CN113468694B - Processing method, processing system, processing equipment and processing medium for designing liquefied gas tank compartment - Google Patents

Abstract

The invention discloses a processing method, a system, equipment and a medium for designing a liquefied gas tank compartment, wherein the processing method comprises the following steps: receiving an externally input target volume parameter and a seal head type parameter for designing the liquefied gas tank compartment, and receiving an externally input first length parameter for designing the liquefied gas tank compartment; receiving a locking instruction input from the outside, and locking the first length parameter unchanged; receiving a first processing instruction input from the outside, and processing according to a first target formula to obtain a first diameter parameter for designing the liquefied gas tank; generating a design model of the liquefied gas tank; or receiving the second diameter parameter, the target volume parameter and the end socket type parameter which are input externally, locking the second diameter parameter unchanged, processing to obtain a second length parameter, and generating a design model of the liquefied gas tank. And a large number of parameters for designing the liquefied gas tank cabin are not required to be manually processed, and a design model is not required to be generated by manual processing, so that a large number of labor and time costs are saved.

Description

Processing method, processing system, processing equipment and processing medium for designing liquefied gas tank compartment

Technical Field

The present invention relates to the field of liquefied gas tank compartment design, and in particular, to a method, a system, an apparatus, and a medium for processing a liquefied gas tank compartment in design.

Background

At present, in the design process of the liquefied gas tank cabin, the liquefied gas tank cabin aims at the technical field of liquefied gas storage equipment design in the ship field, the number of parameters needed for designing the liquefied gas tank cabin is large, the parameters comprise the length of the liquefied gas tank cabin, the diameter of the liquefied gas tank cabin, the mathematical volume of the liquefied gas tank cabin, the effective volume of the liquefied gas tank cabin, the type of end socket and other refinement parameters, in the design process, because a plurality of factors such as functional volume requirements, arrangement space limitations, economic cost control, the technical requirements of the shipmen and the like change, a design engineer needs to quickly make a plurality of design schemes of the liquefied gas tank cabins, but in many cases, only the mathematical volume of the liquefied gas tank cabin and the length or the diameter of the expected liquefied gas tank cabin are known, under the condition that only the mathematical volume, the length or the diameter is known, the design engineer manually processes and generates a design model, the engineering quantity is large and the processing is difficult, if a certain parameter changes, the engineering needs to carry out reprocessing operation and generate a new design model, the engineering engineer cannot respond to the change of a certain parameter, the design scheme of the liquefied gas cabin cannot be quickly made, and the basic requirements cannot be met, and the like are not preferred to change.

Disclosure of Invention

The invention aims to overcome the defects of high labor cost and time cost of manually processing parameters required by designing a liquefied gas tank compartment in the prior art, and provides a processing method, a processing system, processing equipment and a processing medium for designing the liquefied gas tank compartment.

The invention solves the technical problems by the following technical scheme:

the invention provides a treatment method when designing a liquefied gas tank compartment, which comprises the following steps:

receiving externally input target volume parameters, head type parameters and first length parameters for designing a liquefied gas tank;

receiving a locking instruction input from outside, and locking the first length parameter unchanged;

receiving a first processing instruction input from the outside, and processing according to a first target formula to obtain a first diameter parameter for designing the liquefied gas tank;

generating a design model of the liquefied gas tank compartment; or alternatively, the first and second heat exchangers may be,

the processing method comprises the following steps:

receiving an externally input target volume parameter, a head type parameter and a second diameter parameter for designing the liquefied gas tank;

receiving a locking instruction input from the outside, and locking the second diameter parameter unchanged;

Receiving a second processing instruction input from the outside, and processing according to a second target formula to obtain a second length parameter for designing the liquefied gas tank;

generating a design model of the liquefied gas tank.

Preferably, before the step of generating the design model of the liquefied gas tank compartment, the method further comprises:

acquiring volume ratio parameters for designing the liquefied gas tank compartment, wherein the volume ratio parameters comprise filling rate parameters, content ratio parameters and cargo residual parameters;

receiving a third processing instruction, and processing according to a third target formula by combining the length parameter, the end socket type parameter, the diameter parameter and the volume ratio parameter to obtain an effective volume parameter for designing the liquefied gas tank compartment;

the length parameter and the diameter parameter are the first length parameter and the first diameter parameter or the second length parameter and the second diameter parameter.

Preferably, after the step of generating the design model of the liquefied gas tank compartment, the method further comprises the steps of:

and generating a design diagram according to the design model of the liquefied gas tank, wherein the design diagram is a two-dimensional design diagram or a three-dimensional design diagram.

Preferably, the processing method further comprises:

Presetting a first virtual indicator lamp and a second virtual indicator lamp;

controlling the first virtual indicator lamp to be lightened when a first diameter parameter for designing the liquefied gas tank compartment is obtained according to a first target formula;

and controlling the second virtual indicator lamp to be lightened when a second length parameter for designing the liquefied gas tank compartment is obtained according to a second target formula.

A processing system in designing a liquefied gas tank compartment, the processing system comprising:

the receiving module is used for receiving an externally input target volume parameter, a seal head type parameter and a first length parameter for designing the liquefied gas tank;

the locking module is used for receiving an externally input locking instruction and locking the first length parameter;

the processing module is used for receiving a first processing instruction input from the outside, and processing the first processing instruction according to a first target formula to obtain a first diameter parameter for designing the liquefied gas tank compartment;

the model generation module is used for generating a design model of the liquefied gas tank; or alternatively, the first and second heat exchangers may be,

the processing system comprises the following steps:

the receiving module is used for receiving an externally input target volume parameter, a seal head type parameter and a second diameter parameter for designing the liquefied gas tank;

The locking module is used for receiving an externally input locking instruction and locking the second diameter parameter;

the processing module is used for receiving a second processing instruction input from the outside, and processing the second processing instruction according to a second target formula to obtain a second length parameter for designing the liquefied gas tank compartment;

and the model generation module is used for generating a design model of the liquefied gas tank.

