CN112734366B - Dynamic management method, system and storage medium for whole engineering settlement process cost - Google Patents

Abstract

The application relates to a dynamic management method, a system and a storage medium for the construction cost of the whole construction settlement process, which relate to the technical field of construction settlement and solve the problems that when the current process of a construction project is finished and the actual investment and the planning investment are inconsistent, analysis and corresponding approval of related reasons are carried out, and the management personnel have hysteresis on the control of the whole construction cost, wherein the method comprises the steps of adding the sum of the building material cost required by the next process of the predicted construction and the personnel cost required by the next process of the construction, adding the sum of the building material cost and the personnel cost of the next process of the planning and carrying out difference, and the obtained difference is taken as the predicted expense deviation; and confirming whether approval is needed and personnel corresponding to the approval based on the predicted condition of the expense deviation. The application can lead the manager to know the predicted cost of the next working procedure in advance, thereby being beneficial to the management of the whole engineering cost.

Description

Dynamic management method, system and storage medium for whole engineering settlement process cost

Technical Field

The application relates to the technical field of engineering settlement, in particular to a dynamic management method, a system and a storage medium for the whole engineering settlement process cost.

Background

Engineering settlement is directly related to construction units and the tangential interests of the construction units. In the process of the investigation of the settlement, the positions and the purposes of the investigation personnel are different, and the working levels of the investigation personnel are different, so that the investigation results have differences of different degrees and are purely normal. But with too great a difference, there is the potential for intentional depression of manufacturing costs or overestimation.

The prior application number is CN201911160731.1 and the name is a dynamic management method for the construction cost of the whole engineering settlement process, which compares the actual investment and the planned investment conditions of each process of engineering projects, and allows approval personnel to know deviation data and deviation reasons in the actual investment and the planned investment conditions in time when the deviation occurs, so that the planned investment adjustment is conveniently carried out later when the demand exists, and the approval personnel can enter the next process after the approval is finished.

With respect to the related art in the above, the inventors consider that there are the following drawbacks: when the current working procedure of the engineering project is finished and the actual investment and the planning investment are inconsistent, analysis and corresponding approval of related reasons are carried out, so that management personnel have hysteresis on controlling the whole engineering cost.

Disclosure of Invention

In order to enable a manager to know the expected cost of the next process in advance, thereby being beneficial to the management of the overall engineering cost, the application provides a dynamic management method, a dynamic management system and a storage medium for the whole engineering cost of engineering settlement.

In a first aspect, the present application provides a dynamic management method for the cost of the whole process of engineering settlement, which adopts the following technical scheme:

a dynamic management method for the construction cost of the whole process of engineering settlement comprises the following steps:

acquiring building materials and the weight of the building materials required to be applied in each working procedure, and the number of the working types required to be matched with the corresponding working types required to be finished in the corresponding working procedures;

predicting the cost of building materials applied to the next working procedure based on the building material cost of the working procedure completed by the current engineering, and predicting the building material cost required by the next working procedure of the engineering, and synchronously, predicting the personnel cost required by the next working procedure of the engineering based on the personnel cost expense of technicians of the working class matched with the working procedure completed by the current engineering;

adding the sum of the building material cost required by the next working procedure of the project and the personnel cost required by the next working procedure of the project, and adding the sum of the building material cost and the personnel cost of the next working procedure of the project, and taking the obtained difference as the predicted expense deviation;

confirming whether approval is needed or not and personnel corresponding to the approval based on the predicted expense deviation, and if so, sending information to terminal equipment of the approval personnel to remind the approval personnel of approval;

and acquiring information without approval or approval completion information, and starting the next procedure.

Through adopting above-mentioned technical scheme, can effectively analyze and predict building materials cost and personnel's the expense condition of next process to when building materials cost and personnel's expense condition surpassed the planning, in time inform the approval personnel and examine and approve, compare just examine and approve the mode with the cost report after current completion, accomplish the advance of examination and approval, avoided because examine and approve the influence to the process delay, and let staff's cost have better understanding and management and control.

