CN218595564U

CN218595564U - Feeding system

Info

Publication number: CN218595564U
Application number: CN202223216637.3U
Authority: CN
Inventors: 牟金合; 谭晓峰; 吴亚赛; 潘操; 张铭; 肖国; 殷贺; 张旭君; 杜微
Original assignee: MCC Capital Engineering and Research Incorporation Ltd
Current assignee: MCC Capital Engineering and Research Incorporation Ltd
Priority date: 2022-11-30
Filing date: 2022-11-30
Publication date: 2023-03-10
Anticipated expiration: 2032-11-30

Abstract

The utility model discloses a feeding system, it relates to metallurgical technology field, and feeding system includes: the underground storage bin system comprises a plurality of underground storage bins, wherein each underground storage bin comprises a first storage bin body; the first bin frame is connected with the first bin body; the first support mechanism is provided with a first weighing sensor, and the lower end of the first bin frame is arranged on the first weighing sensor; a first feeder is arranged at an outlet of the first bin body; the belt conveying mechanism is arranged below the first feeder and is in flexible connection with the first feeder or keeps a non-contact state; the intelligent gates correspond to the underground bins one by one and are provided with license plate recognition units; and the control unit is respectively and electrically connected with the first weighing sensor of each underground storage bin and each intelligent gate. The problem that the feeding system produces metering error in long-term use can be solved to this application.

Description

Feeding system

Technical Field

The utility model relates to the technical field of metallurgy, in particular to feeding system.

Background

Along with the development of industrial automation, the intelligent demand of metallurgical enterprises on equipment is higher and higher. The automation degree of the processes of iron making, steel rolling and the like is high, workers needed on site are few, most of operations are completed by being concentrated in a central control room, and various combustion models, one-key steel tapping systems and the like are widely applied without manual excessive intervention.

The raw material system has more non-standardized facilities, although a central control room is provided, most processes still need to be set by manual operation, and a lot of work needs manual operation of field workers. The problems of severe environment of a raw material system, long operation process, high labor intensity of workers, various materials, easy material loading error, various small-batch loading requirements, unplanned emergency loading and the like are more and more prominent, and the requirement on intellectualization is higher and higher.

Chinese patent No. 201410140458.7 discloses an automatic control method for a steelmaking auxiliary raw material feeding system, which only utilizes a simple database function to realize automatic control of the steelmaking auxiliary raw material feeding system, and three databases are established in the control method: the method comprises the steps that a material seed database, an underground stock bin database and an overhead stock bin database are used for establishing and initializing an overhead stock bin data queue to be loaded; calculating the warehousing weight of the high-level storage bin through a belt scale, calculating the ex-warehouse weight through a weighing hopper, and subtracting the warehousing weight of the high-level storage bin and the ex-warehouse weight to obtain the stock weight of the high-level storage bin; and sorting the feeding sequence and the feeding time according to the weight of the material stored in the overhead bin. The automatic control method of the steelmaking auxiliary raw material feeding system has the following defects: the belt weigher has large error, and the weight of the materials in the high-level stock bin cannot be accurately counted; the material is generally scattered in the transferring process of the feeding system or the discharging process of the discharging car, and in addition, the dust pumped by the dust removal system, the feeding amount read by the belt weigher has a large error with the actual feeding amount of the high-level storage bin, and the accumulated error is more and more uncontrollable along with the prolonging of time; the high-level bin is also scattered when discharging, and the dust pumped by the dust removal system is added, so that the discharge amount of the high-level bin is measured by the weighing hopper, a large error is generated between the discharge amount of the high-level bin and the actual discharge amount of the high-level bin, and the accumulated error is more and more uncontrollable along with the prolonging of time; the volume of the weighing hopper is very small relative to the high-level silo, the volume of one high-level silo is about 20 to 300 times of the volume of the weighing hopper, the single error of the weighing hopper is low, but the accumulated error after multiple times of weighing is not negligible.

Interpretation of key terms

Feeding: when the bunker of the mixing batching tank, sintering, pelletizing, blast furnace, converter, electric furnace, refining, coal injection powder-making station, lime kiln and other facilities of the metallurgical enterprise needs the raw fuel, the raw fuel is transported from the underground bunker or a stock yard and a storage silo.

Intelligence: the method is characterized in that the method is an operation of automatically determining the starting of a flow according to a system instruction, a field instrument and a signal without human intervention.

Basic automation (L1) level: the field equipment control system mainly uses PLC (programmable logic controller) to realize simple control of mechanical equipment, but also only controls input and output of I/O signals, and can use program to control on-off of equipment.

Process automation (L2) level: the production process monitoring system is the most core control layer in the whole automation, comprises tracking logic control and model calculation, carries out material tracking and actual measurement data acquisition and processing on a conveying system, realizes optimized setting calculation of various control parameters through a series of mathematical models and control algorithms, and transmits the control parameters to a basic automation level to realize direct control on production.

Plant automation (L3) level: the MES manufacturing execution system comprises workshop management, online scheduling and quality management. The main task is to give production plan, production statistics and report forms to the L2 level.

Low material level: the minimum storage capacity of the materials in the storage bin can generally meet the requirement of the material quantity of a furnace or a plurality of batches, and is required to be set according to the time required by feeding and supplementing.

