WO2023178827A1 - Feeding control method and apparatus, and asphalt stirring station - Google Patents

Feeding control method and apparatus, and asphalt stirring station Download PDF

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Publication number
WO2023178827A1
WO2023178827A1 PCT/CN2022/095564 CN2022095564W WO2023178827A1 WO 2023178827 A1 WO2023178827 A1 WO 2023178827A1 CN 2022095564 W CN2022095564 W CN 2022095564W WO 2023178827 A1 WO2023178827 A1 WO 2023178827A1
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Prior art keywords
cold
aggregate
bin
speed
cold material
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PCT/CN2022/095564
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French (fr)
Chinese (zh)
Inventor
罗洪源
任水祥
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常德市三一机械有限公司
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Publication of WO2023178827A1 publication Critical patent/WO2023178827A1/en

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    • EFIXED CONSTRUCTIONS
    • E01CONSTRUCTION OF ROADS, RAILWAYS, OR BRIDGES
    • E01CCONSTRUCTION OF, OR SURFACES FOR, ROADS, SPORTS GROUNDS, OR THE LIKE; MACHINES OR AUXILIARY TOOLS FOR CONSTRUCTION OR REPAIR
    • E01C19/00Machines, tools or auxiliary devices for preparing or distributing paving materials, for working the placed materials, or for forming, consolidating, or finishing the paving
    • E01C19/02Machines, tools or auxiliary devices for preparing or distributing paving materials, for working the placed materials, or for forming, consolidating, or finishing the paving for preparing the materials
    • E01C19/10Apparatus or plants for premixing or precoating aggregate or fillers with non-hydraulic binders, e.g. with bitumen, with resins, i.e. producing mixtures or coating aggregates otherwise than by penetrating or surface dressing; Apparatus for premixing non-hydraulic mixtures prior to placing or for reconditioning salvaged non-hydraulic compositions
    • E01C19/1059Controlling the operations; Devices solely for supplying or proportioning the ingredients
    • E01C19/1068Supplying or proportioning the ingredients
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B28WORKING CEMENT, CLAY, OR STONE
    • B28CPREPARING CLAY; PRODUCING MIXTURES CONTAINING CLAY OR CEMENTITIOUS MATERIAL, e.g. PLASTER
    • B28C7/00Controlling the operation of apparatus for producing mixtures of clay or cement with other substances; Supplying or proportioning the ingredients for mixing clay or cement with other substances; Discharging the mixture
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65GTRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
    • B65G65/00Loading or unloading
    • EFIXED CONSTRUCTIONS
    • E01CONSTRUCTION OF ROADS, RAILWAYS, OR BRIDGES
    • E01CCONSTRUCTION OF, OR SURFACES FOR, ROADS, SPORTS GROUNDS, OR THE LIKE; MACHINES OR AUXILIARY TOOLS FOR CONSTRUCTION OR REPAIR
    • E01C19/00Machines, tools or auxiliary devices for preparing or distributing paving materials, for working the placed materials, or for forming, consolidating, or finishing the paving
    • E01C19/02Machines, tools or auxiliary devices for preparing or distributing paving materials, for working the placed materials, or for forming, consolidating, or finishing the paving for preparing the materials
    • EFIXED CONSTRUCTIONS
    • E01CONSTRUCTION OF ROADS, RAILWAYS, OR BRIDGES
    • E01CCONSTRUCTION OF, OR SURFACES FOR, ROADS, SPORTS GROUNDS, OR THE LIKE; MACHINES OR AUXILIARY TOOLS FOR CONSTRUCTION OR REPAIR
    • E01C19/00Machines, tools or auxiliary devices for preparing or distributing paving materials, for working the placed materials, or for forming, consolidating, or finishing the paving
    • E01C19/02Machines, tools or auxiliary devices for preparing or distributing paving materials, for working the placed materials, or for forming, consolidating, or finishing the paving for preparing the materials
    • E01C19/10Apparatus or plants for premixing or precoating aggregate or fillers with non-hydraulic binders, e.g. with bitumen, with resins, i.e. producing mixtures or coating aggregates otherwise than by penetrating or surface dressing; Apparatus for premixing non-hydraulic mixtures prior to placing or for reconditioning salvaged non-hydraulic compositions

Definitions

  • This application relates to the field of mechanical control technology, and in particular to a feeding control method and device, and an asphalt mixing station.
  • Asphalt mixing plant is a complete set of equipment used for batch production of asphalt concrete.
  • the main feeding operation of the asphalt mixing station is manually operated by the operator.
  • the feeding speed of the cold silo needs to be controlled by the operator based on manual experience. This method of relying on manual experience to control the feeding speed of the cold silo is not precise.
  • This application provides a feeding control method and device, as well as an asphalt mixing station, to solve the defect in the existing technology that relies on manual experience to control the feeding speed of the cold silo, and to realize the loading of each cold silo.
  • the speed is accurately controlled automatically and independently, with higher reliability.
  • This application provides a feeding control method, including:
  • each cold material bin is used to supply material to each aggregate bin;
  • the cold material data model includes the cold material data of each cold material bin. The content of each aggregate in the material;
  • the loading of each cold silo is controlled.
  • the target loading speed of each cold material bin is determined based on the cold material data model, including:
  • the target feeding speed of each cold silo is determined.
  • calculating the current feeding speed of each cold feed bin based on the cold feed data model includes:
  • the unloading speed and material level change rate of each aggregate bin is calculated.
  • the current feeding speed of each cold material bin is calculated based on the cold material data model, the unloading speed and the material level change rate of each aggregate bin.
  • each aggregate bin For each aggregate bin, obtain the cold material supply priority corresponding to the aggregate in the aggregate bin, and determine at least one of the cold material supply priorities for the aggregate bin based on the cold material supply priority.
  • the cold material bin with the highest priority of cold material in the cold material bin is based on the unloading speed and material level change rate of the aggregate bin and the cold material of the cold material bin with the highest priority.
  • the aggregate content in the aggregate bin determines the current feeding speed of the cold material bin with the highest priority;
  • the cold material supply priority is determined according to the aggregate content of the aggregate bin in the cold material of each cold material bin, and the aggregate content of the aggregate bin in the cold material of the cold material bin. The greater the material content, the higher the priority of the cold material in the cold material bin.
  • the said aggregate bin is based on the discharging speed and material level change rate of the aggregate bin and the cold material of the cold bin with the highest priority.
  • the content of the aggregate determines the current feeding speed of the cold silo with the highest priority, including:
  • the current feeding speed of the cold hopper with the highest priority is determined.
  • the method is based on the unloading speed of the aggregate bin and the aggregate content of the aggregate bin in the cold material of the cold bin with the highest priority. , determine the first speed corresponding to the cold silo with the highest priority, including:
  • the cold material with the highest priority is determined based on the ratio of the unloading speed of the aggregate bin to the aggregate content of the cold material in the cold material bin with the highest priority.
  • a feeding control method provided by this application, it also includes:
  • Determining, based on the cold material supply priority, the cold material silo with the highest priority of cold material in at least one of the cold material silos supplying the aggregate silo including:
  • the available cold material bin is the cold material bin whose material level value is greater than the preset material level value and/or the supply status indicates that the material is available .
  • obtaining the discharging speed of each aggregate bin includes:
  • the unloading speed of each of the aggregate bins is obtained.
  • the preset material level interval includes a first material level interval, a second material level interval and a third material level interval in which the material level value increases in sequence;
  • Determining the target feeding speed of each cold silo based on the current feeding speed of each cold silo and the comparison results includes:
  • the current feeding speed of at least one of the cold material bins that supplies materials to the aggregate bin is increased to obtain the The target feeding speed of at least one of the cold silos supplied by the silos;
  • the current feeding speed of at least one cold material silo that supplies material to the aggregate silo will be used as the supply speed for the aggregate silo.
  • the current feeding speed of at least one of the cold material bins that supplies materials to the aggregate bin is reduced to obtain the The target feeding speed of at least one of the cold silos supplied by the aggregate silo.
  • determining the target feeding speed of each cold silo based on the current feeding speed of each cold silo and the result of each comparison also includes:
  • the aggregate supply priority is determined according to the demand for aggregates in each of the aggregate bins. The greater the demand for aggregates in the aggregate bins, the higher the demand for aggregates in the aggregate bins. The higher the priority of the aggregate;
  • the target feeding speed of at least one cold silo that supplies at least one aggregate silo with the lowest priority is reduced so that the total speed is less than or equal to the preset speed upper limit.
  • the demand for aggregates in each aggregate bin is determined based on the proportion of each aggregate in the production formula.
  • This application also provides a feeding control device, including:
  • the speed determination module is used to determine the target feeding speed of each cold material bin based on the cold material data model; each cold material bin is used to supply material to each aggregate bin; the cold material data model includes each Describe the content of each aggregate in the cold material in the cold material bin;
  • a loading control module is used to control the loading of each cold silo based on the target loading speed of each cold silo.
  • This application also provides an asphalt mixing station, including an asphalt mixing station body and a controller, and the controller is used to implement any of the above feeding control methods.
  • This application also provides an electronic device, including a memory, a processor, and a computer program stored in the memory and executable on the processor.
  • the processor executes the program, it implements any one of the above mentioned feeding controls. method.
  • This application also provides a non-transitory computer-readable storage medium on which a computer program is stored.
  • a computer program is stored on which a computer program is stored.
  • the computer program is executed by a processor, any one of the above feeding control methods is implemented.
  • the present application also provides a computer program product, which includes a computer program.
  • a computer program product which includes a computer program.
  • the computer program When executed by a processor, it implements any one of the above feeding control methods.
  • the material loading control method and cold material data model provided by this application can provide the content of each aggregate contained in the cold material in the cold material silo, and can accurately reflect the differences in the composition of different cold materials, providing a basis for the loading of the cold material silo.
  • Speed control provides a data basis. Based on the cold material data model, the target feeding speed of each cold material bin can be determined, and then the loading of each cold material bin can be automatically controlled, which solves the problem of relying on manual experience to control the cold material bin in the existing technology. The problem of inaccurate feeding speed has been realized.
  • the feeding speed of each cold material bin can be accurately and automatically controlled independently, with higher reliability.
  • the feeding speed of multiple cold silos can be quickly adjusted in real time, and the control is more timely, avoiding shortages or overflows, thereby improving production efficiency. , reducing losses and lowering costs.
  • FIG 1 is one of the flow diagrams of the feeding control method provided by this application.
  • FIG. 2 is a schematic structural diagram of the feeding control system provided by this application.
  • FIG. 3 is the second schematic flow chart of the feeding control method provided by this application.
  • FIG. 4 is a schematic structural diagram of the feeding control device provided by this application.
  • Figure 5 is a schematic structural diagram of an electronic device provided by this application.
  • the method of controlling the loading speed of cold material in the cold material silo based on manual experience is not accurate and prone to errors. Because the cold material silo is far away from the operation room, it is impossible to accurately judge the situation of the cold material silo in a timely manner. In various situations, When cold materials are loaded at the same time, the operation will be restricted. It is not easy to quickly adjust the feeding speed of various cold material bins. It is easy to cause shortage or overflow caused by untimely loading, which reduces production efficiency. Increase losses, thereby increasing costs.
  • cold material silos some manufacturers require cold material silos to be fixed when loading cold materials.
  • the cold material system has 6 cold material silos, and each cold material warehouse stores different cold materials.
  • the six cold materials are individually numbered. That is, 1# cold material, 2# cold material, 3# cold material, 4# cold material, 5# cold material and 6# cold material.
  • 6 aggregate bins are set up to store 1# to 6# aggregates respectively. , when the 1# aggregate is missing, start the 1# cold material loading, when the 2# aggregate is missing, start the 2# cold material loading, and so on. This method is inflexible and requires that the number of the cold material strictly corresponds to the number of the aggregate.
  • this application provides a cold material loading method that accurately realizes automatic control of the target feeding speed of each cold material bin. It can be applied to asphalt mixing stations and executed by the software and/or hardware in the asphalt mixing stations. , exemplarily, it can be executed by a controller, which can control various parts of the material loading control system.
  • the controller can be, but is not limited to, a programmable logic controller (Programmable Logic Controller, PLC) or a single-chip microcomputer.
  • FIG 1 is one of the flow diagrams of the feeding control method provided by this application.
  • this embodiment provides a feeding control method, which at least includes:
  • Step 101 Based on the cold material data model, determine the target feeding speed of each cold material bin; each cold material bin is used to supply materials to each aggregate bin; the cold material data model includes each cold material in each cold material bin. Aggregate content.
  • the target feeding speed is the feeding speed that needs to be controlled by the cold material bin.
  • Cold materials generally contain aggregates of different particle sizes.
  • the content of each aggregate in the cold material can be understood as the content of each aggregate contained in the cold material.
  • the content of aggregates can be the aggregate content in the cold material.
  • the weight ratio can also be the volume ratio of aggregate in cold material, etc.
  • the particle sizes of aggregates stored in each aggregate bin are different.
  • the cold material is stored in the cold material bin, and the cold material in the cold material bin can be transported to a screen (such as a vibrating screen, etc.), and then the screen will subdivide the cold material into aggregates of different particle sizes.
  • a screen such as a vibrating screen, etc.
  • These different particles Aggregates with different particle sizes can enter the aggregate silo with corresponding particle size, thereby realizing the cold material silo supplying the aggregate silo.
  • the material loading control system shown in Figure 2 includes a host computer (such as a computer), a controller electrically connected to the host machine, multiple cold material bins and multiple aggregate bins, together with the multiple cold material bins.
  • a plurality of motors (indicated by M in the figure) connected in a one-to-one manner, a plurality of frequency converters electrically connected to a plurality of motors in a one-to-one correspondence, a plurality of feeding belts corresponding to a plurality of cold material silos, and multiple Each feeding belt corresponds to the conveyor belt, roller, elevator and vibrating screen.
  • the controller is electrically connected to each frequency converter.
  • the figure shows 6 cold material silos and they are numbered, namely No. 1 cold material silo, No.
  • the bins are represented by 6 aggregate bins and are numbered, namely No. 1 aggregate bin, No. 2 aggregate bin, No. 3 aggregate bin, No. 4 aggregate bin, No. 5 aggregate bin and No. 6 aggregate bin. warehouse.
  • the controller can control the speed of the motor by controlling the frequency of the frequency converter, thereby controlling the loading speed of the cold material bin, and passing the cold material in the cold material bin into vibration through the feeding belt, conveyor belt, roller, and elevator.
  • Screen through the vibration of the vibrating screen, the cold material is subdivided into aggregates of different particle sizes and enters the aggregate bin of corresponding particle sizes. Among them, the cold material enters the elevator through the discharge port of the drum.
  • the cold material data model can be obtained first.
  • the pre-stored cold material data model can be obtained locally, or through The cold material data model stored in the cloud can be downloaded online, and the cold material data model input manually can also be obtained.
  • the above cold material data model can be stored in the local host computer.
  • the controller can obtain the cold material data model from the host computer.
  • Step 102 Control the loading of each cold silo based on the target loading speed of each cold silo.
  • the cold material data model can provide the content of each aggregate contained in the cold material in the cold material silo, can accurately reflect the differences in the composition of different cold materials, and provide a method for controlling the loading speed of the cold material silo.
  • the target feeding speed of each cold silo can be determined based on the cold material data model, and then the loading of each cold silo can be automatically controlled, which solves the problem of relying on manual experience in the existing technology to control the loading speed of the cold silo. Accurate questions realize accurate automatic independent control of the feeding speed of each cold material bin, with higher reliability.
  • the feeding speed of multiple cold silos can be quickly adjusted in real time, and the control is more timely, avoiding shortages or overflows, thereby improving production efficiency. , reducing losses and lowering costs.
  • one cold silo can supply materials to multiple aggregate silos, and one aggregate silo can also be fed by multiple cold silos. There is no need to require a certain cold silo to be fixed as When an aggregate silo supplies materials, based on the content of each aggregate contained in the cold material in the cold silo provided by the cold material data model, the feeding speed can be controlled accurately and more reliably.
  • the target feeding speed of each cold material bin is determined, as shown in Figure 3.
  • Specific implementation methods may include:
  • Step 301 Obtain the material level value of each aggregate bin.
  • a material level meter in the feeding control system, can be set in each aggregate bin (the strip structure in each aggregate bin is shown in the figure).
  • the material level meter is used to detect the level in the aggregate bin in real time.
  • the material level value is sent to the controller.
  • the controller can obtain the material level value of the aggregate bin based on the detection results of the material level meter.
  • Step 302 Calculate the current feeding speed of each cold material bin based on the cold material data model.
  • the specific implementation of this step may include: obtaining the unloading speed and material level change rate of each aggregate bin; based on the cold material data model, the unloading speed and material level change rate of each aggregate bin, calculating the Current loading speed.
  • the discharging speed of the aggregate bin can be obtained based on the weight of the aggregate measured by the weighing scale corresponding to each aggregate bin and the weighing cycle.
  • the loading control system also includes a weighing scale.
  • the weighing scale can weigh the weight of the aggregate during unloading of the aggregate bin according to the preset time period and send it to the controller. For example, the ratio of the weight of the aggregate measured by the weighing scale to the weighing cycle can be used as the discharging speed of the aggregate bin. In this way, the discharge speed of the aggregate bin can be accurately obtained.
  • the controller can also obtain the material level change rate of the aggregate bin based on the detection results of the material level meter.
  • the material level change rate is the ratio of the difference between the material level value at the current moment and the material level value at the previous moment and the time change of the two moments.
  • the unloading speed and material level change rate of each aggregate bin is calculated. Specifically, it can include: for each aggregate bin, obtain the data related to the aggregate bin.
  • the cold material supply priority corresponding to the aggregate is based on the cold material supply priority.
  • the cold material silo with the highest priority among at least one cold material silo supplying the aggregate silo is determined based on the unloading speed of the aggregate silo.
  • the current feeding speed of the cold material silo with the highest priority is determined; among them, the cold material supply priority is based on each
  • the cold material in the cold material bin is determined by the aggregate content in the aggregate bin. The greater the aggregate content in the cold material in the cold material bin, the higher the priority of the cold material in the cold material bin.
  • the cold material data model can include the corresponding relationship between the cold material, each aggregate in the cold material, and the content of each aggregate.
  • the cold material data model can contain a variety of cold materials, and the content (weight ratio or volume ratio) of each aggregate in each cold material is arranged in order from large to small.
  • the number of each cold material and the corresponding number and content of each aggregate are recorded.
  • six kinds of cold materials are represented, namely cold materials No. 1 to No. 6.
  • Each cold material includes the content of No. 1 aggregate, the content of No. 2 aggregate, the content of No. 3 aggregate, etc.
  • the content of these aggregates is relatively high, and the content of other aggregates is relatively low, which has a small impact on the feeding speed. Therefore, the influence of these aggregates can be ignored, thus Obtain the aggregates with the highest content in the cold material data model, that is, focus on the main aggregates to simplify the cold material data model.
  • the simplified cold material data model as shown in Table 2, is represented by six types of cold materials, namely cold materials No. 1 to No. 6. Each cold material corresponds to the three highest-content aggregates.
