CN116993330A - Intelligent rock powder recycling method, device, equipment and medium - Google Patents

Abstract

The application relates to an intelligent rock powder recycling method, device, equipment and medium, which are applied to the technical field of rock powder recycling, and the method comprises the following steps: acquiring rock powder content and rock powder type in a recovery area; generating a rock dust recovery scheme based on the rock dust content and the rock dust type; acquiring the total amount of recovered rock powder and the information of the recovered rock powder of the rock powder recovered based on the rock powder recovery scheme; determining available rock dust information based on the recovered rock dust total amount and the recovered rock dust information; and acquiring local demand information, and generating a rock powder utilization scheme based on the local demand information and the available rock powder information. The application has the effect of improving the utilization rate of rock powder.

Description

Intelligent rock powder recycling method, device, equipment and medium

Technical Field

The application relates to the technical field of rock powder recovery, in particular to an intelligent rock powder recovery and utilization method, device, equipment and medium.

Background

When carrying out nonmetal mining, the mode of generally using blasting carries out the crushing of mine rock, in the in-process of blasting, in order to improve the convenience of operation, most mines often all adopt to carry out the big gun hole with current rock powder and block up, but, because the rock powder does not possess the compactibility, adopts the rock powder to directly block up the big gun hole, can produce a large amount of dust, and along with the dynamics of environmental supervision constantly increases and the gradual promotion of environmental protection requirement, the mode of directly using the rock powder is difficult to satisfy the demand of environmental protection, how to retrieve the rock powder and make full use of become current key problem.

Disclosure of Invention

In order to improve the utilization rate of rock powder, the application provides an intelligent rock powder recycling method, device, equipment and medium.

In a first aspect, the application provides an intelligent rock powder recycling method, which adopts the following technical scheme:

an intelligent rock powder recycling method comprises the following steps:

acquiring rock powder content and rock powder type in a recovery area;

generating a rock dust recovery scheme based on the rock dust content and the rock dust type;

acquiring the total amount of recovered rock powder and the information of the recovered rock powder of the rock powder recovered based on the rock powder recovery scheme;

determining available rock dust information based on the recovered rock dust total amount and the recovered rock dust information;

and acquiring local demand information, and generating a rock powder utilization scheme based on the local demand information and the available rock powder information.

By adopting the technical scheme, firstly, the rock powder recovery scheme is formulated according to the rock powder content and the rock powder type, the recovery modes adopted by different rock powder content and different rock powder types are different, and in order to recover more thoroughly and improve the overall recovery efficiency, the corresponding rock powder recovery scheme is formulated according to the actual condition in the recovery area, so that the rock powder is recovered by using the rock powder recovery scheme, after recovery, the total quantity of recovered rock powder and the recovered rock powder information of the recovered rock powder are determined, then the available rock powder information is determined according to the total quantity of the recovered rock powder and the recovered rock powder information, the corresponding rock powder utilization scheme is formulated by utilizing the available rock powder information, and the rock powder utilization scheme is utilized, so that the utilization rate of the rock powder is improved.

Optionally, the generating a rock dust recovery scheme based on the rock dust content and the rock dust type includes:

determining a rock dust recovery threshold based on the rock dust type, determining a rock dust collection device based on the rock dust type;

judging whether the rock powder content is not less than the rock powder recovery threshold value;

if the rock dust is not smaller than the rock dust recovery threshold, generating a rock dust recovery scheme based on the rock dust collection device and the recovery area;

and if the rock dust content is not less than the rock dust recovery threshold, generating a rock dust recovery scheme based on the rock dust content, the rock dust recovery device and the recovery area.

Optionally, the generating a rock dust recovery scheme based on the rock dust collection device and the recovery area includes:

determining a device usage amount based on the rock dust content and the rock dust collection device;

acquiring a collection range of the rock powder collection device;

determining a collection route based on the recovery area, the number of device uses, and the collection range;

a rock dust recovery scheme is generated based on the collection route and the rock dust collection device.