Optionally, the prediction steps of building material cost required for the next process of engineering are as follows:

taking building materials required by the next working procedure of the engineering one by one as query objects from a first preset database storing the working procedures of the engineering completed and the actual unit weight prices of different building materials of the corresponding working procedures, and querying and acquiring the unit weight price of each building material required by the next working procedure in the completed working procedure;

if building materials required by the next working procedure of the engineering are all obtained by inquiring the first database, the unit weight price of each building material required by the next working procedure of the engineering is calculated one by one based on the average value of the unit weight prices of the working procedures completed by the building materials and the unit weight price construction weight formula applied last time by the corresponding building materials, and the weight formula is as follows: z is Z _i =(A ₁ +....A _i +....A _n )/n*q ₁ +A _n *q ₂ N represents the total number of working procedures of applying corresponding building materials, A _i Representing the price per unit weight of the corresponding building material at the ith application step of the corresponding building material, A _n Represents the price per unit weight of the corresponding building material in the nth process of applying the corresponding building material, and the nth process also refers to the last time the corresponding building material is applied, q ₁ Weight ratio, q, of average value of price per unit weight of completed process of building material ₂ The weight ratio of the price per unit weight applied to the corresponding building material at the last time is Z, which is the price per unit weight of the corresponding building material;

acquiring the unit weight price of the building material required to be applied in the next process, multiplying the unit weight price by the weight of the same building material required to be applied in the next process, acquiring the total cost of the building materials required to be applied in the next process one by one, and adding the total cost of each building material required to be applied in the next process to be used as the building material cost required in the next process of engineering;

if the building materials required by the next working procedure of the engineering are not obtained by inquiring the first database, determining the building materials which are not obtained by inquiring, and taking the product of the unit weight price of the building materials which are not obtained by inquiring and the weight of the corresponding building materials which are not obtained by inquiring in the local area as the cost of the building materials which are not obtained by inquiring in the next working procedure;

and taking the sum of the building material cost which is not inquired and obtained in the next process and the building material cost which is inquired and obtained in the next process as the building material cost required in the next process of engineering.

By adopting the technical scheme, the unit weight price of each building material required by the next working procedure of the engineering can be effectively analyzed based on the average value of the unit weight prices of the working procedures completed by the building materials and the unit weight price applied last time by the corresponding building materials, so that the building material cost required by the next working procedure of the engineering can be more accurately predicted.

Optionally, the prediction of the personnel cost for the next process of the project is as follows:

the method comprises the steps of obtaining the actual wages of wages required by next working procedures in unit time of the finished working procedures by taking wages required by the next working procedures of engineering as query objects from a second preset database storing the finished working procedures of the engineering and the actual wages of different wages of the wages of different wages required by the corresponding working procedures;

screening out the unit time wages given by technicians of the work types required by the next working procedure of the last selected working procedure, multiplying the time consumption of the work types corresponding to the next working procedure by the product of the number of the technicians of the corresponding work types required by the next working procedure, and taking the finally obtained product as the cost expense of the technicians of the corresponding work types required by the next working procedure of the engineering;

the sum of the cost of all technicians required for the next process is taken as the cost of personnel required for the next process of engineering.

By adopting the technical scheme, the technical personnel applying the same work types in the next working procedure can be directly referred by acquiring the unit time wages given by the technical personnel selecting the work types needed in the next working procedure of the engineering last time, so that the personnel cost expense needed in the next working procedure of the engineering is predicted better.

Optionally, the steps for confirming whether approval is required and the personnel for the corresponding approval based on the predicted expense deviation are as follows:

acquiring a cost deviation range in which the predicted cost deviation falls and a corresponding cost deviation range corresponding to the contact manner of the approver from a third database which is preset and stores the cost deviation range and the contact manner of the approver corresponding to the corresponding cost deviation range by taking the predicted cost deviation as a query object;

if the predicted expense deviation is not in the corresponding expense deviation range obtained by inquiring in the third database, judging that approval is not needed; otherwise, the approval is determined and the approval personnel are synchronously determined.

By adopting the technical scheme, the predicted expense deviation condition can be corresponding to different approvers, and compared with the method that all approves are piled on one person, the approvers can have more definite cognition on own approval tasks, and the possibility of approval errors is avoided.

Optionally, if approval is required, the step of sending information to the terminal device of the approver to remind the approver of approval is as follows:

transmitting approval information to the terminal equipment of the confirmed approval personnel;

if the approver does not confirm in the preset time, acquiring the position of the terminal equipment of the approver, selecting the approver closest to the confirmed approver as a generation reminding person based on the position of the terminal equipment of the approver and the terminal positions of the rest approvers, and sending the generation reminding information and the path information from the generation reminding person to the confirmed approver to the terminal equipment of the generation reminding person.

By adopting the technical scheme, when the approver cannot contact, the latest generation reminding personnel can be timely found to remind the approver on site, so that smooth approval is ensured.