  • the aggregate content of the cold materials in each cold bin can be found from the cold material data model and sorted, and the aggregate bin is determined based on the sorting results.
  • the cold material supply priority corresponding to the aggregate is. The greater the aggregate content of the cold material in the cold material bin, the higher the priority of the cold material in the cold material bin.
  • Table 3 which shows the cold material supply priority corresponding to each aggregate from No. 1 aggregate to No. 6 aggregate.
  • the optimal cold material supply that is, the cold material with the highest priority
  • the second-best cold material supply i.e. the cold material with the second highest priority
  • the cold material supplied last i.e. the cold material with the lowest priority
  • the best The cold material supplied is No. 1 cold material
  • the second best cold material supplied is No. 3 cold material
  • the last cold material supplied is No. 2 cold material.
  • the optimal cold material supply is 2. No. 1 cold material, the second best cold material supply is No. 1 cold material, the last cold material supplied is No. 5 cold material, and so on. Based on this, for example, the cold materials supplying No. 1 aggregate to the No. 1 aggregate bin include No. 6 cold materials, No. 2 cold materials and No. 1 cold materials, then the cold materials of No. 6 cold materials with the highest priority are determined. Silo.
  • the current loading of the cold silo with the highest priority is determined based on the unloading speed and material level change rate of the aggregate silo and the aggregate content of the cold material in the cold silo with the highest priority.
  • Speed specifically can include:
  • the first step is to determine the first speed corresponding to the cold silo with the highest priority based on the unloading speed of the aggregate silo and the aggregate content of the aggregate silo in the cold silo with the highest priority.
  • the first speed corresponding to the cold silo with the highest priority can be determined based on the ratio of the unloading speed of the aggregate silo to the aggregate content of the cold silo in the cold silo with the highest priority.
  • the ratio of the unloading speed of the aggregate silo to the aggregate content of the aggregate silo in the cold silo with the highest priority can be used as the first speed corresponding to the cold silo with the highest priority.
  • the ratio of the unloading speed of the aggregate silo to the aggregate content of the aggregate silo in the cold silo with the highest priority can also be multiplied by a set coefficient as the first speed corresponding to the cold silo with the highest priority.
  • the second step is to determine the second speed corresponding to the cold silo with the highest priority based on the material level change rate of the aggregate silo.
  • the material level change rate of the aggregate silo can be used as the second speed corresponding to the cold silo with the highest priority.
  • the material level change rate of the aggregate silo can also be multiplied by the set coefficient as the second speed corresponding to the highest cold silo.
  • the third step is to determine the current feeding speed of the cold silo with the highest priority based on the first speed and the second speed.
  • the current feeding speed of the cold silo with the highest priority can be determined based on the first speed and the second speed according to a preset algorithm. For example, the first speed and the second speed can be summed to obtain the current feeding speed of the cold silo with the highest priority. You can also average the first speed and the second speed to obtain the current loading speed of the cold silo with the highest priority.
  • Step 303 Compare the material level value of each aggregate bin with the preset material level interval.
  • the preset material level intervals corresponding to each aggregate bin can be preset, and the preset material level intervals corresponding to each aggregate bin can be the same or different. Since the demand for aggregates in each aggregate bin may be different, setting the preset material level interval corresponding to each aggregate bin separately will make the control more accurate. It can receive the preset material level interval input by the user, and can also automatically determine the preset material level interval based on the demand for aggregates in the production formula.
  • the production formula generally contains the required proportion of each aggregate, and the proportion of the aggregate can represent the demand for the aggregate. For example, the corresponding relationship between the demand for aggregate and the preset material level interval can be set in advance, and the preset material level interval corresponding to the demand for aggregate is determined based on the correspondence.
  • Step 304 Determine the target feeding speed of each cold silo based on the current feeding speed of each cold silo and the results of each comparison.
  • the preset material level interval may include a first material level interval, a second material level interval and a third material level interval in which the material level value increases sequentially. Then, based on the current feeding speed of each cold silo and the results of each comparison, determine the target feeding speed of each cold silo, which may include:
  • the current feeding speed of at least one cold silo supplying material to the aggregate silo is increased to obtain at least one cold silo supplying material to the aggregate silo. target feeding speed. If the material level value of the aggregate bin is within the first material level interval, it means that there is less aggregate in the aggregate bin and more aggregate needs to be added to avoid material shortage. At this time, the current feeding speed can be increased.
  • the current feeding speed of at least one cold silo supplying material to the aggregate silo will be used as the target of at least one cold silo supplying material to the aggregate silo. Feeding speed. If the material level value of the aggregate bin is within the second material level range, it means that the aggregate in the aggregate bin is more suitable and the current feeding speed can be maintained.
  • the current feeding speed of at least one cold material silo that supplies material to the aggregate silo is reduced to obtain at least one cold material that supplies material to the aggregate silo.
  • the current feeding speed of the cold material bin can be reduced or increased according to the preset step length.
  • the specific value of the preset step length can be set according to the actual situation, and is not specifically limited here.
  • the current feeding speed of the cold material bin can also be reduced or increased based on other methods, which will not be listed here.
  • the content of each aggregate in the cold material provided in the cold material data model, as well as the unloading speed, material level value and material level change rate of each aggregate bin are comprehensively considered to accurately measure
  • the current feeding speed of each cold silo is determined based on the comparison between the material level value of each aggregate silo and the preset material level interval, and the target feeding speed of each cold silo is determined to accurately realize the loading of the cold silo. Quantitative control of feeding speed.
  • the material loading control method may also include: detecting the material level value of each cold material bin and/or a supply status indicating whether material is available; accordingly, based on the cold material supply priority, determine the aggregate
  • the cold silo with the highest priority of cold material in at least one cold silo supplied by the warehouse may include: based on the cold material supply priority, and based on the material level value of each cold silo and/or indicating whether material is available supply status, determine the cold silo with the highest priority of cold material in at least one available cold silo that supplies materials to the aggregate silo.
  • the available cold silo has a material level value greater than the preset material level value and/or supply The status represents the cold silo available for feeding.
  • a material level meter can be set up in the cold material bin to detect the material level value of the cold material bin. If the material level value of the cold material bin is greater than the preset material level value, it means that the cold material in the cold material bin is sufficient. , if the material level value of the cold material bin is less than or equal to the preset material level value, it means that the cold material bin is about to be short of material.
  • a proximity sensor can also be set at the bottom of the cold silo to detect the supply status of the cold silo. If the cold silo is empty, the material cannot be supplied. At this time, the proximity sensor can send an electrical signal to the controller that no object is approaching. , the controller can determine that the supply status of the cold silo is unavailable to prevent idling, otherwise, it can determine that the supply status of the cold silo is available.
  • the available cold material bins can be prioritized, that is, the cold material bins whose material level value is greater than the preset material level value and/or the supply status indicates the available materials, to supply materials to the aggregate bin to avoid The shortage of materials affects production.
  • the cold material bin is less than or equal to the preset material level value and/or is unavailable, it can automatically switch to the cold material bin with the highest priority of available cold material.
  • the cold material supply priority can be determined by the cold material supply priority corresponding to the aggregate.
  • the cold material bin with the highest priority for cold materials i.e., optimal cold material supply
  • determining the target feeding speed of each cold silo based on the current feeding speed of each cold silo and the results of each comparison may also include:
  • the first step is to obtain the aggregate supply priority.
  • the aggregate supply priority is determined according to the demand for aggregates in each aggregate bin. The greater the demand for aggregates in the aggregate bin, the higher the demand for aggregates in the aggregate bin. The higher the priority.
  • the demand for aggregates in each aggregate bin can be determined based on the proportion of each aggregate in the production formula. Based on this, the pre-stored production formula can be obtained, and the proportion of each aggregate required in the production formula can be sorted. Based on the sorting results, the priority of aggregate supply is determined. The greater the demand for aggregates in the aggregate bin, the higher the aggregate demand. The higher the priority of the aggregates in the bin.
  • the aggregate supply priority can also be entered manually and stored.
  • the second step is to determine the sum of the target feeding speeds of each cold material bin to obtain the total speed.
  • Step 3 If the total speed is greater than the preset speed limit, based on the aggregate supply priority, determine at least one aggregate bin with the lowest priority among the aggregate bins.
  • the fourth step is to reduce the target feeding speed of at least one cold silo that supplies at least one aggregate silo with the lowest priority, so that the total speed is less than or equal to the preset speed upper limit.
  • the load that the loading control system can load is limited. Therefore, it is necessary to control the target loading speed of each cold material bin within the load range.
  • the sum of the target loading speeds of each cold silo can reflect the total load loaded by the loading control system. If the total speed exceeds the preset speed upper limit, the loading control system will not be able to bear it. In this case, you can consider
  • the demand for aggregates gives priority to the supply of aggregates with large demand, and reduces the supply of aggregates with small demand. Based on this, the above-mentioned aggregate supply priority is set. The greater the demand for aggregates in the aggregate silo, the higher the demand for aggregates in the aggregate silo.
  • the higher the priority of the aggregate if the total speed of the determined target feeding speed of each cold silo is greater than the preset speed limit, then according to the aggregate supply priority, at least one aggregate silo with the lowest priority will be The target feeding speed of at least one cold silo of the supplied material is reduced so that the total speed is less than or equal to the preset speed upper limit, thereby further ensuring continuous production.
  • the target feeding speed of at least one cold silo that supplies at least one aggregate silo with the lowest priority is reduced so that the total speed is less than or equal to the preset speed upper limit. Specifically, it can be reduced first The target loading speed of a cold silo with the lowest priority. If the target loading speed of the cold silo with the lowest priority is reduced to zero, then reduce the target loading speed of the cold silo with the next lowest priority. speed, and so on, until the total speed is less than or equal to the preset speed upper limit. In this way, aggregates with high priority can be supplied first.
  • the type of cold material in the cold material bin may be determined according to the user's first input operation. Because the raw materials of cold materials may come from different geological areas and other factors, the composition of the cold materials formed will be different. In practical applications, the content of each aggregate in various cold materials can be obtained in advance to build a cold material data model. Users can select the type of cold material in the cold material silo through input operations according to production needs. Based on the selected type of cold material in the cold material silo, each aggregate in the cold material in the cold material silo is obtained from the cold material data model. content, production is more flexible.
  • the contents of different aggregates in the cold material of the cold material bin may be updated according to the user's second input operation.
  • the cold material supply priority corresponding to the aggregate will also change. This embodiment is suitable for situations where there are fewer types of cold materials on site. If there is no cold material with the highest priority in the cold material supply priority corresponding to the aggregate, cold materials of the same type as those in other cold material bins can be used. To replace, you can update the content of different aggregates in the cold material used for replacement through input operations. The cold material used for replacement becomes the cold material with the highest priority in the cold material supply priority corresponding to the aggregate. At this time, the same cold material is placed in multiple cold materials. However, the cold material supply priority corresponding to the aggregate can be changed by manually adjusting the aggregate content in the cold material data model so that the same cold material is installed. Different cold silos of materials become the optimal suppliers of different aggregates, rather than the optimal suppliers of the same aggregate.
  • the cold material data model can be constructed in the following manner: transport the cold material in the target cold material bin to multiple aggregate bins, where each aggregate in the cold material enters the corresponding aggregate bin respectively; Detect the storage amount of each aggregate in the cold material in the corresponding aggregate bin; determine the content of each aggregate in the cold material based on the storage amount of each aggregate in the cold material; build a cold material based on the content of each aggregate in the cold material Material data model.
  • the target cold material bin here is the cold material bin where the content of each aggregate in the cold material is currently to be determined. Both the cold material silo and the aggregate silo are existing in the asphalt mixing plant. Refer to the material loading control system in the asphalt mixing plant shown in Figure 2.
  • the cold material in the cold material silo can be transported to multiple aggregate bins.
  • the existing asphalt mixing station can be used to automatically construct the cold material data model without the need for other professional equipment.
  • the operation is simple and has strong generalizability.
  • transporting the cold material in the target cold material bin to multiple aggregate bins includes: transporting the cold material in the target cold material bin to a screen, and screening each aggregate in the cold material through the screen. Divide into corresponding aggregate bins.
  • the screen has a screening function and is used to screen the cold material into aggregates of different particle sizes, and then store them into aggregate bins of corresponding particle sizes.
  • the screen here can be a vibrating screen. In this way, each aggregate of the cold material can be accurately distinguished.
  • the specific implementation method may include: using a weighing scale to detect the weight of each aggregate in the cold material in the corresponding aggregate bin; or, using the material The level meter detects the material level value of each aggregate in the cold material in the corresponding aggregate bin.
  • the loading control system has a weighing scale corresponding to the aggregate bin.
  • the aggregates in each aggregate bin can be discharged to the weighing scale in sequence, and the currently discharged weight can be weighed by the weighing scale.
  • the weight of the aggregate as the storage capacity, is obtained as w 1 , w 2 , w 3 , w 4 , w 5 , w 6 ,... w n , w n represents the bone in the n aggregate bin in the n aggregate bins The weight of the material.
  • the material level meter in each aggregate bin can also be used to detect the material level value of the aggregate in the aggregate bin, as the storage amount, that is, L 1 , L 2 , L 3 , L 4 , L 5 , L 6 ... ...L n , L n represents the material level value of the aggregate in the n aggregate bin in n aggregate bins, and the material level value can reflect the volume of the aggregate.
  • the content of each aggregate in the cold material is determined based on the storage capacity of each aggregate in the cold material.
  • the implementation method may include: summing the storage capacity of each aggregate to obtain the total storage capacity; based on the storage capacity of each aggregate The ratio of storage capacity to total storage capacity determines the content of each aggregate.
  • the ratio of the aggregate storage capacity to the total storage capacity can be directly used as the aggregate content.
  • the storage capacity of aggregate is the weight of aggregate
  • the storage capacity of aggregate is the material level value of the aggregate
  • L k is the material level value of the kth aggregate. Based on this, the content of aggregate is the volume proportion of aggregate.
  • the ratio of the aggregate storage amount to the total storage amount can also be multiplied by a set coefficient as the aggregate content.
  • the storage volume of each aggregate can be accurately obtained, and then the content of each aggregate in the cold material can be accurately obtained.
  • the cold material in the target cold silo is transported to multiple aggregate silos.
  • the specific implementation may include: transporting the cold material in the target cold silo according to the preset loading time or the preset The total amount of material is transported to multiple aggregate bins.
  • this embodiment provides two ways to transport cold materials to multiple aggregate bins.
  • One way is to continue loading for a preset loading time, and then stop loading.
  • the other way is to continue loading for a preset loading time, and then stop loading.
  • the first method is to load materials according to the preset total amount of materials, and stop loading after reaching the preset total amount of materials.
  • the cold materials of the preset total amount of materials can be weighed in advance and put into the cold material bin.
  • the preset feeding time and the preset total amount of feeding can be set based on empirical statistics, and there are no specific limitations here.
  • a cold material data model is constructed based on the content of each aggregate in the cold material.
  • the specific implementation may include: sorting the content of each aggregate in the cold material; building a cold material data model based on the sorting results. .
  • before transporting the cold material in the target cold silo to multiple aggregate silos it may also include: selecting one cold silo as the target in a preset order for the multiple cold silos. Cold silo.
  • a variety of cold materials can be stored in multiple cold material silos. Based on this, the content of each aggregate in the cold material can be determined for each cold material. Based on the content of each aggregate in the cold material in multiple cold material silos, The content of the cold material is determined and a cold material data model is constructed. In this way, a very comprehensive cold material data model containing the content of each aggregate in a variety of cold materials can be quickly obtained.
  • cold material bin No. 1 among the six cold material bins can be selected as the target cold material bin, and cold material No. 1 among them can be loaded according to the preset
  • the duration and preset feeding speed are transported to multiple aggregate bins, and then the feeding is stopped.
  • the No. 2 cold material bin is selected as the target cold material. warehouse, and transport the No. 2 cold material to multiple aggregate warehouses according to the preset loading time and preset loading speed. In this way, until all 6 cold material warehouses are selected, the cold materials in the 6 cold material warehouses are obtained.
  • the content of each aggregate in the material is determined to complete the automatic construction of the cold material database.
  • the controller is electrically connected to each material level gauge and each frequency converter.
  • the controller may be a PLC, and the host computer may be a computer.
  • material level meters and proximity sensors can also be installed in the cold material bin.
  • the host computer can store cold material data models, production recipes and preset material level intervals, and can also display production status in real time, such as the loading speed of the cold material bin.
  • the preset material level intervals include the accelerated loading material level interval add_zone (i.e., the above-mentioned first material level interval), the fixed frequency material level interval static_zone (i.e., the above-mentioned second material level interval), and the decelerated loading material level interval sub_zone (i.e. The above third material level interval) and full material level stop_line and other material level marks.
  • the full material level is used to trigger the full material prompt.
  • the type of cold material for production can be selected from the cold material data model through the computer.
  • the first step is to automatically capture device information and device status through the program.
  • the equipment status includes the operating status of belts, rollers, vibrating screens, etc. If the operating status is on, the prerequisites for adaptive feeding are met.
  • the equipment information includes the preset upper limit frequency selected according to the model of the asphalt mixing station, that is, the upper limit allowed by the sum of the frequencies of all frequency converters, which can be converted into the above-mentioned preset maximum speed.
  • the second step is to download the cold material data model, production formula and preset material level interval through host computer interaction, and determine the aggregate supply priority based on the proportion of each aggregate in the production formula. Based on the cold material data model, establish the aggregate Corresponding cold material supply priority.
  • the third step is to automatically obtain the cold material supply status.
  • the fourth step is to automatically obtain the material level values L 1 , L 2 , L 3 , L 4 , L 5 , and L 6 of the material level meters of different aggregate bins, based on the cold material data model and the discharge speed of each aggregate bin. and material level change rate, calculate the current feeding speed of each cold material bin, compare the material level value of each aggregate bin with the preset material level interval, based on the current material loading speed of each cold material bin and the results of each comparison , determine the target feeding speed of each cold material bin.
  • the unloading speed of the aggregate silo can be obtained based on the weight of the aggregate measured by the weighing scale corresponding to the aggregate silo and the elapsed time since the last weighing.
  • the sum of the target feeding speeds of each cold material bin can also be determined to obtain the total speed. If the total speed is greater than the preset speed upper limit, based on the aggregate supply priority, at least one aggregate bin with the lowest priority of aggregate among multiple aggregate bins is determined. The target feeding speed of at least one cold silo feeding at least one aggregate silo with the lowest priority is reduced so that the total speed is less than or equal to a preset speed upper limit.
  • Step 5 The controller controls the frequency corresponding to the inverter output of the cold silo based on the final target loading speed of each cold silo.
  • Step 6 The frequency converter controls the output of the motor to adjust the loading speed of the cold material bin.
  • the feeding speed of various cold materials can be quickly and automatically adjusted, thereby achieving the goal of stabilizing the material level of the aggregate bin and preventing material shortage and overflow; 2)
  • the raw material requirements for cold materials are low, and the operation method is flexible.
