CN116306759B - Label-bearing balancing weight, and label-based balancing weight allocation method and device - Google Patents

Abstract

The invention discloses a balancing weight with a label, a balancing weight allocation method and a balancing weight allocation device based on the label, wherein the balancing weight allocation method comprises the following steps: a balancing weight body and a fixing clamping groove; the side of balancing weight body is equipped with the fluting, the fluting is equipped with fixed gasket, fixed gasket is equipped with the gasket opening, the bottom surface of fixed draw-in groove is equipped with the base of L font, the base be equipped with the via hole that the gasket opening matches, the gasket opening with the via hole passes through the screw fixation, so that the base is fixed on the fixed gasket, fixed draw-in groove with use epoxy or concrete to fill around the fluting, fixed draw-in groove is equipped with the RFID label, and utilize the RFID label is right the balancing weight body manages. According to the invention, the RFID tag can be arranged on the balancing weight, and the information of each using and operating link of the balancing weight is recorded by using the tag, so that the information of the balancing weight is disclosed and transparent, and a user can conveniently and efficiently monitor and manage the balancing weight.

Description

Label-bearing balancing weight, and label-based balancing weight allocation method and device

Technical Field

The invention relates to the technical field of static load equipment of foundation pile foundation, in particular to a balancing weight with a tag, a balancing weight allocation method and a balancing weight allocation device based on the tag.

Background

As economies develop, the construction of various capital construction projects has also gradually increased, including: new construction, reconstruction, extension, restoration and other projects of roads, railways, bridges, schools, various industries, civil buildings and the like. In the construction project field, cooperative cooperation of various static load devices (e.g., balancing weights) is required to complete engineering construction. If the building or bridge is large, the weight of the needed balancing weight is heavier (each balancing weight can reach 2-3 tons).

Because the balancing weight is formed by injecting concrete or steel into the shell through hard fixation, the balancing weight has large volume and occupies space on a construction site easily. Therefore, in the project construction process, the balancing weights are generally arranged in a warehouse or an empty construction site of an engineering team, and then are manually positioned and managed. When the balancing weights are needed, the balancing weights are manually allocated from a warehouse or a construction site according to the required quantity, transported to a project construction site for additional installation and use, and manually allocated to the next project site or a transportation meeting site for storage after the balancing weights are completed.

However, the conventional balancing weights have the following technical problems: each balancing weight is formed by integrally hardening, and has a simple structure, but lacks of effective supervision and management, so that the information of the balancing weight is opaque. In the process of allocation and transportation, the phenomenon of private bill receiving is easy to occur, namely a transportation driver privately transports the balancing weight to different construction sites during transportation and privately rents the balancing weight to different engineering teams; or the private hiding phenomenon occurs, namely, a transportation driver privately uses the balancing weight in a personal manual way by transporting the balancing weight during transportation, so that the balancing weight is lost. The above engineering phenomena not only can cause the loss of the balancing weight, but also can require additional purchase or lease of a new balancing weight, thereby increasing the construction cost; and because the quantity, flow direction, state, position and other information of each balancing weight are not clear, subsequent project construction and service development arrangement cannot be carried out according to the actual condition of the balancing weights, and the construction cost of enterprises is further increased, so that the development of subsequent services is influenced.

Disclosure of Invention

The invention provides a balancing weight with a tag, a balancing weight allocation method and a balancing weight allocation device based on the tag, wherein a slot is formed in the side edge of the balancing weight, a fixed clamping groove is arranged in the slot, and an RFID tag capable of tracking and identifying is arranged in the fixed clamping groove, so that the balancing weight can be identified by the RFID tag, related data of the balancing weight can be obtained, and the balancing weight can be effectively supervised and managed, so that various private sheets or private hiding phenomena can be avoided.

A first aspect of an embodiment of the present invention provides a labeled balancing weight, the labeled balancing weight comprising: a balancing weight body and a fixing clamping groove;

the side of balancing weight body is equipped with the fluting, the fluting is equipped with fixed gasket, fixed gasket is equipped with the gasket opening, the bottom surface of fixed draw-in groove is equipped with the base of L font, the base be equipped with the via hole that the gasket opening matches, the gasket opening with the via hole passes through the screw fixation, so that the base is fixed on the fixed gasket, fixed draw-in groove with use epoxy or concrete to fill around the fluting, fixed draw-in groove is equipped with the RFID label, and utilize the RFID label is right the balancing weight body manages.

A second aspect of an embodiment of the present invention provides a method for allocating a balancing weight based on a tag, the method being applicable to a balancing weight with a tag as described above, the method comprising:

counting and recording state information of a plurality of labeled balancing weights stored in a warehouse by utilizing RFID labels;

after acquiring a deployment service request, generating a deployment scheme according to the deployment service request and the state information;

And notifying a user to transport a plurality of the labeled balancing weights to a target area corresponding to the allocation service request according to the allocation scheme.

In a possible implementation manner of the second aspect, the state information includes: storing the number value and the storage location area every day; the allocation service request comprises a request quantity value, a request time and a target area;

the generating an allocation scheme according to the allocation service request and the state information includes:

calculating the region interval distance between the storage positioning region and the target region;

when the interval distance of the areas is smaller than a preset distance, calculating the allocation days required by transporting the balancing weights according to the request time;

generating a deployment plan according to the deployment days, the daily storage quantity value and the request quantity value.

In a possible implementation manner of the second aspect, the generating a deployment scenario according to the deployment day, the daily storage quantity value and the request quantity value includes:

calculating a first allocation quantity value by adopting the request quantity value and the allocation days, wherein the first allocation quantity value is the quantity of balancing weights to be allocated every day;

And if the daily storage quantity value is larger than or equal to the first allocation quantity value, determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route and the first allocation quantity value as allocation schemes.

