is a necessary but not sufficient condition for the operation of the device. It is necessary to have a good calibration device, which is used as a calibration device for conveyor scales (VHF) [RU 2284483]. The known calibration device allows for 4-5 points of the scale (20, 40, 60, 80, 100%) to linearize the scale of the scales, i.e. it is possible to set 5 values of the linear density of the material on the belt and adjust the readings of the conveyor weights, achieving a minimum error, and then calibrate the conveyor weights at the minimum, average and maximum linear density (kg / m) based on the maximum performance of a particular conveyor.

The installation of the calibration device over the conveyor scales for calibrating the conveyor scales using VHF is shown in FIG. 4. The weight roller support 1 and two stationary weight roller supports 14 limit the weight zone (section) 12 and the measuring section 13. The calibration device has calibration trolleys 15, which are supported by rollers (wheels) 16 mounted symmetrically to the longitudinal axis of the conveyor, arranged by a chain. The calibration trolleys 15 are interconnected by means of hinge assemblies 18. The calibration trolleys 15 are loaded with calibration weights 17. The necessary linear densities q are calculated by the formula:

where: m ₅ , m ₆ , m ₇ - weight of calibration trolleys with a mass of calibration cargo of class M1 (M2) according to GOST 73328-2001 with values of 1, 2, 5, 10, 20 kg; l ₁ , l ₂ - the distance between the fixed weight roller support 14, weight roller support 1. After installing the calibration device (VHF) on the conveyor belt above the calibration chain of the trolleys is fixed in tension using chain 19 between the racks 20 mounted on the conveyor 3 on both sides of the conveyor belt 21.

Each calibration trolley can set at least five values of linear q densities, kg / m.

The proposed conveyor scales provide the following.

1. Improving accuracy due to

- the ability to take into account the flow of material across the entire width of the belt due to the location of two weight sensors on both sides of the conveyor;

- compensation of the influence of the horizontal components of the load in the oncoming installation of two nodes of the sensors;

- summing not of an analog, but of a digital signal from weight sensors.

2. Increased reliability due to the maximum simplification of the design.

3. Reduced metal consumption compared to the previous design, depending on the width of the tape (500-2000 mm) 3-10 times.

4. Simplified installation and reduced setup time by eliminating linkage platforms, zoom lever, and counterweights.

5. The ability to calibrate and verify the balance without using suspended material, if the company does not have a carriage or automobile scale of the middle class, using a calibration device for conveyor scales (UKKV).

In the claimed technical solution, it was possible to avoid a disadvantage due to the use of the design of the nodes for mounting the platform-type sensors and, which is especially important, due to the counter-inclusion of the weight sensor. In the claimed design, the same sensor assembly unit module is used for the entire line of conveyors with belt widths from 400 mm to 2000 mm, using one type of platform sensors. The choice of a platform weight sensor is made according to the value of the rated load.

The maximum static load E _{max is} calculated by the formula:

Where:

R _l - the weight of one linear meter of conveyor belt, kg;

P _roll - weight of roller support, kg;

q _100% - maximum linear density of materials, kg / m;

L is the length of the measuring section, m;

n is the number of sensors on which the roller support rests, m.

Claims (1)

Conveyor scales containing a weight roller support, two weight sensor attachment nodes connected to the weight controller, characterized in that platform weight sensors are built into the load sensor attachment nodes mounted opposite each other, include an information processing unit, and the device is linearized scales and calibrations without suspended material using a conveyor belt calibration device.

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