  • the type of cold materials can be quickly changed through the computer, thereby completing the matching of types of cold materials in different regions; 3)
  • the production process can be completed When the medium cold material is short of material, it will automatically switch to replace the cold material to prevent the lack of material from affecting production; 4)
  • the content of the aggregate in the cold material data model can be adjusted to adjust the order of the cold material supply priority corresponding to the aggregate, so that the cold material supply priority sequence can be adjusted.
  • One kind of cold material can be supplied to multiple types of aggregates to achieve automatic production; 5) The supply of cold materials can be automatically controlled based on changes in the material level value of the aggregate bin, thereby reducing overflow when multiple types of cold materials are used to supply one type of aggregate. Probability; 6) Through the equipped cold material data model, the type of cold material supply can be selected and replaced according to the actual production situation; 7) The preset material level interval can be set manually or automatically according to the production formula.
  • the feeding control device provided by the present application will be described below.
  • the feeding control device described below and the feeding control method described above may be mutually referenced.
  • FIG. 4 is a schematic structural diagram of the feeding control device provided by this application.
  • this embodiment provides a feeding control device, including:
  • the speed determination module 401 is used to determine the target feeding speed of each cold material silo based on the cold material data model; each cold material silo is used to supply materials to each aggregate silo; the cold material data model includes the data of each cold material silo. The content of each aggregate in the cold mix;
  • the loading control module 402 is used to control the loading of each cold silo based on the target loading speed of each cold silo.
  • the speed determination module is specifically used for:
  • the target feeding speed of each cold silo is determined.
  • the speed determination module is specifically used for:
  • the unloading speed and material level change rate of each aggregate bin is calculated.
  • the speed determination module is specifically used for:
  • each aggregate bin For each aggregate bin, obtain the cold material supply priority corresponding to the aggregate in the aggregate bin. Based on the cold material supply priority, determine the highest priority of cold material in at least one cold material bin that supplies material to the aggregate bin.
  • cold silo based on the unloading speed and material level change rate of the aggregate silo and the aggregate content of the cold material in the cold silo with the highest priority, determine the current load of the cold silo with the highest priority. Material speed;
  • the cold material supply priority is determined according to the aggregate content of the cold material in the cold material silo.
  • the cold material has a higher priority.
  • the speed determination module is specifically used for:
  • the current loading speed of the cold hopper with the highest priority is determined.
  • the speed determination module is specifically used for:
  • the first speed corresponding to the cold bin with the highest priority is determined.
  • it also includes:
  • the detection module is used to detect the material level value of each cold material bin and/or indicate the supply status of whether the material is available;
  • Speed determination module specifically used for:
  • the priority of the cold material in at least one available cold material bin that supplies the aggregate bin Based on the cold material supply priority, and based on the material level value of each cold material bin and/or the supply status indicating whether material is available, determine the priority of the cold material in at least one available cold material bin that supplies the aggregate bin.
  • the highest cold material bin, the available cold material bin is the cold material bin whose material level value is greater than the preset material level value and/or the supply status indicates that the material is available.
  • the speed determination module is specifically used for:
  • the unloading speed of each aggregate bin is obtained.
  • the preset material level interval includes a first material level interval, a second material level interval and a third material level interval whose material level values increase in sequence; the speed determination module is specifically used for:
  • the current feeding speed of at least one cold silo supplying material to the aggregate silo is increased to obtain at least one cold silo supplying material to the aggregate silo.
  • the current feeding speed of at least one cold silo supplying material to the aggregate silo will be used as the target of at least one cold silo supplying material to the aggregate silo. Feeding speed;
  • the current feeding speed of at least one cold material silo that supplies material to the aggregate silo is reduced to obtain at least one cold material that supplies material to the aggregate silo.
  • the target loading speed of the warehouse is
  • the speed determination module is also used to:
  • the aggregate supply priority is determined according to the demand for aggregates in each aggregate bin. The greater the demand for aggregates in the aggregate bin, the higher the priority of the aggregate in the aggregate bin. ;
  • the target feeding speed of at least one cold silo feeding at least one aggregate silo with the lowest priority is reduced so that the total speed is less than or equal to a preset speed upper limit.
  • the required amount of aggregate in each aggregate bin is determined based on the proportion of each aggregate in the production formula.
  • it also includes:
  • the input module is used to determine the type of cold material in the cold material bin according to the user's first input operation
  • An embodiment of the present application also provides an asphalt mixing station, including an asphalt mixing station body and a controller.
  • the controller is used to implement the feeding control method as in any of the above embodiments.
  • Figure 5 illustrates a schematic diagram of the physical structure of an electronic device.
  • the electronic device may include: a processor (processor) 510, a communication interface (Communications Interface) 520, a memory (memory) 530 and a communication bus 540.
  • the processor 510, the communication interface 520, and the memory 530 complete communication with each other through the communication bus 540.
  • the processor 510 can call logical instructions in the memory 530 to execute a loading control method, which includes:
  • the target feeding speed of each cold material bin is determined; each cold material bin is used to supply materials to each aggregate bin; the cold material data model includes the data of each aggregate in the cold material of each cold material bin content;
  • the loading of each cold silo is controlled.
  • the above-mentioned logical instructions in the memory 530 can be implemented in the form of software functional units and can be stored in a computer-readable storage medium when sold or used as an independent product.
  • the technical solution of the present application is essentially or the part that contributes to the existing technology or the part of the technical solution can be embodied in the form of a software product.
  • the computer software product is stored in a storage medium, including Several instructions are used to cause a computer device (which may be a personal computer, a server, or a network device, etc.) to execute all or part of the steps of the methods of various embodiments of the present application.
  • the aforementioned storage media include: U disk, mobile hard disk, read-only memory (ROM, Read-Only Memory), random access memory (RAM, Random Access Memory), magnetic disk or optical disk and other media that can store program code. .
  • the present application also provides a computer program product.
  • the computer program product includes a computer program stored on a non-transitory computer-readable storage medium.
  • the computer program includes program instructions. When the program instructions are executed by the computer, the computer can execute The feeding control method provided by each of the above methods includes:
  • the target feeding speed of each cold material bin is determined; each cold material bin is used to supply materials to each aggregate bin; the cold material data model includes the data of each aggregate in the cold material of each cold material bin content;
  • the loading of each cold silo is controlled.
  • the present application also provides a non-transitory computer-readable storage medium on which a computer program is stored.
  • the computer program is implemented when executed by the processor to execute the above-mentioned feeding control methods.
  • the method includes:
  • the target feeding speed of each cold material bin is determined; each cold material bin is used to supply materials to each aggregate bin; the cold material data model includes the data of each aggregate in the cold material of each cold material bin content;
  • the loading of each cold silo is controlled.
  • the device embodiments described above are only illustrative.
  • the units described as separate components may or may not be physically separated.
  • the components shown as units may or may not be physical units, that is, they may be located in one place. , or it can be distributed to multiple network units. Some or all of the modules can be selected according to actual needs to achieve the purpose of the solution of this embodiment. Persons of ordinary skill in the art can understand and implement the method without any creative effort.
  • each embodiment can be implemented by software plus a necessary general hardware platform, and of course, it can also be implemented by hardware.
  • the computer software product can be stored in a computer-readable storage medium, such as ROM/RAM, magnetic disc, optical disk, etc., including a number of instructions to cause a computer device (which can be a personal computer, a server, or a network device, etc.) to execute various embodiments or methods of certain parts of the embodiments.

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Abstract

The present application relates to the field of mechanical control. Provided are a feeding control method and apparatus, and an asphalt stirring station. The method comprises: determining a target feeding speed of each cold material bin on the basis of a cold material data model, wherein the cold material bins are used for feeding materials to aggregate bins, and the cold material data model includes the content of aggregate in cold materials of each cold material bin; and on the basis of the target feeding speeds of the cold material bins, controlling the cold material bins to feed materials.

Description

上料控制方法及装置、沥青搅拌站Feeding control method and device, asphalt mixing station
相关申请的交叉引用Cross-references to related applications
本申请要求于2022年3月23日提交的申请号为2022102923523,发明名称为“上料控制方法及装置、沥青搅拌站”的中国专利申请的优先权,其通过引用方式全部并入本文。This application claims priority to the Chinese patent application with application number 2022102923523 and the invention title "Feeding Control Method and Device, Asphalt Mixing Station" submitted on March 23, 2022, which is fully incorporated herein by reference.
技术领域Technical field
本申请涉及机械控制技术领域,尤其涉及一种上料控制方法及装置、沥青搅拌站。This application relates to the field of mechanical control technology, and in particular to a feeding control method and device, and an asphalt mixing station.
背景技术Background technique
沥青搅拌站是用于批量生产沥青混凝土的成套设备。Asphalt mixing plant is a complete set of equipment used for batch production of asphalt concrete.
现有技术中,沥青搅拌站主要上料操作为操作人员手动操作,冷料仓的上料速度需要操作人员根据人工经验控制,这种依靠人工经验控制冷料仓的上料速度的方式并不准确。In the existing technology, the main feeding operation of the asphalt mixing station is manually operated by the operator. The feeding speed of the cold silo needs to be controlled by the operator based on manual experience. This method of relying on manual experience to control the feeding speed of the cold silo is not precise.
发明内容Contents of the invention
本申请提供一种上料控制方法及装置、沥青搅拌站,用以解决现有技术中依靠人工经验控制冷料仓的上料速度的方式并不准确的缺陷,实现各冷料仓的上料速度的准确地自动独立控制,可靠性更高。This application provides a feeding control method and device, as well as an asphalt mixing station, to solve the defect in the existing technology that relies on manual experience to control the feeding speed of the cold silo, and to realize the loading of each cold silo. The speed is accurately controlled automatically and independently, with higher reliability.
本申请提供一种上料控制方法,包括:This application provides a feeding control method, including:
基于冷料数据模型,确定各冷料仓的目标上料速度;所述各冷料仓用于为各骨料仓供料;所述冷料数据模型中包含每个所述冷料仓的冷料中各骨料的含量;Based on the cold material data model, the target feeding speed of each cold material bin is determined; each cold material bin is used to supply material to each aggregate bin; the cold material data model includes the cold material data of each cold material bin. The content of each aggregate in the material;
基于各所述冷料仓的目标上料速度,控制各所述冷料仓上料。Based on the target feeding speed of each cold silo, the loading of each cold silo is controlled.
根据本申请提供的一种上料控制方法,所述基于冷料数据模型,确定各冷料仓的目标上料速度,包括:According to a loading control method provided by this application, the target loading speed of each cold material bin is determined based on the cold material data model, including:
获取各所述骨料仓的料位值;Obtain the material level value of each aggregate bin;
基于所述冷料数据模型,计算各所述冷料仓的当前上料速度;Based on the cold material data model, calculate the current feeding speed of each cold material bin;
将各所述骨料仓的料位值与预设料位区间进行对比;Compare the material level value of each aggregate bin with the preset material level interval;
基于各所述冷料仓的当前上料速度以及各所述对比的结果,确定各所述冷料仓的目标上料速度。Based on the current feeding speed of each cold silo and the results of each comparison, the target feeding speed of each cold silo is determined.
根据本申请提供的一种上料控制方法,所述基于所述冷料数据模型,计算各所述冷料仓的当前上料速度,包括:According to a feeding control method provided by this application, calculating the current feeding speed of each cold feed bin based on the cold feed data model includes:
获取各所述骨料仓的卸料速度和料位变化率;Obtain the discharge speed and material level change rate of each aggregate bin;
基于所述冷料数据模型、各所述骨料仓的卸料速度和料位变化率,计算各所述冷料仓的当前上料速度。Based on the cold material data model, the unloading speed and material level change rate of each aggregate bin, the current loading speed of each cold material bin is calculated.
根据本申请提供的一种上料控制方法,所述基于所述冷料数据模型、各所述骨料仓的卸料速度和料位变化率,计算各所述冷料仓的当前上料速度,包括:According to a feeding control method provided by the present application, the current feeding speed of each cold material bin is calculated based on the cold material data model, the unloading speed and the material level change rate of each aggregate bin. ,include:
针对每个所述骨料仓,获取与所述骨料仓的骨料对应的冷料供应优先级,基于所述冷料供应优先级,确定为所述骨料仓供料的至少一个所述冷料仓中冷料的优先级最高的所述冷料仓,基于所述骨料仓的卸料速度和料位变化率以及所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量,确定所述优先级最高的所述冷料仓的当前上料速度;For each aggregate bin, obtain the cold material supply priority corresponding to the aggregate in the aggregate bin, and determine at least one of the cold material supply priorities for the aggregate bin based on the cold material supply priority. The cold material bin with the highest priority of cold material in the cold material bin is based on the unloading speed and material level change rate of the aggregate bin and the cold material of the cold material bin with the highest priority. The aggregate content in the aggregate bin determines the current feeding speed of the cold material bin with the highest priority;
其中,所述冷料供应优先级是按照各所述冷料仓的冷料中所述骨料仓的骨料的含量确定的,所述冷料仓的冷料中所述骨料仓的骨料的含量越大,所述冷料仓的冷料的优先级越高。Wherein, the cold material supply priority is determined according to the aggregate content of the aggregate bin in the cold material of each cold material bin, and the aggregate content of the aggregate bin in the cold material of the cold material bin. The greater the material content, the higher the priority of the cold material in the cold material bin.
根据本申请提供的一种上料控制方法,所述基于所述骨料仓的卸料速度和料位变化率以及所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量,确定所述优先级最高的所述冷料仓的当前上料速度,包括:According to a feeding control method provided by the present application, the said aggregate bin is based on the discharging speed and material level change rate of the aggregate bin and the cold material of the cold bin with the highest priority. The content of the aggregate determines the current feeding speed of the cold silo with the highest priority, including:
基于所述骨料仓的卸料速度和所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量,确定所述优先级最高的所述冷料仓对应的第一速度;Based on the unloading speed of the aggregate bin and the aggregate content of the cold material in the cold material bin with the highest priority, it is determined that the cold material bin with the highest priority corresponds to the first speed;
基于所述骨料仓的料位变化率,确定所述优先级最高的所述冷料仓对应的第二速度;Based on the material level change rate of the aggregate silo, determine the second speed corresponding to the cold silo with the highest priority;
基于所述第一速度和所述第二速度,确定所述优先级最高的所述冷料仓的当前上料速度。Based on the first speed and the second speed, the current feeding speed of the cold hopper with the highest priority is determined.
根据本申请提供的一种上料控制方法,所述基于所述骨料仓的卸料速 度和所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量,确定所述优先级最高的所述冷料仓对应的第一速度,包括:According to a feeding control method provided by the present application, the method is based on the unloading speed of the aggregate bin and the aggregate content of the aggregate bin in the cold material of the cold bin with the highest priority. , determine the first speed corresponding to the cold silo with the highest priority, including:
基于所述骨料仓的卸料速度与所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量的比值,确定所述优先级最高的所述冷料仓对应的第一速度。The cold material with the highest priority is determined based on the ratio of the unloading speed of the aggregate bin to the aggregate content of the cold material in the cold material bin with the highest priority. The first speed corresponding to the bin.
根据本申请提供的一种上料控制方法,还包括:According to a feeding control method provided by this application, it also includes:
检测各所述冷料仓的料位值和/或表征是否可供料的供应状态;Detect the material level value of each cold material bin and/or indicate the supply status of whether material is available;
所述基于所述冷料供应优先级,确定为所述骨料仓供料的至少一个所述冷料仓中冷料的优先级最高的所述冷料仓,包括:Determining, based on the cold material supply priority, the cold material silo with the highest priority of cold material in at least one of the cold material silos supplying the aggregate silo, including:
基于所述冷料供应优先级,以及基于各所述冷料仓的料位值和/或表征是否可供料的供应状态,确定为所述骨料仓供料的可用的至少一个所述冷料仓中冷料的优先级最高的所述冷料仓,所述可用的所述冷料仓是料位值大于预设料位值和/或供应状态表征可供料的所述冷料仓。Based on the cold material supply priority, and based on the material level value of each of the cold material bins and/or the supply status indicating whether material is available, at least one of the cold materials available for supplying the aggregate bin is determined. The cold material bin with the highest priority of cold material in the bin, the available cold material bin is the cold material bin whose material level value is greater than the preset material level value and/or the supply status indicates that the material is available .
根据本申请提供的一种上料控制方法,所述获取各所述骨料仓的卸料速度,包括:According to a feeding control method provided by this application, obtaining the discharging speed of each aggregate bin includes:
基于各所述骨料仓对应的计量秤称量的骨料重量以及称量周期,得到各所述骨料仓的卸料速度。Based on the weight of the aggregate measured by the weighing scale corresponding to each of the aggregate bins and the weighing cycle, the unloading speed of each of the aggregate bins is obtained.
根据本申请提供的一种上料控制方法,所述预设料位区间包括料位值依次增大的第一料位区间、第二料位区间和第三料位区间;According to a feeding control method provided by this application, the preset material level interval includes a first material level interval, a second material level interval and a third material level interval in which the material level value increases in sequence;
所述基于各所述冷料仓的当前上料速度以及各所述对比的结果,确定各所述冷料仓的目标上料速度,包括:Determining the target feeding speed of each cold silo based on the current feeding speed of each cold silo and the comparison results includes:
若所述骨料仓的料位值位于所述第一料位区间内,将为所述骨料仓供料的至少一个所述冷料仓的当前上料速度增加,以得到为所述骨料仓供料的至少一个所述冷料仓的目标上料速度;If the material level value of the aggregate bin is within the first material level interval, the current feeding speed of at least one of the cold material bins that supplies materials to the aggregate bin is increased to obtain the The target feeding speed of at least one of the cold silos supplied by the silos;
若所述骨料仓的料位值位于所述第二料位区间内,将为所述骨料仓供料的至少一个所述冷料仓的当前上料速度作为为所述骨料仓供料的至少一个所述冷料仓的目标上料速度;If the material level value of the aggregate silo is within the second material level interval, the current feeding speed of at least one cold material silo that supplies material to the aggregate silo will be used as the supply speed for the aggregate silo. The target feeding speed of at least one of the cold hoppers;
若所述骨料仓的料位值位于所述第三料位区间内,将为所述骨料仓供料的至少一个所述冷料仓的当前上料速度减小,以得到为所述骨料仓供料的至少一个所述冷料仓的目标上料速度。If the material level value of the aggregate bin is within the third material level interval, the current feeding speed of at least one of the cold material bins that supplies materials to the aggregate bin is reduced to obtain the The target feeding speed of at least one of the cold silos supplied by the aggregate silo.
