CN223444495U - Multi-belt linkage coordinated system for alumina raw material ore composition analysis - Google Patents

Abstract

The utility model discloses a multi-belt linkage coordinated system for analyzing the composition of alumina raw material ore, comprising an analyzer and a mobile mechanism, the mobile mechanism comprising a mobile frame, a guide rail, a driving trolley and a control cabinet, the driving trolley comprising a frame, a pulley block I, a pulley block II and a driver, the mobile frame spanning over at least two conveyor belts, the mobile frame being provided with two laterally extending guide rails, the bottom of the frame being provided with a pulley block I and a pulley block II, the pulley block I and the pulley block II being respectively slidably connected to the two guide rails, the analyzer being provided on the frame, the driver being electrically connected to the control cabinet to drive the frame to move or stop. The mobile frame spans over at least two conveyor belts, the mobile frame being provided with a guide rail, the guide rail being slidably connected to the frame, the analyzer being provided on the frame, the driver being electrically connected to the control cabinet to drive the frame and the analyzer thereon to move to a certain belt detection position and then stop, and then the analyzer performs detection.

Description

Multi-belt linkage cooperative system for analyzing ore components of alumina raw materials

Technical Field

The utility model relates to the technical field of sampling detection, in particular to a multi-belt linkage cooperative system for analyzing the ore components of alumina raw materials.

Background

Traditional income grinding sample is mainly through artifical mode sample, and sampling personnel regularly get back to the laboratory and carry out breakage, shrinkage, grinding, analysis after getting a certain amount of sample on the raw materials belt grinding scale, detects, and such sampling mode is wasted time, is laborious and has mechanical injury and inhale the hidden danger of dust. Under such a background, the present technicians design an alumina raw material ore component analysis instrument for online detection, realize communication with DCS through Modbus protocol by utilizing non-radioactive NIR near infrared spectrum analysis technology, realize real-time transmission of detection results to a production control platform, but generally adopt more than two belt conveyors for conveying, and each belt conveyor is provided with one analyzer, which results in higher cost.

Disclosure of utility model

The utility model aims to solve the problems, and provides a multi-belt linkage cooperative system for analyzing the ore components of alumina raw materials, which can switch belt measurement according to A, B belt running conditions to realize real-time detection of the chemical components of ore materials on the belt.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

The multi-belt linkage cooperative system for analyzing the components of the alumina raw material ore comprises an analyzer, a moving mechanism, a driving trolley and a control cabinet, wherein the analyzer is arranged at a detection position above conveyor belts and can analyze the components of the alumina raw material ore on the belts, the driving mechanism comprises a moving frame, guide rails, the driving trolley and the control cabinet, the driving trolley comprises a frame, a pulley block I, a pulley block II and a driver, the moving frame stretches across the upper parts of at least two conveyor belts, two guide rails which transversely extend are arranged on the moving frame, the pulley block I and the pulley block II are arranged at the bottom of the frame, the pulley block I and the pulley block II are respectively and slidably connected to the two guide rails, the analyzer is arranged on the frame, and the driver is electrically connected with the control cabinet to drive the frame to reciprocate or stop at the detection position above the at least two conveyor belts.

The movable frame comprises upright posts, cross beams and longitudinal beams, the four upright posts are connected transversely and longitudinally through the two cross beams and the two longitudinal beams, the longitudinal beams are longitudinally extended and arranged, the cross beams are transversely extended and arranged, and the two guide rails are respectively extended on the two cross beams.

The frame comprises cross bars and longitudinal bars, pulley blocks I are arranged at two ends of one longitudinal bar, pulley blocks II are arranged at two ends of the other longitudinal bar, the two cross bars are connected with the two longitudinal bars transversely and longitudinally, the longitudinal bars are longitudinally arranged in an extending mode, the cross bars are arranged at the bottoms of the longitudinal bars in the transversely extending mode, and analyzers are arranged at the bottoms of the two cross bars.

The horizontal pole is I-shaped steel or square steel, and every horizontal pole all is provided with two at least hanging holes that link up from top to bottom, and the casing of analysis appearance passes through bolted connection in hanging hole.