Optionally, if the approval is required, the step of sending the information to the terminal device of the approver to remind the approver of the approval further comprises the step of synchronously performing the step of synchronously dialing the approval personnel through voice with the step of sending the approval information to the confirmed approver.

By adopting the technical scheme, the voice prompt mode is added to further ensure the prompt of the approver, so that the approver is prevented from negligence of approval due to other things.

In a second aspect, the application provides a dynamic management system for the construction cost of the whole process of engineering settlement, which adopts the following technical scheme:

an engineering settlement whole process cost dynamic management system comprises a memory, a processor and a program stored on the memory and capable of running on the processor, wherein the program can realize the engineering settlement whole process cost dynamic management method according to the first aspect when being loaded and executed by the processor.

Through adopting above-mentioned technical scheme, through the calling of procedure, can effectively analyze and predict building materials cost and personnel's the expense condition of next process to when building materials cost and personnel's expense condition surpassed the planning, in time inform the approval personnel to examine and approve, just examine and approve the mode to the cost report after current completion, accomplish the advance of examination and approval, avoided because examine and approve the influence to the process delay, and let staff's cost has better understanding and management and control.

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

a computer storage medium comprising a program capable of realizing the dynamic management method of the construction cost of the whole process of engineering settlement according to the first aspect when loaded and executed by a processor.

Through adopting above-mentioned technical scheme, through the calling of procedure, can effectively analyze and predict building materials cost and personnel's the expense condition of next process to when building materials cost and personnel's expense condition surpassed the planning, in time inform the approval personnel to examine and approve, just examine and approve the mode to the cost report after current completion, accomplish the advance of examination and approval, avoided because examine and approve the influence to the process delay, and let staff's cost has better understanding and management and control.

In summary, the beneficial technical effects of the application are as follows:

1. whether the expenditure of the next procedure exceeds the planning can be prejudged in advance, and approval is carried out in advance, so that workers can more comprehensively know the construction cost;

2. when the approval personnel are required to approve and the corresponding approval personnel are not notified, the nearby approval personnel can be found to work on site.

Drawings

FIG. 1 is a schematic diagram of the overall steps of a dynamic management method for the construction cost of the whole process of engineering settlement according to the embodiment of the application.

Fig. 2 is a schematic diagram of a prediction step of building material costs required for the next process of the project mentioned in step S200 in fig. 1.

Fig. 3 is a schematic diagram of the acquisition step of the personnel cost expense required for the next process of the project mentioned in step S200 in fig. 1.

Fig. 4 is a schematic diagram of the step of confirming whether approval is required and the personnel corresponding to the approval based on the case of the predicted expense deviation mentioned in step S400 in fig. 1.

Fig. 5 is a schematic diagram of the step of sending information to the terminal device of the approver to remind the approver of approval if approval is required, which is mentioned in step S400 in fig. 1.

Detailed Description

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

Referring to fig. 1, a dynamic management method for the whole construction cost of engineering settlement disclosed by the application comprises steps S100 to S500.

In step S100, the building material and the weight of the building material required to be applied to complete each process and the number of workers required to be matched with the job type and the corresponding job type required to complete the corresponding process are obtained.

The building materials, the weight of the building materials, the work types and the number of technicians required to be matched for the corresponding work types in the step S100 are all obtained by retrieving the related databases.

In step S200, the cost of the building material to be used in the next process is predicted based on the cost of the building material in the process completed in the current project, and the cost of the building material required in the next process is predicted based on the cost of the technician in the process matched with the process completed in the current project.

Referring to fig. 2, the prediction steps of the building material cost required for the next process of the project mentioned in step S200 may be divided into steps Sa10, saA0, saB0, saa0 and Sab0, wherein step SaA0 and Saa0 are parallel steps.

In step Sa10, building materials required for the next process are searched one by one as a search object from a first database preset and storing the completed process of the project and actual price per unit weight of building materials different from the corresponding process, and the price per unit weight of each building material required for the next process is searched and acquired.

In step SaA, if all the building materials required for the next process are obtained by querying the first database, the unit weight price of each building material required for the next process is calculated one by one based on the average value of the unit weight prices of the completed process and the unit weight price construction weight formula applied last time for the corresponding building material, and the weight formula is as follows: z= (a ₁ +....A _i +....A _n )/n*q ₁ +A _n *q ₂ N represents the total number of working procedures of applying corresponding building materials, A _i Representing the price per unit weight of the corresponding building material at the ith application step of the corresponding building material, A _n Represents the price per unit weight of the corresponding building material in the nth process of applying the corresponding building material, and the nth process also refers to the last time the corresponding building material is applied, q ₁ Average value of price per unit weight of completed process for building materialWeight duty ratio, q ₂ The weight ratio of the price per unit weight applied last time for the corresponding building material; z is the price per unit weight of the corresponding building material.