根据本申请提供的一种上料控制方法,所述基于各所述冷料仓的当前上料速度以及各所述对比的结果,确定各所述冷料仓的目标上料速度,还包括:According to a feeding control method provided by this application, determining the target feeding speed of each cold silo based on the current feeding speed of each cold silo and the result of each comparison also includes:
获取骨料供应优先级,所述骨料供应优先级是按照各所述骨料仓的骨料的需求量确定的,所述骨料仓的骨料的需求量越大,所述骨料仓的骨料的优先级越高;Obtain the aggregate supply priority. The aggregate supply priority is determined according to the demand for aggregates in each of the aggregate bins. The greater the demand for aggregates in the aggregate bins, the higher the demand for aggregates in the aggregate bins. The higher the priority of the aggregate;
确定各所述冷料仓的目标上料速度之和,得到总速度;Determine the sum of the target feeding speeds of each cold material bin to obtain the total speed;
若所述总速度大于预设的速度上限,基于所述骨料供应优先级,确定各所述骨料仓中骨料的优先级最低的至少一个所述骨料仓;If the total speed is greater than the preset speed upper limit, based on the aggregate supply priority, determine at least one of the aggregate bins with the lowest priority of aggregate in each of the aggregate bins;
将为所述优先级最低的至少一个所述骨料仓供料的至少一个所述冷料仓的目标上料速度减小,以使得所述总速度小于或者等于所述预设的速度上限。The target feeding speed of at least one cold silo that supplies at least one aggregate silo with the lowest priority is reduced so that the total speed is less than or equal to the preset speed upper limit.
根据本申请提供的一种上料控制方法,各所述骨料仓的骨料的需求量是基于生产配方中各骨料的比例确定的。According to a feeding control method provided by this application, the demand for aggregates in each aggregate bin is determined based on the proportion of each aggregate in the production formula.
本申请还提供一种上料控制装置,包括:This application also provides a feeding control device, including:
速度确定模块,用于基于冷料数据模型,确定各冷料仓的目标上料速度;所述各冷料仓用于为各骨料仓供料;所述冷料数据模型中包含每个所述冷料仓的冷料中各骨料的含量;The speed determination module is used to determine the target feeding speed of each cold material bin based on the cold material data model; each cold material bin is used to supply material to each aggregate bin; the cold material data model includes each Describe the content of each aggregate in the cold material in the cold material bin;
上料控制模块,用于基于各所述冷料仓的目标上料速度,控制各所述冷料仓上料。A loading control module is used to control the loading of each cold silo based on the target loading speed of each cold silo.
本申请还提供一种沥青搅拌站,包括沥青搅拌站本体和控制器,所述控制器用于实现如上述任一种所述上料控制方法。This application also provides an asphalt mixing station, including an asphalt mixing station body and a controller, and the controller is used to implement any of the above feeding control methods.
本申请还提供一种电子设备,包括存储器、处理器及存储在存储器上并可在处理器上运行的计算机程序,所述处理器执行所述程序时实现如上述任一种所述上料控制方法。This application also provides an electronic device, including a memory, a processor, and a computer program stored in the memory and executable on the processor. When the processor executes the program, it implements any one of the above mentioned feeding controls. method.
本申请还提供一种非暂态计算机可读存储介质,其上存储有计算机程序,该计算机程序被处理器执行时实现如上述任一种所述上料控制方法。This application also provides a non-transitory computer-readable storage medium on which a computer program is stored. When the computer program is executed by a processor, any one of the above feeding control methods is implemented.
本申请还提供一种计算机程序产品,包括计算机程序,所述计算机程序被处理器执行时实现如上述任一种所述上料控制方法。The present application also provides a computer program product, which includes a computer program. When the computer program is executed by a processor, it implements any one of the above feeding control methods.
本申请提供的上料控制方法,冷料数据模型能够提供冷料仓中的冷料 所包含的各骨料的含量,能够准确体现出不同冷料的成分的差异,为冷料仓的上料速度的控制提供了数据基础,可以基于冷料数据模型,确定各冷料仓的目标上料速度,进而自动控制各冷料仓上料,解决了现有技术中依靠人工经验控制冷料仓的上料速度不准确的问题,实现了各冷料仓的上料速度的准确地自动独立控制,可靠性更高。并且,与人工经验控制冷料仓的上料速度相比,能够实时快速调整多个冷料仓的上料速度,控制更加及时,避免了出现缺料或者溢料等情况,从而提高了生产效率,减少了损耗,降低了成本。The material loading control method and cold material data model provided by this application can provide the content of each aggregate contained in the cold material in the cold material silo, and can accurately reflect the differences in the composition of different cold materials, providing a basis for the loading of the cold material silo. Speed control provides a data basis. Based on the cold material data model, the target feeding speed of each cold material bin can be determined, and then the loading of each cold material bin can be automatically controlled, which solves the problem of relying on manual experience to control the cold material bin in the existing technology. The problem of inaccurate feeding speed has been realized. The feeding speed of each cold material bin can be accurately and automatically controlled independently, with higher reliability. Moreover, compared with manual control of the feeding speed of cold silos, the feeding speed of multiple cold silos can be quickly adjusted in real time, and the control is more timely, avoiding shortages or overflows, thereby improving production efficiency. , reducing losses and lowering costs.
附图说明Description of the drawings
为了更清楚地说明本申请或现有技术中的技术方案,下面将对实施例或现有技术描述中所需要使用的附图作简单地介绍,显而易见地,下面描述中的附图是本申请的一些实施例,对于本领域普通技术人员来讲,在不付出创造性劳动的前提下,还可以根据这些附图获得其他的附图。In order to more clearly illustrate the technical solutions in this application or the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings in the following description are the drawings used in the present application. For some embodiments, those of ordinary skill in the art can also obtain other drawings based on these drawings without exerting creative efforts.
图1是本申请提供的上料控制方法的流程示意图之一;Figure 1 is one of the flow diagrams of the feeding control method provided by this application;
图2是本申请提供的上料控制系统的结构示意图;Figure 2 is a schematic structural diagram of the feeding control system provided by this application;
图3是本申请提供的上料控制方法的流程示意图之二;Figure 3 is the second schematic flow chart of the feeding control method provided by this application;
图4是本申请提供的上料控制装置的结构示意图;Figure 4 is a schematic structural diagram of the feeding control device provided by this application;
图5是本申请提供的电子设备的结构示意图。Figure 5 is a schematic structural diagram of an electronic device provided by this application.
具体实施方式Detailed ways
为使本申请的目的、技术方案和优点更加清楚,下面将结合本申请中的附图,对本申请中的技术方案进行清楚、完整地描述,显然,所描述的实施例是本申请一部分实施例,而不是全部的实施例。基于本申请中的实施例,本领域普通技术人员在没有作出创造性劳动前提下所获得的所有其他实施例,都属于本申请保护的范围。In order to make the purpose, technical solutions and advantages of this application clearer, the technical solutions in this application will be clearly and completely described below in conjunction with the drawings in this application. Obviously, the described embodiments are part of the embodiments of this application. , not all examples. Based on the embodiments in this application, all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the scope of protection of this application.
沥青搅拌站中,依靠人工经验控制冷料仓的冷料的上料速度的方式并不准确,容易存在误差,因冷料仓远离操作室,无法及时准确判断冷料仓的情况,在多种冷料同时上料时,操作就会受到限制,不容易做到各种冷料仓的上料速度的快速调整,容易出现上料不及时导致的缺料或者溢料等 情况,降低生产效率,增加损耗,从而增加成本。In asphalt mixing stations, the method of controlling the loading speed of cold material in the cold material silo based on manual experience is not accurate and prone to errors. Because the cold material silo is far away from the operation room, it is impossible to accurately judge the situation of the cold material silo in a timely manner. In various situations, When cold materials are loaded at the same time, the operation will be restricted. It is not easy to quickly adjust the feeding speed of various cold material bins. It is easy to cause shortage or overflow caused by untimely loading, which reduces production efficiency. Increase losses, thereby increasing costs.
另外,部分厂家冷料上料要求冷料仓固定,举例来说,假设冷料系统有6个冷料仓,每个冷料仓储存不同的冷料,假设为6种冷料分别设置编号,即1#冷料、2#冷料、3#冷料、4#冷料、5#冷料和6#冷料,相应的,设置6个骨料仓,分别存放1#到6#骨料,缺少1#骨料时,启动1#冷料上料,缺少2#骨料时,启动2#冷料上料,依此类推。此种方法作业不灵活,需要冷料的编号与骨料的编号严格对应,同时要求1#冷料中的1#骨料的占比较大,否则可能会出现上错料的情况,可见,这种方式对冷料原材料和作业要求非常高,有时难以达到,控制可靠性不高。In addition, some manufacturers require cold material silos to be fixed when loading cold materials. For example, assume that the cold material system has 6 cold material silos, and each cold material warehouse stores different cold materials. Assume that the six cold materials are individually numbered. That is, 1# cold material, 2# cold material, 3# cold material, 4# cold material, 5# cold material and 6# cold material. Correspondingly, 6 aggregate bins are set up to store 1# to 6# aggregates respectively. , when the 1# aggregate is missing, start the 1# cold material loading, when the 2# aggregate is missing, start the 2# cold material loading, and so on. This method is inflexible and requires that the number of the cold material strictly corresponds to the number of the aggregate. At the same time, it is required that the 1# aggregate in the 1# cold material accounts for a large proportion, otherwise the wrong material may be loaded. It can be seen that this This method has very high requirements on cold material raw materials and operations, which are sometimes difficult to achieve and the control reliability is not high.
为此,本申请提供了一种冷料上料方法,准确实现各冷料仓的目标上料速度的自动控制,可以应用于沥青搅拌站中,由沥青搅拌站中的软件和/或硬件执行,示例性的,可以由控制器执行,该控制器可以控制上料控制系统中的各部分,该控制器可以但不限于为可编程逻辑控制器(Programmable Logic Controller,PLC)或者单片机。To this end, this application provides a cold material loading method that accurately realizes automatic control of the target feeding speed of each cold material bin. It can be applied to asphalt mixing stations and executed by the software and/or hardware in the asphalt mixing stations. , exemplarily, it can be executed by a controller, which can control various parts of the material loading control system. The controller can be, but is not limited to, a programmable logic controller (Programmable Logic Controller, PLC) or a single-chip microcomputer.
下面结合图1至图3描述本申请的上料控制方法。The feeding control method of the present application will be described below with reference to Figures 1 to 3.
图1是本申请提供的上料控制方法的流程示意图之一。Figure 1 is one of the flow diagrams of the feeding control method provided by this application.
如图1所示,本实施例提供一种上料控制方法,该方法至少包括:As shown in Figure 1, this embodiment provides a feeding control method, which at least includes:
步骤101、基于冷料数据模型,确定各冷料仓的目标上料速度;各冷料仓用于为各骨料仓供料;冷料数据模型中包含每个冷料仓的冷料中各骨料的含量。 Step 101. Based on the cold material data model, determine the target feeding speed of each cold material bin; each cold material bin is used to supply materials to each aggregate bin; the cold material data model includes each cold material in each cold material bin. Aggregate content.
目标上料速度即需要控制冷料仓达到的上料速度。The target feeding speed is the feeding speed that needs to be controlled by the cold material bin.
冷料中一般包含不同粒径的骨料,冷料中各骨料的含量可以理解为冷料所包含的各骨料的含量,示例性的,骨料的含量可以为骨料在冷料中的重量比例,也可以为骨料在冷料中的体积比例,等等。Cold materials generally contain aggregates of different particle sizes. The content of each aggregate in the cold material can be understood as the content of each aggregate contained in the cold material. For example, the content of aggregates can be the aggregate content in the cold material. The weight ratio can also be the volume ratio of aggregate in cold material, etc.
各骨料仓储存的骨料的粒径不同。实施中,冷料仓中储存冷料,可以将冷料仓的冷料输送到筛网(例如振动筛等),然后由筛网将冷料细分成不同粒径的骨料,这些不同粒径的骨料可以进入到对应粒径的骨料仓中,从而实现冷料仓对骨料仓的供料。The particle sizes of aggregates stored in each aggregate bin are different. In practice, the cold material is stored in the cold material bin, and the cold material in the cold material bin can be transported to a screen (such as a vibrating screen, etc.), and then the screen will subdivide the cold material into aggregates of different particle sizes. These different particles Aggregates with different particle sizes can enter the aggregate silo with corresponding particle size, thereby realizing the cold material silo supplying the aggregate silo.
示例性的,如图2所示的上料控制系统,包括上位机(例如计算机),与上位机电连接的控制器,多个冷料仓和多个骨料仓,与多个冷料仓一一 对应连接的多个电机(图中以M示意),以及与多个电机一一对应电连接的多个变频器,与多个冷料仓一一对应设置的多个上料皮带,与多个上料皮带对应的输送皮带,滚筒,提升机和振动筛。控制器与各变频器电连接。图中以6个冷料仓示意,并进行编号,分别为1号冷料仓、2号冷料仓、3号冷料仓、4号冷料仓、5号冷料仓和6号冷料仓,以6个骨料仓示意,并进行编号,分别为1号骨料仓、2号骨料仓、3号骨料仓、4号骨料仓、5号骨料仓和6号骨料仓。Exemplary, the material loading control system shown in Figure 2 includes a host computer (such as a computer), a controller electrically connected to the host machine, multiple cold material bins and multiple aggregate bins, together with the multiple cold material bins. A plurality of motors (indicated by M in the figure) connected in a one-to-one manner, a plurality of frequency converters electrically connected to a plurality of motors in a one-to-one correspondence, a plurality of feeding belts corresponding to a plurality of cold material silos, and multiple Each feeding belt corresponds to the conveyor belt, roller, elevator and vibrating screen. The controller is electrically connected to each frequency converter. The figure shows 6 cold material silos and they are numbered, namely No. 1 cold material silo, No. 2 cold material silo, No. 3 cold material silo, No. 4 cold material silo, No. 5 cold material silo and No. 6 cold material The bins are represented by 6 aggregate bins and are numbered, namely No. 1 aggregate bin, No. 2 aggregate bin, No. 3 aggregate bin, No. 4 aggregate bin, No. 5 aggregate bin and No. 6 aggregate bin. warehouse.
基于此,控制器可以通过控制变频器的频率,来控制电机的速度,进而控制冷料仓的上料速度,将冷料仓的冷料通过上料皮带、输送皮带、滚筒、提升机进入振动筛,通过振动筛的振动将冷料细分成不同粒径的骨料进入对应粒径的骨料仓。其中,冷料通过滚筒的出料口进入提升机。Based on this, the controller can control the speed of the motor by controlling the frequency of the frequency converter, thereby controlling the loading speed of the cold material bin, and passing the cold material in the cold material bin into vibration through the feeding belt, conveyor belt, roller, and elevator. Screen, through the vibration of the vibrating screen, the cold material is subdivided into aggregates of different particle sizes and enters the aggregate bin of corresponding particle sizes. Among them, the cold material enters the elevator through the discharge port of the drum.
实际应用中,在基于冷料数据模型,确定各冷料仓的目标上料速度之前,可以先获取冷料数据模型,示例性的,可以从本地获取预先存储的冷料数据模型,也可以通过网络下载云端存储的冷料数据模型,还可以获取人工手动输入的冷料数据模型。In practical applications, before determining the target feeding speed of each cold material bin based on the cold material data model, the cold material data model can be obtained first. For example, the pre-stored cold material data model can be obtained locally, or through The cold material data model stored in the cloud can be downloaded online, and the cold material data model input manually can also be obtained.
示例性的,上述冷料数据模型可以存储在本地的上位机中。控制器可以从上位机中获取冷料数据模型。For example, the above cold material data model can be stored in the local host computer. The controller can obtain the cold material data model from the host computer.
步骤102、基于各冷料仓的目标上料速度,控制各冷料仓上料。Step 102: Control the loading of each cold silo based on the target loading speed of each cold silo.
本实施例中,冷料数据模型能够提供冷料仓中的冷料所包含的各骨料的含量,能够准确体现出不同冷料的成分的差异,为冷料仓的上料速度的控制提供了数据基础,可以基于冷料数据模型,确定各冷料仓的目标上料速度,进而自动控制各冷料仓上料,解决了现有技术中依靠人工经验控制冷料仓的上料速度不准确的问题,实现了各冷料仓的上料速度的准确地自动独立控制,可靠性更高。并且,与人工经验控制冷料仓的上料速度相比,能够实时快速调整多个冷料仓的上料速度,控制更加及时,避免了出现缺料或者溢料等情况,从而提高了生产效率,减少了损耗,降低了成本。In this embodiment, the cold material data model can provide the content of each aggregate contained in the cold material in the cold material silo, can accurately reflect the differences in the composition of different cold materials, and provide a method for controlling the loading speed of the cold material silo. With the data foundation, the target feeding speed of each cold silo can be determined based on the cold material data model, and then the loading of each cold silo can be automatically controlled, which solves the problem of relying on manual experience in the existing technology to control the loading speed of the cold silo. Accurate questions realize accurate automatic independent control of the feeding speed of each cold material bin, with higher reliability. Moreover, compared with manual control of the feeding speed of cold silos, the feeding speed of multiple cold silos can be quickly adjusted in real time, and the control is more timely, avoiding shortages or overflows, thereby improving production efficiency. , reducing losses and lowering costs.
需要说明的是,本实施例的方案中,一个冷料仓可以为多个骨料仓供料,一个骨料仓也可以由多个冷料仓供料,无需要求某个冷料仓固定为某个骨料仓供料,基于冷料数据模型提供的冷料仓中的冷料所包含的各骨料的含量,就能够准确地进行上料速度的控制,更加可靠。It should be noted that in the solution of this embodiment, one cold silo can supply materials to multiple aggregate silos, and one aggregate silo can also be fed by multiple cold silos. There is no need to require a certain cold silo to be fixed as When an aggregate silo supplies materials, based on the content of each aggregate contained in the cold material in the cold silo provided by the cold material data model, the feeding speed can be controlled accurately and more reliably.
在示例性实施例中,基于冷料数据模型,确定各冷料仓的目标上料速度,如图3所示,具体实现方式可以包括:In an exemplary embodiment, based on the cold material data model, the target feeding speed of each cold material bin is determined, as shown in Figure 3. Specific implementation methods may include:
步骤301、获取各骨料仓的料位值。Step 301: Obtain the material level value of each aggregate bin.
参见图2,上料控制系统中,每个骨料仓中可以设置料位计(图中在每个骨料仓内条状结构示意),该料位计用于实时检测骨料仓中的料位值并发送至控制器。控制器可以基于料位计的检测结果,获取到骨料仓的料位值。Referring to Figure 2, in the feeding control system, a material level meter can be set in each aggregate bin (the strip structure in each aggregate bin is shown in the figure). The material level meter is used to detect the level in the aggregate bin in real time. The material level value is sent to the controller. The controller can obtain the material level value of the aggregate bin based on the detection results of the material level meter.
步骤302、基于冷料数据模型,计算各冷料仓的当前上料速度。本步骤的具体实现方式可以包括:获取各骨料仓的卸料速度和料位变化率;基于冷料数据模型、各骨料仓的卸料速度和料位变化率,计算各冷料仓的当前上料速度。Step 302: Calculate the current feeding speed of each cold material bin based on the cold material data model. The specific implementation of this step may include: obtaining the unloading speed and material level change rate of each aggregate bin; based on the cold material data model, the unloading speed and material level change rate of each aggregate bin, calculating the Current loading speed.