Optionally, the generating a rock dust recovery scheme based on the rock dust content, the rock dust recovery apparatus, and the recovery area includes:

acquiring the working state of the recovery area;

calculating rock dust collection time based on the working state and the rock dust content;

determining a device usage amount based on the rock dust content and the rock dust collection device;

acquiring a collection range of the rock powder collection device;

determining a collection route based on the recovery area, the number of device uses, and the collection range;

a rock dust recovery scheme is generated based on the rock dust collection time, the collection route, and the rock dust collection device.

Optionally, the determining available rock dust information based on the recovered rock dust total amount and the recovered rock dust information includes:

obtaining target powder quality of target use rock powder;

screening the recovered rock powder in the recovered area based on the target powder, and determining the available amount of the available rock powder;

determining an available rock dust fraction based on the available amount and the total amount of recovered rock dust;

and generating available rock dust information based on the available rock dust ratio and the recovered rock dust information.

Optionally, the local demand information includes a target filling number and a target filling size; the generating a rock dust utilization scheme based on the local demand information and the available rock dust information includes:

calculating a target usage amount based on the target fill amount and the target fill size;

determining deployment information based on the target usage amount and the available rock dust information;

acquiring target filling time;

and generating a rock powder utilization scheme based on the target filling time and the allocation information.

Optionally, the determining deployment information based on the target usage amount and the available rock dust information includes:

judging whether additional supplementation is required based on the target usage amount and the available amount;

if additional replenishment is required, determining a replenishment amount based on the target usage amount and the availability amount;

determining an amount of water to use based on the supplemental amount and the available amount;

generating fitting information based on the supplemental amount and the water usage;

if no additional supplement is required, determining the water consumption based on the target usage;

and generating allocation information based on the water consumption.

In a second aspect, the application provides an intelligent rock powder recycling device, which adopts the following technical scheme:

an intelligent rock dust recycling device, comprising:

the rock powder information acquisition module is used for acquiring the rock powder content and the rock powder type in the recovery area;

the recovery scheme generation module is used for generating a rock powder recovery scheme based on the rock powder content and the rock powder type;

the recovery information acquisition module is used for acquiring the total amount of the recovered rock powder and the recovery rock powder information of the rock powder recovered based on the rock powder recovery scheme;

an available information determining module for determining available rock dust information based on the total amount of recovered rock dust and the recovered rock dust information;

and the utilization scheme generation module is used for acquiring the local demand information and generating a rock powder utilization scheme based on the local demand information and the available rock powder information.

By adopting the technical scheme, firstly, the rock powder recovery scheme is formulated according to the rock powder content and the rock powder type, the recovery modes adopted by different rock powder content and different rock powder types are different, and in order to recover more thoroughly and improve the overall recovery efficiency, the corresponding rock powder recovery scheme is formulated according to the actual condition in the recovery area, so that the rock powder is recovered by using the rock powder recovery scheme, after recovery, the total quantity of recovered rock powder and the recovered rock powder information of the recovered rock powder are determined, then the available rock powder information is determined according to the total quantity of the recovered rock powder and the recovered rock powder information, the corresponding rock powder utilization scheme is formulated by utilizing the available rock powder information, and the rock powder utilization scheme is utilized, so that the utilization rate of the rock powder is improved.

In a third aspect, the present application provides an electronic device, which adopts the following technical scheme:

an electronic device comprising a processor coupled with a memory;

the processor is configured to execute a computer program stored in the memory, so that the electronic device executes the computer program of the rock dust intelligent recycling method according to any one of the first aspects.

In a fourth aspect, the present application provides a computer readable storage medium, which adopts the following technical scheme:

a computer readable storage medium storing a computer program loadable by a processor and performing the method of intelligent rock dust recycling of any of the first aspects.

Drawings

Fig. 1 is a schematic flow chart of an intelligent rock powder recycling method provided by an embodiment of the application.

Fig. 2 is a block diagram of an intelligent rock powder recycling device according to an embodiment of the present application.

Fig. 3 is a block diagram of an electronic device according to an embodiment of the present application.

Detailed Description

The present application will be described in further detail with reference to the accompanying drawings.