Preferably, the receiving module is further configured to obtain a volume ratio parameter for designing the liquefied gas tank, where the volume ratio parameter includes a filling rate parameter, a content ratio parameter, and a cargo residual parameter;

the processing module is also used for receiving a third processing instruction, and processing according to a third target formula and combining the length parameter, the end socket type parameter, the diameter parameter and the volume ratio parameter to obtain an effective volume parameter for designing the liquefied gas tank;

the length parameter and the diameter parameter are the first length parameter and the first diameter parameter or the second length parameter and the second diameter parameter.

Preferably, the processing system further comprises:

and the design diagram generating module is used for generating a design diagram according to the design model of the liquefied gas tank, wherein the design diagram is a two-dimensional design diagram or a three-dimensional design diagram.

Preferably, the processing system further comprises:

the preset indicator lamp module is used for presetting a first virtual indicator lamp and a second virtual indicator lamp;

the indicator light control module is used for controlling the first virtual indicator light to be lightened when a first diameter parameter for designing the liquefied gas tank compartment is obtained according to a first target formula;

the indicator light control module is also used for controlling the second virtual indicator light to be lightened when a second length parameter for designing the liquefied gas tank compartment is obtained according to a second target formula.

An electronic device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, the processor implementing the processing method when designing a liquefied gas tank compartment when executing the computer program.

A computer readable medium having stored thereon a computer program which, when executed by a processor, implements the method of processing in designing a liquefied gas tank compartment.

The invention has the positive progress effects that: by providing a processing method when designing the liquefied gas tank compartment, the target volume parameter and the end socket type parameter which are input from outside and used for designing the liquefied gas tank compartment can be received, the target volume can be any number, the end socket type parameter can be input according to actual needs, the first length parameter which is input from outside and used for designing the liquefied gas tank compartment is received, the first length parameter is locked, after receiving a processing instruction, the first diameter parameter for designing the liquefied gas tank compartment can be processed according to a corresponding formula, a design model of the liquefied gas tank compartment can be generated based on the target volume parameter, the end socket type parameter, the first length parameter and the first diameter parameter, or the target volume parameter and the end socket type parameter which are input from outside and the second diameter parameter when designing the liquefied gas tank compartment are received, and under the condition that the second diameter parameter is locked, the processing instruction is received, the second length parameter for designing the liquefied gas tank compartment is processed according to the corresponding target formula, and the design model of the liquefied gas tank compartment can be generated based on the parameters obtained by input and processing. Through the scheme, parameters required by designing the liquefied gas tank compartment do not need manual processing operation, a large amount of time cost and labor cost are saved, a design model of the liquefied gas tank compartment can be quickly generated based on the obtained parameters, the parameters for designing the liquefied gas tank compartment can be randomly changed, the design scheme of the liquefied gas tank compartment can be quickly formulated in response to certain parameter change, multiple schemes can be quickly generated, multiple schemes are realized, and constraint is preferred.

Drawings

Fig. 1 is a flowchart of a processing method in designing a liquefied gas tank compartment according to embodiment 1 of the present invention.

Fig. 2 is an operational interface diagram of the processing method in designing a liquefied gas tank compartment according to embodiment 1 of the present invention.

Fig. 3 is a flowchart of a processing method in designing a liquefied gas tank compartment according to embodiment 2 of the present invention.

Fig. 4 is a schematic diagram showing the processing system module in designing the liquefied gas tank compartment according to embodiment 3 of the present invention.

Fig. 5 is a schematic diagram of the processing system module in designing the liquefied gas tank compartment according to embodiment 4 of the present invention.

Fig. 6 is a schematic structural diagram of an electronic device according to embodiment 5 of the present invention.

Detailed Description

The invention is further illustrated by means of the following examples, which are not intended to limit the scope of the invention.

Example 1

The present embodiment provides a processing method in designing a liquefied gas tank compartment, referring to fig. 1, including the steps of:

s1, receiving an externally input target volume parameter, a seal head type parameter and a first length parameter for designing the liquefied gas tank.

In this embodiment, fig. 2 is an operation interface diagram of a processing method in designing a liquefied gas tank and tank according to the present embodiment, as shown in fig. 2, when a user designs the liquefied gas tank and tank, the user needs to process parameters in designing the liquefied gas tank and tank first, and the user can input a target volume parameter (i.e. a target mathematical volume in the figure), a seal head type parameter and a first length parameter (i.e. a full length parameter of the tank in the figure) on the operation interface, where the seal head type parameter preferably includes a disc seal head parameter and a spherical seal head parameter, these two parameters are two types commonly used in the marine industry, and the seal head type parameter can be set according to actual needs, and is not limited herein.

S2, receiving a locking instruction input from the outside, and locking the first length parameter unchanged;

referring to fig. 5, there are two locking options below the target mathematical volume, and after the user clicks to lock the first length parameter, that is, the first length parameter cannot be input or changed externally, the accuracy of the subsequent processing result can be ensured.

S3, receiving a first processing instruction input from the outside, and processing according to a first target formula to obtain a first diameter parameter for designing the liquefied gas tank.

As shown in fig. 2, when a user inputs a target volume parameter, a seal head type parameter, and locks a first length parameter, a solving button is clicked, that is, a first processing instruction input from the outside is triggered, according to a first target formula, the first target formula is preferably a nonlinear mathematical algorithm, according to which a first diameter parameter for designing a liquefied gas tank can be obtained by processing, and the process of the operation processing adopts the principle of inverse constraint operation processing, and when the target volume parameter, the first length parameter, and the seal head type parameter are known, the operation processing obtains the first diameter parameter, and if the operation processing process is performed manually, a large amount of labor and time are required, the speed of the manual processing is slow, the accuracy is not high, and by the processing method of the embodiment, a large amount of labor cost and time cost can be saved, the accuracy of the processing result can be improved, the parameter change can be responded quickly, the result can be obtained by processing quickly, and multiple choices and optimization of the scheme are realized.

