CN112488570A

CN112488570A - Method, device, electronic equipment and storage medium for determining special scheme of elevator

Info

Publication number: CN112488570A
Application number: CN202011472534.6A
Authority: CN
Inventors: 钟立; 曾桂涛; 黄文杰; 侯应浩
Original assignee: Guangzhou Guangri Elevator Industry Co Ltd
Current assignee: Guangzhou Guangri Elevator Industry Co Ltd
Priority date: 2020-12-15
Filing date: 2020-12-15
Publication date: 2021-03-12
Anticipated expiration: 2040-12-15
Also published as: CN112488570B

Abstract

The invention provides a method, a device, electronic equipment and a storage medium for determining a special scheme of an elevator, wherein the method comprises the steps of receiving a plurality of special demand points input by a user; acquiring a plurality of parameter names and a plurality of component names associated with special demand points; receiving the input parameter value of each parameter name; acquiring corresponding information corresponding to each special demand point according to a special corresponding rule, and marking the special demand points of which the corresponding information is incapable of being responded as first special demand points; obtaining a plurality of final coping schemes according to the integration rule, and obtaining a total special price according to the plurality of final coping schemes; and displaying and outputting the plurality of final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to a user. The method can shorten the confirmation time of the special demand point scheme, improve the response efficiency and reduce the economic loss caused by field engineering delay.

Description

Method, device, electronic equipment and storage medium for determining special scheme of elevator

Technical Field

The invention belongs to the technical field of elevators, and particularly relates to a method and a device for determining a special scheme of an elevator, electronic equipment and a storage medium.

Background

In the elevator industry, each company is configured by a set of size, has functional characteristics, is matched with corresponding price, and is used as the standard configuration of the company, so that the front-end response efficiency is improved. If a client has special requirements on elevator functions, the current practice is to summarize the special requirements of the client by field services and improve the technical confirmation of a company, the company technology improves the configuration of a response scheme aiming at the summarized special requirements, converts financial summary cost quotation into financial summary cost quotation, and then communicates with the client by the field services, so that the scheme adjustment confirmation mode of the special requirements excessively depends on manual operation, and relates to confirmation processing of engineering, technology, production, finance and the like and a plurality of supporting departments, and all the departments are independent from each other and do not form a finished system and coherent information flow, so that the scheme confirmation period of the characteristic requirements of the client is too long, the actual requirements of the client cannot be met, and even the field engineering delay is caused to cause economic loss.

Disclosure of Invention

The invention aims to provide a method, a device, electronic equipment and a storage medium for determining a special scheme of an elevator, which can shorten the confirmation time of the scheme of a special demand point, improve the response efficiency and reduce the economic loss caused by field engineering delay.

The invention is realized by the following technical scheme:

a method of determining a special profile for an elevator, comprising the steps of:

s1, receiving a plurality of special demand points input by a user;

s2, for each special demand point, acquiring a plurality of parameter names and a plurality of component names associated with the special demand point from a preset scheme database, marking the acquired parameter names as first parameter names, wherein the scheme database at least comprises a plurality of special demand points, a plurality of parameter names and a plurality of component names, and each special demand point is associated with a plurality of parameter names and a plurality of component names;

s3, displaying and outputting the first parameter names to a user, receiving the input parameter value of each first parameter name, combining the first parameter name and the parameter value corresponding to the first parameter name into parameter information, and obtaining a plurality of parameter information of each special demand point;

s4, for each special demand point, processing a plurality of part names and a plurality of parameter information corresponding to the special demand point according to a special corresponding rule to obtain corresponding information corresponding to each special demand point, marking the special demand point of which the corresponding information is incapable of being responded as a first special demand point, wherein the corresponding information comprises a plurality of corresponding schemes or cannot be responded, and the corresponding schemes comprise the part names and the part parameters corresponding to the part names;

s5, integrating all the coping schemes according to the integration rule to obtain a plurality of final coping schemes, obtaining the added price of each final coping scheme in a preset price database, summarizing the obtained added prices to obtain a total special price, wherein the price database at least comprises the added prices of different final coping schemes;

and S6, displaying and outputting the plurality of final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to a user.

Further, an association relationship between parameter names is pre-established, the association relationship between the parameter names is a relationship or no relationship, for each parameter name, the parameter name is associated with a component name correspondingly, the component parameter comprises at least one of a model parameter or a specification size, the specification size at least comprises one size parameter, the size parameter is associated with a parameter name, the scheme database further comprises a plurality of model data corresponding to each component name and a parameter range of a plurality of parameter names corresponding to each model data;

the step of processing the information of the plurality of parts and the information of the plurality of parameters corresponding to the special demand points according to the special handling rules to obtain the handling information corresponding to each special demand point comprises the following steps:

in the parameter information corresponding to the special demand points, judging whether the parameter value of each first parameter name is a default value or not for each first parameter name;

if so, recording the first parameter name as a second parameter name, and if not, recording the first parameter name as a third parameter name;

selecting a fourth parameter name in sequence from the plurality of third parameter names, recording the third parameter name which is related to the association relationship of the fourth parameter name as a fifth parameter name, processing the fourth parameter name and the parameter value thereof according to a preset range rule to obtain a parameter range of the fifth parameter name, and judging whether the parameter value of the fifth parameter name is in the corresponding parameter range, wherein the range rule comprises setting the parameter range of the parameter name associated with the target parameter according to the parameter value of the target parameter name;

if not, setting the corresponding information as the information which cannot be responded to, and obtaining the corresponding information corresponding to the special demand point;

if yes, judging whether a third parameter name with a relationship relation with the second parameter name exists in the plurality of third parameter names or not for each second parameter name, and if yes, modifying the parameter value of the second parameter name into a parameter range of the second parameter name according to the parameter value of the third parameter name with the relationship relation with the second parameter name;

for each part name associated with a special demand point, executing step a and/or executing step b;

the step a is specifically as follows: obtaining the conforming model data in the scheme database according to the first parameter name associated with the part name and the parameter value corresponding to the first parameter name, and modifying the model parameter in the coping information into the obtained model data;

the step b is specifically as follows: and setting the size parameter in the corresponding information as the associated parameter name and the parameter value of the associated parameter name.