The embodiment of the application provides an intelligent rock powder recycling method which can be executed by electronic equipment, wherein the electronic equipment can be a server or terminal equipment, the server can be an independent physical server, a server cluster or a distributed system formed by a plurality of physical servers, and a cloud server for providing cloud computing service. The terminal device may be, but is not limited to, a smart phone, a tablet computer, a desktop computer, etc.

Fig. 1 is a schematic flow chart of an intelligent rock powder recycling method provided by an embodiment of the application.

As shown in fig. 1, the main flow of the method is described as follows (steps S101 to S105):

and step S101, acquiring the rock powder content and the rock powder type in the recovery area.

In this embodiment, the recovery area is an influence area severely affected by mining obtained after the mining area is divided, and may be one or more, when the recovery area is one, the recovery area needs to be sorted and divided according to the influence area, that is, the recovery area needs to be divided into a relatively regular rectangle, and the recovery area needs to include the whole influence area, that is, the area of the recovery area is greater than or equal to the area of the influence area. When the recovery areas are multiple, firstly judging whether the recovery areas cannot be divided into a whole due to overlarge areas or the mining areas are too dense, if the areas are overlarge, dividing the mining areas into a large rectangle firstly in the same mode as when the areas are divided into one area, and then dividing the large rectangle according to the areas of the rectangles, so that multiple recovery areas are obtained; if the mining areas are dense, the dividing line is determined according to the distance between the two mining areas, and is generally the middle value of the distance, namely, the distance is 10 meters, then the dividing line is 5 meters, and then the dividing area is divided in the same way when the dividing area is one, it is noted that when the dividing area is divided according to the area, the dividing mask is required to be set according to the actual requirement, the specific limitation is not needed, and the rock powder recovery scheme adopted by each recovery area is independently set when the recovery is carried out.

In general, the rock powder type of rock powder is the same as the ore type of a mining area, but the rock powder type is different due to the fact that the components and the types of the ore may be impure, so that the rock powder type needs to be determined according to the previous mining result and the current condition of the ore.

And step S102, generating a rock dust recycling scheme based on the rock dust content and the rock dust type.

For step S102, determining a rock dust recovery threshold based on the rock dust type, and determining a rock dust collection device based on the rock dust type; judging whether the rock powder content is not less than a rock powder recovery threshold value; if the rock dust is not smaller than the rock dust recovery threshold, generating a rock dust recovery scheme based on the rock dust collection device and the recovery area; and if the rock dust content is not less than the rock dust recovery threshold, generating a rock dust recovery scheme based on the rock dust content, the rock dust recovery equipment and the recovery area.

In this embodiment, the rock dust recovery scheme of the region is generated by the rock dust content and the rock dust type in the region, and the rock dust recovery operation is performed according to the rock dust recovery scheme. When the rock powder recovery scheme is generated, the rock powder recovery threshold value is determined according to the rock powder type, and the rock powder collection equipment for rock powder recovery is used, and the corresponding attribute is different due to the different rock powder types, so that the sedimentation speed when the rock powder is generated, the influence on the outside and the floating range when the rock powder is influenced by the outside are different, and the rock powder recovery threshold value and the rock powder collection equipment which are suitable for the rock powder type need to be selected. After the rock powder recovery threshold value and the rock powder collecting device are determined, judging whether the operation of rock powder recovery is needed according to the currently obtained rock powder content and the rock powder recovery threshold value, namely judging whether the rock powder content is not less than the rock powder recovery threshold value, if the rock powder content is not less than the rock powder recovery threshold value, indicating that the operation of rock powder recovery is needed immediately, generating a rock powder recovery scheme according to the rock powder collecting device and the recovery area, and if the rock powder content is less than the rock powder recovery threshold value, indicating that the operation of rock powder recovery is not needed immediately, but can be predicted in advance, thereby generating the rock powder recovery scheme.