The driver is a motor, the pulley block I is provided with a motor drive forming driving wheel set, the pulley block II is used as a driven wheel set, and the motor is electrically connected with the control cabinet.

As described above, the above at least two conveyor belts span the moving frame, the moving frame is provided with the guide rail, the frame is slidingly connected with the guide rail, the analyzer is arranged on the frame, the driver is electrically connected with the control cabinet to drive the frame and the analyzer thereon to move to a certain belt detection position and then stop, and then the analyzer detects.

As an option, based on the foregoing solution, in an improved solution, in order to solve the problem of accurately detecting that the driving trolley moves to a position right above the belt, the moving mechanism of the cooperative system further includes a position detecting unit disposed on the moving frame, and the position detecting unit is electrically connected with the control cabinet to detect in-place information of the driving trolley or the analyzer. Therefore, the in-place information of the detection position right above a certain belt, which drives the trolley or the analyzer to move, can be detected, and the analyzer is further controlled to stop moving, so that the moving position of the analyzer is accurately controlled.

As an option, based on the foregoing solution, in the improved solution, in order to solve the problem that the different belt conveying amounts do not correspond to the sampling frequency, in the collaborative system, the conveyor is configured with a camera unit, a pressure detection unit and a speed detection unit, the camera unit is arranged above the conveyor belt, the pressure detection unit is arranged below the conveyor belt, the speed detection unit detects the rotation speed of the conveyor belt, and the camera unit, the pressure detection unit and the speed detection unit are respectively electrically connected with the control cabinet. Therefore, the conveying raw material quantity and the conveying speed on the belts can be monitored, so that the next sampling time point of each belt can be adjusted accordingly, and the sampling frequency can be correspondingly coordinated according to the conveying quantity.

As an option, based on the scheme, in the improved scheme, the cooperative system further comprises a server, the control cabinet is in communication connection with the server, and therefore the purpose of remote control can be achieved by utilizing the server to communicate with the control cabinet. Preferably, the control cabinet is provided with an audible and visual alarm so as to realize the aim of audible and visual alarm.

By adopting the technical scheme, the utility model has the following beneficial effects:

The multi-belt linkage cooperative system for analyzing the components of the alumina raw material ore comprises a plurality of conveyor belts, wherein the conveyor belts are arranged on a plurality of conveyor belts, a plurality of conveyor belts are arranged on the conveyor belts, a plurality of analyzers are arranged on the conveyor belts, a driver is electrically connected with a control cabinet to drive the conveyor belts and the analyzers on the conveyor belts to move to a certain belt detection position and then stop, and the analyzers detect the conveyor belts, so that the analyzers move to the positions above different conveyor belts to switch the belt measurement purposes.

Drawings

Fig. 1 is a system block diagram of a collaborative system example 1 of the present utility model.

Fig. 2 is a schematic diagram of the moving mechanism of fig. 1.

Fig. 3 is a partial enlarged view of fig. 2.

Fig. 4 is a further enlarged partial view of fig. 2.

Fig. 5 is a side view of fig. 2.

Fig. 6 is a top view of fig. 2.

Fig. 7 is a schematic view of the connection structure of the chassis and the cap peak of the analyzer in fig. 2.

In the drawings, 100, a moving mechanism, 200, an analyzer, 201, a cap peak, 300, a belt, 1, a column, 2, a longitudinal beam, 3, a cross beam, 4, a guide rail, 5, a driving trolley, 51, a longitudinal rod, 52, a cross rod, 53, a hanging hole, 54, a hanging bolt, 55, a driving wheel group, 56, a driven wheel group, 6 and a control cabinet.

Detailed Description

The utility model is described in further detail below with reference to the drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the utility model and are not limiting thereof. It should be further noted that, for convenience of description, only some, but not all of the structures related to the present utility model are shown in the drawings.