High material level: the method refers to the highest storage capacity of materials in a storage bin, when the materials reach a high material level, the starting end of a feeding system starts to stop feeding, and the storage capacity on a belt conveyor of the feeding system can just fill the storage bin.

SUMMERY OF THE UTILITY MODEL

In order to overcome the above-mentioned defect of prior art, the embodiment of the utility model provides a technical problem that will solve provides a feeding system, and it can solve feeding system and produce the problem of measuring error in permanent use.

The embodiment of the utility model provides a concrete technical scheme is:

a feeding system, comprising:

the underground storage bin system comprises a plurality of underground storage bins, wherein each underground storage bin comprises a first storage bin body; the first bin frame is connected with the first bin body; the first support mechanism is provided with a first weighing sensor, and the lower end of the first bin frame is arranged on the first weighing sensor; a first feeder is arranged at an outlet of the first bin body;

the belt conveying mechanism is arranged below the first feeder, and the belt conveying mechanism and the first feeder are in flexible connection or are kept in a non-contact state;

the intelligent gates correspond to the underground bins one by one and are provided with license plate recognition units;

and the control unit is respectively and electrically connected with the first weighing sensor of each underground storage bin and the intelligent gate.

Preferably, the feeding system further comprises:

a steelmaking shop bin system comprising a plurality of steelmaking shop bins, each of said steelmaking shop bins comprising: a second bin body; the second bin frame is connected with the second bin body; the second support mechanism is provided with a second weighing sensor, and the lower end of the second bin frame is arranged on the second weighing sensor; a second feeder is arranged at an outlet of the second bin body;

the belt type conveying mechanism is positioned above the plurality of steelmaking workshop bins; the first positioning unit is used for determining the position of the first discharging car, so that the first discharging car can discharge materials on the belt conveying mechanism into the corresponding steel-making workshop storage bin;

the first discharging car, the first positioning unit and the second weighing sensor are electrically connected with the control unit.

Preferably, part of the steelmaking workshop bins are auxiliary raw material bins, and part of the steelmaking workshop bins are ferroalloy bins; the auxiliary raw material bin is positioned at a high position; the ferroalloy bin is positioned at a high position or a middle position.

Preferably, the underground feed bin is still including installing the first anti-scattering material mechanism of the opening part of the first feed bin storehouse body, first anti-scattering material mechanism is from top to bottom convergent form, the first opening that prevents scattering material mechanism upper end is greater than the opening of the first feed bin storehouse body.

Preferably, at least part of the underground bins are sequentially and linearly arranged, and gaps between adjacent underground bins are lapped by adopting a light plate.

Preferably, the feeding system further comprises:

blast furnace ore groove system, including a plurality of blast furnace feed bins, every the blast furnace feed bin includes: a third bin body; the third bin frame is connected with the third bin body; the third support mechanism is provided with a third weighing sensor, and the lower end of the three bin frame is arranged on the third weighing sensor; a third feeder or a gate is arranged at an outlet of the third bin body;

the belt type conveying mechanism is positioned above the blast furnace bins; the belt conveying mechanism is provided with a second discharging car and a second positioning unit, and the second positioning unit is used for determining the position of the second discharging car so that the second discharging car can discharge the materials on the belt conveying mechanism into the corresponding blast furnace bin;

the second discharging car, the second positioning unit and the third weighing sensor are electrically connected with the control unit.

Preferably, the blast furnace material bin further comprises a second scattering prevention mechanism arranged at an opening of the third bin body, the second scattering prevention mechanism is in a gradually reducing shape from top to bottom, and an opening at the uppermost end of the second scattering prevention mechanism is larger than an opening of the third bin body.

Preferably, at least part of the blast furnace material bins are sequentially and linearly arranged, and gaps between the adjacent blast furnace material bins are lapped by adopting light plates.

Preferably, the openings of adjacent second spill guard means are in close proximity.

Preferably, the third feeder or the gate and the subsequent screening device are in soft connection or are kept in a non-contact state.

The technical scheme of the utility model following beneficial effect is shown to have:

1. this application can be real realize whole unmanned on duty, intelligent operation realizes unmanned participation material loading, greatly reduced workman's intensity of labour. 2. Secondly, can judge the material kind and the material volume that different feed bins need the material loading through weighing sensor is automatic, avoid the wrong material problem of going up that artifical selection flow produced, perhaps the material loading produces the flash accident excessively to long-term steady operation for the feeding system provides the powerful guarantee, compares in the charge level indicator that uses in the past, and the charge level indicator error is huge, the trouble is many, unable intelligent operation at all. 3. In addition, the intelligent gate with the license plate recognition unit can ensure that vehicles for transporting materials can only enter the corresponding correct underground storage bin, so that the problem of material unloading and wrong material unloading in the link only needing personnel to participate is avoided; 4. moreover, the first weighing sensor can accurately track the material quantity of the underground storage bin in real time, and a feeding vehicle can feed materials in advance, so that the occurrence of material shortage accidents is avoided; 5. and finally, whether the materials are spilled or not can be judged by tracking the feeding amount of the underground storage bins and the feeding amount of the storage bins in the workshop, and the natural loss and the actual consumption of the materials can be counted.