When the rock powder content is not less than the rock powder recovery threshold value, determining the using quantity of equipment based on the rock powder content and the rock powder collecting equipment; acquiring a collection range of rock powder collection equipment; determining a collection route based on the recycling area, the number of equipment uses, and the collection range; a rock dust recovery scheme is generated based on the collection route and the rock dust collection device.

Acquiring a collection range, a single collection degree and collection available time of rock powder collection equipment, determining the first equipment quantity according to a collection range and a collection area, then determining collection use time required to be consumed under the condition of the first equipment quantity according to the collection degree and rock powder content, judging whether the collection use time is smaller than the collection available time, taking the first equipment quantity as the equipment use quantity if the collection use time is smaller than the collection available time, determining the increment quantity according to a time difference between the mobile phone use time and the mobile phone available time if the collection use time is larger than the collection available time, determining the increment quantity according to the time difference and a preset increment table, recording increment quantities corresponding to different time differences in the preset increment table, determining the increment quantity corresponding to the collection equipment according to the rock powder collection equipment, determining the increment quantity in the table according to the rock powder collection equipment, and then determining the increment quantity and the quantity corresponding to the first equipment quantity in the table according to the use time difference, and taking the increment quantity and the increment quantity as the equipment use quantity.

After the equipment usage is obtained, a collection route is determined according to the recovery area, the equipment usage amount and the collection range, wherein the collection route is the collection route of the single equipment usage amount, and the collection route is bound with the rock powder collection equipment, so that a rock powder recovery scheme is generated.

When the rock powder content is smaller than the rock powder recovery threshold value, acquiring the working state of a recovery area; calculating rock dust collection time based on the working state and the rock dust content; determining the using quantity of equipment based on the rock powder content and the rock powder collecting equipment; acquiring a collection range of rock powder collection equipment; determining a collection route based on the recycling area, the number of equipment uses, and the collection range; a rock dust recovery scheme is generated based on the rock dust collection time, the collection route, and the rock dust collection device.

In case the rock dust content does not reach the rock dust recovery threshold, the rock dust collection time, i.e. how long after recovery is performed, is calculated from the current working state of the recovery area and the rock dust content. Firstly, determining the rock powder increasing speed according to the working state, namely determining a time interval, acquiring the rock powder yield in the time interval, determining the rock powder increasing speed according to the time interval and the rock powder yield, then calculating a rock powder recovery difference value according to the current rock powder content by using a rock powder recovery threshold value, calculating the rock powder recovery difference value and the rock powder increasing speed to obtain the increasing duration, acquiring the acquisition time when the rock powder content is acquired, and acquiring the rock powder collecting time according to the acquisition time.

After the rock powder collecting time is obtained, adopting a calculation mode which is the same as a rock powder recovery threshold value and is not smaller than the rock powder content, namely obtaining the collecting range, the single collecting degree and the collecting available time of the rock powder collecting equipment, determining the first equipment quantity according to the collecting range and the recovery area, then determining the collecting available time which needs to be consumed under the condition of the first equipment quantity according to the collecting degree and the rock powder content, judging whether the collecting available time is smaller than the collecting available time, taking the first equipment quantity as the equipment using quantity if the collecting available time is smaller than the collecting available time, determining the increment quantity corresponding to different time differences according to the time differences and the preset increment table, determining the increment quantity corresponding to different time differences of the rock powder collecting equipment according to the rock powder collecting equipment when the determination is performed, and then taking the first equipment quantity as the equipment quantity, and calculating the increment quantity and the first equipment quantity in the table according to the time differences and the increment table.

After the equipment usage amount and the rock powder collection time are obtained, a collection route is determined according to the recovery area, the equipment usage amount and the collection range, wherein the collection route is the collection route of the single equipment usage amount, and then the collection route, the rock powder collection equipment and the rock powder collection time are bound, so that a rock powder recovery scheme is generated.

And step S103, acquiring the total amount of the recovered rock powder and the recovered rock powder information of the rock powder recovered based on the rock powder recovery scheme.