In step SaB, the unit weight price of the building material required to be applied in the next step is obtained, the unit weight price is multiplied by the weight of the same building material required to be applied in the next step, the total cost of the building materials required to be applied in the next step is obtained one by one, and the sum of the total cost of each building material required to be applied in the next step is added as the building material cost required in the next step of the engineering.

For example, the building material required for the next process of engineering is a, and he has been applied in the previous three processes, and the prices of the building material a are a, b and c in sequence from long to short in time, assuming that q1 is 0.5 and q2 is 0.5, the price of the building material a is (q+b+c)/3×0.5+c×0.5.

In step Saa0, if the building material required by the next process of the project is not obtained by querying the first database, determining the building material which is not obtained by querying, and taking the product of the unit weight price of the building material which is not obtained by querying and the weight of the corresponding building material which is not obtained by querying in the local area as the cost of the building material which is not obtained by querying in the next process.

In step Sab0, the sum of the costs of all building materials acquired without querying the first database in the next process and the costs of all building materials acquired with querying the first database in the next process is used as the building material cost required for the next process of the project.

Referring to fig. 3, wherein the prediction step of the personnel cost for the next process of the project mentioned in step S200 may be divided into steps Sb10 to Sb30.

In step Sb10, from a second database storing the actual unit time wages of the engineering completed process and the different kinds of technicians in the corresponding process, the wages of the engineering required by the next process in the unit time wages of the engineering required by the next process are obtained by taking the wages of the engineering required by the next process as query objects.

In step Sb20, the unit time wages given by the technicians who need the job in the next process of the last selected project are screened out, and multiplied by the product of the time consumption of the job corresponding to the next process and the number of the technicians corresponding to the job in the next process, and the finally obtained product is used as the cost expense of the technicians corresponding to the job in the next process of the project.

In step Sb30, the sum of the costs of all technicians required for the next process is taken as the cost of personnel required for the next process.

For example, when a technician of a certain job is applied last time, the job is t yuan of one day, the number of applications required by the job in the next process is 10, the time required by the technician of the job in the next process is 10 days, and the cost of the corresponding process in the next process is 100t.

In step S300, the sum of the building material cost required for the next process of the project and the personnel cost required for the next process of the project is predicted, and the sum of the building material cost and the personnel cost of the next process of the project is summed and differed, and the obtained difference is used as the predicted expense deviation.

In step S400, whether approval is required and personnel corresponding to the approval are confirmed based on the predicted expense deviation, and if approval is required, information is sent to the terminal device of the approval personnel to remind the approval personnel of approval.

Referring to fig. 4, the step of confirming whether approval is required and the person who is to be approved accordingly based on the case of the predicted expense deviation as mentioned in step S400 may be divided into steps S4a0 to S4b0.

In step S4a0, from a third database storing the preset expense deviation ranges and the contact information of the approver corresponding to the corresponding expense deviation ranges, the predicted expense deviation is used as the query object, and the expense deviation range in which the predicted expense deviation falls and the contact information of the approver corresponding to the corresponding expense deviation range are obtained.

In step S4b0, if the predicted expense deviation is not found in the third database to obtain the corresponding expense deviation range, determining that approval is not required; otherwise, the approval is determined and the approval personnel are synchronously determined.

For example, the cost bias range stored in the third database is as follows: [10, 50] ten thousand yuan, (50, 100] ten thousand yuan, if the cost deviation is lower than 10 ten thousand yuan, the approval is not needed.

Referring to fig. 5, if approval is required, the steps of sending information to the terminal device of the approver to remind the approver of approval in step S400 can be divided into steps S4A0 to S4B0.

In step S4A0, approval information is sent to the terminal device of the confirmed approval person.

The step of reminding the approver of the approval at the terminal equipment for sending the information to the approver further comprises reminding the approver by voice in synchronization with the step of sending the approval information to the confirmed approver.

The terminal device mentioned in step S4A0 includes, but is not limited to, a mobile phone and a computer of an approver.