Further, the step of integrating all the coping schemes according to the integration rule to obtain a plurality of final coping schemes comprises:

dividing the coping schemes with the same component name into coping scheme groups to obtain a plurality of coping scheme groups;

for a plurality of corresponding schemes in the same corresponding scheme group, dividing the size parameters containing the same parameter name into a size parameter group to obtain a plurality of size parameter groups;

and for a plurality of size parameters of the same size parameter group, carrying out collection and intersection operation on parameter values contained in the plurality of size parameters to obtain a final size parameter, and replacing the corresponding plurality of size parameters with the obtained final size parameter to obtain a plurality of final coping schemes.

Further, the component names are associated with type information, the type information includes a model type, a size type and a common type, and the step of executing step a and/or the step b includes, for each component name associated with a special demand point:

for each part name associated with the special demand point, acquiring type information associated with the part name and judging;

if the type information associated with the part name is the model type, executing the step a;

if the type information associated with the part name is the size type, executing the step b;

and if the type information associated with the part name is a common type, executing the step a and the step b.

Further, after the step of displaying and outputting the plurality of final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to the user, the method further comprises:

for each first special demand point, displaying and outputting a fourth parameter name and a fifth parameter name of the first special demand point to a user;

detecting whether a signal that a user modifies a parameter value corresponding to the fourth parameter name is received or not, and/or detecting whether a signal that a user modifies a parameter value corresponding to the fifth parameter name is received or not;

if yes, replacing the old parameter value corresponding to the fourth parameter name with the new parameter value of the fourth parameter name input by the user, and/or replacing the old parameter value corresponding to the fifth parameter name with the new parameter value of the fifth parameter name input by the user, and repeating the steps S4 to S6.

The invention also provides a device for determining the special scheme of the elevator, which comprises:

the receiving module is used for receiving a plurality of special demand points input by a user;

the system comprises an acquisition module, a data processing module and a processing module, wherein the acquisition module is used for acquiring a plurality of parameter names and a plurality of component names which are associated with special demand points in a preset scheme database for each special demand point, the acquired parameter names are marked as first parameter names, the scheme database at least comprises a plurality of special demand points, a plurality of parameter names and a plurality of component names, and each special demand point is associated with a plurality of parameter names and a plurality of component names;

the first display module is used for displaying and outputting a plurality of first parameter names to a user, receiving an input parameter value of each first parameter name, combining the first parameter name and the parameter value corresponding to the first parameter name into parameter information, and obtaining a plurality of parameter information of each special demand point;

the processing module is used for processing a plurality of part names and a plurality of parameter information corresponding to each special demand point according to a special corresponding rule to obtain corresponding information corresponding to each special demand point, and marking the special demand points which cannot be responded by the corresponding information as first special demand points, wherein the corresponding information comprises a plurality of corresponding schemes or cannot be responded, and the corresponding schemes comprise the part names and the part parameters corresponding to the part names;

the integration module is used for integrating all the coping schemes according to the integration rule to obtain a plurality of final coping schemes, obtaining the added price of each final coping scheme in a preset price database, summarizing the obtained added prices to obtain a total special price, and the price database at least comprises the added prices of different final coping schemes;

and the output module is used for displaying and outputting the plurality of final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to a user.

The invention also discloses an electronic device, which comprises a memory and a processor, wherein the memory stores a computer program, and the processor realizes the steps of any one of the methods when executing the computer program.

The invention also discloses a computer-readable storage medium, on which a computer program is stored, which computer program, when being executed by a processor, realizes the steps of the method of any of the above.

Compared with the prior art, the invention has the beneficial effects that: the method comprises the steps of receiving a plurality of special demand points input by a user, receiving parameter values input by the user after determining parameters required to be provided by the user according to the special demand points, obtaining a coping scheme of each special demand point according to a preset special coping rule, integrating all coping schemes according to an integration rule to obtain a final coping scheme, summarizing the added price of each final coping scheme in a price database to obtain a total special price, and finally outputting the coping scheme and the total special price to the user for confirmation, wherein the whole process does not need human intervention, reduces subsequent information circulation of each department, realizes full-automatic coping of the special demand points of the user, improves coping efficiency, is beneficial to quickly determining modification cost change, obtains quote for contract modification, promotes determination of field special schemes, accelerates completion of contract modification, and shortens time for contract modification, and economic loss caused by field engineering delay is reduced.

Drawings

Fig. 1 is a flow chart of the steps of the method of determining elevator special plans according to the invention;

fig. 2 is a block diagram of an arrangement for determining the special case of an elevator according to the invention;

FIG. 3 is a block diagram illustrating the structure of an embodiment of the electronic device of the present invention;

FIG. 4 is a block diagram illustrating a structure of an embodiment of a computer-readable storage medium according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures. Meanwhile, in the description of the present invention, the terms "first", "second", and the like are used only for distinguishing the description, and are not to be construed as indicating or implying relative importance.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inside", "outside", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships conventionally put in use of products of the present invention, and are only for convenience of description and simplification of description, but do not indicate or imply that the devices or elements referred to must have specific orientations, be constructed in specific orientations, and be operated, and thus, should not be construed as limiting the present invention.

Referring to fig. 1, fig. 1 is a flow chart illustrating the steps of a method for determining a special plan of an elevator according to the present invention. A method of determining a special profile for an elevator, comprising the steps of:

s1, receiving a plurality of special demand points input by a user;

In the step S1, a plurality of special demand points are pre-entered, and when the user inputs a special demand point, the user directly selects the corresponding special demand point. The special demand points can be functions related to special functions, such as face recognition, two-dimensional code elevator riding and the like, or parts related to special functions, such as control surfaces, buttons or guide rails and the like.