In a possible implementation manner of the second aspect, the generating a deployment scenario according to the deployment day, the daily storage quantity value, and the request quantity value further includes:

if the daily storage quantity value is smaller than the first allocation quantity value, calculating a difference value between the daily storage quantity value and the first allocation quantity value to obtain a quantity difference value, and determining a supplementing number of days in a time interval corresponding to the request time, wherein the supplementing number of days comprises a plurality of days, and the daily storage quantity value is larger than the first allocation quantity value;

calculating a blending and supplementing quantity value by adopting the quantity difference value and the supplementing days, and adding the blending and supplementing quantity value and the first blending quantity value to obtain a second blending quantity value;

and determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route, the daily storage quantity value and the second allocation quantity value as allocation schemes.

In a possible implementation manner of the second aspect, after the step of notifying, according to the deployment scenario, a user to transport a plurality of the tagged balancing weights to a target area corresponding to the deployment service request, the method includes:

counting the number of the balancing weights with labels remained in the warehouse to obtain a remaining number value;

if the remaining quantity value is smaller than a preset quantity value, carrying out early warning detection on a plurality of labeled balancing weights corresponding to the allocation scheme, wherein the early warning detection comprises: single pile overtime unfinished detection, single-turn super-tonnage counterweight detection, equipment idle overtime detection, equipment overtime unreturned detection, equipment transportation overtime detection, flight inspection anomaly detection and inventory anomaly detection.

In a possible implementation manner of the second aspect, after the step of notifying, according to the deployment scenario, a user to transport a plurality of the tagged balancing weights to a target area corresponding to the deployment service request, the method includes:

and visually displaying the storage areas of the plurality of the labeled balancing weights corresponding to the allocation scheme based on the target areas corresponding to the allocation service request, and generating a data chart according to the state information of the plurality of the labeled balancing weights corresponding to the allocation scheme.

A third aspect of embodiments of the present invention provides a tag-based balancing weight deployment device, the device being adapted for a tagged balancing weight as described above, the device comprising:

the counting and recording module is used for counting and recording state information of a plurality of labeled balancing weights stored in the warehouse by utilizing the RFID labels;

the generation module is used for generating a deployment scheme according to the deployment service request and the state information after acquiring the deployment service request;

and the allocation module is used for informing a user to transport a plurality of the labeled balancing weights to a target area corresponding to the allocation service request according to the allocation scheme.

Compared with the prior art, the balancing weight with the tag, the balancing weight allocation method and the balancing weight allocation device based on the tag provided by the embodiment of the invention have the beneficial effects that: according to the invention, the side edge of the balancing weight is provided with the slot, the fixed gasket is arranged at the slot, the fixed clamping groove is arranged on the fixed gasket, the RFID tag is arranged on the fixed clamping groove, and the tag is used for recording the information of each using and calculating link of the balancing weight, so that the information of the balancing weight is disclosed and transparent, and a user can conveniently and efficiently monitor and manage the balancing weight.

Drawings

FIG. 1 is a schematic diagram of a weight with a tag according to an embodiment of the present invention;

FIG. 2 is a front view of a fixing slot according to an embodiment of the present invention;

FIG. 3 is a top view of a fixing clip groove according to an embodiment of the present invention;

FIG. 4 is a side view of a fixing clip groove according to an embodiment of the present invention;

FIG. 5 is a side plan view of a fixing clip groove according to an embodiment of the present invention;

FIG. 6 is a front view of a mounting pad provided in accordance with one embodiment of the present invention;

FIG. 7 is a top view of a mounting pad provided in accordance with one embodiment of the present invention;

FIG. 8 is a side view of a mounting pad provided in accordance with one embodiment of the present invention;

FIG. 9 is a side plan view of a mounting pad provided in accordance with one embodiment of the present invention;

FIG. 10 is a flow chart of a balancing weight allocation method based on labels according to an embodiment of the present invention;

FIG. 11 is a flow chart of balancing weight information provided by an embodiment of the present invention;

FIG. 12 is a flowchart illustrating an exemplary method for deploying a tag-based balancing weight according to one embodiment of the present invention;

FIG. 13 is a flowchart illustrating the operation of early warning detection according to one embodiment of the present invention;

FIG. 14 is an effect diagram of a visual display provided by an embodiment of the present invention;

FIG. 15 is a schematic structural diagram of a balancing weight blending device based on a tag according to an embodiment of the present invention;

in the figure: the balancing weight body 1, the fixed clamping groove 2, the slot 3, the fixed gasket 4, the gasket opening 5 and the base 6.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As economies develop, the construction of various capital construction projects has also gradually increased, including: new construction, reconstruction, extension, restoration and other projects of roads, railways, bridges, schools, various industries, civil buildings and the like. In the construction project field, cooperative cooperation of various static load devices (e.g., balancing weights) is required to complete engineering construction. If the building or bridge is large, the weight of the needed balancing weight is heavier (each balancing weight can reach 2-3 tons).

Because the balancing weight is formed by injecting concrete or steel into the shell through hard fixation, the balancing weight has large volume and occupies space on a construction site easily. Therefore, in the project construction process, the balancing weights are generally arranged in a warehouse or an empty construction site of an engineering team, and then are manually positioned and managed. When the balancing weights are needed, the balancing weights are manually allocated from a warehouse or a construction site according to the required quantity, transported to a project construction site for additional installation and use, and manually allocated to the next project site or a transportation meeting site for storage after the balancing weights are completed.

However, the conventional balancing weights have the following technical problems: each balancing weight is formed by integrally hardening, and has a simple structure, but lacks of effective supervision and management, so that the information of the balancing weight is opaque.

In order to solve the above problems, the following detailed description and descriptions will be given of a weight block with a tag according to the embodiments of the present application.

Referring to fig. 1, a schematic structural diagram of a balancing weight with a tag according to an embodiment of the present application is shown.

Wherein, as an example, the labeled balancing weight may include: the balancing weight body 1 and the fixing clamping groove 2.