Specific embodiments of the present invention are disclosed in detail with reference to the following description and the accompanying drawings, which specify the manner in which the principles of the invention may be employed. It should be understood that the embodiments of the present invention are not so limited in scope. Features that are described and/or illustrated with respect to one embodiment may be used in the same way or in a similar way in one or more other embodiments, in combination with or instead of the features of the other embodiments.

Drawings

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way. In addition, the shapes, the proportional sizes, and the like of the respective members in the drawings are merely schematic for helping the understanding of the present invention, and do not specifically limit the shapes, the proportional sizes, and the like of the respective members of the present invention. The skilled person in the art can, under the teaching of the present invention, choose various possible shapes and proportional dimensions to implement the invention according to the specific situation.

Fig. 1 is a schematic view of an underground storage bin system and an intelligent gate in an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of an underground storage bin in an embodiment of the present invention;

FIG. 3 is a schematic structural view of a steel plant bin system according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a blast furnace ore tank system in an embodiment of the present invention.

Reference numerals of the above figures:

1. an underground storage bin system; 11. an underground storage bin; 111. a first bin body; 112. a first bin frame; 113. a first support mechanism; 114. a first weighing sensor; 115. a first feeder; 116. a first spill prevention mechanism; 2. a belt conveyor; 21. a first discharging vehicle; 22. a first positioning unit; 23. a second discharging vehicle; 24. a second positioning unit; 3. an intelligent gate; 4. a steelmaking workshop bin system; 41. a steel-making workshop stock bin; 411. a second load cell; 412. a second feeder; 5. a blast furnace ore tank system; 51. a blast furnace bunker; 511. a third weighing sensor; 512. a third feeder; 513. and (4) a gate.

Detailed Description

The details of the present invention can be more clearly understood with reference to the accompanying drawings and the description of the embodiments of the present invention. However, the specific embodiments of the present invention described herein are for the purpose of explanation only, and should not be construed as limiting the invention in any way. Given the teachings of the present invention, the skilled person can conceive of any possible variants based on the invention, which should all be considered as belonging to the scope of the invention. It will be understood that when an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "mounted," "connected," and "connected" are to be construed broadly and may include, for example, mechanical or electrical connections, communications between two elements, direct connections, indirect connections through intermediaries, and the like. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

In order to solve the problem that feed system produced metering error in permanent use, proposed a feed system in this application, fig. 1 does the embodiment of the utility model provides an in the principle sketch of underground storage bin system and intelligent gate, fig. 2 does the embodiment of the utility model provides an in the structural schematic diagram of underground storage bin, as shown in fig. 1 and fig. 2, feed system includes: the underground storage bin system 1 comprises a plurality of underground storage bins 11, wherein each underground storage bin 11 comprises a first storage bin body 111; a first silo frame 112 connected to the first silo body 111; a first weighing sensor 114 is mounted on the first supporting mechanism 113, and the lower end of the first bin frame 112 is mounted on the first weighing sensor 114; a first feeder 115 is arranged at the outlet of the first silo body 111; the belt conveying mechanism 2 is arranged below the first feeder 115, and the belt conveying mechanism 2 is in flexible connection with the first feeder 115 or keeps a non-contact state; the intelligent gates 3 correspond to the underground bins 11 one by one, and the intelligent gates 3 are provided with license plate recognition units; and the control unit is respectively and electrically connected with the weighing sensor of each underground bin 11 and the intelligent gate 3.

As shown in fig. 1, the underground bunker system 1 may include a plurality of underground bunkers 11, wherein some of the underground bunkers 11 may be arranged in a straight line in turn, which may facilitate the belt conveyor 2 to transport the material output from the outlet of the belt conveyor 2. Meanwhile, the adjacent underground storage bins 11 can be arranged closely, and gaps between the adjacent underground storage bins 11 can be lapped by adopting a light plate, so that the material is prevented from being lost and leaked from the gaps between the adjacent underground storage bins 11 when a vehicle for transporting the material unloads the material.

As shown in fig. 1, each underground silo 11 can include a first silo body 111; a first silo frame 112 connected to the first silo body 111; the first support mechanism 113. The first silo body 111 is generally of a funnel configuration with an opening above and facing upwards to facilitate the direct replenishment of material, the outlet of the first silo body 111 being located lowermost. The first bin frame 112 is located at the side wall of the first bin body 111, and is used for improving the strength and the dispersion stress of the side wall, so that the first bin body 111 and the weight of the materials in the first bin body 111 can be supported by the first bin frame 112. The first supporting mechanism 113 is used for supporting the first bin frame 112, so as to support the whole first bin body 111 and the weight of the materials in the first bin body 111. The first supporting mechanism 113 may be a plurality of support rods for catch-eye in the vertical direction, and may further include a plurality of cross rods for connecting the support rods, thereby improving the stability of the entire first supporting mechanism 113. The first load cell 114 is mounted on the first support mechanism 113, and the lower end of the first bin frame 112 is mounted on the first load cell 114. The first silo body 111 is separated from the other structures except the first silo frame 112, so that the weight of the material in the first silo body 111 can be weighed by the first weighing sensor 114. The number of the first weighing sensors 114 may be multiple, the first weighing sensor 114 is installed between each position of the first bin frame 112 and the first supporting mechanism 113, the first weighing sensor 114 can weigh the total weight of the materials in the first bin frame 112, the first bin body 111 and the first bin body 111, and the weight of the materials in the first bin frame 112 and the first bin body 111 is known, so that the weight of the materials in the first bin body 111 can be weighed. The first feeding machine 115 is installed at the outlet of the first bin body 111, and by opening the first feeding machine 115, the materials in the first bin body 111 can be outwards output to the belt conveying mechanism 2 through the outlet and are transported away through the belt conveying mechanism 2. The belt conveying mechanism 2 is arranged below the first feeding machine 115, and the belt conveying mechanism 2 and the first feeding machine 115 are in a flexible connection or a non-contact state, so that the belt conveying mechanism 2 does not support the first feeding machine 115, the weight of the material in the first storage bin body 111 can be accurately calculated by the first weighing sensor 114, and the weight of the material output outwards through the first feeding machine 115 can be further accurately controlled.