In step S4B0, if the approver does not confirm within the preset time, the position of the terminal device of the approver is obtained, and based on the position of the terminal device of the approver and the positions of the terminals of the rest approvers, the approver closest to the confirmed approver is selected as the generation reminding person, and the generation reminding information and the path information from the generation reminding person to the confirmed approver are sent to the terminal device of the generation reminding person.

The step S4B0 mentioned in the step of obtaining the location of the terminal device of the approver and the location of the terminal of the residual approver may be implemented by a tracker disposed on the terminal device of the corresponding approver, and if the approver uses a mobile phone, the implementation may be tracked by a mobile phone tracker.

The selecting of the nearest approver to the identified approver in step S4B0 is mainly implemented by a trip planner, and the corresponding path is planned by the trip planner with the identified approver as the end point and the positions of the rest approvers as the start points.

In step S500, a message without approval or approval completion information is acquired, and the next process is started.

Embodiments of the present application also provide a computer readable storage medium comprising a program capable of implementing a method as any of fig. 1-5 when loaded and executed by a processor.

The computer-readable storage medium includes, for example: a U-disk, a removable hard disk, a Read-only memory (ROM), a random access memory (RandomAccessMemory, RAM), a magnetic disk, an optical disk, or other various media capable of storing program codes.

Based on the same inventive concept, the embodiment of the application also provides a dynamic management system for the whole process cost of engineering settlement, which comprises a memory and a processor, wherein the memory stores a program capable of running on the processor to realize any one of the methods shown in fig. 1 to 5.

It will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-described division of the functional modules is illustrated, and in practical application, the above-described functional allocation may be performed by different functional modules according to needs, i.e. the internal structure of the apparatus is divided into different functional modules to perform all or part of the functions described above. The specific working processes of the above-described systems, devices and units may refer to the corresponding processes in the foregoing method embodiments, which are not described herein.

In the several embodiments provided in the present application, it should be understood that the disclosed systems, devices, and methods may be implemented in other manners. For example, the apparatus embodiments described above are merely illustrative, e.g., the division of modules or units is merely a logical functional division, and there may be additional divisions when actually implemented, e.g., multiple units or components may be combined or integrated into another system, or some features may be omitted or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be an indirect coupling or communication connection via some interfaces, devices or units, which may be in electrical, mechanical or other form.

The units described as separate units may or may not be physically separate, and units shown as units may or may not be physical units, may be located in one place, or may be distributed over a plurality of network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in the embodiments of the present application may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit. The integrated units may be implemented in hardware or in software functional units.

The integrated units, if implemented in the form of software functional units and sold or used as stand-alone products, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present application may be embodied in essence or a part contributing to the prior art or all or part of the technical solution in the form of a software product stored in a storage medium, including several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) or a processor (processor) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: various media capable of storing program codes, such as a U disk, a mobile hard disk, a read-only memory, a random access memory, a magnetic disk or an optical disk.

The embodiments of the present application are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in this way, therefore: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (6)

1. The dynamic management method for the construction cost of the whole engineering settlement process is characterized by comprising the following steps:

acquiring building materials and the weight of the building materials required to be applied in each working procedure, and the number of the working types required to be matched with the corresponding working types required to be finished in the corresponding working procedures;

predicting the cost of building materials applied to the next working procedure based on the building material cost of the working procedure completed by the current engineering, and predicting the building material cost required by the next working procedure of the engineering, and synchronously, predicting the personnel cost required by the next working procedure of the engineering based on the personnel cost expense of technicians of the working class matched with the working procedure completed by the current engineering;

adding the sum of the building material cost required by the next working procedure of the project and the personnel cost required by the next working procedure of the project, and adding the sum of the building material cost and the personnel cost of the next working procedure of the project, and taking the obtained difference as the predicted expense deviation;

confirming whether approval is needed or not and personnel corresponding to the approval based on the predicted expense deviation, and if so, sending information to terminal equipment of the approval personnel to remind the approval personnel of approval;

acquiring information without approval or approval completion information, and starting the next procedure;

the prediction steps of building material cost required for the next engineering procedure are as follows:

taking building materials required by the next working procedure of the engineering one by one as query objects from a first preset database storing the working procedures of the engineering completed and the actual unit weight prices of different building materials of the corresponding working procedures, and querying and acquiring the unit weight price of each building material required by the next working procedure in the completed working procedure;