Referring to fig. 2-5, a front view of a fixing clip groove provided by an embodiment of the present application, a top view of a fixing clip groove provided by an embodiment of the present application, a side view of a fixing clip groove provided by an embodiment of the present application, and a side top view of a fixing clip groove provided by an embodiment of the present application are shown, respectively. And referring to fig. 6-9, a front view of a fixing spacer provided by an embodiment of the present application, a top view of a fixing spacer provided by an embodiment of the present application, a side view of a fixing spacer provided by an embodiment of the present application, and a side top view of a fixing spacer provided by an embodiment of the present application are shown, respectively.

In an embodiment, the side of balancing weight body 1 is equipped with fluting 3, fluting 3 is equipped with fixed gasket 4, fixed gasket 4 is equipped with gasket opening 5, the bottom surface of fixed draw-in groove 2 is equipped with the base 6 of L font, base 6 be equipped with the via hole that gasket opening 5 matees, gasket opening 5 with the via hole passes through the screw fixation, so that base 6 is fixed on fixed gasket 4, fixed draw-in groove 2 with use epoxy or concrete to fill around fluting 3, fixed draw-in groove 2 is equipped with the RFID label, and utilize the RFID label is right balancing weight body 1 manages.

In particular, referring to fig. 6 to 9, the fixing spacer 4 may be further provided with a plurality of fixing openings, and then screws are driven at the fixing openings so that the fixing spacer 4 may be fixed at the slot 3.

The spacer openings 5 and the vias may also be threaded so that the base 6 and the mounting spacer 4 may be joined together. And simultaneously, the RFID tag can be directly arranged in the fixed clamping groove 2. Meanwhile, in order to enable the surface of the balancing weight body 1 to be flat, epoxy resin or concrete can be added into a gap between the fixing clamping groove 2 and the slot 3, so that the gap between the fixing clamping groove 2 and the slot 3 is filled.

In an alternative embodiment, the thickness of the fixing pad 4 is 4-10mm, the width may be 25-35mm, and the length 150-250mm. The thickness of the fixing clamping groove 2 can be 1-3mm, the width can be 30-40mm, the length can be 150-250mm, the depth of the fixing clamping groove 2 can be 15-30mm, and the depth can be adjusted according to the size of an RFID label to be installed.

Optionally, the fixing gasket 4 and the fixing clamping groove 2 can be made of metal or plastic materials, and the finished product is non-soft, strong, compression-resistant and dust-proof, so that the implantation fixing mode of static load equipment is satisfied.

In order to reduce the difficulty of installation, the fixing gasket 4 and the fixing clamping groove 2 can be directly fixed on the slot 3 by using epoxy resin or concrete, and after the epoxy resin or the concrete is solidified and fixed, the ultrahigh frequency RFID electronic tag is fixed to the fixing clamping groove 2 by using screws, and finally the balancing weight with the tag is realized.

When the portable handheld device is used, various portable mobile handheld devices can be used, the handheld devices and the ultrahigh frequency chip are combined to solve the problem of reading distance, and key links of warehousing, ex-warehouse, entering, pile turning, evacuation, warehousing and the like of each balancing weight are scanned and positioned through the handheld devices. The handheld terminal equipment is used for carrying out scanning induction on each link, recording information such as the state and the positioning of the equipment in real time, collecting response data in real time and uploading the response data to a background server or a background system (also a cloud system), and managing each data and information through the background server, so that the information of the balancing weight is disclosed and transparent, the phenomenon of receiving private sheets and the phenomenon of private hiding can be avoided, the loss probability of the balancing weight can be reduced, and the construction cost is reduced; after the information of each balancing weight is monitored and managed, subsequent project construction and service development arrangement can be rapidly carried out according to the actual conditions of the balancing weights, and a user can conveniently develop subsequent engineering services.

In this embodiment, the embodiment of the invention provides a balancing weight with a tag, which has the beneficial effects that: according to the invention, the side edge of the balancing weight is provided with the slot, the fixed gasket is arranged at the slot, the fixed clamping groove is arranged on the fixed gasket, the RFID tag is arranged on the fixed clamping groove, and the tag is used for recording the information of each using and calculating link of the balancing weight, so that the information of the balancing weight is disclosed and transparent, and a user can conveniently and efficiently monitor and manage the balancing weight.

Because the balancing weight is formed by injecting concrete or steel into the shell through hard fixation, the balancing weight has large volume and occupies space on a construction site easily. Therefore, in the project construction process, the balancing weights are generally arranged in a warehouse or an empty construction site of an engineering team, and then are manually positioned and managed. When the balancing weights are needed, the balancing weights are manually allocated from a warehouse or a construction site according to the required quantity, transported to a project construction site for additional installation and use, and manually allocated to the next project site or a transportation meeting site for storage after the balancing weights are completed.

The manual blending mode has the following technical problems: the efficiency of manual processing is low, and once the quantity of balancing weights required for allocation is large, when the content of related engineering projects is large, mistakes are easy to occur, so that the engineering progress is delayed, and the construction cost of engineering is increased.

In order to improve the balancing efficiency of the balancing weights, referring to fig. 10, a flow chart of a balancing weight balancing method based on labels according to an embodiment of the present invention is shown.

In one embodiment, the method is applicable to a labeled balancing weight as in the previous embodiment. Alternatively, the method may also be applied to individual tagged static devices, such as jacks, steel beams, electronic static meters, oil pumps, and the like. In this embodiment, only the labeled weight is described as an example.

In one implementation, the method is applied to a background management system, which can be in communication connection with a plurality of different mobile portable handsets, and each mobile portable handset can scan RFID tags to collect various information of the balancing weights.

In an actual application mode, the background management system can be also in communication connection with the intelligent terminal of the manager, and transmits various data and information to the intelligent terminal of the manager for the manager to check.

It should be noted that the background management system may include: user center function, asset management function, service management function, allocation management function, lease management function, asset inventory/flight inspection function, data summarization function, cockpit function, and trace source.

Wherein, user center function: a user workbench is built by taking a user as a center, comprises modules of products and services, enterprise management, project department management, a security center, personal information and the like, and provides viewing and downloading of help documents and other programs.