As a practical matter, the first feeding machine 115 may be a vibratory feeding machine, a disk feeding machine, a belt feeding machine, or the like, and is not limited in any way in this application.

As a matter of course, the number of underground silos 11 can generally correspond to the number of material types.

As shown in fig. 1, a plurality of intelligent gates 3 correspond to a plurality of underground storage bins 11 one by one, and the vehicle transporting the material can unload to the underground storage bins 11 after passing through the intelligent gates 3, and the intelligent gates 3 have license plate recognition units. The control unit is respectively electrically connected with the first weighing sensor 114 of each underground bunker 11 and each intelligent gate 3. When the control unit judges that the weight of the materials in a certain underground storage bin 11 does not meet the loading requirement of the storage bin in the workshop through the first weighing sensor 114 on each underground storage bin 11, the intelligent gate 3 corresponding to the underground storage bin 11 which does not meet the loading requirement of the storage bin in the workshop can be opened.

When the control unit judges that the weight of the material in a certain underground storage bin 11 does not meet the feeding requirement of the storage bin in the workshop through the first weighing sensor 114 on each underground storage bin 11, the control unit determines that the material needs to be supplemented, at the moment, when the vehicle for transporting the material only enters the intelligent gate 3 corresponding to the underground storage bin 11 needing to be supplemented, the control unit controls the intelligent gate 3 to be opened, so that the vehicle for transporting the material is allowed to pass through, the purpose of accurately controlling the vehicle for transporting the material to supplement the underground storage bin 11 needing to be supplemented with the material is achieved, the supplement error is avoided, and meanwhile, the automatic control is not required to be artificially participated.

As a practical matter, as shown in fig. 1 and 2, the underground silo 11 may include a first scattering prevention mechanism 116 installed at an opening of the first silo body 111, wherein the first scattering prevention mechanism 116 is tapered from top to bottom, and an opening at the uppermost end of the first scattering prevention mechanism 116 is larger than an opening of the first silo body 111. Through the structure, when the vehicle for transporting materials unloads the underground storage bin 11, the materials fall into the first storage bin body 111 as far as possible, and the scattering amount is reduced.

Fig. 3 is a schematic structural diagram of a storage bin system of a steelmaking plant according to an embodiment of the present invention, as shown in fig. 3, as feasible, the feeding system may further include: the steelmaking shop bin system 4 includes a plurality of steelmaking shop bins 41. Each steelmaking plant silo 41 includes: a second bin body; the second bin frame is connected with the second bin body; the second weighing sensor 411 is arranged on the second supporting mechanism, and the lower end of the second storage bin frame is arranged on the second weighing sensor 411; the outlet of the second silo body is provided with a second feeder 412. The structure of the steelmaking plant silo 41 is substantially similar to that of the underground silo 11 and will not be described again. The second silo body is separated from other structures except the second silo frame, so that the second weighing sensor 411 can weigh the materials in the second silo body.

The belt conveying mechanism 2 is located above the plurality of steel-making workshop bins 41, and materials output by the underground bins 11 in the underground bin system 1 can be conveyed to the steel-making workshop bin system 4 through the belt conveying mechanism 2, so that the materials are supplemented to the corresponding steel-making workshop bins 41. The belt conveyor 2 is provided with a first discharging carriage 21 and a first positioning unit 22. The first positioning unit is used to position the first tripper carriage 21 so that the first tripper carriage 21 can discharge the material on the belt conveyor 2 into the corresponding steelmaking shop bin 41. The first discharging carriage 21 is used for discharging the materials loaded by the belt conveyor 2 to the lower steel-making shop bin 41. The first discharging carriage 21, the first positioning unit 22 and the second weighing sensor 411 are electrically connected with the control unit.

As a practical matter, part of the steelmaking shop bins 41 are auxiliary raw material bins, and part of the steelmaking shop bins 41 are ferroalloy bins. The auxiliary raw material bin may be located at an elevated position. The ferroalloy silo can be located at a high position or a middle position. As shown in fig. 3, the auxiliary raw material bin is located at a high position, and the ferroalloy bin is located at a medium position.