In the description of the present utility model, unless explicitly stated and limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, mechanically connected, electrically connected, directly connected, indirectly connected through intermediaries, or in communication between two elements or in interaction with each other. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Example 1

As described above, the multi-belt linkage cooperative system for analyzing the ore components of the alumina raw material according to the present utility model has basic and improved aspects, and each aspect feature combination is described above, for example, a preferred aspect includes a position detection unit, another preferred aspect includes a control cabinet configured with an audible and visual alarm connected thereto, another preferred aspect includes a position detection unit, and a control cabinet configured with an audible and visual alarm connected thereto, and the like, which are described herein by taking all the best feature combination examples as examples. The utility model relates to a belt material monitoring system for a driving trolley and a conveyor, which is characterized in that the system is improved on the basis of the existing analyzer, the existing analyzer is fixed at a detection position above a certain belt for detection, the system is composed of the existing driving trolley and the belt material monitoring system for the conveyor, so as to control the analyzer to move to the certain belt for detection, and the improvement is in the reciprocating structure and the connection relation of the analyzer.

Referring to fig. 1-7, the multi-belt linkage cooperative system for analyzing the components of the alumina raw material ore in this embodiment 1 comprises an analyzer 200, wherein the analyzer is disposed at a detection position above the conveyor belt and can analyze the components of the alumina raw material ore on the belt, and further comprises a moving mechanism 100, the moving mechanism 100 comprises a moving frame, a guide rail 4, a driving trolley 5 and a control cabinet 6, the driving trolley 5 comprises a frame, a pulley block I, a pulley block II and a driver, the moving frame spans over at least two conveyor belts 300 (illustrated by A, B belts as an example), two guide rails 4 extending transversely are disposed on the moving frame, the pulley block I and the pulley block II are disposed at the bottom of the frame and are respectively slidably connected to the two guide rails 4, the analyzer 200 is disposed on the frame, and the driver is electrically connected with the control cabinet 6 to drive the frame to move or stop, i.e. drive the frame to reciprocate or stop at the detection position above the at least two conveyor belts (the at least two detection positions).

When the analyzer moves above the belt along the guide rail, the analyzer is the same as the existing analyzer in terms of fixed installation position to the height of the belt, and the analyzer can detect and analyze the ore ingredients of the alumina raw material by taking the position as a detection position.

The movable frame comprises upright posts 1, cross beams 3 and longitudinal beams 2, wherein four upright posts are connected transversely and longitudinally through two cross beams and two longitudinal beams, the longitudinal beams are longitudinally extended and arranged, the cross beams are transversely extended and arranged, and two guide rails are respectively extended on the two cross beams.

The frame includes horizontal pole 52 and vertical pole 51, and assembly pulley I has been disposed at the both ends of a vertical pole, and assembly pulley II has been disposed at the both ends of another vertical pole, and two horizontal poles are connected with two vertical poles violently indulgingly, and the both ends of horizontal pole are connected on two vertical poles through bolt and gasket bolt respectively as shown in fig. 4 and 7, and vertical pole longitudinal extension arranges, and the horizontal pole is arranged in vertical pole bottom along transversely extending, and two horizontal pole bottoms are provided with the analysis appearance.

The cross bars 52 are of an i-beam or square steel, as shown in fig. 2-7 for example, each cross bar 52 is provided with at least two hanging holes 53 penetrating up and down, as shown in fig. 5 for example, 2 through holes 19mm in diameter are arranged, and the housing of the analyzer is connected to the hanging holes 53 by bolts (hanging bolts 54, provided with nuts). The side wall of the analyzer housing is provided with a cap peak 201 of a convex plate-like structure, on which fixing holes are respectively opened corresponding to the hanging holes, as shown in fig. 7 (fig. 7 shows the local structure of the analyzer, and the whole structure of the analyzer is shown in fig. 1), so as to cooperate with the hanging holes 53 and the hanging bolts 54, and the hanging bolts are inserted into the hanging holes and the fixing holes and the nuts are screwed down, thereby realizing the installation and fixation.

The driver is a motor, the pulley block I is provided with a motor drive assembly driving pulley group 55, the pulley block II is used as a driven pulley group 56, and the motor of the driving pulley group 55 is electrically connected with the control cabinet.