Asset management function: registering the asset equipment, managing the chip implantation, and providing information inquiry of the asset equipment.

Service single management function: including the management of processes from ordering, receiving, scheduling of service orders to service site implementation, etc.

Deployment management function: the equipment allocation management based on the service list supports the allocation plan to compile and select a plurality of ways of idle equipment, possible idle equipment, newly added borrowing equipment and the like as allocation data sources, and can provide an optimized selection scheme according to the equipment positioning information.

Lease management function: lending management of the self-owned device and the external device.

Asset inventory/flight check function: asset inventory information registration and management can be performed monthly, quarterly and yearly, and temporary flight inspection management is also provided for property warehouses, temporary warehouses and equipment at inspection sites.

Data summarizing function: the asset data summarization support data summarize according to the types, the dimensions of a warehouse and the like, and the workload data summarization support data summarize according to the multiple roles of project responsibility personnel, allocation personnel and the like.

Cockpit function: the system comprises a key base statistics module, a multidimensional data distribution and comparison module, an asset map distribution module, an asset early warning reminding module and the like, and is used for supporting custom generation of a cockpit report according to year, quarter and month.

Tracking and tracing functions: the RFID identification chip of the scanning device is used for rapidly tracking the state information of each node in the equipment circulation process, and data can be verified and traced for each piece of equipment.

Wherein, as an example, the balancing weight allocation method based on the label may include:

s11, counting and recording state information of a plurality of labeled balancing weights stored in a warehouse by utilizing RFID labels.

In an embodiment, in a storage warehouse or a storage place, a worker can utilize an ultrahigh frequency chip built in a mobile portable handset to read an RFID tag of the balancing weight, and key links such as warehousing, ex-warehouse, entering, pile turning, withdrawal, warehousing and the like of the balancing weight or static load equipment are scanned and positioned through the mobile portable handset to acquire various information of the balancing weight or static load equipment.

The handheld terminal equipment is used for carrying out scanning induction on each link, recording information such as the state and the positioning of the equipment in real time, uploading data to a background management system in real time after acquisition, and recording and counting information of each piece of balancing weight with a tag or static load equipment with a tag by the background management system to obtain state information of the balancing weight with the tag.

In one implementation, each time the links of allocation or transportation such as warehousing, ex-warehouse, entering, transferring piles, evacuating, warehousing and the like are performed, the handset performs data acquisition once and then uploads the acquired data to the background management system, and the background management system can perform statistics and recording.

Referring to fig. 11, a flow chart of balancing weight information provided by an embodiment of the present invention is shown.

Optionally, statistics can be performed once a day at night, so that corresponding allocation and management are convenient for the next day.

S12, after the allocation service request is acquired, generating an allocation scheme according to the allocation service request and the state information.

In one embodiment, when the project engineering needs to use the balancing weight, a deployment service request may be sent to the background management system. Alternatively, the provisioning service request may be sent to the background management system by the mobile portable handset.

The background management system can generate a deployment scheme according to the deployment service request and the state information of each balancing weight after receiving the deployment service request, and does not need to manually perform deployment management and arrangement so as to improve the processing efficiency of deployment.

In an alternative embodiment, the status information includes: storing the number value and the storage location area every day; the provisioning service request includes a request quantity value, a request time, and a target area.

Where the requested number value refers to the number of weights required, for example 100 blocks. The request time is from the current time to the expiration time required to complete the preparation, for example, the current time is 6 months and 1 day, and the expiration time required to complete the preparation is 6 months and 4 days. The target area refers to a coordinate area of a destination to be transported.

The daily storage quantity value refers to the number of balancing weights stored in the warehouse or the storage place every day in the interval of the request time, for example, the current time is 6 months and 1 day, and the deadline for completing the allocation is 6 months and 4 days, and then the daily storage quantity value respectively comprises the number of balancing weights stored in the warehouse at 6 months and 1 day, the number of balancing weights stored in the warehouse at 6 months and 2 days, the number of balancing weights stored in the warehouse at 6 months and 3 days and the number of balancing weights stored in the warehouse at 6 months and 4 days. The storage location area refers to a coordinate area of a warehouse or a storage place.

Referring to fig. 12, an operation flowchart of a balancing weight allocation method based on a tag according to an embodiment of the present invention is shown.

As an example, step S12 may include the following sub-steps:

s121, calculating the region interval distance between the storage positioning region and the target region.

Specifically, the driving distance between the two coordinates may be calculated according to the coordinates of the storage location area and the coordinates of the target area, to obtain the area separation distance. The calculation method is similar to the calculation of the driving distance of two coordinate points of a map.

And S122, calculating the number of allocation days required for transporting the balancing weights according to the request time when the interval distance of the areas is smaller than the preset distance.

If the area interval distance is smaller than the preset distance, the destination to be transported is relatively close, and the number of allocation days required for transporting the balancing weights can be calculated according to the request time.

The number of allocation days refers to the number of days of actual transportation, and generally, the number of allocation days is obtained by subtracting the emergency buffer time (for example, one or two days) from the number of days included in the request time, so as to cope with the fact that allocation cannot be in place due to excessive plan fluctuation through the emergency buffer time.

For the above example, the request time is 4 days from 1 day 6 months to 4 days 6 months, and may be 4 days to 1 day=3 days, and 3 days is the number of days of preparation.

The number of days of the emergency cache time can be adjusted according to actual needs.

S123, generating a deployment scheme according to the deployment days, the daily storage quantity value and the request quantity value.

After the allocation days are determined, an allocation scheme can be generated within the allocation days according to the relation between the daily storage quantity value and the request quantity value, so that the application requirements of engineering are met.

In one embodiment, the daily storage count value may satisfy the request count value over the number of deployment days.

As an example, step S123 may include the following sub-steps:

s1231, calculating a first allocation quantity value by adopting the request quantity value and the allocation days, wherein the first allocation quantity value is the quantity of balancing weights to be allocated every day.