S6, generating a design model of the liquefied gas tank.

And generating a design model of the liquefied gas tank according to the externally input target volume parameter, the seal head type parameter, the first length parameter and the first diameter parameter obtained by processing.

Before step S6, the method further comprises the following steps:

s4, acquiring volume ratio parameters for designing the liquefied gas tank, wherein the volume ratio parameters comprise filling rate parameters, content ratio parameters and cargo residual parameters.

As shown in fig. 2, the volume ratio parameter is a part of parameters necessary for calculating the effective volume of the liquefied gas tank, and the volume ratio parameter may be set to be a constant parameter, may be set according to actual requirements by external input, and is not limited herein.

S5, receiving a third processing instruction, and processing according to a third target formula by combining the length parameter, the end socket type parameter, the diameter parameter and the volume ratio parameter to obtain an effective volume parameter for designing the liquefied gas tank. The length parameter and the diameter parameter are a first length parameter and a first diameter parameter.

As shown in fig. 2, when the user inputs the volume ratio parameter, the length parameter, the diameter parameter and the end socket parameter, or after the user inputs the target volume parameter, the length parameter and the end socket type parameter and performs post-processing to obtain the diameter parameter, a third processing instruction is triggered by clicking a calculation tank capacity button in the graph, and the effective volume parameter of the designed liquefied gas tank is obtained by a forward constraint operation processing method according to a third target formula, namely a corresponding mathematical algorithm, wherein the difficulty of the forward constraint operation processing is lower than that of the reverse constraint operation processing, but the manual processing is slower, the manual processing is complex and error-prone, and the result can be obtained by the processing method of the embodiment quickly and accurately, so that the labor and time cost are saved. After the effective volume parameter is obtained through processing operation, the target volume parameter, the end socket type parameter, the first length parameter, the first diameter parameter, the filling rate parameter, the content duty ratio parameter, the goods residual parameter and the effective volume parameter are displayed on a display screen in a pre-selected and set mode, as shown in fig. 2, the preferred processing method of the embodiment displays the parameters on the display screen in a list mode, the parameters are orderly arranged and convenient to view, the parameters displayed on the display screen can be copied and pasted, different first diameter parameter schemes can be obtained through processing the conditions of different input target parameters, end socket types and the first length parameter, the different first diameter parameter schemes can be copied and pasted, and the different first diameter parameter schemes can be stored in other files for storage, so that the optimal scheme can be selected from a plurality of schemes.

After step S6, the method further comprises the steps of:

and S7, generating a design drawing according to the design model of the liquefied gas tank, wherein the design drawing is a two-dimensional design drawing or a three-dimensional design drawing.

As shown in FIG. 2, clicking the drawing paper generates a design chart according to the design model of the liquefied gas tank, and the design chart can be automatically generated without manually drawing the corresponding design chart according to parameters, so that the liquefied gas tank is convenient and efficient.

The processing method provided in the embodiment when designing the liquefied gas tank compartment further includes the following steps:

a first virtual indicator lamp is preset.

And controlling the first virtual indicator lamp to be lightened when a first diameter parameter for designing the liquefied gas tank compartment is obtained according to a first target formula.

As shown in fig. 2, a is a virtual indicator lamp, which is turned on when a first diameter parameter of the designed liquefied gas tank is obtained according to a first target formula, the color of the virtual indicator lamp can be set arbitrarily, and the virtual indicator lamp a can be set beside an operating interface or can cover characters on the interface for prompting. The number of the virtual indicator lamps is not limited herein, and the virtual indicator lamps can be set according to actual needs.

As shown in fig. 2, the user clicks the data reset button, so that the parameters input on the operation interface can be cleared, one parameter does not need to be deleted singly, the time is saved, and the operation is convenient; and also provides real-time noun interpretation (including partial English), wherein the nouns are nouns and English related to the liquefied gas tank, and the corresponding paraphrasing of the nouns occurs when a user places a mouse on a certain noun.

According to the processing method for designing the liquefied gas tank compartment, the problem that parameters required by the process of manually processing and operating the liquefied gas tank compartment in the prior art are solved, under the condition of receiving externally input target volume parameters, end socket type parameters and first length parameters, the first length parameters are locked, the first diameter parameters of the designed liquefied gas tank compartment can be obtained through operation of a nonlinear mathematical algorithm, the design parameters of the liquefied gas tank compartment can be obtained without manual complex operation of design engineering, the diameter parameters required by the process of designing the liquefied gas tank compartment can be obtained, after the externally input volume occupation ratio parameters are received, the effective volume parameters of the designed liquefied gas tank compartment can be obtained through forward operation processing according to the corresponding algorithm, and the design model of the liquefied gas tank compartment can be generated according to the obtained target volume parameters, end socket type parameters, first length parameters, effective volume parameters, volume occupation ratio parameters and first diameter parameters, time cost is saved, the externally input parameters can be input randomly, the volume occupation ratio parameters can be changed correspondingly, the user can be satisfied or the user can be satisfied by changing the parameters correspondingly, and the requirements can be met.

Example 2

The present embodiment provides a processing method in designing a liquefied gas tank compartment, referring to fig. 3, including the steps of:

s11, receiving an external input, wherein the external input is used for designing a target volume parameter, a head type parameter and a second diameter parameter of the liquefied gas tank.