The cooperative system has the working process that the driver is started to drive the frame to move to the detection position of the belt A and stop, then the analyzer is started to detect, then the driver is started to drive the frame to move to the detection position of the belt B and stop, and then the analyzer is started to detect, so that the analyzer can move back and forth to the detection position of the belt A, B, and the detection of the belt A, B can be switched according to the requirement. As described above, the above at least two conveyor belts span the moving frame, the moving frame is provided with the guide rail, the frame is slidingly connected on the guide rail, the analyzer is arranged on the frame, the driver is electrically connected with the control cabinet to drive the frame and the analyzer thereon to move to a certain belt detection position and then stop, and then the analyzer detects, so that the analyzer can move back and forth to different belt upper detection positions to switch the belt measurement purpose.

Examples of partial dimensions, in mm, are given in fig. 5 and 6, and are further described below.

In the continuous conveying of the raw materials, the ore components are required to be subjected to multi-component real-time online detection, and the multi-component real-time online detection comprises 13 components such as total aluminum, effective aluminum and the like. The ore component analyzer forms a 40 x 40cm irradiation range on the surface of the belt, and sequentially and initially sequentially detects according to the conveying direction of the ore bulk on the conveying belt (belt). The analyzer and the detection system thereof comprise a timing origin unit, an energy spectrum detection unit, a belt speed measurement unit, a remote vision detection unit, a near infrared NIR detection unit, a belt pressure control detection unit and the like.

And the remote visual detection unit (camera shooting unit) is a camera and is used for detecting granularity, stacking degree and inclusion of ore bulk materials in a belt conveying flowing state and preventing abnormal conditions.

The belt pressure control detection unit (pressure detection unit) is a pressure sensor group and acquires real-time pressure data of ore which is spread on a belt in an average mode, so that continuity detection of an ore homogenization effect is realized.

In the analyzer, a near infrared NIR detection unit detects real-time randomness of various taste components of the ore bulk material in a belt ore flowing state. And the energy spectrum detection unit is used for detecting the irradiation signal intensity of the halogen lamp in a conveying flow state and automatically adjusting the irradiation power according to the signal intensity. The timing origin unit is used for acquiring a starting point and an ending point of the on-line measurement, and the starting point and the ending point are used as critical points of the measurement in a certain time range and are used as starting signals of bulb heating. A purging control unit can be designed to purge dust on the bulb periodically, and the self-correcting deviation value is linked.

The belt speed measuring unit (speed detecting unit) is a speed sensor and is linked with the belt pressure control detecting unit, and the belt speed is automatically adjusted according to the pressure control state.

In order to improve the detection accuracy of the raw material amount of the belt, a photoelectric control metering unit can be designed, and the instantaneous flow of the ore bulk material in a flowing transmission state is detected for a flowing speed sensor, so that accurate metering of the accurate feeding amount of weight and volume is realized.

The mechanical screen vibration control unit can be designed to be a vibrator connected with the control cabinet, and the vibrator is arranged on the movable frame, so that dust and other sundries such as a movable guide rail and the like can be automatically vibrated according to a fixed time interval or ore quantity, the failure rate is reduced, and the jamming is prevented.

The multi-belt cooperative system can automatically detect which belt is operated in the continuous ore conveying process, gives out an instruction, knows that an ore analyzer automatically moves to the upper part of the belt, gives an alarm in advance to prompt nearby maintenance personnel and other personnel to withdraw rapidly, monitors pressure and voltage current signals on the belt in real time after the belt is in place, and if the voltage and current signals meet the starting requirement of the analyzer, the analyzer enters a moving state and starts a detection system to enter a working state, the analyzer is prepared before preheating and starting, a belt speed sensor starts the three-in-one of two electric signals above the belt speed sensor is linked to meet the requirement and gives out an instruction for entering the preheating state after the starting operation, a starting operation instruction is sent to a vision control unit and a timing origin unit, the origin of the time measuring time position is detected to mark the starting detection unit of the analyzer, and the processes of the analyzer entering the working state are restarted when the belt is stopped, restarted, the ore is cut off, and the analyzer enters the working state after the belt is emptied. The ore is emptied on the belt, the analyzer immediately exits the operation and prompts the end of the cycle.