In the above step S2, a plurality of special demand points, a plurality of parameter names, and a plurality of component names are previously entered in the plan database, and each special demand point is associated with a plurality of parameter names and a plurality of component names, the parameter names associated with the special demand points are parameter names that need to be known in response to the special demand, and the component names associated with the special demand points are components that need to be replaced with respect to the standard elevator configuration. After the parameter names are acquired from the scheme database, the acquired parameter names are marked as first parameter names, so that the parameter names can be conveniently and subsequently output to a user to fill in the parameter values.

In step S3, the first parameter names are deleted and then displayed and output to the user, so that the user may provide corresponding parameter values according to the output first parameter names, and if the user does not input the first parameter names of the parameter values, the first parameter names are input according to default parameter values, where the default parameter values are parameter ranges.

In the above step S4, the part names and the parameter information corresponding to each special demand point are processed according to the special response rule to obtain the response information corresponding to each special demand point, and the parameter information corresponding to the special demand points is obtained according to the parameter values input by the user, so that some special demand points may not be able to be specially responded, so if the special demand points may be able to be non-standard responded, the obtained response information is a plurality of response schemes, and if the special demand points are unable to be responded, the obtained response information is unable to be responded.

Further, an association relationship between the parameter names is pre-established, the association relationship between the parameter names is a relationship or no relationship, for each parameter name, the parameter name is associated with a component name correspondingly, the component parameter includes at least one of a model parameter or a specification, the specification at least includes one dimension parameter, the dimension parameter is associated with a parameter name, the solution database further includes a plurality of model data corresponding to each component name, and a parameter range of a plurality of parameter names corresponding to each model data;

in elevator design, a parameter value of one parameter name of an elevator may affect a parameter value of another parameter name, for example, the size of a hoistway may affect the size of a car, so that an association relationship between the parameter names is established in advance according to the relationship, if the association relationship between the two parameter names is a relationship, it means that the parameter value of one parameter name may affect the parameter value of another parameter name, and if the association relationship between the two parameter names is a non-relationship, it means that the parameter value of one parameter name may not affect the parameter value of another parameter name.

In step S4, the step of processing the part information and the parameter information corresponding to the special demand point according to a special handling rule to obtain handling information corresponding to each special demand point includes:

s41, judging whether the parameter value of each first parameter name is a default value or not in the parameter information corresponding to the special demand point;

s42, if yes, recording the first parameter name as a second parameter name, and if not, recording the first parameter name as a third parameter name;

s43, sequentially selecting a fourth parameter name from the third parameter names, recording the third parameter name which is related to the fourth parameter name as a fifth parameter name, processing the fourth parameter name and the parameter value thereof according to a preset range rule to obtain a parameter range of the fifth parameter name, and judging whether the parameter value of the fifth parameter name is in the corresponding parameter range, wherein the range rule comprises setting the parameter range of the parameter name related to the target parameter according to the parameter value of the target parameter name;

s44, if not, setting the corresponding information as incapable of corresponding to obtain corresponding information corresponding to the special demand point;

s45, if yes, judging whether the association relationship between the second parameter name and each of the plurality of third parameter names is a related third parameter name, and if yes, modifying the parameter value of the second parameter name into the parameter range of the second parameter name according to the association relationship between the second parameter name and the related third parameter name;

s46, executing step a and/or executing step b for each component name associated with the special demand point;

the step b is specifically as follows: and setting the size parameter in the response information as the associated parameter name and the parameter value of the associated parameter name to obtain the response information corresponding to the special demand point.

In step S41, there may be a plurality of first parameter names associated with the special demand points, but each first parameter name does not require a user to input a parameter value, the user only needs to input a basic parameter, and the user does not input the first parameter name of the parameter value, and inputs a preset default value, where the default value may be a standard parameter range corresponding to the first parameter name, and the default value may be a standard parameter range corresponding to the first parameter name, where the user does not input a corresponding parameter value, that is, the first parameter name may adopt any parameter value within a variable resistance parameter range, and in the corresponding parameter information, for each first parameter name, it is determined whether the parameter value of the first parameter name is the default value in order to find the first parameter name of the parameter value input by the user.

In step S42, the first parameter name with the parameter value as the default value is marked as the second parameter name, and the first parameter name with the parameter value as the parameter value input by the user is marked as the third parameter name, so as to facilitate subsequent determination of whether the parameter value input by the user is valid or not, and whether correspondence is possible or not.

In the step S43, one third parameter name is selected from the plurality of third parameter names as a fourth parameter name, the third parameter name having a relationship with the fourth parameter name in the plurality of third parameter names is marked as a fifth parameter name, the fourth parameter name and the parameter value thereof are processed according to a preset range rule to obtain a parameter range of the fifth parameter name, and then whether the parameter value of the fifth parameter name is within the obtained parameter range of the fifth parameter name is determined, i.e., whether the special demand point can be responded to can be determined. Presetting a range rule comprises setting a parameter range of a parameter name associated with a target parameter according to a parameter value of the target parameter name, for example, the parameter value of the shaft width is a, the parameter range of the car width obtained by the range rule is [900, a-400], and a-400 is less than or equal to 2200; or the parameter value of the car width is b, and the parameter range of the shaft width obtained by the range rule is [ b +400, 3000 ].

In the above step S44, if the parameter value of the fifth parameter name is not within the obtained parameter range of the fifth parameter name, it indicates that the parameter value of the fifth parameter name is beyond the parameter range to be handled, so the special demand point cannot be handled, that is, there is no handling scheme, the handling information corresponding to the special demand point is set as being unable to be handled, and the parameter value of the fourth parameter name or the parameter value of the fifth parameter name needs to be modified.