Fig. 2 is a diagram of an operation interface of a processing method in designing a liquefied gas tank compartment according to the embodiment, as shown in fig. 2, when a user needs to process parameters in designing the liquefied gas tank compartment, the user may input a target volume parameter (i.e. a target mathematical volume in the figure), a seal head type parameter and a second diameter parameter (i.e. a nominal diameter parameter in the figure) on the operation interface, and the seal head type parameter preferably includes a disc type seal head parameter and a spherical seal head parameter in the embodiment, where the two seal head type parameters are commonly used in the current ship field, and the seal head type parameter may be set according to actual needs, and is not limited herein.

S12, receiving an externally input locking instruction, and locking the second diameter parameter unchanged.

As shown in fig. 2, there are two locking options below the target mathematical volume, and after the user clicks to lock the second diameter parameter, that is, the second diameter parameter cannot be input or changed externally, the accuracy of the subsequent processing result can be ensured.

S13, receiving a second processing instruction input from the outside, and processing according to a second target formula to obtain a second length parameter for designing the liquefied gas tank.

As shown in fig. 2, when the user inputs the target volume parameter, the end socket type parameter, and locks the second diameter parameter, the user clicks the solving button, that is, triggers the externally input second processing instruction, and according to the externally input second processing instruction, the processing method of this embodiment preferably uses a nonlinear mathematical algorithm according to the second target formula, and according to this nonlinear mathematical algorithm, the second length parameter for designing the liquefied gas tank can be obtained by processing, and the process of this operation adopts a reverse constraint operation process, and under the condition that the target volume parameter, the second diameter parameter, and the end socket type parameter are known, the operation process obtains the second length parameter, and this operation process requires a large amount of labor and time, and the speed of the manual process is slow, and the accuracy is not high.

S16, generating a design model of the liquefied gas tank.

And generating a design model of the liquefied gas tank according to the externally input target volume parameter, the seal head type parameter, the second diameter parameter and the processed second length parameter.

Before step S16, the method further comprises the following steps:

s14, acquiring volume ratio parameters for designing the liquefied gas tank, wherein the volume ratio parameters comprise filling rate parameters, content ratio parameters and cargo residual parameters.

As shown in fig. 2, the volume ratio parameter is a part of parameters necessary for calculating the effective volume of the liquefied gas tank, and the volume ratio parameter may be set to be a constant parameter, may be set according to actual requirements by external input, and is not limited herein.

S15, receiving a third processing instruction, and processing according to a third target formula by combining the length parameter, the end socket type parameter, the diameter parameter and the volume ratio parameter to obtain an effective volume parameter for designing the liquefied gas tank. The length parameter and the diameter parameter are a second length parameter and a second diameter parameter.

As shown in fig. 2, when the user inputs the volume ratio parameter, the length parameter, the diameter parameter and the end socket parameter, or after the user inputs the target volume parameter, the length parameter and the end socket type parameter and performs post-processing to obtain the diameter parameter, a third processing instruction is triggered by clicking a calculation tank capacity button in the graph, and the effective volume parameter of the designed liquefied gas tank is obtained by a forward constraint operation processing method according to a third target formula, namely a corresponding mathematical algorithm, wherein the difficulty of the forward constraint operation processing is lower than that of the reverse constraint operation processing, but the manual processing is slower, the manual processing is complex and error-prone, and the result can be obtained by the processing method of the embodiment quickly and accurately, so that the labor and time cost are saved.

After the effective volume parameter is obtained through processing operation, the target volume parameter, the end socket type parameter, the second length parameter, the second diameter parameter, the filling rate parameter, the content duty ratio parameter, the goods residual parameter and the effective volume parameter are displayed on a display screen in a pre-selected and set mode, as shown in fig. 2, the preferred processing method of the embodiment displays the parameters on the display screen in a list mode, the parameters are orderly arranged and convenient to view, the parameters displayed on the display screen can be copied and pasted, different second length parameter schemes can be obtained through processing the conditions of different input target parameters, end socket types and second diameter parameters, the different second length parameter schemes can be copied and pasted, and the different second length parameter schemes are stored in other files for storage, so that the optimal scheme can be selected from a plurality of schemes conveniently.

After step S16, the method further comprises the steps of:

s17, generating a design drawing according to the design model of the liquefied gas tank, wherein the design drawing is a two-dimensional design drawing or a three-dimensional design drawing.

As shown in FIG. 2, clicking the drawing paper generates a design chart according to the design model of the liquefied gas tank, and the design chart can be automatically generated without manually drawing the corresponding design chart according to parameters, so that the liquefied gas tank is convenient and efficient.

The processing method provided in the embodiment when designing the liquefied gas tank compartment also includes the following steps:

and presetting a second virtual indicator lamp.

And controlling the second virtual indicator lamp to be lightened when a second length parameter for designing the liquefied gas tank compartment is obtained according to a second target formula.

As shown in fig. 2, a is a virtual indicator lamp, which is turned on when a second length parameter of the designed liquefied gas tank is obtained according to a second target formula, the color of the virtual indicator lamp can be set arbitrarily, and the virtual indicator lamp a can be set beside an operating interface or can cover characters on the interface for prompting. The number of the virtual indicator lamps is not limited herein, and the virtual indicator lamps can be set according to actual needs.

As shown in fig. 2, the user clicks the data reset button, so that the parameters input on the operation interface can be emptied, one parameter does not need to be deleted singly, the time is saved, and the operation is convenient; and also provides real-time noun interpretation (including partial English), wherein the nouns are nouns and English related to the liquefied gas tank, and the corresponding paraphrasing of the nouns occurs when a user places a mouse on a certain noun.