In this embodiment, after determining the rock powder recovery scheme, the rock powder recovery operation is performed by using the rock powder recovery scheme, so as to obtain recovered rock powder, and the recovered rock powder is collected to obtain the total amount of recovered rock powder and recovered rock powder information, where the recovered rock powder information is information about which recovery area or areas the recovered rock powder comes from, recovery time, and the like, and it is to be noted that specific recovered rock powder information needs to be set according to actual requirements, which is not specifically limited herein.

And step S104, determining available rock dust information based on the total amount of the recovered rock dust and the recovered rock dust information.

Aiming at step S104, obtaining target powder quality of target use rock powder; screening the recovered rock powder in the recovered area based on the target powder, and determining the available rock powder amount; determining an available rock dust fraction based on the available amount and the total amount of recovered rock dust; the available rock dust information is generated based on the available rock dust duty and the recovered rock dust information.

In this embodiment, since the ore mining is performed in a manner of blasting, the powder quality of the rock powder is different, and the powder quality is the thickness of the rock powder, but when the rock powder is used for filling the blast holes, not all the rock powder of the powder quality can be used for filling the blast holes, so that the available rock powder is required to be obtained by screening according to the target powder quality of the target rock powder, the available rock powder ratio is determined according to the available rock powder and the total amount of the recovered rock powder, the purpose of calculating the available rock powder ratio is to provide relevant basis for subsequent calculation, and because the available rock powder is insufficient to support the required amount, preparation of the supplementing amount can be performed in advance after the available rock powder ratio is determined, and after the available rock powder ratio is obtained, the available rock powder ratio and the recovered rock powder information are bound to generate final available rock powder information.

Step S105, obtaining local demand information, and generating a rock powder utilization scheme based on the local demand information and the available rock powder information.

For step S105, the local demand information includes a target filling number and a target filling size; calculating a target usage amount based on the target filling amount and the target filling size; determining deployment information based on the target usage and the available rock dust information; acquiring target filling time; and generating a rock powder utilization scheme based on the target filling time and the allocation information.

Further, whether additional replenishment is required is judged based on the target usage amount and the available amount; if the demand is additionally supplemented, determining a supplementing amount based on the target using amount and the available amount; determining a water usage based on the make-up amount and the available amount; generating allocation information based on the replenishment amount and the water consumption; if no additional supplement is required, determining the water consumption based on the target usage; and generating allocation information based on the water consumption.

In this embodiment, when filling the blastholes, the target usage amount of rock powder needs to be calculated according to the target filling amount and the target filling size of the blastholes, so as to obtain how much rock powder is needed to completely fill all the blastholes to be filled, the usage amount of rock powder needed by a single blasthole can be determined according to the target filling size, and the target usage amount can be obtained according to the usage amount of rock powder needed by the single blasthole multiplied by the target filling amount.

After the target usage amount is obtained, whether the target usage amount is smaller than the available amount or not is judged, namely whether additional supplementation is required or not is judged according to the target usage amount and the available amount, if the target usage amount is smaller than the available amount, the available amount can support all blast hole filling and use, therefore, additional supplementation is not required, the water consumption is determined according to the rock powder type, the water consumption is associated with the available amount, allocation information is generated, and the allocation information is associated with the target filling time, so that a rock powder utilization scheme is obtained. If the target usage amount is not less than the available amount, that is, the target usage amount is greater than the available amount, the available amount cannot support all blastholes to be filled, so that additional supplement is needed, first, a first water amount corresponding to the available amount is determined according to the available amount, a difference value between the available amount and the target usage amount is calculated, the difference value is used as a supplement amount, supplement materials are selected after the supplement amount is obtained, a second water amount corresponding to the supplement materials is obtained according to the supplement materials, the sum of the first water amount and the second water amount is used as the water amount, then the same processing mode is adopted, that is, the water amount is related to the available amount and the supplement amount, so that allocation information is generated, and then the allocation information is related to the target filling time, so that a rock powder utilization scheme is obtained. The water consumption is related to the water absorption of the rock powder and the supplementary material and the required filling state at the time of filling the blasthole, and is set according to the actual properties, and is not particularly limited herein.

Fig. 2 is a block diagram of an intelligent rock powder recycling device 200 according to an embodiment of the present application.