The analyzer, the control cabinet, the camera unit, the pressure detection unit, the speed detection unit and other components and connection control thereof are all existing technologies, and can be realized through connection of factory configuration standard power supply data lines, and the details are not repeated here. The analyzer and the detection system thereof can also realize the following functions.

When the time point signal of entering the working state is obtained, the remote machine vision detection unit starts to capture the frequency for 1 second, so that high-definition photos of various stacking states of the surface layer ore paved on the conveyor belt are obtained, and meanwhile, the safety around the belt is ensured.

After the ore stacking height and pressure and the current signal data are obtained, the near infrared NIR detection unit starts an energy spectrum detection power supply according to the measured pressure and current, and adjusts the power of an irradiation light source.

When the working state is obtained, the timing origin unit and the near infrared NIR detection signal are synchronously acquired so as to realize the corresponding association of the data and the full-component detection data.

After the time point signal entering the working state is obtained, the mechanical vibrating screen unit vibrates the analyzer and the movable sliding rail according to the sampling timing and the time interval of ore, so that the equipment is ensured to be clean.

When the subsequent detection unit is started randomly and the detection unit is out of working state, the purging control unit can indirectly clean the dust of the bulb.

According to the apparent height and pressure measurement of ore, flow speed measurement, preheating detection system, starting detection, interrupt detection, restarting detection, changing belt transmission, changing control concentration, ending detection and stopping detection system operation, data recording and reporting, time reporting and day reporting, etc..

And (3) adjusting a data processing self-learning algorithm of mother liquor and flow detection according to the component records.

The multi-element detection data is subjected to independent superposition processing and associated dissolution feed-forward control processing.

The real-time on-line detection method for the ore components by the analyzer comprises the following specific steps:

Firstly, judging that the ore position passes through an analyzer and is completely below the analyzer;

Judging the ore transmission pressure and current and the accumulation height on the belt;

And thirdly, processing detection data acquired by a bulb of the detection analyzer, outputting the content of the integral components and the apparent indexes of the ore per minute, outputting and recording the component results in a single time range in real time, and associating traceable information.

As described above, the system solves the problems that the ore grade on the belt cannot be monitored and linked, and the random extraction sampling process is avoided, and the complex measurement and test comparison of the ore element content and apparent physical characteristics are realized through a plurality of technical units, so that the linked real-time monitoring is realized. Belt measurement can be switched according to A, B belt running conditions, and real-time detection of chemical components of ore materials on the belt is realized. When the belt stops rotating, idles and runs out, the data detection is automatically stopped, 148 groups of data are measured every minute by the system, the measurement result is more representative and timely, and the system has more accurate guiding significance for the control of the production process.

The method has the advantages of high-frequency sample scanning, high coverage rate, online real-time analysis, high stability, multi-unit detection, large sample record comparison self-learning correction, avoidance of abnormal data and variance adjustment, real-time detection and non-associated data element comparison and continuous approach to static chemical analysis detection accuracy. The method has the advantages of no need of manual sampling and sample preparation, labor intensity reduction, no physical detection of sample, no chemical analysis of samples, detection efficiency improvement, mass raw data storage, convenient and accurate retrieval and comprehensive and durable data storage.

Example 2

This embodiment 2 differs from embodiment 1 in the driver, specifically as follows:

In this cooperative system of embodiment 2, the driver is an electric putter, at this time, the driving wheel set in fig. 1-7 is replaced by a driven wheel set, the fixed end of the electric putter is disposed on the moving frame (specifically, the longitudinal beam 2, for example, the fixed end of the electric putter is connected to the middle of the longitudinal beam 2 through a bolt), the moving end of the electric putter is disposed on the frame (specifically, the longitudinal rod 51, for example, the moving end of the electric putter is connected to the middle of the longitudinal rod 51 through a bolt), the electric putter is disposed in a transversely telescopic manner, and the electric putter is electrically connected to the control cabinet. The electric push rod is an existing component, and is connected with the control cabinet by an existing technology, and can be realized through factory configuration standard power supply data line connection, and the details are omitted here. Therefore, the electric push rod is electrically connected with the control cabinet to realize the extension or contraction movement so as to push the frame and the analyzer on the frame to move, and the analyzer can move back and forth to detection positions above different belts so as to switch the belt measurement purpose.