According to the processing method for designing the liquefied gas tank compartment, the problem that parameters required by the process of manually processing and operating the liquefied gas tank compartment in the prior art are solved, under the condition of receiving externally input target volume parameters, end socket type parameters and second diameter parameters, the second diameter parameters are locked, the second length parameters of the designed liquefied gas tank compartment can be obtained through operation of a nonlinear mathematical algorithm, the length parameters required by the process of designing the liquefied gas tank compartment can be obtained without manually cutting complex operation of design engineering, after the externally input volume ratio parameters are received, the effective volume parameters of the designed liquefied gas tank compartment can be obtained through operation processing according to the target volume parameters and the volume ratio parameters, the end socket type parameters, the second length parameters and the second diameter parameters, a design model of the liquefied gas tank compartment can be generated according to the obtained target volume parameters, the end socket type parameters, the second length parameters, the effective volume ratio parameters and the second diameter parameters, time cost and labor cost are saved, the externally input parameters can be input at will, and the parameters can be changed correspondingly or can be changed in a very good mode under the condition of changing parameters, and the user can be satisfied, and the requirements can be met.

Example 3

The present embodiment provides a processing system in designing a liquefied gas tank compartment, see fig. 4, the processing system comprising:

the receiving module 1 is used for receiving an externally input target volume parameter, a seal head type parameter and a first length parameter for designing the liquefied gas tank.

The receiving module 1 receives external input, preferably user input, and the user needs to design the liquefied gas tank, at this time, the user may give an estimated volume, that is, a target volume parameter, and then the user may input the target volume parameter, and select a seal head type parameter required for designing the liquefied gas tank, where the seal head type parameter preferably includes a disc seal head and a spherical seal head in this embodiment, the seal head type parameter may be set according to actual needs, and not limited herein, and after the user inputs the target volume parameter, the user needs to input a first length parameter of the desired liquefied gas tank, that is, a length of the liquefied gas tank.

The locking module 2 is used for receiving an externally input locking instruction and locking the first length parameter unchanged.

After the user locks the target volume parameter, the seal head type parameter and the first length parameter, the first length parameter needs to be locked by the locking module 2, and the first length parameter cannot be changed, so that the accuracy of a subsequent data processing result can be ensured.

The processing module 3 is used for receiving a first processing instruction input from the outside, and processing the first processing instruction according to a first target formula to obtain a first diameter parameter for designing the liquefied gas tank.

Under the condition that the target volume parameter, the head type parameter and the first length parameter are input, after the processing module 3 receives the first processing instruction, the first target formula is preferably a nonlinear mathematical algorithm according to the first target formula, the first diameter parameter for designing the liquefied gas tank can be obtained through processing according to the nonlinear mathematical algorithm, the processing process is inverse constraint operation processing, the first diameter parameter is obtained through operation processing under the condition that the target volume parameter, the first length parameter and the head type parameter are known, if the operation processing process is manually processed, a large amount of labor and time are needed, the manual processing speed is low, the accuracy is not high, a large amount of labor cost and time cost can be saved through the processing method of the embodiment, the accuracy of the processing result can be improved, the parameter change can be responded quickly, the result can be obtained through quick processing, and the scheme multiple selection and the scheme preference are realized.

The model generation module 4, the model generation module 4 is used for generating the design model of the liquefied gas tank.

The model generation module 4 generates a design model of the liquefied gas tank compartment according to the target volume parameter, the head type parameter, the first length parameter and the first diameter parameter.

The model generating module 4 may generate a design model of the liquefied gas tank according to the target volume parameter, the head type parameter, the first length parameter and the first diameter parameter obtained by processing which are input from the outside.

The receiving module 1, the receiving module 1 is further used for obtaining the volume ratio parameter for designing the liquefied gas tank, wherein the volume ratio parameter comprises a filling rate parameter, a content ratio parameter and a cargo residual parameter.

The volume ratio parameter is a part of parameters necessary for calculating the effective volume of the liquefied gas tank, and may be set to be a constant parameter or may be input externally, and is not limited herein.

The processing module 3 is further configured to receive a third processing instruction, and process the third processing instruction according to a third target formula in combination with the length parameter, the end socket type parameter, the diameter parameter and the volume ratio parameter to obtain an effective volume parameter for designing the liquefied gas tank. The length parameter and the diameter parameter are a first length parameter and a first diameter parameter.

Under the condition that a user inputs the volume ratio parameter, the length parameter, the diameter parameter and the end socket parameter, or after the diameter parameter is obtained by carrying out post-processing on the input target volume parameter, the length parameter and the end socket type parameter, the user triggers a third processing instruction, the effective volume parameter of the designed liquefied gas tank is obtained by a forward constraint operation processing method according to a third target formula, the third target formula is a corresponding mathematical algorithm, the difficulty of the forward constraint operation processing is lower than that of the reverse constraint operation processing, but the manual processing speed is lower, the manual processing is complex and error-prone, the result can be obtained by the rapid and accurate processing through the processing method of the embodiment, and the labor and time cost are saved. After the processing module 3 processes and computes to obtain the effective volume parameter, the processing system of the embodiment can display the target volume parameter, the end socket type parameter, the first length parameter, the first diameter parameter, the filling rate parameter, the content duty ratio parameter, the goods residual parameter and the effective volume parameter on the display screen in a pre-selected and set form, and the processing system of the preferred embodiment displays the parameters on the display screen in a list form, is orderly arranged and convenient to check, and the parameters displayed on the display screen can be copied and pasted, and can process the conditions of different input target parameters, end socket types and the first length parameter to obtain different first diameter parameter schemes for copying and pasting, and store the different first diameter parameter schemes in other files for storing, thereby being convenient for selecting the optimal scheme among a plurality of schemes.

The processing system of this embodiment further includes the following modules:

the design diagram generating module 5 is configured to generate a design diagram according to a design model of the liquefied gas tank, where the design diagram is a two-dimensional design diagram or a three-dimensional design diagram.

The preset indication lamp module 6 is used for presetting a first virtual indication lamp, and the preset indication lamp module 6 is used for presetting a first virtual indication lamp.

The indicator light control module 7 is used for controlling the first virtual indicator light to be lightened when the first diameter parameter for designing the liquefied gas tank compartment is processed according to the first target formula.