In the above step S45, if the parameter value of the fifth parameter name is within the parameter range of the obtained fifth parameter name, it indicates that the special demand point can be dealt with, and the second parameter name generally has an association relationship with the third parameter name, so if it is determined that there is a third parameter name in which the association relationship with the second parameter name is a relationship among a plurality of third parameter names, the parameter value of the second parameter name needs to be adjusted according to the parameter value of the third parameter name input by the user, and if it does not exist, the parameter value of the second parameter name is kept as the default parameter value.

In step S46, for each component name associated with the special requirement point, since the component parameter corresponding to the component name may be a model parameter, a size parameter, or both, step a and step b are executed as needed to obtain the component parameter corresponding to the component name, so as to obtain the corresponding handling information corresponding to the special requirement point.

In the step a, the plan database includes a plurality of model data corresponding to each part name and a parameter range of a plurality of parameter names corresponding to each model data, so that the model data meeting the part name correlation first parameter name and the parameter value corresponding to the first parameter name are found in the plan database, and the model parameter in the corresponding information corresponding to the special demand point is modified into the model data.

In the step b, the size parameter is associated with a parameter name, so that the size parameter in the response information corresponding to the special demand point is directly set as the associated parameter name and the parameter value of the associated parameter name.

Further, the component name is associated with type information including a model type, a size type and a common type, and the step of performing step a and/or performing step b in step S46 includes, for each component name associated with a special demand point:

s461, for each part name associated with the special demand point, acquiring type information associated with the part name and judging;

s462, if the type information associated with the component name is the model type, executing the step a;

s463, if the type information associated with the part name is the size type, executing step b;

and S464, if the type information related to the part name is the common type, executing the step a and the step b.

In the above steps S461 to S464, type information is associated in advance for each component name, and if the type information associated with the component name is a model type, it is described that the component parameter corresponding to the component name is a model parameter, so step a is executed to obtain corresponding information as the component name and the model parameter corresponding to the component name, such as a rail, model a. If the type information associated with the component name is a dimension type, it is described that the component parameter corresponding to the component name is a dimension parameter, and therefore, step b is executed to obtain corresponding information, such as a hoistway, width 1000, of the dimension parameter corresponding to the component name and the component name. If the type information associated with the part name is a common type, the part parameters corresponding to the part name are the model parameters and the dimension parameters, and the step a and the step B are executed, so that the obtained corresponding information is the model parameters and the dimension parameters corresponding to the name and the part name, such as a fireproof door, a model B and a door width 500.

In the step S5, the added prices of different final solutions are recorded in the price database in advance, the added prices are the difference between the final solutions and the standard solutions in the standard size configuration, and there may be solutions with mutual intersections in all the solutions, so that all the solutions are processed according to the integration rule to obtain a plurality of final solutions, the added prices of each final solution are obtained in the price database directly according to the final solutions, and the obtained added prices are superposed and summarized to obtain the total special price, that is, the prices of the special demand points which need to be increased relative to the standard size configuration are obtained.

Further, in step S5, the step of integrating all the solutions according to the integration rule to obtain a plurality of final solutions includes:

s51, dividing the corresponding schemes with the same component name into a corresponding scheme group to obtain a plurality of corresponding scheme groups;

s52, for a plurality of corresponding schemes in the same corresponding scheme group, dividing the size parameters containing the same parameter name into a size parameter group to obtain a plurality of size parameter groups;

and S53, performing collective operation on the parameter values contained in the plurality of size parameters to obtain final size parameters for the plurality of size parameters of the same size parameter group, and replacing the corresponding plurality of size parameters with the obtained final size parameters to obtain a plurality of final coping schemes.

In the above-described steps S51 to S53, the solutions having the same component name relate to the same component in all the solutions, so the solutions having the same component name are divided into one solution group, in a plurality of solutions of the same solution group, the dimension parameter with the same parameter name relates to a certain same parameter for designing the same component, therefore, the dimension parameters containing the same parameter name are divided into a dimension parameter group, the parameter values contained in a plurality of dimension parameters are subjected to aggregation and intersection operation to obtain the final dimension parameter, the parameter value of the final dimension parameter conforms to the parameter range of the same parameter name, and according to the parameter names contained in the final size parameters, replacing the corresponding size parameters with the same parameter names by the obtained final size parameters, and deleting the repeated coping schemes to finally obtain a plurality of final coping schemes. For example, the coping plan A comprises widths [700, 3000] corresponding to the shaft and the shaft, the coping plan B comprises widths [600, 2000] corresponding to the shaft and the shaft, parameter values of the shaft and the shaft are collected and processed to obtain the widths [700, 2000], and the final coping plan C comprises the widths [700, 2000] corresponding to the shaft and the shaft.

In step S6, the response information corresponding to the final response schemes, the total special price, the first special demand point, and the first special demand point is displayed and output to the user, so that the user can confirm the response schemes and the total special price. The whole process does not need human intervention, reduces the information circulation of each follow-up department, and realizes the full-automatic response of special demand points of users, thereby improving the response efficiency, being beneficial to quickly determining the change of modification cost, obtaining the quotation of contract modification, promoting the determination of a field special scheme, accelerating the completion of contract modification, shortening the confirmation time of contract modification, and reducing the economic loss caused by field engineering delay.

Further, in step S6, after the step of displaying and outputting the final solutions, the total special price, the first special demand point and the handling information corresponding to the first special demand point to the user, the method further includes:

s7, for each first special demand point, displaying and outputting a fourth parameter name and a fifth parameter name of the first special demand point to a user;

s8, detecting whether a signal that a user modifies a parameter value corresponding to the fourth parameter name is received or not, and/or detecting whether a signal that a user modifies a parameter value corresponding to the fifth parameter name is received or not;

and S9, if yes, replacing the old parameter value corresponding to the fourth parameter name with the new parameter value of the fourth parameter name input by the user, and/or replacing the old parameter value corresponding to the fifth parameter name with the new parameter value of the fifth parameter name input by the user, and repeating the steps S4 to S6.