As shown in fig. 2, the rock powder intelligent recycling device 200 mainly includes:

the rock powder information acquisition module 201 is used for acquiring the rock powder content and the rock powder type in the recovery area;

a recovery scenario generation module 202 for generating a rock dust recovery scenario based on the rock dust content and the rock dust type;

a recovery information acquisition module 203 for acquiring a total amount of recovered rock dust and recovered rock dust information of the rock dust recovered based on the rock dust recovery scheme;

an available information determination module 204 for determining available rock dust information based on the recovered rock dust total amount and the recovered rock dust information;

the utilization scheme generation module 205 is configured to obtain local demand information, and generate a rock powder utilization scheme based on the local demand information and the available rock powder information.

As an alternative implementation of the present embodiment, the recycling scheme generation module 202 includes:

the collecting equipment determining module is used for determining a rock powder recovery threshold value based on the rock powder type and determining a rock powder collecting equipment based on the rock powder type;

the recovery threshold judging module is used for judging whether the rock powder content is not less than a rock powder recovery threshold or not;

a first pattern generation module for generating a rock dust recovery pattern based on the rock dust collection device and the recovery area;

and the second scheme generation module is used for generating a rock powder recovery scheme based on the rock powder content, the rock powder recovery equipment and the recovery area.

In this alternative embodiment, the first scheme generation module is specifically configured to determine the number of uses of the device based on the rock dust content and the rock dust collection device; acquiring a collection range of rock powder collection equipment; determining a collection route based on the recycling area, the number of equipment uses, and the collection range; a rock dust recovery scheme is generated based on the collection route and the rock dust collection device.

In this optional embodiment, the second scheme generating module is specifically configured to obtain a working state of the recovery area; calculating rock dust collection time based on the working state and the rock dust content; determining the using quantity of equipment based on the rock powder content and the rock powder collecting equipment; acquiring a collection range of rock powder collection equipment; determining a collection route based on the recycling area, the number of equipment uses, and the collection range; a rock dust recovery scheme is generated based on the rock dust collection time, the collection route, and the rock dust collection device.

As an alternative implementation manner of this embodiment, the available information determining module 204 is specifically configured to obtain a target powder quality of the target usage rock powder; screening the recovered rock powder in the recovered area based on the target powder, and determining the available rock powder amount; determining an available rock dust fraction based on the available amount and the total amount of recovered rock dust; the available rock dust information is generated based on the available rock dust duty and the recovered rock dust information.

As an alternative implementation of the present embodiment, the usage scenario generation module 205 includes:

a target usage calculation module for calculating a target usage based on the target fill quantity and the target fill size;

the allocation information determining module is used for determining allocation information based on the target usage amount and the available rock powder information;

the filling time determining module is used for obtaining target filling time;

and generating a rock powder utilization scheme based on the target filling time and the allocation information.

In this optional embodiment, the allocation information determining module is specifically configured to determine whether to perform additional replenishment based on the target usage amount and the available amount; if the demand is additionally supplemented, determining a supplementing amount based on the target using amount and the available amount; determining a water usage based on the make-up amount and the available amount; generating allocation information based on the replenishment amount and the water consumption; if no additional supplement is required, determining the water consumption based on the target usage; and generating allocation information based on the water consumption.

In one example, a module in any of the above apparatuses may be one or more integrated circuits configured to implement the above methods, for example: one or more application specific integrated circuits (application specific integratedcircuit, ASIC), or one or more digital signal processors (digital signal processor, DSP), or one or more field programmable gate arrays (field programmable gate array, FPGA), or a combination of at least two of these integrated circuit forms.

For another example, when a module in an apparatus may be implemented in the form of a scheduler of processing elements, the processing elements may be general-purpose processors, such as a central processing unit (central processing unit, CPU) or other processor that may invoke a program. For another example, the modules may be integrated together and implemented in the form of a system-on-a-chip (SOC).

It will be clearly understood by those skilled in the art that, for convenience and brevity of description, the specific working process of the apparatus and modules described above may refer to the corresponding process in the foregoing method embodiment, which is not repeated herein.