As shown in fig. 2, a is a virtual indicator lamp, which is turned on when a first diameter parameter of the designed liquefied gas tank is obtained according to a first target formula, the color of the virtual indicator lamp can be set arbitrarily, and the virtual indicator lamp a can be set beside an operating interface or can cover characters on the interface for prompting. The number of the virtual indicator lamps is not limited herein, and the virtual indicator lamps can be set according to actual needs.

The processing system also comprises a data emptying module, wherein the data emptying module is used for completely emptying data on a system interface and a display screen without deleting parameters on the interface singly; the system also comprises a noun paraphrasing module which is used for displaying noun paraphrasing corresponding to nouns when a mouse is placed on a certain word or word on a system interface, and the nouns are nouns or English related to the liquefied gas tank, so that a user can learn and understand quickly.

According to the processing system of the embodiment, the receiving module 1 is arranged, the receiving module 1 can receive externally input target volume parameters, end socket type parameters and first length parameters, then the locking module 2 locks the first length parameters unchanged, the processing module 3 receives externally input processing instructions, the first diameter parameters are obtained through input parameter processing according to a first target formula, the processing process is complex and the workload is large, a large amount of labor can be saved through the processing system, the time cost and the labor cost are saved, the parameters input by a user can be changed randomly, other parameters can be obtained through quick processing according to the changed parameters, and the processing is convenient and error is avoided. Under the condition that the target volume parameter, the end socket type parameter, the first length parameter and the first diameter parameter are known, the receiving module 1 receives the volume duty ratio parameter input from the outside, and the processing module 3 processes the effective volume parameter of the liquefied gas tank according to the third target formula after receiving the processing instruction input from the outside. The processing process is quick and ready, different effective volume parameters can be processed according to different length parameters and diameter parameters, and different design models for designing the liquefied gas tank compartment are generated according to the parameters input from the outside and the parameters obtained by processing. The parameters required by processing and designing the liquefied gas tank compartment and the design model for generating and designing the liquefied gas tank compartment are very convenient, a large amount of manual processing is not needed, the accuracy is high, the flexibility is good, the parameters for processing operation and input can be displayed on a display screen, copying and pasting can be performed, various processing schemes can be saved, and the selection and preferred processing can be performed by a supply and demand party.

Example 4

This embodiment provides a processing system in designing a liquefied gas tank compartment, see fig. 5, comprising:

the receiving module 11, the receiving module 11 is used for receiving the target volume parameter, the end socket type parameter and the second diameter parameter which are input from the outside and are used for designing the liquefied gas tank.

The receiving module 11 receives external input, preferably user input, and the user needs to design the liquefied gas tank, at this time, the user may give an estimated volume, that is, a target volume parameter, and then the user may input the target volume parameter, and then select a seal type parameter required for designing the liquefied gas tank, where the seal type parameter preferably includes a disc seal and a spherical seal in this embodiment, these two seal types are types commonly used in the ship field, and the seal type parameter may be set according to actual needs, and is not limited herein, and after the user inputs the target volume parameter, the user needs to input a second diameter parameter of the liquefied gas tank, that is, a length of the liquefied gas tank, which is desired.

The locking module 12, the locking module 12 is used for receiving the locking instruction input from outside, and locking the second diameter parameter unchanged.

After the user locks the target volume parameter, the seal head type parameter and the second diameter parameter, the second diameter parameter needs to be locked by the locking module 12, and the second diameter parameter cannot be changed, so that the accuracy of the subsequent data processing result can be ensured.

The processing module 13 is used for receiving a second processing instruction input from the outside, and processing the second processing instruction according to a second target formula to obtain a second length parameter for designing the liquefied gas tank.

Under the condition that the target volume parameter, the head type parameter and the second diameter parameter are input, after the processing module 13 receives the first processing instruction, the first target formula is preferably a nonlinear mathematical algorithm according to the first target formula, the second length parameter for designing the liquefied gas tank can be obtained through processing according to the nonlinear mathematical algorithm, the processing process is inverse constraint operation processing, under the condition that the target volume parameter, the first length parameter and the head type parameter are known, the first diameter parameter is obtained through operation processing, if the operation processing process is manually processed, a large amount of labor and time are needed, the manual processing speed is low, the accuracy is not high, a large amount of labor cost and time cost can be saved through the processing method of the embodiment, the accuracy of the processing result can be improved, the parameter change can be responded quickly, the result can be obtained through quick processing, and the scheme multiple selection and the optimization are realized.

The model generation module 14, the model generation module 14 is used for generating a design model of the liquefied gas tank.

The model generation module 14 generates a design model of the liquefied gas tank compartment based on the target volume parameter, the head type parameter, the second diameter parameter, and the second length parameter.

The receiving module 11, the receiving module 11 is further configured to receive input volume ratio parameters for designing the liquefied gas tank, where the volume ratio parameters include a filling rate parameter, a content ratio parameter, and a cargo residual parameter.

The volume ratio parameter is a part of parameters necessary for processing the effective volume of the liquefied gas tank, and may be set to be a constant parameter or may be input externally, and is not limited herein.

The processing module 13, the processing module 13 is configured to receive a third processing instruction, and process the third processing instruction according to a third target formula in combination with the length parameter, the end socket type parameter, the diameter parameter and the volume ratio parameter to obtain an effective volume parameter for designing the liquefied gas tank. The length parameter and the diameter parameter are a second length parameter and a second diameter parameter.

Under the condition that a user inputs the volume ratio parameter, the length parameter, the diameter parameter and the end socket parameter, or after the diameter parameter is obtained by carrying out post-processing on the input target volume parameter, the length parameter and the end socket type parameter, the user triggers a third processing instruction, the effective volume parameter of the designed liquefied gas tank is obtained by a forward constraint operation processing method according to a third target formula, the third target formula is a corresponding mathematical algorithm, the difficulty of the forward constraint operation processing is lower than that of the reverse constraint operation processing, but the manual processing speed is lower, the manual processing is complex and error-prone, the result can be obtained by the rapid and accurate processing through the processing method of the embodiment, and the labor and time cost are saved.