In the above steps S7 to S9, the first special demand point cannot be handled because the input parameter has a problem, and therefore, the fourth parameter name and the fifth parameter name having a problem are displayed and output to the user, and it is seen whether the user will modify the parameter value of the fourth parameter name and/or the fifth parameter name, if the user modifies the parameter value of the fourth parameter name and/or the fifth parameter name, the old parameter value corresponding to the fourth parameter name is replaced with the new parameter value of the fourth parameter name input by the user, and/or the old parameter value corresponding to the fifth parameter name is replaced with the new parameter value of the fifth parameter name input by the user, and then the steps S4 to S6 are repeated to process the special demand point, and it is seen whether a handling scheme of the special demand point can be obtained.

Referring to fig. 2, fig. 2 is a block diagram of an apparatus for determining a special plan of an elevator according to the present invention. The invention also provides a device for determining the special scheme of the elevator, which comprises:

the receiving module 1 is used for receiving a plurality of special demand points input by a user;

the acquisition module 2 is used for acquiring a plurality of parameter names and a plurality of component names associated with the special demand points in a preset scheme database for each special demand point, marking the acquired parameter names as first parameter names, wherein the scheme database at least comprises a plurality of special demand points, a plurality of parameter names and a plurality of component names, and each special demand point is associated with a plurality of parameter names and a plurality of component names;

the first display module 3 is used for displaying and outputting a plurality of first parameter names to a user, receiving an input parameter value of each first parameter name, combining the first parameter name and the parameter value corresponding to the first parameter name into parameter information, and obtaining a plurality of parameter information of each special demand point;

the processing module 4 is used for processing a plurality of part names and a plurality of parameter information corresponding to each special demand point according to a special corresponding rule to obtain corresponding information corresponding to each special demand point, and marking the special demand point of which the corresponding information is incapable of being responded as a first special demand point, wherein the corresponding information comprises a plurality of corresponding schemes or cannot be responded, and the corresponding schemes comprise the part names and the part parameters corresponding to the part names;

the integration module 5 is used for integrating all the coping schemes according to the integration rule to obtain a plurality of final coping schemes, obtaining the added price of each final coping scheme in a preset price database, summarizing the obtained added prices to obtain a total special price, and the price database at least comprises the added prices of different final coping schemes;

and the output module 6 is used for displaying and outputting the plurality of final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to a user.

A plurality of special demand points are input in advance and displayed on the receiving module 1, and when a user inputs the special demand points, the corresponding special demand points are directly selected on the receiving module 1. The special demand points can be functions related to special functions, such as face recognition, two-dimensional code elevator riding and the like, or parts related to special functions, such as control surfaces, buttons or guide rails and the like.

A plurality of special demand points, a plurality of parameter names and a plurality of component names are pre-recorded in the scheme database, each special demand point is associated with a plurality of parameter names and a plurality of component names, the parameter names associated with the special demand points are parameter names which need to be known for the special demand, and the component names associated with the special demand points are components which need to be replaced relative to the standard elevator configuration. The obtaining module 2 marks the obtained parameter names as first parameter names after obtaining the parameter names in the scheme database, so as to facilitate subsequent output to a user to fill in the parameter values.

The first display module 3 deletes the first parameter name of all the acquired first parameter names, displays the first parameter names and outputs the first parameter names to the user, so that the user can provide corresponding parameter values according to the output first parameter names, if the user does not input the first parameter names of the parameter values, the first parameter names are input according to default parameter values, and the default parameter values are parameter ranges.

The processing module 4 processes the part names and the parameter information corresponding to each special demand point according to the special handling rule to obtain handling information corresponding to each special demand point, and the parameter information corresponding to the special demand points is obtained according to the parameter values input by the user, so that some special demand points can not be specially handled, if the special demand points can be non-standard handled, the obtained handling information is a plurality of handling schemes, and if the special demand points can not be handled, the obtained handling information is unable to be handled.

The processing module 4 includes:

the first judgment submodule is used for judging whether the parameter value of each first parameter name is a default value or not in the plurality of parameter information corresponding to the special demand points;

the marking sub-module is used for marking the first parameter name as a second parameter name if the judgment result of the judging sub-module is yes, and marking the first parameter name as a third parameter name if the judgment result of the judging sub-module is no;

the second judgment submodule is used for sequentially selecting a fourth parameter name from the plurality of third parameter names, recording the third parameter name which has a relationship with the fourth parameter name as a fifth parameter name, processing the fourth parameter name and the parameter value of the fourth parameter name according to a preset range rule to obtain the parameter range of the fifth parameter name, and judging whether the parameter value of the fifth parameter name is in the corresponding parameter range, wherein the range rule comprises the parameter range of the parameter name which is set to be associated with the target parameter according to the parameter value of the target parameter name;

the setting submodule is used for setting the corresponding information as the non-corresponding information if the judgment result of the second judgment submodule is negative, and obtaining the corresponding information corresponding to the special demand point;

the modification submodule is used for judging whether a correlation relationship between the plurality of third parameter names and the second parameter name is a related third parameter name or not for each second parameter name if the judgment result of the second judgment submodule is yes, and modifying the parameter value of the second parameter name into a parameter range of the second parameter name according to the range rule if the correlation relationship between the plurality of third parameter names and the second parameter name is a parameter value of the related third parameter name;

the execution submodule is used for executing the first setting unit and/or the second setting unit for each part name associated with the special demand point;

the first setting unit is used for obtaining the conforming model data in the scheme database according to the first parameter name associated with the part name and the parameter value corresponding to the first parameter name, and modifying the model parameter in the coping information into the obtained model data;

and the first setting unit is used for setting the size parameter in the response information as the associated parameter name and the parameter value of the associated parameter name to obtain the response information corresponding to the special demand point.