其中,获取各骨料仓的卸料速度时,具体的,可以基于各骨料仓对应的计量秤称量的骨料重量以及称量周期,得到骨料仓的卸料速度。实际应用中,参见图2,上料控制系统中还包括计量秤,计量秤可以按照预设时长为称量周期,称量骨料仓的卸料时的骨料重量并发送至控制器。示例性的,可以将计量秤称量的骨料重量与称量周期的比值,作为骨料仓的卸料速度。如此,可以准确得到骨料仓的卸料速度。When obtaining the discharging speed of each aggregate bin, specifically, the discharging speed of the aggregate bin can be obtained based on the weight of the aggregate measured by the weighing scale corresponding to each aggregate bin and the weighing cycle. In practical applications, see Figure 2. The loading control system also includes a weighing scale. The weighing scale can weigh the weight of the aggregate during unloading of the aggregate bin according to the preset time period and send it to the controller. For example, the ratio of the weight of the aggregate measured by the weighing scale to the weighing cycle can be used as the discharging speed of the aggregate bin. In this way, the discharge speed of the aggregate bin can be accurately obtained.
控制器还可以基于料位计的检测结果,获取到骨料仓的料位变化率。料位变化率即当前时刻的料位值与上一时刻的料位值的差值与两个时刻的时间变化量的比值。The controller can also obtain the material level change rate of the aggregate bin based on the detection results of the material level meter. The material level change rate is the ratio of the difference between the material level value at the current moment and the material level value at the previous moment and the time change of the two moments.
其中,基于冷料数据模型、各骨料仓的卸料速度和料位变化率,计算各冷料仓的当前上料速度,具体可以包括:针对每个骨料仓,获取与骨料仓的骨料对应的冷料供应优先级,基于冷料供应优先级,确定为骨料仓供料的至少一个冷料仓中冷料的优先级最高的冷料仓,基于骨料仓的卸料速度和料位变化率以及优先级最高的冷料仓的冷料中骨料仓的骨料的含量,确定优先级最高的冷料仓的当前上料速度;其中,冷料供应优先级是按照各冷料仓的冷料中骨料仓的骨料的含量确定的,冷料仓的冷料中骨料仓的骨料的含量越大,冷料仓的冷料的优先级越高。Among them, based on the cold material data model, the unloading speed and material level change rate of each aggregate bin, the current feeding speed of each cold material bin is calculated. Specifically, it can include: for each aggregate bin, obtain the data related to the aggregate bin. The cold material supply priority corresponding to the aggregate is based on the cold material supply priority. The cold material silo with the highest priority among at least one cold material silo supplying the aggregate silo is determined based on the unloading speed of the aggregate silo. Based on the material level change rate and the aggregate content of the cold material in the cold material silo with the highest priority, the current feeding speed of the cold material silo with the highest priority is determined; among them, the cold material supply priority is based on each The cold material in the cold material bin is determined by the aggregate content in the aggregate bin. The greater the aggregate content in the cold material in the cold material bin, the higher the priority of the cold material in the cold material bin.
表1 冷料数据模型Table 1 Cold material data model
Figure PCTCN2022095564-appb-000001
Figure PCTCN2022095564-appb-000001
表2 简化后的冷料数据模型Table 2 Simplified cold material data model
Figure PCTCN2022095564-appb-000002
Figure PCTCN2022095564-appb-000002
Figure PCTCN2022095564-appb-000003
Figure PCTCN2022095564-appb-000003
冷料数据模型中可以包含冷料、冷料中的各骨料及各骨料的含量的对应关系。如表1所示的冷料数据模型,冷料数据模型中可以包含多种冷料,每种冷料中各骨料的含量(重量比例或者体积比例)按照从大到小的顺序排列。冷料数据模型中,记录每种冷料的编号及对应的各骨料的编号和含量。表1中,以6种冷料示意,分别为1号到6号冷料,每种冷料包括1号骨料的含量、2号骨料的含量、3号骨料的含量、…….、min_1号骨料的含量Amin_1,其中,min_1表示含量最小的骨料,Amin_1表示含量最小的骨料的含量。又由于有的冷料以某几种骨料为主,这些骨料含量比较高,其它骨料的含量比较低,对上料速度的影响较小,因此,可以忽略这些骨料的影响,从而获取冷料数据模型中多种含量最高的骨料,即关注主要的一些骨料,以对冷料数据模型进行简化。简化后的冷料数据模型,如表2所示,以6种冷料示意,分别为1号到6号冷料,每种冷料对应三种含量最高的骨料。The cold material data model can include the corresponding relationship between the cold material, each aggregate in the cold material, and the content of each aggregate. As shown in the cold material data model shown in Table 1, the cold material data model can contain a variety of cold materials, and the content (weight ratio or volume ratio) of each aggregate in each cold material is arranged in order from large to small. In the cold material data model, the number of each cold material and the corresponding number and content of each aggregate are recorded. In Table 1, six kinds of cold materials are represented, namely cold materials No. 1 to No. 6. Each cold material includes the content of No. 1 aggregate, the content of No. 2 aggregate, the content of No. 3 aggregate, etc. , the content of min_1 aggregate Amin_1, where min_1 represents the aggregate with the smallest content, and Amin_1 represents the content of the aggregate with the smallest content. And because some cold materials are mainly composed of certain types of aggregates, the content of these aggregates is relatively high, and the content of other aggregates is relatively low, which has a small impact on the feeding speed. Therefore, the influence of these aggregates can be ignored, thus Obtain the aggregates with the highest content in the cold material data model, that is, focus on the main aggregates to simplify the cold material data model. The simplified cold material data model, as shown in Table 2, is represented by six types of cold materials, namely cold materials No. 1 to No. 6. Each cold material corresponds to the three highest-content aggregates.
基于此,可以针对每个骨料仓的骨料,从冷料数据模型中查找每个冷料仓的冷料中该骨料仓的骨料的含量并进行排序,基于排序结果确定骨料仓的骨料对应的冷料供应优先级,冷料仓的冷料中骨料仓的骨料的含量越大,冷料仓的冷料的优先级越高。Based on this, for the aggregates in each aggregate bin, the aggregate content of the cold materials in each cold bin can be found from the cold material data model and sorted, and the aggregate bin is determined based on the sorting results. The cold material supply priority corresponding to the aggregate is. The greater the aggregate content of the cold material in the cold material bin, the higher the priority of the cold material in the cold material bin.
表3 骨料对应的冷料供应优先级Table 3 Cold material supply priority corresponding to aggregates
Figure PCTCN2022095564-appb-000004
Figure PCTCN2022095564-appb-000004
Figure PCTCN2022095564-appb-000005
Figure PCTCN2022095564-appb-000005
参见表3,示意了1号骨料到6号骨料中,每种骨料对应的冷料供应优先级。表3中,以1号骨料为例,1号骨料对应的冷料供应优先级中,最优供应冷料(即优先级最高的冷料)为6号冷料,次优供应冷料(即优先级次高的冷料)为2号冷料,最后供应冷料(即优先级最低的冷料)为1号冷料,2号骨料对应的冷料供应优先级中,最优供应冷料为1号冷料,次优供应冷料为3号冷料,最后供应冷料为2号冷料,3号骨料对应的冷料供应优先级中,最优供应冷料为2号冷料,次优供应冷料为1号冷料,最后供应冷料为5号冷料,等等。基于此,示例性的,为1号骨料仓供1号骨料的冷料有6号冷料、2号冷料和1号冷料,则确定出优先级最高的6号冷料的冷料仓。Refer to Table 3, which shows the cold material supply priority corresponding to each aggregate from No. 1 aggregate to No. 6 aggregate. In Table 3, taking No. 1 aggregate as an example, in the cold material supply priority corresponding to No. 1 aggregate, the optimal cold material supply (that is, the cold material with the highest priority) is No. 6 cold material, and the second-best cold material supply (i.e. the cold material with the second highest priority) is cold material No. 2. The cold material supplied last (i.e. the cold material with the lowest priority) is cold material No. 1. Among the cold material supply priorities corresponding to aggregate No. 2, the best The cold material supplied is No. 1 cold material, the second best cold material supplied is No. 3 cold material, and the last cold material supplied is No. 2 cold material. Among the cold material supply priorities corresponding to No. 3 aggregate, the optimal cold material supply is 2. No. 1 cold material, the second best cold material supply is No. 1 cold material, the last cold material supplied is No. 5 cold material, and so on. Based on this, for example, the cold materials supplying No. 1 aggregate to the No. 1 aggregate bin include No. 6 cold materials, No. 2 cold materials and No. 1 cold materials, then the cold materials of No. 6 cold materials with the highest priority are determined. Silo.
示例性的,基于骨料仓的卸料速度和料位变化率以及优先级最高的冷料仓的冷料中骨料仓的骨料的含量,确定优先级最高的冷料仓的当前上料速度,具体可以包括:Illustratively, the current loading of the cold silo with the highest priority is determined based on the unloading speed and material level change rate of the aggregate silo and the aggregate content of the cold material in the cold silo with the highest priority. Speed, specifically can include:
第一步,基于骨料仓的卸料速度和优先级最高的冷料仓中骨料仓的骨料的含量,确定优先级最高的冷料仓对应的第一速度。The first step is to determine the first speed corresponding to the cold silo with the highest priority based on the unloading speed of the aggregate silo and the aggregate content of the aggregate silo in the cold silo with the highest priority.
具体的,可以基于骨料仓的卸料速度与优先级最高的冷料仓的冷料中骨料仓的骨料的含量的比值,确定优先级最高的冷料仓对应的第一速度。示例性的,可以将骨料仓的卸料速度与优先级最高的冷料仓中骨料仓的骨料的含量的比值,作为优先级最高的冷料仓对应的第一速度。也可以将骨料仓的卸料速度与优先级最高的冷料仓中骨料仓的骨料的含量的比值乘以设定的系数,作为优先级最高的冷料仓对应的第一速度。Specifically, the first speed corresponding to the cold silo with the highest priority can be determined based on the ratio of the unloading speed of the aggregate silo to the aggregate content of the cold silo in the cold silo with the highest priority. For example, the ratio of the unloading speed of the aggregate silo to the aggregate content of the aggregate silo in the cold silo with the highest priority can be used as the first speed corresponding to the cold silo with the highest priority. The ratio of the unloading speed of the aggregate silo to the aggregate content of the aggregate silo in the cold silo with the highest priority can also be multiplied by a set coefficient as the first speed corresponding to the cold silo with the highest priority.
第二步,基于骨料仓的料位变化率,确定优先级最高的冷料仓对应的第二速度。The second step is to determine the second speed corresponding to the cold silo with the highest priority based on the material level change rate of the aggregate silo.
具体的,可以将骨料仓的料位变化率,作为优先级最高的冷料仓对应的第二速度。也可以将骨料仓的料位变化率乘以设定的系数,作为最高的 冷料仓对应的第二速度。Specifically, the material level change rate of the aggregate silo can be used as the second speed corresponding to the cold silo with the highest priority. The material level change rate of the aggregate silo can also be multiplied by the set coefficient as the second speed corresponding to the highest cold silo.
第三步,基于第一速度和第二速度,确定优先级最高的冷料仓的当前上料速度。具体的,可以按照预设算法,基于第一速度和第二速度,确定优先级最高的冷料仓的当前上料速度。示例性的,可以将第一速度和第二速度求和,得到优先级最高的冷料仓的当前上料速度。也可以对第一速度和第二速度求均值,得到优先级最高的冷料仓的当前上料速度。The third step is to determine the current feeding speed of the cold silo with the highest priority based on the first speed and the second speed. Specifically, the current feeding speed of the cold silo with the highest priority can be determined based on the first speed and the second speed according to a preset algorithm. For example, the first speed and the second speed can be summed to obtain the current feeding speed of the cold silo with the highest priority. You can also average the first speed and the second speed to obtain the current loading speed of the cold silo with the highest priority.
步骤303、将各骨料仓的料位值与预设料位区间进行对比。Step 303: Compare the material level value of each aggregate bin with the preset material level interval.
实际应用中,可以预先设置各骨料仓对应的预设料位区间,各骨料仓对应的预设料位区间可以相同,也可以不同。由于各骨料仓对骨料的需求量可能不同,单独设置每个骨料仓对应的预设料位区间,控制更加准确。可以接收用户输入的预设料位区间,也可以根据生产配方对骨料的需求量自动确定预设料位区间。生产配方中一般包含需求的各骨料的比例,该骨料的比例能够表征骨料的需求量。例如,可以预先设置骨料的需求量与预设料位区间的对应关系,基于该对应关系确定骨料的需求量对应的预设料位区间。In practical applications, the preset material level intervals corresponding to each aggregate bin can be preset, and the preset material level intervals corresponding to each aggregate bin can be the same or different. Since the demand for aggregates in each aggregate bin may be different, setting the preset material level interval corresponding to each aggregate bin separately will make the control more accurate. It can receive the preset material level interval input by the user, and can also automatically determine the preset material level interval based on the demand for aggregates in the production formula. The production formula generally contains the required proportion of each aggregate, and the proportion of the aggregate can represent the demand for the aggregate. For example, the corresponding relationship between the demand for aggregate and the preset material level interval can be set in advance, and the preset material level interval corresponding to the demand for aggregate is determined based on the correspondence.
步骤304、基于各冷料仓的当前上料速度以及各对比的结果,确定各冷料仓的目标上料速度。Step 304: Determine the target feeding speed of each cold silo based on the current feeding speed of each cold silo and the results of each comparison.
其中,预设料位区间可以包括料位值依次增大的第一料位区间、第二料位区间和第三料位区间。那么,基于各冷料仓的当前上料速度以及各对比的结果,确定各冷料仓的目标上料速度,具体可以包括:The preset material level interval may include a first material level interval, a second material level interval and a third material level interval in which the material level value increases sequentially. Then, based on the current feeding speed of each cold silo and the results of each comparison, determine the target feeding speed of each cold silo, which may include:
若骨料仓的料位值位于第一料位区间内,将为骨料仓供料的至少一个冷料仓的当前上料速度增加,以得到为骨料仓供料的至少一个冷料仓的目标上料速度。若骨料仓的料位值位于第一料位区间内,说明骨料仓内的骨料较少,需要增加骨料,避免缺料,此时,可以增加当前上料速度。If the material level value of the aggregate silo is within the first material level interval, the current feeding speed of at least one cold silo supplying material to the aggregate silo is increased to obtain at least one cold silo supplying material to the aggregate silo. target feeding speed. If the material level value of the aggregate bin is within the first material level interval, it means that there is less aggregate in the aggregate bin and more aggregate needs to be added to avoid material shortage. At this time, the current feeding speed can be increased.
若骨料仓的料位值位于第二料位区间内,将为骨料仓供料的至少一个冷料仓的当前上料速度,作为为骨料仓供料的至少一个冷料仓的目标上料速度。若骨料仓的料位值位于第二料位区间内,说明骨料仓内的骨料比较合适,维持当前上料速度即可。If the material level value of the aggregate silo is within the second material level interval, the current feeding speed of at least one cold silo supplying material to the aggregate silo will be used as the target of at least one cold silo supplying material to the aggregate silo. Feeding speed. If the material level value of the aggregate bin is within the second material level range, it means that the aggregate in the aggregate bin is more suitable and the current feeding speed can be maintained.
若骨料仓的料位值位于第三料位区间内,将为骨料仓供料的至少一个冷料仓的当前上料速度减小,以得到为骨料仓供料的至少一个冷料仓的目 标上料速度。若骨料仓的料位值位于第三料位区间内,说明骨料仓内的骨料较多,为避免溢料,此时,可以减小当前上料速度。If the material level value of the aggregate silo is within the third material level interval, the current feeding speed of at least one cold material silo that supplies material to the aggregate silo is reduced to obtain at least one cold material that supplies material to the aggregate silo. The target loading speed of the warehouse. If the material level value of the aggregate bin is within the third material level interval, it means that there is more aggregate in the aggregate bin. In order to avoid overflow, the current feeding speed can be reduced at this time.
其中,可以按照预设步长,进行冷料仓的当前上料速度减小或者增加,预设步长的具体值可以根据实际情况设置,此处不做具体限定。当然也可以基于其它方式实现冷料仓的当前上料速度减小或者增加,此处不再一一列举。Among them, the current feeding speed of the cold material bin can be reduced or increased according to the preset step length. The specific value of the preset step length can be set according to the actual situation, and is not specifically limited here. Of course, the current feeding speed of the cold material bin can also be reduced or increased based on other methods, which will not be listed here.
本实施例中,综合考虑了冷料数据模型中提供的冷料中各骨料的含量,以及各骨料仓的卸料速度、料位值和料位变化率等多方面的因素,准确衡量各冷料仓的当前上料速度,并基于各骨料仓的料位值与预设料位区间的对比的结果,进而确定各冷料仓的目标上料速度,准确实现了冷料仓的上料速度的定量控制。In this embodiment, the content of each aggregate in the cold material provided in the cold material data model, as well as the unloading speed, material level value and material level change rate of each aggregate bin are comprehensively considered to accurately measure The current feeding speed of each cold silo is determined based on the comparison between the material level value of each aggregate silo and the preset material level interval, and the target feeding speed of each cold silo is determined to accurately realize the loading of the cold silo. Quantitative control of feeding speed.
在示例性实施例中,上料控制方法还可以包括:检测各冷料仓的料位值和/或表征是否可供料的供应状态;相应的,基于冷料供应优先级,确定为骨料仓供料的至少一个冷料仓中冷料的优先级最高的冷料仓,具体可以包括:基于冷料供应优先级,以及基于各冷料仓的料位值和/或表征是否可供料的供应状态,确定为骨料仓供料的可用的至少一个冷料仓中冷料的优先级最高的冷料仓,可用的冷料仓是料位值大于预设料位值和/或供应状态表征可供料的冷料仓。In an exemplary embodiment, the material loading control method may also include: detecting the material level value of each cold material bin and/or a supply status indicating whether material is available; accordingly, based on the cold material supply priority, determine the aggregate The cold silo with the highest priority of cold material in at least one cold silo supplied by the warehouse may include: based on the cold material supply priority, and based on the material level value of each cold silo and/or indicating whether material is available supply status, determine the cold silo with the highest priority of cold material in at least one available cold silo that supplies materials to the aggregate silo. The available cold silo has a material level value greater than the preset material level value and/or supply The status represents the cold silo available for feeding.
实际应用中,可以在冷料仓中设置料位计,用于检测冷料仓的料位值,若冷料仓的料位值大于预设料位值,说明该冷料仓的冷料足够,若冷料仓的料位值小于或者等于预设料位值,说明该冷料仓即将缺料。也可以在冷料仓的底部设置接近传感器,用于检测冷料仓的供应状态,若冷料仓已空,则无法供料,此时,接近传感器可以发出无物体接近的电信号给控制器,控制器可以确定冷料仓的供应状态为不可供料,以防止空转,否则,可以确定冷料仓的供应状态为可供料。In practical applications, a material level meter can be set up in the cold material bin to detect the material level value of the cold material bin. If the material level value of the cold material bin is greater than the preset material level value, it means that the cold material in the cold material bin is sufficient. , if the material level value of the cold material bin is less than or equal to the preset material level value, it means that the cold material bin is about to be short of material. A proximity sensor can also be set at the bottom of the cold silo to detect the supply status of the cold silo. If the cold silo is empty, the material cannot be supplied. At this time, the proximity sensor can send an electrical signal to the controller that no object is approaching. , the controller can determine that the supply status of the cold silo is unavailable to prevent idling, otherwise, it can determine that the supply status of the cold silo is available.