After the processing module 13 processes and computes to obtain the effective volume parameter, the processing system of the embodiment will display the target volume parameter, the end socket type parameter, the second length parameter, the second diameter parameter, the filling rate parameter, the content duty ratio parameter, the cargo residual parameter and the effective volume parameter on the display screen in a pre-selected and set form, and the processing system of the preferred embodiment displays the parameters on the display screen in a list form, so that the parameters are orderly arranged and convenient to view, and the parameters displayed on the display screen can be copied and pasted, and the input conditions of different target parameters, end socket types and second diameter parameters can be processed to obtain different second length parameter schemes for copying and pasting, and the second length parameter schemes are stored in other files for storing, so that the optimal scheme can be selected from a plurality of schemes.

The design diagram generating module 15 is configured to generate a design diagram according to the design model of the liquefied gas tank, where the design diagram is a two-dimensional design diagram or a three-dimensional design diagram.

The preset indication lamp module 16 is used for presetting a second virtual indication lamp, and the preset indication lamp module 16 is used for presetting a second virtual indication lamp.

The pilot lamp control module 17, the pilot lamp control module 17 is further configured to control the second virtual pilot lamp to be turned on when a second length parameter for designing the liquefied gas tank compartment is obtained according to a second target formula.

As shown in fig. 2, a is a virtual indicator lamp, which is turned on when a second length parameter of the designed liquefied gas tank is obtained according to a second target formula, the color of the virtual indicator lamp can be set arbitrarily, and the virtual indicator lamp a can be set beside an operating interface or can cover characters on the interface for prompting. The number of the virtual indicator lamps is not limited herein, and the virtual indicator lamps can be set according to actual needs.

The processing system also comprises a data emptying module, wherein the data emptying module is used for completely emptying data on a system interface and a display screen without deleting parameters on the interface singly; the system also comprises a noun paraphrasing module which is used for displaying noun paraphrasing corresponding to nouns when a mouse is placed on a certain word or word on a system interface, and the nouns are nouns or English related to the liquefied gas tank, so that a user can learn and understand quickly.

According to the processing system of the embodiment, the receiving module 11 is arranged, the receiving module 11 can receive externally input target volume parameters, end socket type parameters and second diameter parameters, then the locking module 12 locks the second diameter parameters unchanged, the processing module 13 receives externally input processing instructions, the second length parameters are obtained through input parameter processing according to a first target formula, the processing process is complex and the workload is large, a large amount of labor can be saved through the processing system, the time cost and the labor cost are saved, the parameters input by a user can be changed randomly, other parameters can be obtained through quick processing according to the changed parameters, and the processing is convenient and free from errors. Under the condition that the target volume parameter, the end socket type parameter, the second length parameter and the second diameter parameter are known, the receiving module 11 receives the volume duty ratio parameter input from the outside, and the processing module 13 processes the effective volume parameter of the liquefied gas tank according to the third target formula after receiving the processing instruction input from the outside. The processing process is quick and ready, different effective volume parameters can be processed according to different length parameters and diameter parameters, and different design models for designing the liquefied gas tank compartment are generated according to the parameters input from the outside and the parameters obtained by processing. The parameters required by processing and designing the liquefied gas tank compartment and the design model for generating and designing the liquefied gas tank compartment are very convenient, a large amount of manual processing is not needed, the accuracy is high, the flexibility is good, the parameters for processing operation and input can be displayed on a display screen, copying and pasting can be performed, various processing schemes can be saved, and the selection and preferred processing can be performed by a supply and demand party.

Example 5

The present embodiment provides an electronic device, as shown in fig. 6, including a memory, a processor, and a computer program stored on the memory and executable on the processor, where the processor executes the computer program to implement the processing method in designing the liquefied gas tank compartment of the foregoing embodiment 1 or embodiment 2. The electronic device 30 shown in fig. 6 is merely an example, and should not be construed as limiting the functionality and scope of use of embodiments of the present invention.

The electronic device 30 may be in the form of a general purpose computing device, which may be a server device, for example. Components of electronic device 30 may include, but are not limited to: the at least one processor 31, the at least one memory 32, a bus 33 connecting the different system components, including the memory 32 and the processor 31.

The bus 33 includes a data bus, an address bus, and a control bus.

Memory 32 may include volatile memory such as Random Access Memory (RAM) 321 and/or cache memory 322, and may further include Read Only Memory (ROM) 323.

Memory 32 may also include a program/utility 325 having a set (at least one) of program modules 324, such program modules 324 including, but not limited to: an operating system, one or more application programs, other program modules, and program data, each or some combination of which may include an implementation of a network environment.

The processor 31 executes various functional applications and data processing such as the processing method in designing the liquefied gas tank compartment of embodiment 1 or embodiment 2 of the present invention by running a computer program stored in the memory 32.

The electronic device 30 may also communicate with one or more external devices 34 (e.g., keyboard, pointing device, etc.). Such communication may be through an input/output (I/O) interface 35. Also, model-generating device 30 may also communicate with one or more networks, such as a Local Area Network (LAN), a Wide Area Network (WAN), and/or a public network, such as the internet, via network adapter 36. As shown, network adapter 36 communicates with the other modules of model-generating device 30 via bus 33. It should be appreciated that although not shown in the figures, other hardware and/or software modules may be used in connection with the model-generating device 30, including, but not limited to: microcode, device drivers, redundant processors, external disk drive arrays, RAID (disk array) systems, tape drives, data backup storage systems, and the like.