According to the foregoing, the balancing weights with the corresponding number of the requested number values need to be allocated within the allocation days, and in order to reduce the transportation pressure, a part of the balancing weights can be transported every day until allocation is completed within the allocation days.

Specifically, the request quantity value may be divided by the number of days of allocation, and the first allocation quantity value may be calculated. The first blending quantity value is the quantity of balancing weights to be blended every day in the blending days.

For example, if the number of days of preparation is 3 days and the number of requests is 30, the first number of preparation is 30/3=10. 10 balancing weights are blended every day.

S1232, if the daily storage quantity value is greater than or equal to the first allocation quantity value, determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route and the first allocation quantity value as allocation schemes.

In one embodiment, it may be determined whether the daily stored quantity value is greater than or equal to the first deployment quantity value. If the daily stored quantity value is greater than or equal to the first dispensing quantity value, the quantity of the balancing weights stored in the warehouse or the storage place in the days of the dispensing days can meet the quantity of the first dispensing quantity value.

Then, a driving transportation route can be designated by using the coordinates of the storage positioning area and the target area, so as to obtain a transportation route, and a blending scheme is generated by combining the transportation route and the first blending quantity value.

The first allocation quantity value can be used as the number of balancing weights transported every day, and the transportation route is used as the driving route for allocation and transportation.

In one embodiment, the daily stored number of days during the days of deployment does not satisfy the requirement of the requested number of days.

S1233, if the daily storage quantity value is smaller than the first allocation quantity value, calculating a difference value between the daily storage quantity value and the first allocation quantity value to obtain a quantity difference value, and determining a supplementing number of days in a time interval corresponding to the request time, wherein the supplementing number of days comprises a plurality of days, and the daily storage quantity value is larger than the first allocation quantity value.

If the daily storage quantity value is smaller than the first allocation quantity value, the daily storage quantity value of each day in the allocation days may be smaller than the first allocation quantity value, or the daily storage quantity value of three or two days may be smaller than the first allocation quantity value.

In order to avoid delaying the progress of the project due to the interruption of transportation, the project can be judged one by one from the last day of the allocation days.

Using the above example, the request time is 4 days from 1 day 6 months to 4 days 6 months, and may be 4 days to 1 day=3 days, and 3 days are the blending days, and are 6 months to 1 day 6 months to 3 days, respectively. It may be first determined whether the daily stored quantity value for 6 months and 3 days is less than the first deployment quantity value. Then judging whether the daily storage quantity value of 6 months and 2 days is smaller than the first allocation quantity value, and judging whether the daily storage quantity value of 6 months and 1 day is smaller than the first allocation quantity value.

If at least one daily stored quantity value is smaller than the first allocation quantity value, for example, the daily stored quantity value for 6 months and 3 days is smaller than the first allocation quantity value, the difference between the daily stored quantity value and the first allocation quantity value can be calculated to obtain a quantity difference value. Meanwhile, it is also possible to calculate that among two days of 6 months 1 to 6 months 2 days, the number of days stored per day is larger than the first formulation number value, and if the number of days stored per day is larger than the first formulation number value for each of 6 months 1 to 6 months 2 days, the number of days to be supplemented is 2 days, and if only 6 months 1 or 6 months 2 days is the number of days stored per day is larger than the first formulation number value, the number of days to be supplemented is 1 day.

S1234, calculating a blending and supplementing quantity value by adopting the quantity difference value and the supplementing days, and adding the blending and supplementing quantity value and the first blending quantity value to obtain a second blending quantity value.

In one embodiment, the quantity difference may be divided by the number of replenishment days, and the quantity of replenishment is calculated. And then adding the blending and supplementing quantity value with the first blending quantity value to obtain a second blending quantity value.

For example, in the above example, the daily storage quantity value for 6 months and 3 days is smaller than the first dispensing quantity value, the quantity difference is 4, the number of days for replenishment is 2 days, and the dispensing replenishment quantity value is 2. The first blending quantity value is 10, and the second blending quantity value is 10+2=12 after calculation.

S1235, determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route, the daily storage quantity value and the second allocation quantity value as allocation schemes.

Then, the coordinates of the storage location area and the target area can be used for designating a driving transportation route, a transportation route is obtained, and a blending scheme is generated by combining the transportation route, the daily storage quantity value and the second blending quantity value.

After the second allocation quantity value is calculated, the second allocation quantity value can be used as the number of balancing weights transported every day in the following 6 months from 1 day to 6 months 2 days, the transportation route is used as the driving route for allocation transportation, and the daily storage quantity value can be used as the number of balancing weights transported every day in the following 6 months 3 days, and the transportation route is used as the driving route for allocation transportation.

For ease of understanding, reference may be made to the following process flow:

the method comprises the steps that firstly, a detection task list or an allocation service request issued by a detection department is obtained, wherein the detection task list comprises engineering addresses, equipment types and quantity and the deadline for requesting allocation to be completed;

secondly, after receiving a detection task list or a deployment service request, a deployment plan is constructed, and specific devices and the quantity of the devices are required to be deployed on each day;

thirdly, detecting that the equipment required by the service bill is not allocated in place in one day, wherein the allocation time is generally 3-5 days or more, updating the equipment conditions of the current warehouse and the equipment storage place once a day by the system, predicting the equipment change conditions of the warehouse and the equipment storage place in the future every day according to business execution feedback, and allocating time allocation plans according to the equipment conditions predicted in the future and the existing day by the following rules:

a1, calculating the number of days T1 left until the blending cut-off time according to the blending cut-off time;

b1, subtracting 1 day (subtracting one day as emergency buffer time to cope with excessive plan change, so that allocation cannot be in place in time) on the basis of T1 to obtain T2;

c1, evenly distributing the number of the various types of equipment to be distributed to each day of T2 (if 100 test blocks are required to be distributed in total, the T2 is 5 days, 20 test blocks are distributed every day);