Fig. 3 is a block diagram of an electronic device 300 according to an embodiment of the present application.

As shown in FIG. 3, electronic device 300 includes a processor 301 and memory 302, and may further include an information input/information output (I/O) interface 303, one or more of a communication component 304, and a communication bus 305.

The processor 301 is configured to control the overall operation of the electronic device 300, so as to complete all or part of the steps of the intelligent rock powder recycling method; the memory 302 is used to store various types of data to support operation at the electronic device 300, which may include, for example, instructions for any application or method operating on the electronic device 300, as well as application-related data. The Memory 302 may be implemented by any type or combination of volatile or non-volatile Memory devices, such as one or more of static random access Memory (Static Random Access Memory, SRAM), electrically erasable programmable Read-Only Memory (Electrically Erasable Programmable Read-Only Memory, EEPROM), erasable programmable Read-Only Memory (Erasable Programmable Read-Only Memory, EPROM), programmable Read-Only Memory (Programmable Read-Only Memory, PROM), read-Only Memory (ROM), magnetic Memory, flash Memory, magnetic disk, or optical disk.

The I/O interface 303 provides an interface between the processor 301 and other interface modules, which may be a keyboard, mouse, buttons, etc. These buttons may be virtual buttons or physical buttons. The communication component 304 is used for wired or wireless communication between the electronic device 300 and other devices. Wireless communication, such as Wi-Fi, bluetooth, near field communication (Near Field Communication, NFC for short), 2G, 3G or 4G, or a combination of one or more thereof, the corresponding communication component 104 may thus comprise: wi-Fi part, bluetooth part, NFC part.

The electronic device 300 may be implemented by one or more application specific integrated circuits (Application Specific Integrated Circuit, abbreviated as ASIC), digital signal processors (Digital Signal Processor, abbreviated as DSP), digital signal processing devices (Digital Signal Processing Device, abbreviated as DSPD), programmable logic devices (Programmable Logic Device, abbreviated as PLD), field programmable gate arrays (Field Programmable Gate Array, abbreviated as FPGA), controllers, microcontrollers, microprocessors, or other electronic components for performing the intelligent rock dust recycling method as set forth in the above embodiments.

Communication bus 305 may include a pathway to transfer information between the aforementioned components. The communication bus 305 may be a PCI (Peripheral Component Interconnect, peripheral component interconnect standard) bus or an EISA (Extended Industry Standard Architecture ) bus, or the like. The communication bus 305 may be divided into an address bus, a data bus, a control bus, and the like.

The electronic device 300 may include, but is not limited to, mobile terminals such as mobile phones, notebook computers, digital broadcast receivers, PDAs (personal digital assistants), PADs (tablet computers), PMPs (portable multimedia players), car terminals (e.g., car navigation terminals), and the like, and fixed terminals such as digital TVs, desktop computers, and the like, and may also be a server, and the like.

The application also provides a computer readable storage medium, wherein the computer readable storage medium is stored with a computer program, and the steps of the rock powder intelligent recycling method are realized when the computer program is executed by a processor.

The computer readable storage medium may include: a U-disk, a removable hard disk, a read-Only Memory (ROM), a random access Memory (Random Access Memory, RAM), a magnetic disk, or an optical disk, or other various media capable of storing program codes.

The terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The above description is only illustrative of the preferred embodiments of the present application and of the principles of the technology employed. It will be appreciated by persons skilled in the art that the scope of the application is not limited to the specific combinations of the features described above, but also covers other embodiments which may be formed by any combination of the features described above or their equivalents without departing from the spirit of the application. Such as the above-mentioned features and the technical features having similar functions (but not limited to) applied for in the present application are replaced with each other.

Claims (10)

1. An intelligent rock powder recycling method is characterized by comprising the following steps:

acquiring rock powder content and rock powder type in a recovery area;

generating a rock dust recovery scheme based on the rock dust content and the rock dust type;

acquiring the total amount of recovered rock powder and the information of the recovered rock powder of the rock powder recovered based on the rock powder recovery scheme;

determining available rock dust information based on the recovered rock dust total amount and the recovered rock dust information;

and acquiring local demand information, and generating a rock powder utilization scheme based on the local demand information and the available rock powder information.