The control unit stores the type and weight of each auxiliary raw material bin and the type and weight of each ferroalloy bin in the steelmaking workshop bin system 4, and the weight of the material in each steelmaking workshop bin 41 can be updated in real time through the second weighing sensor 411. The control unit may control the steelworks silo 41 up to a preset level to turn on the second feeder 412 to feed the converter or ladle as required.

When the control unit judges that the weight of the material in a certain steel-making workshop bin 41 does not reach the preset material level through the second weighing sensor 411 on each steel-making workshop bin 41, the control unit determines that the material needs to be supplemented, at the moment, the first discharging car 21 is positioned through the first positioning unit 22 and then moves to the steel-making workshop bin 41 where the material needs to be supplemented, the first feeding machine 115 of the corresponding underground bin 11 in the control underground bin system 1 is started to start feeding, the material is output to the first discharging car 21 in the steel-making workshop bin system 4 through the belt conveying mechanism 2, and the material is discharged into the steel-making workshop bin 41 where the material needs to be supplemented through the first discharging car 21. At this time, the weight of the material output by the corresponding underground bunker 11 can be obtained through the first weighing sensor 114 of the corresponding underground bunker 11, the weight of the actually supplemented material can be obtained through the second weighing sensor 411 of the steel plant bunker 41 which needs to supplement the material, and the loss amount in the material supplementing process can be calculated through the above manner.

Fig. 4 is a schematic structural diagram of a blast furnace ore tank system in an embodiment of the present invention, as shown in fig. 4, a feeding system may include: the blast furnace pit system 5 includes a plurality of blast furnace silos 51. Each blast furnace hopper 51 includes: a third bin body; the third bin frame is connected with the third bin body; the third weighing sensor 511 is arranged on the third supporting mechanism, and the lower end of the three-bin frame is arranged on the third weighing sensor 511; and a third feeder 512 or a gate 513 is arranged at the outlet of the third silo body. The belt conveyor 2 is located above the plurality of blast furnace silos 51. The belt conveyor 2 is provided with a second discharging carriage 23 and a second positioning unit 24, and the second positioning unit is used for determining the position of the second discharging carriage 23, so that the second discharging carriage 23 can discharge the material on the belt conveyor 2 to the corresponding blast furnace bin 51.

Because in blast furnace ore groove system 5, a raw materials of blast furnace generally needs a plurality of blast furnace material storehouses 51, consequently, second dummy car 23 generally is unloaded in succession, consequently, blast furnace material storehouse 51 can be including installing the second anti-scattering mechanism at the opening part of the third feed bin storehouse body, and the second is anti-scattering mechanism and is from top to bottom convergent form, and the opening of the upper end of second anti-scattering mechanism is greater than the opening of the third feed bin storehouse body. The openings of the adjacent second material scattering prevention mechanisms are abutted. At least part of the blast furnace storage bins 51 are arranged in a straight line in sequence, and gaps between the adjacent blast furnace storage bins 51 are lapped by adopting light plates. Through the mode, the material scattering amount of the second discharging car 23 during discharging can be reduced as much as possible, and the weighing of the third weighing sensor 511 is not influenced. The third feeder 512 or the gate 513 is in soft connection or in a non-contact state with the subsequent screening device, so that the weighing of the third weighing sensor 511 is not influenced. The material conveyed by the belt conveyor 2 into the blast furnace launder system 5 can come not only from the underground bunker system 1, but also from the stockyard, other storage bins, etc.

The belt conveyor 2 is located above the plurality of blast furnace material bins 51, and the materials output by the underground material bins 11 in the underground material bin system 1 can be transported to the blast furnace ore trough system 5 through the belt conveyor 2, so as to be supplemented to the corresponding blast furnace material bins 51. The second positioning unit is used for determining the position of the second discharging carriage 23, so that the second discharging carriage 23 can discharge the material on the belt conveyor mechanism 2 to the corresponding blast furnace bin 51. The second discharging carriage 23 is used for discharging the upper material of the belt conveyor 2 to the blast furnace bunker 51 below. The second discharging carriage 23, the second positioning unit 24 and the third load cell 511 are electrically connected with the control unit.

The control unit stores the corresponding type and weight of each blast furnace bunker 51 in the blast furnace ore tank system 5, and the weight of the material in each blast furnace bunker 51 can be updated in real time through the third weighing sensor 511. The control unit may control the blast furnace silo 51 reaching the preset level to open the third feeder 512 or the gate 513 to feed the subsequent screening device as required.

The structure of feed bin among the feeding system in this application not only can be applicable to steelmaking and ironmaking workshop, can also be applicable to the workshop of other material loadings, like mixing proportioning bins, sintering, pelletizing, electric stove, concise, coal injection powder process station, lime kiln etc. its feed bin all can set up weighing sensor. The accurate material type and the accurate material quantity needing to be fed are judged by tracking the reading of the weighing sensor in real time, and the reserve is supplemented by the feeding system in time.

The operation process of the feeding system in the application can be as follows:

the weight of the material in each underground storage bin 11 is read through the first weighing sensor 114, and whether the weight of the material in the underground storage bin 11 meets the feeding requirement of the storage bin in the workshop or not is judged, so that the underground storage bin 11 which does not meet the feeding requirement of the storage bin in the workshop is obtained.