D1, if the allocation quantity is evenly allocated, checking from the last day onwards, and if the quantity of idle equipment in a certain day cannot meet the allocation requirement, defining the excessive quantity as N, defining the number of days before the certain day as T3, evenly allocating N according to the rule of C and then evenly allocating N according to the T3 days, and repeating the steps of C1 and D1 until the adaption is completed;

the background management system takes the existing warehouse address and the equipment storage address as the departure place according to the position of the destination, automatically generates a track route from each departure place to the destination by means of a map engine technology, obtains the distance of each track route, finally arranges the distance from each departure place to the destination from near to far according to the distance length, and can select nearby warehouses and equipment storage places to allocate according to the result;

step five, the background management system can calculate how many devices and which types of devices exist in each warehouse and device storage place at present according to the current device state and distribution condition, and the arrangement and combination of warehouse-out allocation are carried out according to the types and the quantity of the devices required to be allocated on the same day and the following rules:

a2, if a certain warehouse and equipment storage place can meet the allocation requirement, the warehouse can be taken out of the warehouse to allocate according to the certain warehouse and equipment storage place preferentially;

If A1 is not satisfied, a warehouse and a device storage place which are closest to the meeting requirements are preferentially allocated, and then the parts which are required to be allocated are repeatedly adapted according to the rules of A2 and B2 until the adaptation is completed;

and a sixth step of integrating rules of the third step, the fourth step and the fifth step, generating the types and the quantity of equipment which need to be allocated every day preferentially according to the track of the third step, generating a re-allocation scheme respectively according to the rules of the fourth step and the fifth step, wherein the combination of the third step and the fourth step is priority distance allocation, and the combination of the third step and the fifth step is priority warehouse and equipment storage allocation.

And S13, notifying a user to transport a plurality of the labeled balancing weights to a target area corresponding to the allocation service request according to the allocation scheme.

In an embodiment, the deployment scheme may be sent to the handset that uploads the deployment service request for viewing by a corresponding manager or user, so that the driver is arranged to transport the balancing weight to the target area corresponding to the deployment service request according to the deployment scheme.

In an alternative embodiment, the background management system may also send the deployment scenario to the manager's intelligent terminal, which is checked by the manager for shipping and deployment.

According to the description of the previous steps, the background management system can generate a plurality of different allocation schemes, the generated allocation schemes can be sent to the intelligent terminal of the user, the user can select the matched scheme according to the scheme generated by the system, and after the scheme generated by the system is selected, the manual adjustment scheme can be performed, and particularly the adjustment can be performed according to actual needs.

RFID identification is carried out on static load equipment (such as balancing weights) of heavy assets through the internet of things technology, so that the state and position information of the equipment are mastered in time, and the digital management of the equipment is realized; and the intelligent algorithm is used for providing intelligent allocation scheme analysis and generation for enterprises, so that the equipment allocation efficiency is improved.

In one embodiment, after the balancing weights are deployed and leased, the balancing weights remaining in the warehouse need to be managed to determine whether there are transportation errors or whether the balancing weights are not returned to warehouse.

Referring to fig. 13, a flowchart of the operation of early warning detection according to an embodiment of the present invention is shown.

Wherein, as an example, the method may comprise the steps of:

s21, counting the number of the balancing weights with labels remained in the warehouse to obtain a remaining number value.

Specifically, the background management system can send a query request to the intelligent terminal of the manager, and then the manager checks and counts the number of the balancing weights actually remained in the warehouse to obtain the value of the remaining number.

S22, if the residual quantity value is smaller than a preset quantity value, carrying out early warning detection on a plurality of labeled balancing weights corresponding to the allocation scheme, wherein the early warning detection comprises: single pile overtime unfinished detection, single-turn super-tonnage counterweight detection, equipment idle overtime detection, equipment overtime unreturned detection, equipment transportation overtime detection, flight inspection anomaly detection and inventory anomaly detection.

And counting the number of the balancing weights with labels remained in the warehouse once every time when the links of warehousing, ex-warehouse, entering, pile turning, evacuation, warehousing and other allocation or transportation are completed, and taking the remaining number counted by the system as a preset value. If the remaining number is smaller than the preset number, it means that the number of the actual balancing weights remaining in the warehouse is smaller than the number of the balancing weights counted by the system, and the balancing weights may be privately used or some of the balancing weights are not returned to warehouse. To avoid losses, early warning detection is required.

In an alternative embodiment, the early warning detection includes: single pile overtime unfinished detection, single-turn super-tonnage counterweight detection, equipment idle overtime detection, equipment overtime unreturned detection, equipment transportation overtime detection, flight inspection anomaly detection and inventory anomaly detection.

Specifically, the single pile out-of-date unfinished detection may be: when a foundation pile is in an unfinished state, or the balancing weight or static load equipment does not finish application processing, and the planned finishing time is exceeded, the system generates early warning.

The single-turn super-tonnage counterweight detection can be: when the weight of a balancing weight or static load equipment bound by a foundation pile exceeds the ton of planned balancing weight, the system generates early warning.

The device idle timeout detection may be: when the single balancing weight or static load equipment is in an idle state (not allocated) and exceeds a preset threshold value, the system generates early warning.

The device timeout unreturned detection may be: when the single borrowing balancing weight or the static load equipment is in an unreturned state and the borrowing time exceeds a preset threshold value, the system generates early warning.

The device transportation timeout detection may be: when the single balancing weight or static load equipment is in a state of leaving warehouse and not entering field (indicated in transportation), and the transportation time exceeds a preset threshold value, the system generates early warning.

The flight inspection anomaly detection may be: and the equipment management department checks the warehouse and the equipment storage place to find abnormality, and the system generates early warning.

Inventory anomaly detection may be: the equipment management department regularly checks the warehouse and the equipment storage place to find abnormality, and the system generates early warning.

In an application mode, the background management system can be provided with a plurality of early warning detection models, each early warning detection model is responsible for early warning detection, and a digital prediction model of a key service point is established by analyzing the balancing weight and the static load detection overall process service, so that intelligent early warning can be carried out on the key service.