It is to be understood that the above examples of the present utility model are provided for clarity of illustration only and are not limiting of the embodiments of the present utility model. Various obvious changes, rearrangements and substitutions can be made by those skilled in the art without departing from the scope of the utility model. It is not necessary here nor is it exhaustive of all embodiments. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the utility model are desired to be protected by the following claims.

Claims (9)

1. The multi-belt linkage cooperative system for analyzing the components of the alumina raw material ore comprises an analyzer, wherein the analyzer is arranged at a detection position above conveyor belts and can analyze the components of the alumina raw material ore on the conveyor belts, and the multi-belt linkage cooperative system is characterized by further comprising a moving mechanism, a driving trolley and a control cabinet, wherein the moving mechanism comprises a moving frame, a guide rail, the driving trolley and a control cabinet, the driving trolley comprises a frame, a pulley block I, a pulley block II and a driver, the moving frame spans above at least two conveyor belts, two transversely extending guide rails are arranged on the moving frame, the pulley block I and the pulley block II are arranged at the bottom of the frame and are respectively and slidably connected onto the two guide rails, and the analyzer is arranged on the frame and is electrically connected with the control cabinet to drive the frame to reciprocate or stop at the detection position above the at least two conveyor belts.

2. The multi-belt linkage cooperative system for analyzing the ore composition of alumina raw materials according to claim 1, wherein the movable frame comprises upright posts, cross beams and longitudinal beams, the four upright posts are connected transversely and longitudinally through two cross beams and two longitudinal beams, the longitudinal beams are longitudinally extended and arranged, the cross beams are transversely extended and arranged, and the two guide rails are respectively extended on the two cross beams.

3. The multi-belt linkage cooperative system for analyzing the ore composition of alumina raw materials according to claim 1, wherein the frame comprises cross bars and longitudinal bars, pulley blocks I are arranged at two ends of one longitudinal bar, pulley blocks II are arranged at two ends of the other longitudinal bar, the two cross bars are connected with the two longitudinal bars transversely and longitudinally, the longitudinal bars are longitudinally extended and arranged at the bottoms of the longitudinal bars, and analyzers are arranged at the bottoms of the two cross bars.

4. The multi-belt linked cooperative system for analyzing the ore composition of an alumina raw material according to claim 3, wherein the cross bars are of an I-shaped steel or a square steel, each cross bar is provided with at least two hanging holes which are vertically penetrated, and a shell of the analyzer is connected with the hanging holes through bolts.

5. The multi-belt linked cooperative system for analyzing the ore composition of an alumina raw material according to claim 1, wherein the moving mechanism further comprises a position detecting unit arranged on the moving frame, and the position detecting unit is electrically connected with the control cabinet to detect in-place information of the driving trolley or the analyzer.

6. The multi-belt linkage cooperative system for analyzing the ore composition of the alumina raw material according to claim 1, wherein the conveyor is provided with a camera unit, a pressure detection unit and a speed detection unit, the camera unit is arranged above a conveyor belt, the pressure detection unit is arranged below the conveyor belt, the speed detection unit detects the rotating speed of the conveyor belt, and the camera unit, the pressure detection unit and the speed detection unit are respectively electrically connected with the control cabinet.

7. The multi-belt linkage cooperative system for analyzing the ore ingredients of the alumina raw materials according to claim 1, wherein the driver is a motor, the pulley block I is provided with a driving pulley group formed by motor driving, the pulley block II is used as a driven pulley group, and the motor is electrically connected with the control cabinet.

8. The multi-belt linkage cooperative system for analyzing the ore ingredients of the alumina raw materials of claim 1, wherein the driver is an electric push rod, the fixed end of the electric push rod is arranged on the movable frame, the movable end of the electric push rod is arranged on the frame, the electric push rod is arranged in a transversely telescopic manner, and the electric push rod is electrically connected with the control cabinet.

9. The multi-belt linkage cooperative system for analyzing the ore composition of an alumina raw material according to claim 1, further comprising a server, wherein the control cabinet is in communication connection with the server, and wherein the control cabinet is configured with an audible and visual alarm.