And if the underground storage bin 11 which does not meet the feeding requirement of the storage bin in the workshop is judged to exist, sending information for feeding the underground storage bin 11 which does not meet the feeding requirement of the storage bin in the workshop. At this time, the vehicle transporting the material may be notified to transport the kind and weight of the corresponding material to the underground storage bin system 1. After the vehicle is loaded with the materials, the license plate number and the type of the materials have a corresponding relationship, the control unit sends out the license plate number and corresponding information to the corresponding underground storage bin 11, and a vehicle driver knows the underground storage bin 11 corresponding to self unloading

When the vehicle of transportation material passes through intelligent gate 3, open the corresponding intelligent gate 3 of underground storage bin 11 that does not satisfy the material loading demand of feed bin in the workshop. The storage has the license plate number of the vehicle of transportation material among the control unit, and the license plate number of vehicle is unloaded with own needs underground storage bin has the corresponding relation, and when the vehicle of transportation material was through one of them intelligent gate 3, intelligent gate 3 read the license plate number, and what if the vehicle of transportation material will get into is the corresponding intelligent gate 3 of underground storage bin 11 of the material loading demand of the interior storage bin of unsatisfied workshop, then intelligent gate 3 opens the vehicle that allows the transportation material and unloads through the underground storage bin 11 to the material loading demand of the interior storage bin of unsatisfied workshop. If the vehicle for transporting materials is to enter the intelligent gate 3 corresponding to the underground storage bin 11 meeting the feeding requirement of the storage bin in the workshop, the control unit judges that the vehicle for transporting the materials is to drive into the intelligent gate 3 wrongly through the license plate number of the vehicle and the underground storage bin which needs to unload materials according to the corresponding relation, at the moment, the control unit can control the intelligent gate 3 to be closed and prompt the vehicle for transporting the materials to enter the intelligent gate 3 corresponding to the underground storage bin 11 which does not meet the feeding requirement of the storage bin in the workshop, for example, the intelligent gate 3 can prompt that the vehicle for transporting the materials is to drive into the underground storage bin 11 wrongly and display the correct number of the underground storage bin 11.

After the unloading of the vehicle is completed, the weight of the material in the underground storage bin 11 after the material is replenished is read by the first load cell 114 and sent to the control unit. The control unit updates the weight of the materials in the underground storage bin 11 after supplement in time.

When materials need to be replenished to the steel-making workshop bin 41 in the steel-making workshop bin system 4, the issued operation plan is received at first, and the loading operations are sequenced according to the loading frequency and the loading time priority. The job plan may be made available to the L3 system.

The weight of the material in each of the steelmaking plant bins 41 is read by the second weighing sensor 411, and it is determined whether the weight of the material in the steelmaking plant bin 41 reaches a preset material level, so that the steelmaking plant bin 41 not reaching the preset material level is obtained. In this step, the preset level may be a low level.

If there are steelmaking shop bunkers 41 that do not reach the preset level, the loading schedule of the steelmaking shop bunkers 41 that do not reach the preset level is raised to the highest priority. All the feeding operations are in a queue and are executed from the highest priority to the low priority in sequence until all the feeding operation flows are finished.

When the loading work of the highest priority is started, the position of the first discharging carriage 21 is determined by the first positioning unit 22. The control unit sends an instruction to the first discharging carriage 21 to move the first discharging carriage, and the control unit tracks and knows the position of the first discharging carriage 21 in real time through the first positioning unit 22. The first positioning unit 22 may employ a coded cable positioning system to determine the position of the first tripper car 21 as the first tripper car 21 moves.

When the position of the first discharging carriage 21 reaches the steelmaking workshop bunker 41 with the highest priority in the loading plan, the first feeding machine 115 controlling the corresponding underground bunker 11 in the underground bunker system 1 starts to feed. In the above step, when the position of the first discharge car 21 reaches the steel shop bin 41 of the highest priority in the loading plan, the control unit judges that the position of the first discharge car 21 has arrived through the first positioning unit 22, and then the control unit controls the first discharge car 21 to stop on the belt conveyor 2 above the steel shop bin 41 of the highest priority in the loading plan. Then, the control unit controls the first feeding machine 115 of the corresponding underground silo 11 in the underground silo system 1 to start feeding. The corresponding underground bunker 11 is specifically the underground bunker 11 of the same material type as the highest priority steel plant bunker 41 in the loading plan.

The materials are output to a first unloading vehicle 21 in the steel-making workshop bin system 4 through the belt type conveying mechanism 2, and are unloaded into the steel-making workshop bin 41 with the highest priority in the loading plan through the first unloading vehicle 21.

The weight of the material in the steelmaking plant bin 41 with the highest priority in the feeding plan is read through the second weighing sensor 411, and when the weight of the material in the steelmaking plant bin 41 with the highest priority in the feeding plan meets the requirement, the first feeding machine 115 of the corresponding underground bin 11 in the underground bin system 1 is controlled to stop feeding. For example, when the weight of the material in the steelmaking plant silo 41 with the highest priority in the loading plan reaches a high level, the control unit controls the first feeder 115 of the corresponding underground silo 11 in the underground silo system 1 to stop feeding, and the belt conveyor 2 continues to operate.