为保证连续生产,实施中,可以优先利用可用的冷料仓,即料位值大于预设料位值和/或供应状态表征可供料的冷料仓,为骨料仓进行供料,避免出现缺料的情况影响生产。当冷料仓小于或者等于预设料位值和/或不可供料时,可以自动切换至可用的冷料的优先级最高的冷料仓,例如,可以由骨料对应的冷料供应优先级中冷料的优先级最高(即最优供应冷料)的 冷料仓切换至冷料的优先级次高(即次优供应冷料)的冷料仓。In order to ensure continuous production, during implementation, the available cold material bins can be prioritized, that is, the cold material bins whose material level value is greater than the preset material level value and/or the supply status indicates the available materials, to supply materials to the aggregate bin to avoid The shortage of materials affects production. When the cold material bin is less than or equal to the preset material level value and/or is unavailable, it can automatically switch to the cold material bin with the highest priority of available cold material. For example, the cold material supply priority can be determined by the cold material supply priority corresponding to the aggregate. The cold material bin with the highest priority for cold materials (i.e., optimal cold material supply) is switched to the cold material bin with the second highest cold material priority (i.e., suboptimal cold material supply).
在示例性实施例中,基于各冷料仓的当前上料速度以及各对比的结果,确定各冷料仓的目标上料速度,还可以包括:In an exemplary embodiment, determining the target feeding speed of each cold silo based on the current feeding speed of each cold silo and the results of each comparison may also include:
第一步、获取骨料供应优先级,骨料供应优先级是按照各骨料仓的骨料的需求量确定的,骨料仓的骨料的需求量越大,骨料仓的骨料的优先级越高。The first step is to obtain the aggregate supply priority. The aggregate supply priority is determined according to the demand for aggregates in each aggregate bin. The greater the demand for aggregates in the aggregate bin, the higher the demand for aggregates in the aggregate bin. The higher the priority.
其中,各骨料仓的骨料的需求量可以是基于生产配方中各骨料的比例确定的。基于此,可以获取预先存储的生产配方,对生产配方中需求的各骨料的比例进行排序,基于排序结果,确定骨料供应优先级,骨料仓的骨料的需求量越大,骨料仓的骨料的优先级越高。The demand for aggregates in each aggregate bin can be determined based on the proportion of each aggregate in the production formula. Based on this, the pre-stored production formula can be obtained, and the proportion of each aggregate required in the production formula can be sorted. Based on the sorting results, the priority of aggregate supply is determined. The greater the demand for aggregates in the aggregate bin, the higher the aggregate demand. The higher the priority of the aggregates in the bin.
当然,也可以通过手动输入骨料供应优先级并存储。Of course, the aggregate supply priority can also be entered manually and stored.
第二步、确定各冷料仓的目标上料速度之和,得到总速度。The second step is to determine the sum of the target feeding speeds of each cold material bin to obtain the total speed.
第三步、若总速度大于预设的速度上限,基于骨料供应优先级,确定各骨料仓料中骨料的优先级最低的至少一个骨料仓。Step 3: If the total speed is greater than the preset speed limit, based on the aggregate supply priority, determine at least one aggregate bin with the lowest priority among the aggregate bins.
第四步、将为优先级最低的至少一个骨料仓供料的至少一个冷料仓的目标上料速度减小,以使得总速度小于或者等于预设的速度上限。The fourth step is to reduce the target feeding speed of at least one cold silo that supplies at least one aggregate silo with the lowest priority, so that the total speed is less than or equal to the preset speed upper limit.
实际应用中,上料控制系统所能加载的负载是有限的,因此,需要在负载范围内,控制各冷料仓的目标上料速度。各冷料仓的目标上料速度之和能够反应上料控制系统加载的总的负载,若总速度超过预设的速度上限,上料控制系统将无法承受,在这种情况下,可以考虑按照骨料的需求量优先供应需求量大的骨料,减少需求量小的骨料的供应,基于此,设置上述骨料供应优先级,骨料仓的骨料的需求量越大,骨料仓的骨料的优先级越高,若确定的各冷料仓的目标上料速度的总速度大于预设的速度上限,则按照骨料供应优先级,将为优先级最低的至少一个骨料仓供料的至少一个冷料仓的目标上料速度减小,以使得总速度小于或者等于预设的速度上限,从而进一步保证连续生产。In practical applications, the load that the loading control system can load is limited. Therefore, it is necessary to control the target loading speed of each cold material bin within the load range. The sum of the target loading speeds of each cold silo can reflect the total load loaded by the loading control system. If the total speed exceeds the preset speed upper limit, the loading control system will not be able to bear it. In this case, you can consider The demand for aggregates gives priority to the supply of aggregates with large demand, and reduces the supply of aggregates with small demand. Based on this, the above-mentioned aggregate supply priority is set. The greater the demand for aggregates in the aggregate silo, the higher the demand for aggregates in the aggregate silo. The higher the priority of the aggregate, if the total speed of the determined target feeding speed of each cold silo is greater than the preset speed limit, then according to the aggregate supply priority, at least one aggregate silo with the lowest priority will be The target feeding speed of at least one cold silo of the supplied material is reduced so that the total speed is less than or equal to the preset speed upper limit, thereby further ensuring continuous production.
其中,将为优先级最低的至少一个骨料仓供料的至少一个冷料仓的目标上料速度减小,以使得总速度小于或者等于预设的速度上限时,具体的,可以先减小一个优先级最低的冷料仓的目标上料速度,若该一个优先级最低的冷料仓的目标上料速度减小到零,再减小一个优先级次低的冷料仓的 目标上料速度,依此类推,直至总速度小于或者等于预设的速度上限。如此,可以尽量使得骨料优先级高的优先供应。Among them, the target feeding speed of at least one cold silo that supplies at least one aggregate silo with the lowest priority is reduced so that the total speed is less than or equal to the preset speed upper limit. Specifically, it can be reduced first The target loading speed of a cold silo with the lowest priority. If the target loading speed of the cold silo with the lowest priority is reduced to zero, then reduce the target loading speed of the cold silo with the next lowest priority. speed, and so on, until the total speed is less than or equal to the preset speed upper limit. In this way, aggregates with high priority can be supplied first.
在示例性实施例中,可以根据用户的第一输入操作,确定冷料仓的冷料的种类。冷料因原材料可能来自地质不同的地区等因素,导致形成的冷料的成分有差异。实际应用中,可以预先获取各种冷料中各骨料的含量,以构建冷料数据模型。用户可以根据生产的需要,通过输入操作,选择冷料仓的冷料的种类,基于选择的冷料仓的冷料的种类,从冷料数据模型中获取冷料仓的冷料中各骨料的含量,生产更加灵活。In an exemplary embodiment, the type of cold material in the cold material bin may be determined according to the user's first input operation. Because the raw materials of cold materials may come from different geological areas and other factors, the composition of the cold materials formed will be different. In practical applications, the content of each aggregate in various cold materials can be obtained in advance to build a cold material data model. Users can select the type of cold material in the cold material silo through input operations according to production needs. Based on the selected type of cold material in the cold material silo, each aggregate in the cold material in the cold material silo is obtained from the cold material data model. content, production is more flexible.
在示例性实施例中,可以根据用户的第二输入操作,更新冷料仓的冷料中的不同骨料的含量。当冷料中的不同骨料的含量改变之后,骨料对应的冷料供应优先级也会发生改变。本实施例适用于现场冷料的种类较少的情况,骨料对应的冷料供应优先级中优先级最高的冷料没有,则可以利用与其它冷料仓的冷料的种类相同的冷料来替代,可以通过输入操作来更新用来替代的冷料中的不同骨料的含量,使用来替代的冷料成为骨料对应的冷料供应优先级中优先级最高的冷料。此时,多个冷料中放的是同一种冷料,但是,可以通过手动调整冷料数据模型中的骨料的含量来改变骨料对应的冷料供应优先级,以使装同一种冷料的不同冷料仓成为不同骨料的最优供应者,而不是同一骨料的最优供应者。In an exemplary embodiment, the contents of different aggregates in the cold material of the cold material bin may be updated according to the user's second input operation. When the content of different aggregates in the cold material changes, the cold material supply priority corresponding to the aggregate will also change. This embodiment is suitable for situations where there are fewer types of cold materials on site. If there is no cold material with the highest priority in the cold material supply priority corresponding to the aggregate, cold materials of the same type as those in other cold material bins can be used. To replace, you can update the content of different aggregates in the cold material used for replacement through input operations. The cold material used for replacement becomes the cold material with the highest priority in the cold material supply priority corresponding to the aggregate. At this time, the same cold material is placed in multiple cold materials. However, the cold material supply priority corresponding to the aggregate can be changed by manually adjusting the aggregate content in the cold material data model so that the same cold material is installed. Different cold silos of materials become the optimal suppliers of different aggregates, rather than the optimal suppliers of the same aggregate.
示例性的,冷料数据模型可以是通过如下方式构建的:将目标冷料仓中的冷料输送至多个骨料仓中,其中,冷料中各骨料分别进入对应的骨料仓中;检测冷料中各骨料在对应的骨料仓的储存量;基于冷料中各骨料的储存量,确定冷料中各骨料的含量;基于冷料中各骨料的含量,构建冷料数据模型。这里的目标冷料仓是当前待确定冷料中各骨料的含量的冷料仓。冷料仓和骨料仓均是沥青搅拌站中已有的,参见图2所示的沥青搅拌站中的上料控制系统,基于该上料控制系统,可以将冷料仓中的冷料输送至多个骨料仓中。如此,利用已有的沥青搅拌站就可以实现冷料数据模型的自动构建,无需其它专业设备,操作简单,具有很强的推广性。For example, the cold material data model can be constructed in the following manner: transport the cold material in the target cold material bin to multiple aggregate bins, where each aggregate in the cold material enters the corresponding aggregate bin respectively; Detect the storage amount of each aggregate in the cold material in the corresponding aggregate bin; determine the content of each aggregate in the cold material based on the storage amount of each aggregate in the cold material; build a cold material based on the content of each aggregate in the cold material Material data model. The target cold material bin here is the cold material bin where the content of each aggregate in the cold material is currently to be determined. Both the cold material silo and the aggregate silo are existing in the asphalt mixing plant. Refer to the material loading control system in the asphalt mixing plant shown in Figure 2. Based on this material loading control system, the cold material in the cold material silo can be transported to multiple aggregate bins. In this way, the existing asphalt mixing station can be used to automatically construct the cold material data model without the need for other professional equipment. The operation is simple and has strong generalizability.
基于以上实施例,将目标冷料仓中的冷料输送至多个骨料仓中,包括:将目标冷料仓中的冷料输送至筛网,通过筛网将冷料中的各骨料筛分至对应的骨料仓中。其中的筛网具有筛分功能,用于将冷料筛分成不同粒径的 骨料,然后分别存放到对应粒径的骨料仓中。这里的筛网可以为振动筛。如此,可以对冷料的各骨料进行准确区分。Based on the above embodiment, transporting the cold material in the target cold material bin to multiple aggregate bins includes: transporting the cold material in the target cold material bin to a screen, and screening each aggregate in the cold material through the screen. Divide into corresponding aggregate bins. The screen has a screening function and is used to screen the cold material into aggregates of different particle sizes, and then store them into aggregate bins of corresponding particle sizes. The screen here can be a vibrating screen. In this way, each aggregate of the cold material can be accurately distinguished.
其中,检测冷料中各骨料在对应的骨料仓的储存量,其具体实现方式可以包括:利用计量秤,检测冷料中各骨料在对应的骨料仓的重量;或者,利用料位计,检测冷料中各骨料在对应的骨料仓的料位值。Among them, detecting the storage amount of each aggregate in the cold material in the corresponding aggregate bin, the specific implementation method may include: using a weighing scale to detect the weight of each aggregate in the cold material in the corresponding aggregate bin; or, using the material The level meter detects the material level value of each aggregate in the cold material in the corresponding aggregate bin.
如图2所示的上料控制系统,骨料仓对应有计量秤,可以按照顺序来依次将每个骨料仓的骨料卸放到计量秤上,通过计量秤来称量当前卸放的骨料的重量,作为储存量,即得到w 1,w 2,w 3,w 4,w 5,w 6,……w n,w n表示n个骨料仓中n号骨料仓的骨料的重量。也可以利用每个骨料仓中的料位计来检测骨料仓的骨料的料位值,作为储存量,即得到L 1,L 2,L 3,L 4,L 5,L 6……L n,L n表示n个骨料仓中n号骨料仓的骨料的料位值,料位值能够反应骨料的体积。 As shown in Figure 2, the loading control system has a weighing scale corresponding to the aggregate bin. The aggregates in each aggregate bin can be discharged to the weighing scale in sequence, and the currently discharged weight can be weighed by the weighing scale. The weight of the aggregate, as the storage capacity, is obtained as w 1 , w 2 , w 3 , w 4 , w 5 , w 6 ,... w n , w n represents the bone in the n aggregate bin in the n aggregate bins The weight of the material. The material level meter in each aggregate bin can also be used to detect the material level value of the aggregate in the aggregate bin, as the storage amount, that is, L 1 , L 2 , L 3 , L 4 , L 5 , L 6 ... ...L n , L n represents the material level value of the aggregate in the n aggregate bin in n aggregate bins, and the material level value can reflect the volume of the aggregate.
相应的,基于冷料中各骨料的储存量,确定冷料中各骨料的含量,其实现方式可以包括:将各骨料的储存量求和,得到总储存量;基于各骨料的储存量与总储存量的比值,确定各骨料的含量。Correspondingly, the content of each aggregate in the cold material is determined based on the storage capacity of each aggregate in the cold material. The implementation method may include: summing the storage capacity of each aggregate to obtain the total storage capacity; based on the storage capacity of each aggregate The ratio of storage capacity to total storage capacity determines the content of each aggregate.
实际应用中,可以直接将骨料的储存量与总储存量的比值,作为骨料的含量。In practical applications, the ratio of the aggregate storage capacity to the total storage capacity can be directly used as the aggregate content.
若骨料的储存量为骨料的重量,则冷料的n种骨料中第k种骨料的含量A k=w k/(w 1+w 2+w 3+w 4+w 5+w 6+…+w n),1≤k≤n,w k为第k种骨料的重量。基于此,骨料的含量为骨料的重量比例。 If the storage capacity of aggregate is the weight of aggregate, then the content of the kth aggregate in the n aggregates of the cold material A k =w k /(w 1 +w 2 +w 3 +w 4 +w 5 + w 6 +...+w n ), 1≤k≤n, w k is the weight of the kth aggregate. Based on this, the content of aggregate is the weight proportion of aggregate.
若骨料的储存量为骨料的料位值,冷料的n种骨料中第k种骨料的含量A k=L k/(L 1+L 2+L 3+L 4+L 5+L 6+…+L n),1≤k≤n,L k为第k种骨料的料位值。基于此,骨料的含量为骨料的体积比例。 If the storage capacity of aggregate is the material level value of the aggregate, the content of the kth aggregate in the n aggregates of the cold material A k =L k /(L 1 +L 2 +L 3 +L 4 +L 5 +L 6 +...+L n ), 1≤k≤n, L k is the material level value of the kth aggregate. Based on this, the content of aggregate is the volume proportion of aggregate.
当然,也可以将骨料的储存量与总储存量的比值乘以设定的系数之后作为骨料的含量。Of course, the ratio of the aggregate storage amount to the total storage amount can also be multiplied by a set coefficient as the aggregate content.
如此,通过沥青搅拌站中已有的计量秤和料位计,即可以准确得到每个骨料的储存量,进而准确得到冷料中每个骨料的含量。In this way, through the existing weighing scales and material level meters in the asphalt mixing station, the storage volume of each aggregate can be accurately obtained, and then the content of each aggregate in the cold material can be accurately obtained.
在示例性实施例中,将目标冷料仓中的冷料输送至多个骨料仓中,其具体实现方式可以包括:将目标冷料仓中的冷料,按照预设上料时长或者预设上料总量,输送至多个骨料仓中。In an exemplary embodiment, the cold material in the target cold silo is transported to multiple aggregate silos. The specific implementation may include: transporting the cold material in the target cold silo according to the preset loading time or the preset The total amount of material is transported to multiple aggregate bins.
考虑到本实施例的主要目的是得到目标冷料仓中的冷料的各骨料的含量,因此,无需持续上料,只要能够准确地分析出冷料的各骨料的含量即可,如此,可以提高处理效率,基于此,本实施例提供了两种将冷料输送至多个骨料仓的方式,一种方式是,持续上料预设上料时长,然后就停止上料,另一种方式是,按照预设上料总量上料,达到该预设上料总量之后,则停止上料。对于按照预设上料总量上料的方式来说,可以预先称量该预设上料总量的冷料,放入冷料仓中。其中的预设上料时长和预设上料总量均可以根据经验统计进行设置,此处不做具体限定。Considering that the main purpose of this embodiment is to obtain the content of each aggregate of the cold material in the target cold material bin, there is no need to continue feeding materials, as long as the content of each aggregate of the cold material can be accurately analyzed, so , can improve processing efficiency. Based on this, this embodiment provides two ways to transport cold materials to multiple aggregate bins. One way is to continue loading for a preset loading time, and then stop loading. The other way is to continue loading for a preset loading time, and then stop loading. The first method is to load materials according to the preset total amount of materials, and stop loading after reaching the preset total amount of materials. For the method of loading materials according to the preset total amount of materials, the cold materials of the preset total amount of materials can be weighed in advance and put into the cold material bin. The preset feeding time and the preset total amount of feeding can be set based on empirical statistics, and there are no specific limitations here.
在示例性实施例中,基于冷料中各骨料的含量,构建冷料数据模型,其具体实现方式可以包括:将冷料中各骨料的含量排序;基于排序结果,构建冷料数据模型。参见表2所示的冷料数据模型,可以清晰地反应冷料中各骨料的含量排序,查询更加方便。In an exemplary embodiment, a cold material data model is constructed based on the content of each aggregate in the cold material. The specific implementation may include: sorting the content of each aggregate in the cold material; building a cold material data model based on the sorting results. . Refer to the cold material data model shown in Table 2, which can clearly reflect the content sorting of each aggregate in the cold material, making the query more convenient.
在示例性实施例中,在将目标冷料仓中的冷料输送至多个骨料仓中之前,还可以包括:针对多个冷料仓,按照预设顺序,依次选择一个冷料仓作为目标冷料仓。In an exemplary embodiment, before transporting the cold material in the target cold silo to multiple aggregate silos, it may also include: selecting one cold silo as the target in a preset order for the multiple cold silos. Cold silo.
实际应用中,可以在多个冷料仓中储存多种冷料,基于此,可以针对每种冷料,确定冷料中各骨料的含量,基于多个冷料仓的冷料中各骨料的含量,构建冷料数据模型。如此,可以快速得到包含多种冷料中各骨料的含量的冷料数据模型,非常全面。In practical applications, a variety of cold materials can be stored in multiple cold material silos. Based on this, the content of each aggregate in the cold material can be determined for each cold material. Based on the content of each aggregate in the cold material in multiple cold material silos, The content of the cold material is determined and a cold material data model is constructed. In this way, a very comprehensive cold material data model containing the content of each aggregate in a variety of cold materials can be quickly obtained.