According to the invention, through analysis of the business, a digital early warning model is established, the abnormal behavior and state are early warned, and risk prediction and management and control are improved.

Referring to fig. 14, an effect diagram of a visual presentation provided by an embodiment of the present invention is shown.

In an embodiment, to facilitate the user's view of the deployed device or balancing weight, the method may include the steps of:

and S31, visually displaying the storage areas of the plurality of the labeled balancing weights corresponding to the allocation scheme based on the target areas corresponding to the allocation service requests, and generating a data chart according to the state information of the plurality of the labeled balancing weights corresponding to the allocation scheme.

Specifically, dynamic visual display can be performed, and according to the focus of service attention, the data collected in the equipment management process is subjected to operations such as mining, cleaning, aggregation and the like, so that a visual management cockpit derived from key service base numbers, data chart analysis, equipment distribution maps, early warning reminding and custom report forms is formed, as shown in fig. 14.

According to the invention, through statistics and analysis of the collected static load equipment data, visual display of form dynamics is provided, and data basis and decision analysis are provided for enterprise management.

In this embodiment, the embodiment of the invention provides a balancing weight allocation method based on a label, which has the beneficial effects that: the invention can use the background management system to intelligently manage and allocate the balancing weight with the label, can effectively improve the allocating processing efficiency, shortens the allocating processing time, reduces the cost of business processing, reduces the error probability and avoids delaying the engineering progress.

The embodiment of the invention also provides a balancing weight allocation device based on the tag, and referring to fig. 15, a schematic structural diagram of the balancing weight allocation device based on the tag is shown.

The device is suitable for use with a labeled balancing weight as described in the previous embodiments.

Wherein, as an example, the balancing weight allocation device based on the label can include:

a statistics and recording module 201, configured to use an RFID tag to count and record status information of a plurality of labeled balancing weights stored in a warehouse;

a generating module 202, configured to generate an allocation scheme according to the allocation service request and the state information after acquiring the allocation service request;

And the allocating module 203 is configured to notify a user to transport the plurality of labeled balancing weights to a target area corresponding to the allocating service request according to the allocating scheme.

Optionally, the status information includes: storing the number value and the storage location area every day; the allocation service request comprises a request quantity value, a request time and a target area;

the generating module is further configured to:

calculating the region interval distance between the storage positioning region and the target region;

when the interval distance of the areas is smaller than a preset distance, calculating the allocation days required by transporting the balancing weights according to the request time;

generating a deployment plan according to the deployment days, the daily storage quantity value and the request quantity value.

Optionally, the generating module is further configured to:

calculating a first allocation quantity value by adopting the request quantity value and the allocation days, wherein the first allocation quantity value is the quantity of balancing weights to be allocated every day;

and if the daily storage quantity value is larger than or equal to the first allocation quantity value, determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route and the first allocation quantity value as allocation schemes.

Optionally, the generating module is further configured to:

if the daily storage quantity value is smaller than the first allocation quantity value, calculating a difference value between the daily storage quantity value and the first allocation quantity value to obtain a quantity difference value, and determining a supplementing number of days in a time interval corresponding to the request time, wherein the supplementing number of days comprises a plurality of days, and the daily storage quantity value is larger than the first allocation quantity value;

calculating a blending and supplementing quantity value by adopting the quantity difference value and the supplementing days, and adding the blending and supplementing quantity value and the first blending quantity value to obtain a second blending quantity value;

and determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route, the daily storage quantity value and the second allocation quantity value as allocation schemes.

Optionally, the apparatus further comprises:

the statistics remaining number module is used for counting the number of the balancing weights with labels remaining in the warehouse to obtain a remaining number value;

the early warning detection module is used for carrying out early warning detection on a plurality of labeled balancing weights corresponding to the allocation scheme if the residual quantity value is smaller than a preset quantity value, and the early warning detection comprises: single pile overtime unfinished detection, single-turn super-tonnage counterweight detection, equipment idle overtime detection, equipment overtime unreturned detection, equipment transportation overtime detection, flight inspection anomaly detection and inventory anomaly detection.

Optionally, the apparatus further comprises:

and the visual display module is used for visually displaying the storage areas of the plurality of the labeled balancing weights corresponding to the allocation scheme based on the target areas corresponding to the allocation service requests, and generating a data chart according to the state information of the plurality of the labeled balancing weights corresponding to the allocation scheme.

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

Further, an embodiment of the present application further provides an electronic device, including: the system comprises a memory, a processor and a computer program stored on the memory and capable of running on the processor, wherein the processor is used for realizing the balancing weight allocation method based on the label according to the embodiment when executing the program.

Further, an embodiment of the present application further provides a computer readable storage medium, where a computer executable program is stored, where the computer executable program is configured to cause a computer to execute the tag-based balancing weight allocation method according to the above embodiment.

While the foregoing is directed to the preferred embodiments of the present invention, it will be appreciated by those skilled in the art that changes and modifications may be made without departing from the principles of the invention, such changes and modifications are also intended to be within the scope of the invention.