It should be noted that although several units/modules or sub-units/modules of an electronic device are mentioned in the above detailed description, such a division is merely exemplary and not mandatory. Indeed, the features and functionality of two or more units/modules described above may be embodied in one unit/module in accordance with embodiments of the present invention. Conversely, the features and functions of one unit/module described above may be further divided into ones that are embodied by a plurality of units/modules.

Example 6

The present embodiment provides a computer-readable medium having stored thereon a computer program which, when executed by a processor, implements the steps of the processing method of the foregoing embodiment 1 or embodiment 2 when designing a liquefied gas tank compartment.

More specifically, among others, readable storage media may be employed including, but not limited to: portable disk, hard disk, random access memory, read only memory, erasable programmable read only memory, optical storage device, magnetic storage device, or any suitable combination of the foregoing.

In a possible embodiment, the invention may also be realized in the form of a program product comprising program code for causing a terminal device to carry out the steps of implementing the processing method of example 1 or example 2 when designing a liquefied gas tank compartment, when said program product is run on the terminal device.

Wherein the program code for carrying out the invention may be written in any combination of one or more programming languages, which program code may execute entirely on the user device, partly on the user device, as a stand-alone software package, partly on the user device and partly on the remote device or entirely on the remote device.

While specific embodiments of the invention have been described above, it will be appreciated by those skilled in the art that this is by way of example only, and the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the principles and spirit of the invention, but such changes and modifications fall within the scope of the invention.

Claims (4)

1. A method of processing in designing a liquefied gas tank compartment, the method comprising the steps of:

receiving externally input target volume parameters, head type parameters and first length parameters for designing a liquefied gas tank;

receiving a locking instruction input from outside, and locking the first length parameter unchanged;

receiving a first processing instruction input from the outside, and processing according to a first target formula to obtain a first diameter parameter for designing the liquefied gas tank;

generating a design model of the liquefied gas tank compartment; or alternatively, the first and second heat exchangers may be,

the processing method comprises the following steps:

receiving an externally input target volume parameter, a head type parameter and a second diameter parameter for designing the liquefied gas tank;

Receiving a locking instruction input from the outside, and locking the second diameter parameter unchanged;

receiving a second processing instruction input from the outside, and processing according to a second target formula to obtain a second length parameter for designing the liquefied gas tank;

generating a design model of the liquefied gas tank compartment;

the step of generating a design model of the liquefied gas tank compartment further comprises:

acquiring volume ratio parameters for designing the liquefied gas tank compartment, wherein the volume ratio parameters comprise filling rate parameters, content ratio parameters and cargo residual parameters;

receiving a third processing instruction, and processing according to a third target formula by combining the length parameter, the end socket type parameter, the diameter parameter and the volume ratio parameter to obtain an effective volume parameter for designing the liquefied gas tank compartment;

the length parameter and the diameter parameter are the first length parameter and the first diameter parameter or the second length parameter and the second diameter parameter;

after the step of generating the design model of the liquefied gas tank compartment, the method further comprises the following steps:

generating a design chart according to the design model of the liquefied gas tank compartment, wherein the design chart is a two-dimensional design chart or a three-dimensional design chart;

The processing method further comprises the following steps:

presetting a first virtual indicator lamp and a second virtual indicator lamp;

controlling the first virtual indicator lamp to be lightened when a first diameter parameter for designing the liquefied gas tank compartment is obtained according to a first target formula;

and controlling the second virtual indicator lamp to be lightened when a second length parameter for designing the liquefied gas tank compartment is obtained according to a second target formula.

2. A processing system in designing a liquefied gas tank compartment, the processing system comprising:

the receiving module is used for receiving an externally input target volume parameter, a seal head type parameter and a first length parameter for designing the liquefied gas tank;

the locking module is used for receiving an externally input locking instruction and locking the first length parameter;

the processing module is used for receiving a first processing instruction input from the outside, and processing the first processing instruction according to a first target formula to obtain a first diameter parameter for designing the liquefied gas tank compartment;

the model generation module is used for generating a design model of the liquefied gas tank; or alternatively, the first and second heat exchangers may be,

the processing system comprises the following steps:

the receiving module is used for receiving an externally input target volume parameter, a seal head type parameter and a second diameter parameter for designing the liquefied gas tank;

The locking module is used for receiving an externally input locking instruction and locking the second diameter parameter;

the processing module is used for receiving a second processing instruction input from the outside, and processing the second processing instruction according to a second target formula to obtain a second length parameter for designing the liquefied gas tank compartment;

the model generation module is used for generating a design model of the liquefied gas tank;

the receiving module is also used for obtaining volume ratio parameters for designing the liquefied gas tank, wherein the volume ratio parameters comprise filling rate parameters, content ratio parameters and cargo residual parameters;

the processing module is also used for receiving a third processing instruction, and processing according to a third target formula and combining the length parameter, the end socket type parameter, the diameter parameter and the volume ratio parameter to obtain an effective volume parameter for designing the liquefied gas tank;

the length parameter and the diameter parameter are the first length parameter and the first diameter parameter or the second length parameter and the second diameter parameter;

the processing system further includes:

the design diagram generation module is used for generating a design diagram according to the design model of the liquefied gas tank compartment, wherein the design diagram is a two-dimensional design diagram or a three-dimensional design diagram;

The processing system further includes:

the preset indicator lamp module is used for presetting a first virtual indicator lamp and a second virtual indicator lamp;

the indicator light control module is used for controlling the first virtual indicator light to be lightened when a first diameter parameter for designing the liquefied gas tank compartment is obtained according to a first target formula;

the indicator light control module is also used for controlling the second virtual indicator light to be lightened when a second length parameter for designing the liquefied gas tank compartment is obtained according to a second target formula.

3. An electronic device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, characterized in that the processor implements the method of processing in designing a liquefied gas tank compartment according to claim 1 when executing the computer program.

4. A computer-readable medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, implements the method of processing in designing a liquefied gas tank compartment as claimed in claim 1.