The first parameter names associated with the special demand points may be multiple, but each first parameter name does not require a user to input a parameter value, the user only needs to input a basic parameter, and the user does not input the first parameter name of the parameter value, and inputs a preset default value, where the default value may be a standard parameter range corresponding to the first parameter name, and the user does not input a corresponding parameter value, that is, the first parameter name may adopt any parameter value within a variable resistance parameter range, and in the corresponding parameter information, for each first parameter name, the first judgment sub-module judges whether the parameter value of the first parameter name is the default value, which is the first parameter name for finding the parameter value input by the user.

The marking submodule marks the first parameter name with the parameter value as the default value as the second parameter name, and marks the first parameter name with the parameter value as the parameter value input by the user as the third parameter name, so that whether the parameter value input by the user is effective or not can be judged subsequently, and whether the corresponding operation can be carried out or not can be judged.

The second judgment sub-module selects one third parameter name from the plurality of third parameter names as a fourth parameter name, marks the third parameter name which is related to the association relationship between the plurality of third parameter names and the fourth parameter name as a fifth parameter name, processes the fourth parameter name and the parameter value thereof according to a preset range rule to obtain the parameter range of the fifth parameter name, and judges whether the parameter value of the fifth parameter name is in the parameter range of the obtained fifth parameter name, namely, whether the special demand point can be responded or not can be determined. Presetting a range rule comprises setting a parameter range of a parameter name associated with a target parameter according to a parameter value of the target parameter name, for example, the parameter value of the shaft width is a, the parameter range of the car width obtained by the range rule is [900, a-400], and a-400 is less than or equal to 2200; or the parameter value of the car width is b, and the parameter range of the shaft width obtained by the range rule is [ b +400, 3000 ].

If the parameter value of the fifth parameter name is not within the obtained parameter range of the fifth parameter name, it indicates that the parameter value of the fifth parameter name exceeds the corresponding parameter range, so that the special demand point cannot be responded, and there is no corresponding scheme.

If the parameter value of the fifth parameter name is within the parameter range of the obtained fifth parameter name, it indicates that the special demand point can be responded to, and the second parameter name generally has an association relationship with the third parameter name, so that if the modification sub-module determines that the association relationship between the second parameter name and the third parameter name is a related third parameter name, the parameter value of the second parameter name needs to be adjusted according to the parameter value of the third parameter name input by the user, and if the association relationship does not exist, the parameter value of the second parameter name is kept as the default parameter value.

For each part name associated with the special demand point, because the part parameter corresponding to the part name may be a model parameter, a size parameter, or both, the execution submodule executes the first setting unit and/or the second setting unit as required to obtain the part parameter corresponding to the part name, thereby obtaining the corresponding information corresponding to the special demand point.

The scheme database comprises a plurality of model data corresponding to each part name and a parameter range of a plurality of parameter names corresponding to each model data, so that the first setting unit finds the model data which is in accordance with the first parameter name associated with the part name and the parameter value corresponding to the first parameter name in the scheme database, and modifies the model parameter in the corresponding information corresponding to the special demand point into the model data.

The size parameter is associated with a parameter name, so the second setting unit directly sets the size parameter in the response information corresponding to the special demand point as the associated parameter name and the parameter value of the associated parameter name.

Further, the part name is associated with type information, the type information includes a model type, a size type and a common type, and the execution submodule includes:

the judging unit is used for acquiring and judging the type information associated with the component name for each component name associated with the special demand point;

a first execution unit configured to execute the first setting unit if the type information associated with the component name is a model type;

a second execution unit configured to execute the second setting unit if the type information associated with the part name is a size type;

and a third execution unit configured to execute the first setting unit and the second setting unit if the type information associated with the component name is a common type.

The first execution unit executes the first setting unit, and the obtained corresponding information is the model parameter corresponding to the part name and the part name, such as a guide rail and a model A. If the judging unit judges that the type information associated with the component name is the size type, the component parameter corresponding to the component name is the size parameter, so the second executing unit executes the second setting unit, and the obtained corresponding information is the size parameter corresponding to the component name and the component name, such as the hoistway, and the width is 1000. If the judging unit judges that the type information associated with the part name is a common type, the part parameters corresponding to the part name are model parameters and size parameters, the third executing unit executes the first setting unit and the second setting unit, and the obtained corresponding information is the model parameters and the size parameters corresponding to the name and the part name, such as a fireproof door, a model B and a door width 500.

The added price of different final coping schemes is recorded in a price database in advance, the added price is the difference between the final coping scheme and a standard scheme in standard size configuration, and in all coping schemes, solutions which are mutually crossed may exist, so that the integration module 5 processes all coping schemes according to the integration rule, obtains a plurality of final coping schemes, directly obtains the added price of each final coping scheme in the price database according to the final coping schemes, and superposes and summarizes the obtained added prices to obtain the total special price, and obtains the price of a plurality of special demand points which needs to be increased relative to the standard size configuration.

Further, the integration module 5 includes:

the first dividing unit is used for dividing the coping schemes with the same component name into coping scheme groups to obtain a plurality of coping scheme groups;

the second dividing unit is used for dividing the size parameters containing the same parameter name into a size parameter group for a plurality of corresponding schemes in the same corresponding scheme group to obtain a plurality of size parameter groups;

and the calculation unit is used for performing set intersection operation on the parameter values contained in the plurality of size parameters to obtain final size parameters, and replacing the corresponding plurality of size parameters with the obtained final size parameters to obtain a plurality of final coping schemes.