Claims (6)

1. The utility model provides a balancing weight allotment method based on label, its characterized in that, the method is applicable to the balancing weight of area label, the balancing weight of area label includes: a balancing weight body and a fixing clamping groove;

the side of the balancing weight body is provided with a slot, the slot is provided with a fixed gasket, the fixed gasket is provided with a gasket opening, the bottom surface of the fixed clamping groove is provided with an L-shaped base, the base is provided with a through hole matched with the gasket opening, the gasket opening and the through hole are fixed through screws so that the base is fixed on the fixed gasket, the periphery of the fixed clamping groove and the slot is filled with epoxy resin or concrete, the fixed clamping groove is provided with an RFID tag, and the balancing weight body is managed by the RFID tag;

the method comprises the following steps:

counting and recording state information of a plurality of labeled balancing weights stored in a warehouse by utilizing RFID labels;

After acquiring a deployment service request, generating a deployment scheme according to the deployment service request and the state information;

notifying a user to transport a plurality of labeled balancing weights to a target area corresponding to the allocation service request according to the allocation scheme;

the status information includes: storing the number value and the storage location area every day; the allocation service request comprises a request quantity value, a request time and a target area;

the generating an allocation scheme according to the allocation service request and the state information includes:

calculating the region interval distance between the storage positioning region and the target region;

when the interval distance of the areas is smaller than a preset distance, calculating the allocation days required by transporting the balancing weights according to the request time;

generating a deployment plan according to the deployment days, the daily storage quantity value and the request quantity value;

the generating a deployment plan according to the deployment days, the daily storage quantity value and the request quantity value comprises the following steps:

calculating a first allocation quantity value by adopting the request quantity value and the allocation days, wherein the first allocation quantity value is the quantity of balancing weights to be allocated every day;

If the daily storage quantity value is greater than or equal to the first allocation quantity value, determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route and the first allocation quantity value as allocation schemes;

the generating a deployment plan according to the deployment days, the daily storage quantity value and the request quantity value further comprises:

if the daily storage quantity value is smaller than the first allocation quantity value, calculating a difference value between the daily storage quantity value and the first allocation quantity value to obtain a quantity difference value, and determining a supplementing number of days in a time interval corresponding to the request time, wherein the supplementing number of days comprises a plurality of days, and the daily storage quantity value is larger than the first allocation quantity value;

calculating a blending and supplementing quantity value by adopting the quantity difference value and the supplementing days, and adding the blending and supplementing quantity value and the first blending quantity value to obtain a second blending quantity value;

and determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route, the daily storage quantity value and the second allocation quantity value as allocation schemes.

2. The tag-based balancing weight allocation method according to claim 1, wherein after the step of notifying a user of transporting a plurality of the tagged balancing weights to a target area corresponding to the allocation service request according to the allocation scheme, the method further comprises:

counting the number of the balancing weights with labels remained in the warehouse to obtain a remaining number value;

if the remaining quantity value is smaller than a preset quantity value, carrying out early warning detection on a plurality of labeled balancing weights corresponding to the allocation scheme, wherein the early warning detection comprises: single pile overtime unfinished detection, single-turn super-tonnage counterweight detection, equipment idle overtime detection, equipment overtime unreturned detection, equipment transportation overtime detection, flight inspection anomaly detection and inventory anomaly detection.

3. The tag-based balancing weight allocation method according to claim 1, wherein after the step of notifying a user of transporting a plurality of the tagged balancing weights to a target area corresponding to the allocation service request according to the allocation scheme, the method further comprises:

and visually displaying the storage areas of the plurality of the labeled balancing weights corresponding to the allocation scheme based on the target areas corresponding to the allocation service request, and generating a data chart according to the state information of the plurality of the labeled balancing weights corresponding to the allocation scheme.

4. The utility model provides a balancing weight allotment device based on label, its characterized in that, the device is applicable to the balancing weight of taking the label, the balancing weight of taking the label includes: a balancing weight body and a fixing clamping groove;

the side of the balancing weight body is provided with a slot, the slot is provided with a fixed gasket, the fixed gasket is provided with a gasket opening, the bottom surface of the fixed clamping groove is provided with an L-shaped base, the base is provided with a through hole matched with the gasket opening, the gasket opening and the through hole are fixed through screws so that the base is fixed on the fixed gasket, the periphery of the fixed clamping groove and the slot is filled with epoxy resin or concrete, the fixed clamping groove is provided with an RFID tag, and the balancing weight body is managed by the RFID tag;

the device comprises:

the counting and recording module is used for counting and recording state information of a plurality of labeled balancing weights stored in the warehouse by utilizing the RFID labels;

the generation module is used for generating a deployment scheme according to the deployment service request and the state information after acquiring the deployment service request;

the allocation module is used for informing a user to transport a plurality of the labeled balancing weights to a target area corresponding to the allocation service request according to the allocation scheme;

The status information includes: storing the number value and the storage location area every day; the allocation service request comprises a request quantity value, a request time and a target area;

the generating an allocation scheme according to the allocation service request and the state information includes:

calculating the region interval distance between the storage positioning region and the target region;

when the interval distance of the areas is smaller than a preset distance, calculating the allocation days required by transporting the balancing weights according to the request time;

generating a deployment plan according to the deployment days, the daily storage quantity value and the request quantity value;

the generating a deployment plan according to the deployment days, the daily storage quantity value and the request quantity value comprises the following steps:

calculating a first allocation quantity value by adopting the request quantity value and the allocation days, wherein the first allocation quantity value is the quantity of balancing weights to be allocated every day;

if the daily storage quantity value is greater than or equal to the first allocation quantity value, determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route and the first allocation quantity value as allocation schemes;

The generating a deployment plan according to the deployment days, the daily storage quantity value and the request quantity value further comprises:

if the daily storage quantity value is smaller than the first allocation quantity value, calculating a difference value between the daily storage quantity value and the first allocation quantity value to obtain a quantity difference value, and determining a supplementing number of days in a time interval corresponding to the request time, wherein the supplementing number of days comprises a plurality of days, and the daily storage quantity value is larger than the first allocation quantity value;

calculating a blending and supplementing quantity value by adopting the quantity difference value and the supplementing days, and adding the blending and supplementing quantity value and the first blending quantity value to obtain a second blending quantity value;

and determining a transportation route based on the storage and positioning area and the target area, and taking the transportation route, the daily storage quantity value and the second allocation quantity value as allocation schemes.

5. An electronic device, comprising: a memory, a processor and a computer program stored on the memory and executable on the processor, wherein the processor implements the tag-based balancing weight deployment method according to any one of claims 1-3 when executing the program.

6. A computer-readable storage medium, wherein the computer-readable storage medium stores a computer-executable program for causing a computer to execute the tag-based balancing weight allocation method according to any one of claims 1 to 3.