if building materials required by the next working procedure of the engineering are all obtained by inquiring the first database, the unit weight price of each building material required by the next working procedure of the engineering is calculated one by one based on the average value of the unit weight prices of the working procedures completed by the building materials and the unit weight price construction weight formula applied last time by the corresponding building materials, and the weight formula is as follows: z is Z _i =(A ₁ +....A _i +....A _n )/n*q ₁ +A _n *q ₂ N represents the total number of working procedures of applying corresponding building materials, A _i Representing the price per unit weight of the corresponding building material at the ith application step of the corresponding building material, A _n Representing the price per unit weight of the corresponding building material at the nth time of the process of applying the corresponding building material, the nth time also refers to the last time the corresponding building material was appliedSecondary, q ₁ Weight ratio, q, of average value of price per unit weight of completed process of building material ₂ The weight ratio of the price per unit weight applied to the corresponding building material at the last time is Z, which is the price per unit weight of the corresponding building material;

acquiring the unit weight price of the building material required to be applied in the next process, multiplying the unit weight price by the weight of the same building material required to be applied in the next process, acquiring the total cost of the building materials required to be applied in the next process one by one, and adding the total cost of each building material required to be applied in the next process to be used as the building material cost required in the next process of engineering;

if the building materials required by the next working procedure of the engineering are not obtained by inquiring the first database, determining the building materials which are not obtained by inquiring, and taking the product of the unit weight price of the building materials which are not obtained by inquiring and the weight of the corresponding building materials which are not obtained by inquiring in the local area as the cost of the building materials which are not obtained by inquiring in the next working procedure;

taking the sum of the cost of all building materials which are not obtained by inquiring the first database in the next process and the cost of all building materials which are obtained by inquiring the first database in the next process as the building material cost required by the next process of engineering;

the prediction of the personnel cost expense required for the next process of the project is as follows:

the method comprises the steps of obtaining the actual wages of wages required by next working procedures in unit time of the finished working procedures by taking wages required by the next working procedures of engineering as query objects from a second preset database storing the finished working procedures of the engineering and the actual wages of different wages of the wages of different wages required by the corresponding working procedures;

screening out the unit time wages given by technicians of the work types required by the next working procedure of the last selected working procedure, multiplying the time consumption of the work types corresponding to the next working procedure by the product of the number of the technicians of the corresponding work types required by the next working procedure, and taking the finally obtained product as the cost expense of the technicians of the corresponding work types required by the next working procedure of the engineering;

the sum of the cost of all technicians required for the next process is taken as the cost of personnel required for the next process of engineering.

2. The dynamic management method for the construction cost of the whole process of engineering settlement according to claim 1, wherein the method comprises the following steps: the steps for confirming whether approval is needed or not and the personnel for corresponding approval are as follows based on the predicted conditions of the expense deviation:

acquiring a cost deviation range in which the predicted cost deviation falls and a corresponding cost deviation range corresponding to the contact manner of the approver from a third database which is preset and stores the cost deviation range and the contact manner of the approver corresponding to the corresponding cost deviation range by taking the predicted cost deviation as a query object;

if the predicted expense deviation is not in the corresponding expense deviation range obtained by inquiring in the third database, judging that approval is not needed; otherwise, the approval is determined and the approval personnel are synchronously determined.

3. The dynamic management method for the construction cost of the whole process of engineering settlement according to claim 1, wherein the method comprises the following steps: if the approval is needed, sending information to terminal equipment of an approver to remind the approver of the approval, wherein the steps are as follows:

transmitting approval information to the terminal equipment of the confirmed approval personnel;

if the approver does not confirm in the preset time, acquiring the position of the terminal equipment of the approver, selecting the approver closest to the confirmed approver as a generation reminding person based on the position of the terminal equipment of the approver and the terminal positions of the rest approvers, and sending the generation reminding information and the path information from the generation reminding person to the confirmed approver to the terminal equipment of the generation reminding person.

4. The dynamic management method of construction costs for an overall process of engineering settlement as claimed in claim 3, wherein the step of sending the information to the terminal device of the approver to remind the approver of approval if approval is required further comprises the step of synchronously sending the approval information to the confirmed approver, wherein the step of synchronously reminding the approver by voice dialing.

5. An engineering settlement whole process cost dynamic management system, comprising a memory, a processor and a program stored on the memory and capable of running on the processor, wherein the program can be loaded and executed by the processor to realize the engineering settlement whole process cost dynamic management method as claimed in any one of claims 1 to 4.

6. A computer storage medium, characterized by: a program comprising a program capable of realizing the dynamic management method of the construction cost of the whole process of construction settlement according to any one of claims 1 to 4 when loaded and executed by a processor.