2. The method of claim 1, wherein the generating a rock dust recovery scheme based on the rock dust content and the rock dust type comprises:

determining a rock dust recovery threshold based on the rock dust type, determining a rock dust collection device based on the rock dust type;

judging whether the rock powder content is not less than the rock powder recovery threshold value;

if the rock dust is not smaller than the rock dust recovery threshold, generating a rock dust recovery scheme based on the rock dust collection device and the recovery area;

and if the rock dust content is not less than the rock dust recovery threshold, generating a rock dust recovery scheme based on the rock dust content, the rock dust recovery device and the recovery area.

3. The method of claim 2, wherein the generating a rock dust recovery scheme based on the rock dust collection device and the recovery area comprises:

determining a device usage amount based on the rock dust content and the rock dust collection device;

acquiring a collection range of the rock powder collection device;

determining a collection route based on the recovery area, the number of device uses, and the collection range;

a rock dust recovery scheme is generated based on the collection route and the rock dust collection device.

4. The method of claim 2, wherein the generating a rock dust recovery scheme based on the rock dust content, the rock dust recovery device, and the recovery area comprises:

acquiring the working state of the recovery area;

calculating rock dust collection time based on the working state and the rock dust content;

determining a device usage amount based on the rock dust content and the rock dust collection device;

acquiring a collection range of the rock powder collection device;

determining a collection route based on the recovery area, the number of device uses, and the collection range;

a rock dust recovery scheme is generated based on the rock dust collection time, the collection route, and the rock dust collection device.

5. The method of claim 1, wherein the determining available rock dust information based on the recovered rock dust total and the recovered rock dust information comprises:

obtaining target powder quality of target use rock powder;

screening the recovered rock powder in the recovered area based on the target powder, and determining the available amount of the available rock powder;

determining an available rock dust fraction based on the available amount and the total amount of recovered rock dust;

and generating available rock dust information based on the available rock dust ratio and the recovered rock dust information.

6. The method of claim 5, wherein the local demand information includes a target fill quantity and a target fill size; the generating a rock dust utilization scheme based on the local demand information and the available rock dust information includes:

calculating a target usage amount based on the target fill amount and the target fill size;

determining deployment information based on the target usage amount and the available rock dust information;

acquiring target filling time;

and generating a rock powder utilization scheme based on the target filling time and the allocation information.

7. The method of claim 6, wherein the determining deployment information based on the target usage and the available rock dust information comprises:

judging whether additional supplementation is required based on the target usage amount and the available amount;

if additional replenishment is required, determining a replenishment amount based on the target usage amount and the availability amount;

determining an amount of water to use based on the supplemental amount and the available amount;

generating fitting information based on the supplemental amount and the water usage;

if no additional supplement is required, determining the water consumption based on the target usage;

and generating allocation information based on the water consumption.

8. Rock powder intelligence recycle device, its characterized in that includes:

the rock powder information acquisition module is used for acquiring the rock powder content and the rock powder type in the recovery area;

the recovery scheme generation module is used for generating a rock powder recovery scheme based on the rock powder content and the rock powder type;

the recovery information acquisition module is used for acquiring the total amount of the recovered rock powder and the recovery rock powder information of the rock powder recovered based on the rock powder recovery scheme;

an available information determining module for determining available rock dust information based on the total amount of recovered rock dust and the recovered rock dust information;

and the utilization scheme generation module is used for acquiring the local demand information and generating a rock powder utilization scheme based on the local demand information and the available rock powder information.

9. An electronic device comprising a processor coupled to a memory;

the processor is configured to execute a computer program stored in the memory to cause the electronic device to perform the method of any one of claims 1 to 7.

10. A computer readable storage medium comprising a computer program or instructions which, when run on a computer, cause the computer to perform the method of any of claims 1 to 7.