In all the coping schemes, coping schemes having the same component name relate to the same component, so the first division unit divides coping schemes having the same component name into a coping scheme group, in a plurality of solutions of the same solution group, the dimension parameter with the same parameter name relates to a certain same parameter for designing the same component, therefore, the second dividing unit divides the dimension parameters containing the same parameter name into a dimension parameter group, the calculating unit carries out the aggregation and intersection operation on the parameter values contained in a plurality of dimension parameters to obtain the final dimension parameter, the parameter value of the final dimension parameter conforms to the parameter range of the same parameter name, and according to the parameter names contained in the final size parameters, replacing the corresponding size parameters with the same parameter names by the obtained final size parameters, and deleting the repeated coping schemes to finally obtain a plurality of final coping schemes. For example, the coping plan A comprises widths [700, 3000] corresponding to the shaft and the shaft, the coping plan B comprises widths [600, 2000] corresponding to the shaft and the shaft, parameter values of the shaft and the shaft are collected and processed to obtain the widths [700, 2000], and the final coping plan C comprises the widths [700, 2000] corresponding to the shaft and the shaft.

The output module 6 displays and outputs the final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to the user for the user to confirm the coping schemes and the total special price. The whole process does not need human intervention, reduces the information circulation of each follow-up department, and realizes the full-automatic response of special demand points of users, thereby improving the response efficiency, being beneficial to quickly determining the change of modification cost, obtaining the quotation of contract modification, promoting the determination of a field special scheme, accelerating the completion of contract modification, shortening the confirmation time of contract modification, and reducing the economic loss caused by field engineering delay.

Further, the device for determining the special scheme of the elevator further comprises:

the second display module is used for displaying and outputting the fourth parameter name and the fifth parameter name of each first special demand point to a user;

the detection module is used for detecting whether a signal that the user modifies the parameter value corresponding to the fourth parameter name is received or not and/or detecting whether a signal that the user modifies the parameter value corresponding to the fifth parameter name is received or not;

and the repeating module is used for replacing an old parameter value corresponding to the fourth parameter name with a new parameter value of the fourth parameter name input by the user and/or replacing an old parameter value corresponding to the fifth parameter name with a new parameter value of the fifth parameter name input by the user, and repeating the processing module 4, the integrating module 5 and the output module 6 if the detection result of the detecting module is positive.

The first special demand point cannot be responded to due to the problem of the input parameters, therefore, the second display module displays and outputs the fourth parameter name and the fifth parameter name with problems to the user, the detection module detects whether the user modifies the parameter value of the fourth parameter name and/or the fifth parameter name, if the user modifies the parameter value of the fourth parameter name and/or the fifth parameter name, the repeating module replaces the old parameter value corresponding to the fourth parameter name with the new parameter value of the fourth parameter name input by the user, and/or replacing the old parameter value corresponding to the fifth parameter name with the new parameter value of the fifth parameter name input by the user, and then repeating the processing module 4, the integration module 5 and the output module 6 to process the special demand point to see whether a coping scheme of the special demand point can be obtained.

Referring to fig. 3, fig. 3 is a block diagram illustrating a structure of an electronic device according to an embodiment of the invention. An embodiment of the present invention further provides an electronic device 1001, which includes a memory 1003 and a processor 1002, where the memory 1003 stores a computer program 1004, and when the processor 1002 executes the computer program 1004, the method for implementing any sound source localization method includes: receiving a plurality of special demand points input by a user; for each special demand point, acquiring a plurality of parameter names and a plurality of component names associated with the special demand point from a preset scheme database, marking the acquired parameter names as first parameter names, wherein the scheme database at least comprises a plurality of special demand points, a plurality of parameter names and a plurality of component names, and each special demand point is associated with a plurality of parameter names and a plurality of component names; displaying and outputting a plurality of first parameter names to a user, receiving an input parameter value of each first parameter name, combining the first parameter names and the parameter values corresponding to the first parameter names into parameter information, and obtaining a plurality of parameter information of each special demand point; for each special demand point, processing a plurality of part names and a plurality of parameter information corresponding to the special demand point according to a special corresponding rule to obtain corresponding information corresponding to each special demand point, marking the special demand point of which the corresponding information is incapable of being responded as a first special demand point, wherein the corresponding information comprises a plurality of corresponding schemes or cannot be responded, and the corresponding schemes comprise part names and part parameters corresponding to the part names; integrating all the coping schemes according to the integration rule to obtain a plurality of final coping schemes, obtaining the added price of each final coping scheme in a preset price database, summarizing the obtained added prices to obtain a total special price, wherein the price database at least comprises the added prices of different final coping schemes; and displaying and outputting the plurality of final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to a user.

Referring to fig. 4, fig. 4 is a schematic block diagram illustrating a structure of a computer-readable storage medium according to an embodiment of the present invention. An embodiment of the present invention further provides a computer-readable storage medium 2001, on which a computer program 1004 is stored, where the computer program 1004 when executed by the processor 1002 implements the steps of any one of the sound source localization methods described above, including: receiving a plurality of special demand points input by a user; for each special demand point, acquiring a plurality of parameter names and a plurality of component names associated with the special demand point from a preset scheme database, marking the acquired parameter names as first parameter names, wherein the scheme database at least comprises a plurality of special demand points, a plurality of parameter names and a plurality of component names, and each special demand point is associated with a plurality of parameter names and a plurality of component names; displaying and outputting a plurality of first parameter names to a user, receiving an input parameter value of each first parameter name, combining the first parameter names and the parameter values corresponding to the first parameter names into parameter information, and obtaining a plurality of parameter information of each special demand point; for each special demand point, processing a plurality of part names and a plurality of parameter information corresponding to the special demand point according to a special corresponding rule to obtain corresponding information corresponding to each special demand point, marking the special demand point of which the corresponding information is incapable of being responded as a first special demand point, wherein the corresponding information comprises a plurality of corresponding schemes or cannot be responded, and the corresponding schemes comprise part names and part parameters corresponding to the part names; integrating all the coping schemes according to the integration rule to obtain a plurality of final coping schemes, obtaining the added price of each final coping scheme in a preset price database, summarizing the obtained added prices to obtain a total special price, wherein the price database at least comprises the added prices of different final coping schemes; and displaying and outputting the plurality of final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to a user.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium provided herein and used in the examples may include non-volatile and/or volatile memory. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), double-rate SDRAM (SSRSDRAM), Enhanced SDRAM (ESDRAM), synchronous link (Synchlink) DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and bus dynamic RAM (RDRAM).