基于图2所示的上料控制系统,举例来说,可以先将6个冷料仓中的1号冷料仓选择为目标冷料仓,将其中的1号冷料,按照预设上料时长和预设上料速度输送至多个骨料仓,然后停止上料,得到1号冷料仓的1号冷料中各骨料的含量之后,再将2号冷料仓选择为目标冷料仓,将其中的2号冷料,按照预设上料时长和预设上料速度输送至多个骨料仓,如此直到将6个冷料仓都选择完毕,得到6个冷料仓中的冷料的各骨料的含量,从而完成冷料数据库的自动构建。Based on the material loading control system shown in Figure 2, for example, cold material bin No. 1 among the six cold material bins can be selected as the target cold material bin, and cold material No. 1 among them can be loaded according to the preset The duration and preset feeding speed are transported to multiple aggregate bins, and then the feeding is stopped. After obtaining the content of each aggregate in the No. 1 cold material in the No. 1 cold material bin, the No. 2 cold material bin is selected as the target cold material. warehouse, and transport the No. 2 cold material to multiple aggregate warehouses according to the preset loading time and preset loading speed. In this way, until all 6 cold material warehouses are selected, the cold materials in the 6 cold material warehouses are obtained. The content of each aggregate in the material is determined to complete the automatic construction of the cold material database.
下面以具体的应用场景为例,对本申请实施例提供的一种上料控制方法进行更加详细地介绍。Taking a specific application scenario as an example, a feeding control method provided by the embodiment of the present application will be introduced in more detail below.
基于图2所示的沥青搅拌站的上料控制系统,控制器与各料位计、各变频器电连接。其中的控制器可以为PLC,其中的上位机可以为计算机。 另外,冷料仓中也可以设置料位计和接近传感器。上位机中可以存储冷料数据模型、生产配方和预设料位区间,还可以实时显示生产状态,例如冷料仓的上料速度等。其中的预设料位区间包括加速上料料位区间add_zone(即上述第一料位区间),定频料位区间static_zone(即上述第二料位区间),减速上料料位区间sub_zone(即上述第三料位区间)和满料料位stop_line等料位标志。其中,满料料位用于触发发出满料提示。另外,可以通过计算机,从冷料数据模型中选择生产用冷料的种类。Based on the feeding control system of the asphalt mixing station shown in Figure 2, the controller is electrically connected to each material level gauge and each frequency converter. The controller may be a PLC, and the host computer may be a computer. In addition, material level meters and proximity sensors can also be installed in the cold material bin. The host computer can store cold material data models, production recipes and preset material level intervals, and can also display production status in real time, such as the loading speed of the cold material bin. The preset material level intervals include the accelerated loading material level interval add_zone (i.e., the above-mentioned first material level interval), the fixed frequency material level interval static_zone (i.e., the above-mentioned second material level interval), and the decelerated loading material level interval sub_zone (i.e. The above third material level interval) and full material level stop_line and other material level marks. Among them, the full material level is used to trigger the full material prompt. In addition, the type of cold material for production can be selected from the cold material data model through the computer.
第一步、通过程序自动捕捉设备信息和设备状态。The first step is to automatically capture device information and device status through the program.
其中,设备状态包括皮带、滚筒、振动筛等的运行状态,若运行状态为开启状态,满足自适应上料前提条件。Among them, the equipment status includes the operating status of belts, rollers, vibrating screens, etc. If the operating status is on, the prerequisites for adaptive feeding are met.
其中的设备信息包括根据沥青搅拌站的机型选择的预设的上限频率,即所有的变频器的频率之和所允许的上限,可以转换为上述预设最大速度。The equipment information includes the preset upper limit frequency selected according to the model of the asphalt mixing station, that is, the upper limit allowed by the sum of the frequencies of all frequency converters, which can be converted into the above-mentioned preset maximum speed.
第二步、通过上位机交互,下载冷料数据模型,生产配方和预设料位区间,并基于生产配方中各骨料的比例确定骨料供应优先级,基于冷料数据模型,建立骨料对应的冷料供应优先级。The second step is to download the cold material data model, production formula and preset material level interval through host computer interaction, and determine the aggregate supply priority based on the proportion of each aggregate in the production formula. Based on the cold material data model, establish the aggregate Corresponding cold material supply priority.
第三步、自动获取冷料供料情况。The third step is to automatically obtain the cold material supply status.
具体的,可以通过冷料仓中的料位计和接近传感器来获取,以防止空转,及时切换冷料供应,具体可以参考以上相关实施例,此处不做赘述。Specifically, it can be obtained through the material level meter and proximity sensor in the cold material bin to prevent idling and switch the cold material supply in time. For details, please refer to the above related embodiments and will not be described in detail here.
第四步、自动获取不同骨料仓的料位计的料位值L 1、L 2、L 3、L 4、L 5、L 6,基于冷料数据模型、各骨料仓的卸料速度和料位变化率,计算各冷料仓的当前上料速度,将各骨料仓的料位值与预设料位区间进行对比,基于各冷料仓的当前上料速度以及各对比的结果,确定各冷料仓的目标上料速度。实施中,可以基于骨料仓对应的计量秤称量的骨料重量以及距离上一次称量经过的时长,得到骨料仓的卸料速度。 The fourth step is to automatically obtain the material level values L 1 , L 2 , L 3 , L 4 , L 5 , and L 6 of the material level meters of different aggregate bins, based on the cold material data model and the discharge speed of each aggregate bin. and material level change rate, calculate the current feeding speed of each cold material bin, compare the material level value of each aggregate bin with the preset material level interval, based on the current material loading speed of each cold material bin and the results of each comparison , determine the target feeding speed of each cold material bin. In implementation, the unloading speed of the aggregate silo can be obtained based on the weight of the aggregate measured by the weighing scale corresponding to the aggregate silo and the elapsed time since the last weighing.
进一步的,还可以确定各冷料仓的目标上料速度之和,得到总速度。若总速度大于预设的速度上限,基于骨料供应优先级,确定多个骨料仓料中骨料的优先级最低的至少一个骨料仓。将为优先级最低的至少一个骨料仓供料的至少一个冷料仓的目标上料速度减小,以使得总速度小于或者等于预设的速度上限。Furthermore, the sum of the target feeding speeds of each cold material bin can also be determined to obtain the total speed. If the total speed is greater than the preset speed upper limit, based on the aggregate supply priority, at least one aggregate bin with the lowest priority of aggregate among multiple aggregate bins is determined. The target feeding speed of at least one cold silo feeding at least one aggregate silo with the lowest priority is reduced so that the total speed is less than or equal to a preset speed upper limit.
第五步、控制器根据最终的各冷料仓的目标上料速度,控制冷料仓对 应的变频器输出对应的频率。Step 5: The controller controls the frequency corresponding to the inverter output of the cold silo based on the final target loading speed of each cold silo.
第六步、变频器控制电机的输出,以调整冷料仓的上料速度。Step 6: The frequency converter controls the output of the motor to adjust the loading speed of the cold material bin.
以上各步骤的具体实施方式可以参考以上相关实施例,此处不做赘述。For the specific implementation of each of the above steps, reference can be made to the above related embodiments and will not be described in detail here.
通过本实施例的方案,可以达到以下效果:1)无需人工干预上料,可以做到多种冷料的上料速度快速自动调整,从而达到稳定骨料仓的料位的目标,防止缺料和溢料等情况;2)对冷料的原材料要求低,作业方式灵活,可以通过计算机快速更换冷料的种类,从而完成对不同地区的冷料的种类的匹配;3)可以做到生产过程中冷料缺料时自动切换替代冷料,防止因缺料影响生产;4)可以通过调整冷料数据模型中的骨料的含量以调整骨料对应的冷料供应优先级的顺序,从而可以做到一种冷料供应多种骨料实现自动生产;5)可以依据骨料仓的料位值的变化自动控制冷料供应,从而能够降低多种冷料供应一种骨料时的溢料几率;6)通过配备的冷料数据模型,可以依据实际生产情况选择更换冷料供应的种类;7)可以依据生产配方人为设置或者自动设置预设料位区间。Through the solution of this embodiment, the following effects can be achieved: 1) Without manual intervention in feeding, the feeding speed of various cold materials can be quickly and automatically adjusted, thereby achieving the goal of stabilizing the material level of the aggregate bin and preventing material shortage and overflow; 2) The raw material requirements for cold materials are low, and the operation method is flexible. The type of cold materials can be quickly changed through the computer, thereby completing the matching of types of cold materials in different regions; 3) The production process can be completed When the medium cold material is short of material, it will automatically switch to replace the cold material to prevent the lack of material from affecting production; 4) The content of the aggregate in the cold material data model can be adjusted to adjust the order of the cold material supply priority corresponding to the aggregate, so that the cold material supply priority sequence can be adjusted. One kind of cold material can be supplied to multiple types of aggregates to achieve automatic production; 5) The supply of cold materials can be automatically controlled based on changes in the material level value of the aggregate bin, thereby reducing overflow when multiple types of cold materials are used to supply one type of aggregate. Probability; 6) Through the equipped cold material data model, the type of cold material supply can be selected and replaced according to the actual production situation; 7) The preset material level interval can be set manually or automatically according to the production formula.
下面对本申请提供的上料控制装置进行描述,下文描述的上料控制装置与上文描述的上料控制方法可相互对应参照。The feeding control device provided by the present application will be described below. The feeding control device described below and the feeding control method described above may be mutually referenced.
图4是本申请提供的上料控制装置的结构示意图。Figure 4 is a schematic structural diagram of the feeding control device provided by this application.
如图4所示,本实施例提供一种上料控制装置,包括:As shown in Figure 4, this embodiment provides a feeding control device, including:
速度确定模块401,用于基于冷料数据模型,确定各冷料仓的目标上料速度;各冷料仓用于为各骨料仓供料;冷料数据模型中包含每个冷料仓的冷料中各骨料的含量;The speed determination module 401 is used to determine the target feeding speed of each cold material silo based on the cold material data model; each cold material silo is used to supply materials to each aggregate silo; the cold material data model includes the data of each cold material silo. The content of each aggregate in the cold mix;
上料控制模块402,用于基于各冷料仓的目标上料速度,控制各冷料仓上料。The loading control module 402 is used to control the loading of each cold silo based on the target loading speed of each cold silo.
在示例性实施例中,速度确定模块,具体用于:In an exemplary embodiment, the speed determination module is specifically used for:
获取各骨料仓的料位值;Get the material level value of each aggregate bin;
基于冷料数据模型,计算各冷料仓的当前上料速度;Based on the cold material data model, calculate the current feeding speed of each cold material bin;
将各骨料仓的料位值与预设料位区间进行对比;Compare the material level value of each aggregate bin with the preset material level interval;
基于各冷料仓的当前上料速度以及各对比的结果,确定各冷料仓的目标上料速度。Based on the current feeding speed of each cold silo and the results of each comparison, the target feeding speed of each cold silo is determined.
在示例性实施例中,速度确定模块,具体用于:In an exemplary embodiment, the speed determination module is specifically used for:
获取各骨料仓的卸料速度和料位变化率;Obtain the discharge speed and material level change rate of each aggregate bin;
基于冷料数据模型、各骨料仓的卸料速度和料位变化率,计算各冷料仓的当前上料速度。Based on the cold material data model, the unloading speed and material level change rate of each aggregate bin, the current loading speed of each cold material bin is calculated.
在示例性实施例中,速度确定模块,具体用于:In an exemplary embodiment, the speed determination module is specifically used for:
针对每个骨料仓,获取与骨料仓的骨料对应的冷料供应优先级,基于冷料供应优先级,确定为骨料仓供料的至少一个冷料仓中冷料的优先级最高的冷料仓,基于骨料仓的卸料速度和料位变化率以及优先级最高的冷料仓的冷料中骨料仓的骨料的含量,确定优先级最高的冷料仓的当前上料速度;For each aggregate bin, obtain the cold material supply priority corresponding to the aggregate in the aggregate bin. Based on the cold material supply priority, determine the highest priority of cold material in at least one cold material bin that supplies material to the aggregate bin. cold silo, based on the unloading speed and material level change rate of the aggregate silo and the aggregate content of the cold material in the cold silo with the highest priority, determine the current load of the cold silo with the highest priority. Material speed;
其中,冷料供应优先级是按照各冷料仓的冷料中骨料仓的骨料的含量确定的,冷料仓的冷料中骨料仓的骨料的含量越大,冷料仓的冷料的优先级越高。Among them, the cold material supply priority is determined according to the aggregate content of the cold material in the cold material silo. The greater the aggregate content of the cold material in the cold material silo, the higher the cold material content in the cold material silo. The cold material has a higher priority.
在示例性实施例中,速度确定模块,具体用于:In an exemplary embodiment, the speed determination module is specifically used for:
基于骨料仓的卸料速度和优先级最高的冷料仓的冷料中骨料仓的骨料的含量,确定优先级最高的冷料仓对应的第一速度;Based on the unloading speed of the aggregate silo and the aggregate content of the cold material in the cold silo with the highest priority, determine the first speed corresponding to the cold silo with the highest priority;
基于骨料仓的料位变化率,确定优先级最高的冷料仓对应的第二速度;Based on the material level change rate of the aggregate silo, determine the second speed corresponding to the cold silo with the highest priority;
基于第一速度和第二速度,确定优先级最高的冷料仓的当前上料速度。Based on the first speed and the second speed, the current loading speed of the cold hopper with the highest priority is determined.
在示例性实施例中,速度确定模块,具体用于:In an exemplary embodiment, the speed determination module is specifically used for:
基于骨料仓的卸料速度与优先级最高的冷料仓的冷料中骨料仓的骨料的含量的比值,确定优先级最高的冷料仓对应的第一速度。Based on the ratio of the unloading speed of the aggregate bin to the aggregate content of the cold material in the cold bin with the highest priority, the first speed corresponding to the cold bin with the highest priority is determined.
在示例性实施例中,还包括:In an exemplary embodiment, it also includes:
检测模块,用于检测各冷料仓的料位值和/或表征是否可供料的供应状态;The detection module is used to detect the material level value of each cold material bin and/or indicate the supply status of whether the material is available;
速度确定模块,具体用于:Speed determination module, specifically used for:
基于冷料供应优先级,以及基于各冷料仓的料位值和/或表征是否可供料的供应状态,确定为骨料仓供料的可用的至少一个冷料仓中冷料的优先级最高的冷料仓,可用的冷料仓是料位值大于预设料位值和/或供应状态表征可供料的冷料仓。Based on the cold material supply priority, and based on the material level value of each cold material bin and/or the supply status indicating whether material is available, determine the priority of the cold material in at least one available cold material bin that supplies the aggregate bin. The highest cold material bin, the available cold material bin is the cold material bin whose material level value is greater than the preset material level value and/or the supply status indicates that the material is available.
在示例性实施例中,速度确定模块,具体用于:In an exemplary embodiment, the speed determination module is specifically used for:
基于各骨料仓对应的计量秤称量的骨料重量以及称量周期,得到各骨 料仓的卸料速度。Based on the weight of the aggregate measured by the weighing scale corresponding to each aggregate bin and the weighing cycle, the unloading speed of each aggregate bin is obtained.
在示例性实施例中,预设料位区间包括料位值依次增大的第一料位区间、第二料位区间和第三料位区间;速度确定模块,具体用于:In an exemplary embodiment, the preset material level interval includes a first material level interval, a second material level interval and a third material level interval whose material level values increase in sequence; the speed determination module is specifically used for:
若骨料仓的料位值位于第一料位区间内,将为骨料仓供料的至少一个冷料仓的当前上料速度增加,以得到为骨料仓供料的至少一个冷料仓的目标上料速度;If the material level value of the aggregate silo is within the first material level interval, the current feeding speed of at least one cold silo supplying material to the aggregate silo is increased to obtain at least one cold silo supplying material to the aggregate silo. The target feeding speed;
若骨料仓的料位值位于第二料位区间内,将为骨料仓供料的至少一个冷料仓的当前上料速度,作为为骨料仓供料的至少一个冷料仓的目标上料速度;If the material level value of the aggregate silo is within the second material level interval, the current feeding speed of at least one cold silo supplying material to the aggregate silo will be used as the target of at least one cold silo supplying material to the aggregate silo. Feeding speed;
若骨料仓的料位值位于第三料位区间内,将为骨料仓供料的至少一个冷料仓的当前上料速度减小,以得到为骨料仓供料的至少一个冷料仓的目标上料速度。If the material level value of the aggregate silo is within the third material level interval, the current feeding speed of at least one cold material silo that supplies material to the aggregate silo is reduced to obtain at least one cold material that supplies material to the aggregate silo. The target loading speed of the warehouse.
在示例性实施例中,速度确定模块,还用于:In an exemplary embodiment, the speed determination module is also used to:
获取骨料供应优先级,骨料供应优先级是按照各骨料仓的骨料的需求量确定的,骨料仓的骨料的需求量越大,骨料仓的骨料的优先级越高;Obtain the aggregate supply priority. The aggregate supply priority is determined according to the demand for aggregates in each aggregate bin. The greater the demand for aggregates in the aggregate bin, the higher the priority of the aggregate in the aggregate bin. ;
确定各冷料仓的目标上料速度之和,得到总速度;Determine the sum of the target feeding speeds of each cold material bin to obtain the total speed;
若总速度大于预设的速度上限,基于骨料供应优先级,确定各骨料仓中骨料的优先级最低的至少一个骨料仓;If the total speed is greater than the preset speed limit, based on the aggregate supply priority, determine at least one aggregate bin with the lowest priority of aggregate in each aggregate bin;
将为优先级最低的至少一个骨料仓供料的至少一个冷料仓的目标上料速度减小,以使得总速度小于或者等于预设的速度上限。The target feeding speed of at least one cold silo feeding at least one aggregate silo with the lowest priority is reduced so that the total speed is less than or equal to a preset speed upper limit.
在示例性实施例中,各骨料仓的骨料的需求量是基于生产配方中各骨料的比例确定的。In an exemplary embodiment, the required amount of aggregate in each aggregate bin is determined based on the proportion of each aggregate in the production formula.
在示例性实施例中,还包括:In an exemplary embodiment, it also includes:
输入模块,用于根据用户的第一输入操作,确定冷料仓的冷料的种类;The input module is used to determine the type of cold material in the cold material bin according to the user's first input operation;
和/或,根据用户的第二输入操作,更新冷料仓的冷料中的不同骨料的含量。And/or, according to the user's second input operation, update the contents of different aggregates in the cold material of the cold material bin.
本申请实施例还提供一种沥青搅拌站,包括沥青搅拌站本体和控制器,控制器用于实现如以上任一实施例中的上料控制方法。An embodiment of the present application also provides an asphalt mixing station, including an asphalt mixing station body and a controller. The controller is used to implement the feeding control method as in any of the above embodiments.