After the first feeder 115 controlling the corresponding underground bunker 11 in the underground bunker system 1 stops feeding, the materials already existing on the belt conveyor 2 are continuously output to the first tripper 21 in the steelmaking workshop bunker system 4, and are unloaded into the steelmaking workshop bunker 41 with the highest priority in the feeding plan through the first tripper 21 until the second weighing sensor 411 reads that the weight of the materials in the steelmaking workshop bunker 41 with the highest priority in the feeding plan does not change any more, and then the next feeding operation is started. The first dumper 21 moves to the steelworks bin 41 for the next material type and starts to load the next material.

In the above process, the steelmaking workshop bunker 41 reaching the preset material level may also feed into the converter or the ladle one by one, the second weighing sensor 411 of the corresponding steelmaking workshop bunker 41 weighs the weight of the material in the steelmaking workshop bunker 41 in real time, and when the preset material level is not reached, the feeding plan of the steelmaking workshop bunker 41 not reaching the preset material level is promoted to the highest priority. In this way, when the steel plant bin 41 with the highest priority in the feeding plan is replenished, the steel plant bin 41 reaching the preset level can start the second feeder 412 to feed the converter or the ladle, so that the converter or the ladle can be fed through the steel plant bin system 4 while feeding is performed from the underground bin system 1.

And the MES system of the L3 level issues an operation plan, and the operation plan reaches the L2 level and the L1 level after being decomposed to form a feeding operation queue. According to the weight of materials in an iron-making ore tank, a steel-making high-level bin, a middle-level bin and bins of other systems, the feeding of an underground bin 11 or a stock yard and a storage bin is controlled, if the materials are in emergency shortage, the highest priority of a feeding queue is automatically raised, the feeding is preferentially completed, and the method can complete the feeding operation of various materials according to the queue.

When the materials need to be supplemented to the steelmaking workshop bin 41 in the steelmaking workshop bin system 4, the reduction amount of the materials in the underground bin 11 for supplementing the materials to the steelmaking workshop bin 41 can be obtained through the first weighing sensor 114, the increase amount of the materials in the steelmaking workshop bin 41 for supplementing the materials can be obtained through the second weighing sensor 411, and the natural loss and the actual consumption of the materials can be obtained through statistics based on the reduction amount and the increase amount.

When the materials need to be supplemented to the blast furnace storage bin 51 in the blast furnace ore tank system 5, the assigned operation plan is received, and the loading operation is sequenced according to the loading frequency and the loading time priority. The weight of the material in each blast furnace bunker 51 is read by the third weighing sensor 511, and it is determined whether the weight of the material in the blast furnace bunker 51 reaches the preset material level, so that the blast furnace bunker 51 which does not reach the preset material level is obtained. And the feeding plan of the blast furnace storage bin 51 which does not reach the preset material level is promoted to the highest priority.

When the loading work of the highest priority is started, the position of the second discharging carriage 23 is determined by the second positioning unit 24. When the position of the second discharging car 23 reaches the blast furnace silo 51 with the highest priority in the feeding plan, the first feeding machine 115 controlling the corresponding underground storage silo 11 in the underground storage silo system 1 starts feeding. The material is delivered to the second discharging car 23 in the blast furnace ore tank system 5 through the belt conveyor 2, and is discharged into the blast furnace hopper 51 with the highest priority in the charging plan through the second discharging car 23. The third weighing sensor 511 reads the weight of the material in the blast furnace silo 51 with the highest priority in the loading plan, and when the weight of the material in the blast furnace silo 51 with the highest priority in the loading plan meets the requirement, the first feeder 115 of the corresponding underground storage bin 11 in the underground storage bin system 1 is controlled to stop feeding.

After the first feeding machine 115 controlling the corresponding underground storage bin 11 in the underground storage bin system 1 stops feeding, the materials already existing on the belt type conveying mechanism 2 are continuously output to the second discharging car 23 in the blast furnace ore trough system 5, and are discharged into the blast furnace bin 51 with the highest priority in the feeding plan through the second discharging car 23, until the third weighing sensor 511 reads that the weight of the materials in the blast furnace bin 51 with the highest priority in the feeding plan does not change any more, the next feeding operation is started.

In the above process, the blast furnace silo 51 reaching the preset material level may also sequentially feed the subsequent screening devices, the third weighing sensor 511 of the corresponding blast furnace silo 51 weighs the weight of the material in the blast furnace silo 51 in real time, and when the preset material level is not reached, the feeding plan of the blast furnace silo 51 not reaching the preset material level is raised to the highest priority. In this way, when the blast furnace bunker 51 with the highest priority in the feeding plan is supplemented with material, if the subsequent screening device needs to feed, the blast furnace bunker 51 reaching the preset material level can open the third feeder 512 or the gate 513 to feed the subsequent screening device, so that the feeding from the underground bunker system 1 is realized, and the feeding is performed on the screening device through the blast furnace ore tank system 5.