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, apparatus, article, or method that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, apparatus, article, or method. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, apparatus, article, or method that includes the element.

The present invention is not limited to the above-described embodiments, and various modifications and variations of the present invention are intended to be included within the scope of the claims and the equivalent technology of the present invention if they do not depart from the spirit and scope of the present invention. .

Claims

1. A method of determining a special case of an elevator, characterized by the steps of:

s1, receiving a plurality of special demand points input by a user;

s2, for each special demand point, acquiring a plurality of parameter names and a plurality of component names associated with the special demand point from a preset scheme database, and marking the acquired parameter names as first parameter names, wherein the scheme database at least comprises a plurality of special demand points, a plurality of parameter names and a plurality of component names, and each special demand point is associated with a plurality of parameter names and a plurality of component names;

s3, displaying and outputting the first parameter names to a user, receiving the input parameter value of each first parameter name, combining the first parameter name and the parameter value corresponding to the first parameter name into parameter information, and obtaining the parameter information of each special demand point;

s4, for each special demand point, processing a plurality of part names and a plurality of parameter information corresponding to the special demand point according to a special handling rule to obtain handling information corresponding to each special demand point, and marking the handling information as the special demand point which cannot be handled as a first special demand point, wherein the handling information comprises a plurality of handling schemes or cannot be handled, and the handling schemes comprise part parameters corresponding to the part names and the part names;

s5, integrating all the coping schemes according to an integration rule to obtain a plurality of final coping schemes, obtaining the added price of each final coping scheme in a preset price database, summarizing the obtained added prices to obtain a total special price, wherein the price database at least comprises the added prices of different final coping schemes;

and S6, displaying and outputting the final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to a user.

2. The method for determining the special scheme of the elevator according to claim 1, wherein the association relationship between the names of the parameters is pre-established, and the association relationship between the names of the parameters is relational or non-relational, for each name of the parameters, the name of the parameter is associated with a name of a component, the parameter of the component comprises at least one of a model parameter or a specification size, the specification size comprises at least one dimension parameter, the name of the dimension parameter is associated with a name of the parameter, the scheme database further comprises a plurality of model data corresponding to the names of the components, and a parameter range of a plurality of parameter names corresponding to the data of each model;

the step of processing the component information and the parameter information corresponding to the special demand points according to special handling rules to obtain handling information corresponding to each special demand point comprises the following steps:

in the parameter information corresponding to the special demand point, judging whether the parameter value of each first parameter name is a default value or not for each first parameter name;

sequentially selecting a fourth parameter name from the plurality of third parameter names, recording the third parameter name which is related to the association relationship of the fourth parameter name as a fifth parameter name, processing the fourth parameter name and the parameter value thereof according to a preset range rule to obtain a parameter range of the fifth parameter name, and judging whether the parameter value of the fifth parameter name is in the corresponding parameter range, wherein the range rule comprises setting the parameter range of the parameter name associated with the target parameter according to the parameter value of the target parameter name;

if not, setting the corresponding information as the information which cannot be responded to obtain the corresponding information corresponding to the special demand point;

if yes, judging whether a related third parameter name which is related to the second parameter name exists in the plurality of third parameter names or not for each second parameter name, and if yes, modifying the parameter value of the second parameter name into a parameter range of the second parameter name according to a range rule according to the related parameter value which is related to the second parameter name;

for each part name associated with the special demand point, executing step a and/or executing step b;

3. Method for determining elevator special solutions according to claim 2, characterized in that the step of integrating all the solutions according to integration rules to obtain a number of final solutions comprises:

4. Method for determining elevator special solutions according to claim 2, characterized in that the component names are associated with type information, which comprises a model type, a size type and a common type, and the step of performing step a and/or performing step b for each component name associated with the special demand point comprises:

if the type information associated with the component name is the model type, executing the step a;

if the type information associated with the part name is a size type, executing the step b;

5. The method for determining elevator special plans according to claim 2, wherein after the step of displaying and outputting the final solutions, the total special price, the first special demand point and the corresponding handling information of the first special demand point to the user, the method further comprises:

6. An apparatus for determining a particular profile for an elevator, comprising:

the system comprises an acquisition module, a data processing module and a processing module, wherein the acquisition module is used for acquiring a plurality of parameter names and a plurality of component names which are associated with the special demand points in a preset scheme database for each special demand point, marking the acquired parameter names as first parameter names, and the scheme database at least comprises a plurality of special demand points, a plurality of parameter names and a plurality of component names, and each special demand point is associated with a plurality of parameter names and a plurality of component names;

the processing module is used for processing a plurality of part names and a plurality of parameter information corresponding to the special demand points according to special handling rules for each special demand point to obtain handling information corresponding to each special demand point, and marking the handling information as special demand points which cannot be handled as first special demand points, wherein the handling information comprises a plurality of handling schemes or cannot be handled, and the handling schemes comprise part names and part parameters corresponding to the part names;

the integration module is used for integrating all the coping schemes according to an integration rule to obtain a plurality of final coping schemes, obtaining the added price of each final coping scheme in a preset price database, and summarizing the obtained added prices to obtain a total special price, wherein the price database at least comprises the added prices of different final coping schemes;

and the output module is used for displaying and outputting the final coping schemes, the total special price, the first special demand point and coping information corresponding to the first special demand point to a user.

7. An electronic device comprising a memory and a processor, the memory storing a computer program, wherein the processor implements the steps of the method according to any one of claims 1-5 when executing the computer program.

8. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method according to any one of claims 1 to 5.