图5示例了一种电子设备的实体结构示意图,如图5所示,该电子设备可以包括:处理器(processor)510、通信接口(Communications Interface)520、 存储器(memory)530和通信总线540,其中,处理器510,通信接口520,存储器530通过通信总线540完成相互间的通信。处理器510可以调用存储器530中的逻辑指令,以执行上料控制方法,该方法包括:Figure 5 illustrates a schematic diagram of the physical structure of an electronic device. As shown in Figure 5, the electronic device may include: a processor (processor) 510, a communication interface (Communications Interface) 520, a memory (memory) 530 and a communication bus 540. Among them, the processor 510, the communication interface 520, and the memory 530 complete communication with each other through the communication bus 540. The processor 510 can call logical instructions in the memory 530 to execute a loading control method, which includes:
基于冷料数据模型,确定各冷料仓的目标上料速度;各冷料仓用于为各骨料仓供料;冷料数据模型中包含每个冷料仓的冷料中各骨料的含量;Based on the cold material data model, the target feeding speed of each cold material bin is determined; each cold material bin is used to supply materials to each aggregate bin; the cold material data model includes the data of each aggregate in the cold material of each cold material bin content;
基于各冷料仓的目标上料速度,控制各冷料仓上料。Based on the target feeding speed of each cold silo, the loading of each cold silo is controlled.
此外,上述的存储器530中的逻辑指令可以通过软件功能单元的形式实现并作为独立的产品销售或使用时,可以存储在一个计算机可读取存储介质中。基于这样的理解,本申请的技术方案本质上或者说对现有技术做出贡献的部分或者该技术方案的部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质中,包括若干指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)执行本申请各个实施例方法的全部或部分步骤。而前述的存储介质包括:U盘、移动硬盘、只读存储器(ROM,Read-Only Memory)、随机存取存储器(RAM,Random Access Memory)、磁碟或者光盘等各种可以存储程序代码的介质。In addition, the above-mentioned logical instructions in the memory 530 can be implemented in the form of software functional units and can be stored in a computer-readable storage medium when sold or used as an independent product. Based on this understanding, the technical solution of the present application is essentially or the part that contributes to the existing technology or the part of the technical solution can be embodied in the form of a software product. The computer software product is stored in a storage medium, including Several instructions are used to cause a computer device (which may be a personal computer, a server, or a network device, etc.) to execute all or part of the steps of the methods of various embodiments of the present application. The aforementioned storage media include: U disk, mobile hard disk, read-only memory (ROM, Read-Only Memory), random access memory (RAM, Random Access Memory), magnetic disk or optical disk and other media that can store program code. .
另一方面,本申请还提供一种计算机程序产品,计算机程序产品包括存储在非暂态计算机可读存储介质上的计算机程序,计算机程序包括程序指令,当程序指令被计算机执行时,计算机能够执行上述各方法所提供的上料控制方法,该方法包括:On the other hand, the present application also provides a computer program product. The computer program product includes a computer program stored on a non-transitory computer-readable storage medium. The computer program includes program instructions. When the program instructions are executed by the computer, the computer can execute The feeding control method provided by each of the above methods includes:
基于冷料数据模型,确定各冷料仓的目标上料速度;各冷料仓用于为各骨料仓供料;冷料数据模型中包含每个冷料仓的冷料中各骨料的含量;Based on the cold material data model, the target feeding speed of each cold material bin is determined; each cold material bin is used to supply materials to each aggregate bin; the cold material data model includes the data of each aggregate in the cold material of each cold material bin content;
基于各冷料仓的目标上料速度,控制各冷料仓上料。Based on the target feeding speed of each cold silo, the loading of each cold silo is controlled.
又一方面,本申请还提供一种非暂态计算机可读存储介质,其上存储有计算机程序,该计算机程序被处理器执行时实现以执行上述各提供的上料控制方法,该方法包括:On the other hand, the present application also provides a non-transitory computer-readable storage medium on which a computer program is stored. The computer program is implemented when executed by the processor to execute the above-mentioned feeding control methods. The method includes:
基于冷料数据模型,确定各冷料仓的目标上料速度;各冷料仓用于为各骨料仓供料;冷料数据模型中包含每个冷料仓的冷料中各骨料的含量;Based on the cold material data model, the target feeding speed of each cold material bin is determined; each cold material bin is used to supply materials to each aggregate bin; the cold material data model includes the data of each aggregate in the cold material of each cold material bin content;
基于各冷料仓的目标上料速度,控制各冷料仓上料。Based on the target feeding speed of each cold silo, the loading of each cold silo is controlled.
以上所描述的装置实施例仅仅是示意性的,其中作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是或 者也可以不是物理单元,即可以位于一个地方,或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或者全部模块来实现本实施例方案的目的。本领域普通技术人员在不付出创造性的劳动的情况下,即可以理解并实施。The device embodiments described above are only illustrative. The units described as separate components may or may not be physically separated. The components shown as units may or may not be physical units, that is, they may be located in one place. , or it can be distributed to multiple network units. Some or all of the modules can be selected according to actual needs to achieve the purpose of the solution of this embodiment. Persons of ordinary skill in the art can understand and implement the method without any creative effort.
通过以上的实施方式的描述,本领域的技术人员可以清楚地了解到各实施方式可借助软件加必需的通用硬件平台的方式来实现,当然也可以通过硬件。基于这样的理解,上述技术方案本质上或者说对现有技术做出贡献的部分可以以软件产品的形式体现出来,该计算机软件产品可以存储在计算机可读存储介质中,如ROM/RAM、磁碟、光盘等,包括若干指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)执行各个实施例或者实施例的某些部分的方法。Through the above description of the embodiments, those skilled in the art can clearly understand that each embodiment can be implemented by software plus a necessary general hardware platform, and of course, it can also be implemented by hardware. Based on this understanding, the part of the above technical solution that essentially contributes to the existing technology can be embodied in the form of a software product. The computer software product can be stored in a computer-readable storage medium, such as ROM/RAM, magnetic disc, optical disk, etc., including a number of instructions to cause a computer device (which can be a personal computer, a server, or a network device, etc.) to execute various embodiments or methods of certain parts of the embodiments.
最后应说明的是:以上实施例仅用以说明本申请的技术方案,而非对其限制;尽管参照前述实施例对本申请进行了详细的说明,本领域的普通技术人员应当理解:其依然可以对前述各实施例所记载的技术方案进行修改,或者对其中部分技术特征进行等同替换;而这些修改或者替换,并不使相应技术方案的本质脱离本申请各实施例技术方案的精神和范围。Finally, it should be noted that the above embodiments are only used to illustrate the technical solution of the present application, but not to limit it; although the present application has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art should understand that it can still be Modifications are made to the technical solutions described in the foregoing embodiments, or equivalent substitutions are made to some of the technical features; however, these modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions in the embodiments of the present application.

Claims (14)

  1. 一种上料控制方法,包括:A feeding control method includes:
    基于冷料数据模型,确定各冷料仓的目标上料速度;所述各冷料仓用于为各骨料仓供料;所述冷料数据模型中包含每个所述冷料仓的冷料中各骨料的含量;Based on the cold material data model, the target feeding speed of each cold material bin is determined; each cold material bin is used to supply material to each aggregate bin; the cold material data model includes the cold material data of each cold material bin. The content of each aggregate in the material;
    基于各所述冷料仓的目标上料速度,控制各所述冷料仓上料。Based on the target feeding speed of each cold silo, the loading of each cold silo is controlled.
  2. 根据权利要求1所述的上料控制方法,其中,所述基于冷料数据模型,确定各冷料仓的目标上料速度,包括:The loading control method according to claim 1, wherein the determining the target loading speed of each cold material bin based on the cold material data model includes:
    获取各所述骨料仓的料位值;Obtain the material level value of each aggregate bin;
    基于所述冷料数据模型,计算各所述冷料仓的当前上料速度;Based on the cold material data model, calculate the current feeding speed of each cold material bin;
    将各所述骨料仓的料位值与预设料位区间进行对比;Compare the material level value of each aggregate bin with the preset material level interval;
    基于各所述冷料仓的当前上料速度以及各所述对比的结果,确定各所述冷料仓的目标上料速度。Based on the current feeding speed of each cold silo and the results of each comparison, the target feeding speed of each cold silo is determined.
  3. 根据权利要求2所述的上料控制方法,其中,所述基于所述冷料数据模型,计算各所述冷料仓的当前上料速度,包括:The feeding control method according to claim 2, wherein calculating the current feeding speed of each cold material bin based on the cold material data model includes:
    获取各所述骨料仓的卸料速度和料位变化率;Obtain the discharge speed and material level change rate of each aggregate bin;
    基于所述冷料数据模型、各所述骨料仓的卸料速度和料位变化率,计算各所述冷料仓的当前上料速度。Based on the cold material data model, the unloading speed and material level change rate of each aggregate bin, the current loading speed of each cold material bin is calculated.
  4. 根据权利要求3所述的上料控制方法,其中,所述基于所述冷料数据模型、各所述骨料仓的卸料速度和料位变化率,计算各所述冷料仓的当前上料速度,包括:The material loading control method according to claim 3, wherein the current loading of each cold material bin is calculated based on the cold material data model, the unloading speed and material level change rate of each aggregate bin. Material speed, including:
    针对每个所述骨料仓,获取与所述骨料仓的骨料对应的冷料供应优先级,基于所述冷料供应优先级,确定为所述骨料仓供料的至少一个所述冷料仓中冷料的优先级最高的所述冷料仓,基于所述骨料仓的卸料速度和料位变化率以及所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量,确定所述优先级最高的所述冷料仓的当前上料速度;For each aggregate bin, obtain the cold material supply priority corresponding to the aggregate in the aggregate bin, and determine at least one of the cold material supply priorities for the aggregate bin based on the cold material supply priority. The cold material bin with the highest priority of cold material in the cold material bin is based on the unloading speed and material level change rate of the aggregate bin and the cold material of the cold material bin with the highest priority. The aggregate content in the aggregate bin determines the current feeding speed of the cold material bin with the highest priority;
    其中,所述冷料供应优先级是按照各所述冷料仓的冷料中所述骨料仓的骨料的含量确定的,所述冷料仓的冷料中所述骨料仓的骨料的含量越大,所述冷料仓的冷料的优先级越高。Wherein, the cold material supply priority is determined according to the aggregate content of the aggregate bin in the cold material of each cold material bin, and the aggregate content of the aggregate bin in the cold material of the cold material bin. The greater the material content, the higher the priority of the cold material in the cold material bin.
  5. 根据权利要求4所述的上料控制方法,其中,所述基于所述骨料仓的卸料速度和料位变化率以及所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量,确定所述优先级最高的所述冷料仓的当前上料速度,包括:The feeding control method according to claim 4, wherein the method is based on the discharging speed and material level change rate of the aggregate bin and the bone in the cold material of the cold material bin with the highest priority. The aggregate content of the silo determines the current feeding speed of the cold silo with the highest priority, including:
    基于所述骨料仓的卸料速度和所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量,确定所述优先级最高的所述冷料仓对应的第一速度;Based on the unloading speed of the aggregate bin and the aggregate content of the cold material in the cold material bin with the highest priority, it is determined that the cold material bin with the highest priority corresponds to the first speed;
    基于所述骨料仓的料位变化率,确定所述优先级最高的所述冷料仓对应的第二速度;Based on the material level change rate of the aggregate silo, determine the second speed corresponding to the cold silo with the highest priority;
    基于所述第一速度和所述第二速度,确定所述优先级最高的所述冷料仓的当前上料速度。Based on the first speed and the second speed, the current feeding speed of the cold hopper with the highest priority is determined.
  6. 根据权利要求5所述的上料控制方法,其中,所述基于所述骨料仓的卸料速度和所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量,确定所述优先级最高的所述冷料仓对应的第一速度,包括:The material loading control method according to claim 5, wherein the aggregate in the cold material bin based on the unloading speed of the aggregate bin and the cold material in the cold bin with the highest priority is content, determine the first speed corresponding to the cold silo with the highest priority, including:
    基于所述骨料仓的卸料速度与所述优先级最高的所述冷料仓的冷料中所述骨料仓的骨料的含量的比值,确定所述优先级最高的所述冷料仓对应的第一速度。The cold material with the highest priority is determined based on the ratio of the unloading speed of the aggregate bin to the aggregate content of the cold material in the cold material bin with the highest priority. The first speed corresponding to the bin.
  7. 根据权利要求4所述的上料控制方法,其中,还包括:The feeding control method according to claim 4, further comprising:
    检测各所述冷料仓的料位值和/或表征是否可供料的供应状态;Detect the material level value of each cold material bin and/or indicate the supply status of whether material is available;
    所述基于所述冷料供应优先级,确定为所述骨料仓供料的至少一个所述冷料仓中冷料的优先级最高的所述冷料仓,包括:Determining, based on the cold material supply priority, the cold material silo with the highest priority of cold material in at least one of the cold material silos supplying the aggregate silo, including:
    基于所述冷料供应优先级,以及基于各所述冷料仓的料位值和/或表征是否可供料的供应状态,确定为所述骨料仓供料的可用的至少一个所述冷料仓中冷料的优先级最高的所述冷料仓,所述可用的所述冷料仓是料位值大于预设料位值和/或供应状态表征可供料的所述冷料仓。Based on the cold material supply priority, and based on the material level value of each of the cold material bins and/or the supply status indicating whether material is available, at least one of the cold materials available for supplying the aggregate bin is determined. The cold material bin with the highest priority of cold material in the bin, the available cold material bin is the cold material bin whose material level value is greater than the preset material level value and/or the supply status indicates that the material is available .
  8. 根据权利要求3所述的上料控制方法,其中,所述获取各所述骨料仓的卸料速度,包括:The feeding control method according to claim 3, wherein said obtaining the discharging speed of each aggregate bin includes:
    基于各所述骨料仓对应的计量秤称量的骨料重量以及称量周期,得到各所述骨料仓的卸料速度。Based on the weight of the aggregate measured by the weighing scale corresponding to each of the aggregate bins and the weighing cycle, the unloading speed of each of the aggregate bins is obtained.
  9. 根据权利要求2所述的上料控制方法,其中,所述预设料位区间 包括料位值依次增大的第一料位区间、第二料位区间和第三料位区间;The feeding control method according to claim 2, wherein the preset material level interval includes a first material level interval, a second material level interval and a third material level interval in which the material level value increases sequentially;
    所述基于各所述冷料仓的当前上料速度以及各所述对比的结果,确定各所述冷料仓的目标上料速度,包括:Determining the target feeding speed of each cold silo based on the current feeding speed of each cold silo and the comparison results includes:
    若所述骨料仓的料位值位于所述第一料位区间内,将为所述骨料仓供料的至少一个所述冷料仓的当前上料速度增加,以得到为所述骨料仓供料的至少一个所述冷料仓的目标上料速度;If the material level value of the aggregate bin is within the first material level interval, the current feeding speed of at least one of the cold material bins that supplies materials to the aggregate bin is increased to obtain the The target feeding speed of at least one of the cold silos supplied by the silo;
    若所述骨料仓的料位值位于所述第二料位区间内,将为所述骨料仓供料的至少一个所述冷料仓的当前上料速度作为为所述骨料仓供料的至少一个所述冷料仓的目标上料速度;If the material level value of the aggregate silo is within the second material level interval, the current feeding speed of at least one cold material silo that supplies material to the aggregate silo will be used as the supply speed for the aggregate silo. The target feeding speed of at least one of the cold hoppers;
    若所述骨料仓的料位值位于所述第三料位区间内,将为所述骨料仓供料的至少一个所述冷料仓的当前上料速度减小,以得到为所述骨料仓供料的至少一个所述冷料仓的目标上料速度。If the material level value of the aggregate bin is within the third material level interval, the current feeding speed of at least one of the cold material bins that supplies materials to the aggregate bin is reduced to obtain the The target feeding speed of at least one of the cold silos supplied by the aggregate silo.
  10. 根据权利要求9所述的上料控制方法,其中,所述基于各所述冷料仓的当前上料速度以及各所述对比的结果,确定各所述冷料仓的目标上料速度,还包括:The feeding control method according to claim 9, wherein the target feeding speed of each cold silo is determined based on the current feeding speed of each cold silo and the result of each comparison, and further include:
    获取骨料供应优先级,所述骨料供应优先级是按照各所述骨料仓的骨料的需求量确定的,所述骨料仓的骨料的需求量越大,所述骨料仓的骨料的优先级越高;Obtain the aggregate supply priority. The aggregate supply priority is determined according to the demand for aggregates in each of the aggregate bins. The greater the demand for aggregates in the aggregate bins, the higher the demand for aggregates in the aggregate bins. The higher the priority of the aggregate;
    确定各所述冷料仓的目标上料速度之和,得到总速度;Determine the sum of the target feeding speeds of each cold material bin to obtain the total speed;
    若所述总速度大于预设的速度上限,基于所述骨料供应优先级,确定各所述骨料仓中骨料的优先级最低的至少一个所述骨料仓;If the total speed is greater than the preset speed upper limit, based on the aggregate supply priority, determine at least one of the aggregate bins with the lowest priority of aggregate in each of the aggregate bins;
    将为所述优先级最低的至少一个所述骨料仓供料的至少一个所述冷料仓的目标上料速度减小,以使得所述总速度小于或者等于所述预设的速度上限。The target feeding speed of at least one cold silo that supplies at least one aggregate silo with the lowest priority is reduced so that the total speed is less than or equal to the preset speed upper limit.
  11. 根据权利要求10所述的上料控制方法,其中,各所述骨料仓的骨料的需求量是基于生产配方中各骨料的比例确定的。The feeding control method according to claim 10, wherein the required amount of aggregate in each aggregate bin is determined based on the proportion of each aggregate in the production formula.
  12. 一种上料控制装置,包括:A feeding control device includes:
    速度确定模块,用于基于冷料数据模型,确定各冷料仓的目标上料速度;所述各冷料仓用于为各骨料仓供料;所述冷料数据模型中包含每个所述冷料仓的冷料中各骨料的含量;The speed determination module is used to determine the target feeding speed of each cold material bin based on the cold material data model; each cold material bin is used to supply material to each aggregate bin; the cold material data model includes each Describe the content of each aggregate in the cold material in the cold material bin;
    上料控制模块,用于基于各所述冷料仓的目标上料速度,控制各所述冷料仓上料。A loading control module is used to control the loading of each cold silo based on the target loading speed of each cold silo.
  13. 一种电子设备,包括存储器、处理器及存储在所述存储器上并可在所述处理器上运行的计算机程序,其中,所述处理器执行所述程序时实现如权利要求1至11任一项所述上料控制方法。An electronic device, including a memory, a processor and a computer program stored on the memory and executable on the processor, wherein when the processor executes the program, any one of claims 1 to 11 is implemented The feeding control method described in the item.
  14. 一种沥青搅拌站,包括沥青搅拌站本体和控制器,其中,所述控制器用于实现如权利要求1至11任一项所述上料控制方法。An asphalt mixing station includes an asphalt mixing station body and a controller, wherein the controller is used to implement the feeding control method according to any one of claims 1 to 11.
PCT/CN2022/095564 2022-03-23 2022-05-27 Feeding control method and apparatus, and asphalt stirring station WO2023178827A1 (en)

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