Similarly, when the blast furnace bunker 51 in the blast furnace ore trough system 5 needs to be supplemented with materials, the reduction amount of the materials in the underground bunker 11 for supplementing the materials to the blast furnace bunker 51 can be obtained through the first weighing sensor 114, the increase amount of the materials in the blast furnace bunker 51 for supplementing the materials can be obtained through the third weighing sensor 511, and the natural loss and the actual consumption of the materials can be obtained through statistics based on the reduction amount and the increase amount.

No matter the steel-making and iron-making workshops or other workshops needing material loading, such as a blending batching tank, a sintering plant, a pelletizing plant, an electric furnace, a refining plant, a coal injection and powder making station, a lime kiln and the like, the material bin can adopt the control process of the material loading system.

This application can be real realize whole unmanned on duty, intelligent operation realizes unmanned participation material loading, greatly reduced workman's intensity of labour. Secondly, the material types and the material amounts of different storage bins needing to be fed can be automatically judged through a weighing sensor, the problem of wrong feeding caused by a manual selection process is avoided, or a material overflow accident is caused by excessive feeding, so that powerful guarantee is provided for long-term stable operation of a feeding system, and compared with the conventional material level meter, the material level meter has the advantages of large error, more faults and incapability of intelligent operation at all; in addition, the intelligent gate 3 with the license plate recognition unit can ensure that vehicles for transporting materials can only enter the corresponding correct underground storage bin 11, so that the problem of material unloading error in the link of only needing personnel to participate is avoided; moreover, the first weighing sensor 114 can accurately track the material quantity of the underground storage bin 11 in real time, so that the material loading vehicle can prepare materials in advance, and the occurrence of material shortage accidents is avoided. Finally, whether spilled materials exist or not can be judged by tracking the feeding amount of the underground storage bin 11 and the feeding amount of the storage bin in the workshop, and the natural loss and the actual consumption of the materials can be counted.

All articles and references disclosed, including patent applications and publications, are hereby incorporated by reference for all purposes. The term "consisting essentially of 8230comprises the elements, components or steps identified and other elements, components or steps which do not materially affect the basic novel characteristics of the combination. The use of the terms "comprising" or "including" to describe combinations of elements, components, or steps herein also contemplates embodiments that consist essentially of such elements, components, or steps. By using the term "may" herein, it is intended to indicate that any of the described attributes that "may" include are optional. A plurality of elements, components, parts or steps can be provided by a single integrated element, component, part or step. Alternatively, a single integrated element, component, part or step may be divided into separate plural elements, components, parts or steps. The disclosure of "a" or "an" to describe an element, ingredient, component or step is not intended to foreclose other elements, ingredients, components or steps.

The embodiments in the present specification are all described in a progressive manner, and each embodiment focuses on differences from other embodiments, and portions that are the same and similar between the embodiments may be referred to each other. The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered in the protection scope of the present invention.

Claims

1. A feeding system, characterized in that the feeding system comprises:

2. The feeding system as recited in claim 1, further comprising:

a steelmaking shop bin system including a plurality of steelmaking shop bins, each of the steelmaking shop bins including: a second bin body; the second bin frame is connected with the second bin body; the second support mechanism is provided with a second weighing sensor, and the lower end of the second bin frame is arranged on the second weighing sensor; a second feeder is arranged at an outlet of the second bin body;

the belt type conveying mechanism is positioned above the plurality of steel-making workshop bins; the first positioning unit is used for determining the position of the first discharging car, so that the first discharging car can discharge materials on the belt conveying mechanism into the corresponding steel-making workshop storage bin;

3. The loading system of claim 2, wherein a portion of said steelmaking shop bins are auxiliary stock bins and a portion of said steelmaking shop bins are ferroalloy bins; the auxiliary raw material bin is positioned at a high position; the ferroalloy bin is positioned at a high position or a middle position.

4. The loading system of claim 1, wherein the underground silo further comprises a first scattering prevention mechanism installed at the opening of the first silo body, the first scattering prevention mechanism is in a tapered shape from top to bottom, and the opening at the uppermost end of the first scattering prevention mechanism is larger than the opening of the first silo body.

5. The feeding system of claim 4, wherein at least some of the underground bunkers are arranged in a straight line in sequence, and gaps between adjacent underground bunkers are overlapped by using a light plate.

6. The loading system of claim 1, further comprising:

a blast furnace ore chute system comprising a plurality of blast furnace bins, each of said blast furnace bins comprising: a third bin body; the third bin frame is connected with the third bin body; the third support mechanism is provided with a third weighing sensor, and the lower end of the three-bin frame is arranged on the third weighing sensor; a third feeder or a gate is arranged at an outlet of the third bin body;

7. The loading system of claim 6, wherein the blast furnace silo further comprises a second scattering prevention mechanism installed at an opening of the third silo body, the second scattering prevention mechanism is in a tapered shape from top to bottom, and an opening at the uppermost end of the second scattering prevention mechanism is larger than an opening of the third silo body.

8. The charging system according to claim 7, wherein at least some of said blast furnace silos are arranged in a straight line in sequence, and gaps between adjacent blast furnace silos are overlapped by using a light plate.

9. The loading system of claim 7, wherein the openings of adjacent second spillage prevention mechanisms are in close proximity.

10. A feeding system according to claim 6, characterized in that the third feeder or the shutter is in a soft connection or is kept in a non-contact state with the subsequent screening device.