CN110489868A - Heat exchanger multi-pass pipe emulation modelling method, device, system and computer equipment - Google Patents

Abstract

This application involves a kind of heat exchanger multi-pass pipe emulation modelling method, device, system and computer equipments.The described method includes: obtaining operational order, multi-pass pipe submodel is generated in Heat-Exchanger Simulation figure layer according to operational order；Multi-pass pipe submodel is used for the target pore information that is associated in Heat-Exchanger Simulation figure layer, and target pore information is the pore information of ipsilateral pore corresponding to the multiple-way duct that need to be connected to；Multi-pass pipe submodel is parsed, generates the underlying model call instruction comprising pore information, and underlying model call instruction is transferred to Modeling Server；Underlying model call instruction is used to indicate Modeling Server and calls corresponding multi-pass tube bottom layer model；Multi-pass tube bottom layer model in heat exchanger underlying model for being connected to the corresponding pipeline of each pore information, the application is conveniently and efficiently connected to multiple-way duct by creating easily operated and intuitive multi-pass pipe submodel, realization on the two-dimensional surface of Heat-Exchanger Simulation figure layer in simulation modeling.

Description

Heat exchanger multi-pass pipe emulation modelling method, device, system and computer equipment

Technical field

This application involves air-conditioning technical fields, more particularly to a kind of heat exchanger multi-pass pipe emulation modelling method, device, are System and computer equipment.

Background technique

In recent ten years, CAD, computer-aided manufacturing and computer-aided engineering are answered manufacturing With efficiency increasingly wider, that these softwares improve manufacturing production to a certain extent and design.In air conditioner industry, air-conditioning More core is the modeling of heat exchanger connecting leg in simulation software, and the pipeline of the heat exchanger generally emulated can reach rows up to a hundred even more It is more, wherein the connecting leg of multiple-way duct is key points and difficulties in Heat-Exchanger Simulation modeling, and during realization, inventor has found to pass At least there are the following problems in system technology: can not conveniently and efficiently be connected to multiple-way duct in traditional technology in simulation modeling.

Summary of the invention

Based on this, it is necessary to which in view of the above technical problems, Multipath tube can be fast connected in simulation modeling by providing one kind Heat exchanger multi-pass pipe emulation modelling method, device, system and the computer equipment in road.

A kind of heat exchanger multi-pass pipe emulation modelling method, comprising the following steps:

Operational order is obtained, multi-pass pipe submodel is generated in Heat-Exchanger Simulation figure layer according to operational order；Multi-pass pipe Submodel is used for the target pore information being associated in Heat-Exchanger Simulation figure layer, and target pore information is the multiple-way duct that need to be connected to The pore information of corresponding ipsilateral pore；

Parse multi-pass pipe submodel, generate include pore information underlying model call instruction, and by underlying model tune Modeling Server is transferred to instruction；Underlying model call instruction is used to indicate Modeling Server and calls corresponding multi-pass tube bottom layer Model；Multi-pass tube bottom layer model in heat exchanger underlying model for being connected to the corresponding pipeline of each pore information.

Operational order includes submodel creation instruction and pore associated instructions in one of the embodiments,；

The step of obtaining operational order, generating multi-pass pipe submodel in Heat-Exchanger Simulation figure layer according to operational order, Include:

Submodel creation instruction is obtained, is generated in Heat-Exchanger Simulation figure layer according to submodel creation instruction initial auxiliary Help model；

Pore associated instructions are obtained, initial submodel is carried out according to the corresponding target pore information of pore associated instructions It updates, generates multi-pass pipe submodel.

Submodel creation instruction includes that the first pore selection instruction and the creation of multi-pass pipe refer in one of the embodiments, It enables；

Submodel creation instruction is obtained, is generated in Heat-Exchanger Simulation figure layer according to submodel creation instruction initial auxiliary The step of helping model, comprising:

It obtains the first pore and chooses instruction, the first pore in the ipsilateral pore of confirmation command is chosen according to the first pore；

The creation instruction of multi-pass pipe is obtained, the pore information for being associated with the first pore is generated according to the creation instruction of multi-pass pipe Initial submodel.

Pore associated instructions include that at least two pores choose instruction in one of the embodiments,；

Pore associated instructions are obtained, initial submodel is carried out according to the corresponding target pore information of pore associated instructions The step of updating, generating multi-pass pipe submodel, comprising:

It obtains the second pore and chooses instruction, the second pore in the ipsilateral pore of confirmation command is chosen according to the second pore, and Initial submodel is updated according to the pore information of the second pore, generates the second sub- submodel；

It obtains third pore and chooses instruction, the third pore in the ipsilateral pore of confirmation command is chosen according to third pore, and The second sub- submodel is updated according to the pore information of third pore, generates the sub- submodel of third；Until generating more Siphunculus submodel.

The creation instruction of multi-pass pipe is obtained in one of the embodiments, and instruction is created according to multi-pass pipe and is generated for being associated with In the step of initial submodel of the pore information of first pore:

Initial submodel is generated according to white space of the position selection instruction near the first pore.

Multi-pass pipe submodel is rectangular model in one of the embodiments,；

It obtains the second pore and chooses instruction, the second pore in the ipsilateral pore of confirmation command is chosen according to the second pore, and In the step of being updated according to the pore information of the second pore to initial submodel, generating the second sub- submodel:

The second pore of confirmation command is chosen according to the second pore, the first sub- rectangular model is extended into the second pore, and root The first sub- rectangular model is updated according to the pore information of the second pore, generates the second sub- rectangular model.

Third pore is obtained in one of the embodiments, and chooses instruction, and it is ipsilateral to choose confirmation command according to third pore Third pore in pore, and the second sub- submodel is updated according to the pore information of third pore, generate third Submodel；Until in the step of generating multi-pass pipe submodel:

Confirmation command third pore is chosen according to third pore, if third pore is distributed in the one of the second sub- rectangular model Side is then updated the second sub- submodel according to the pore information of third pore, generates the sub- submodel of third；Or, if Third pore is distributed in the extending direction of the second sub- rectangular model, then prolongs the second sub- rectangular model to the direction of third pore It stretches, and the second sub- submodel is updated according to the pore information of third pore, generate the sub- submodel of third.

Pore information includes pore serial number and pore attribute in one of the embodiments,.

Multi-pass pipe submodel is in the region that each ipsilateral pore surrounds in one of the embodiments,.

A kind of heat exchanger multi-pass pipe simulation modeling device, comprising:

Model creation module generates multi-pass in Heat-Exchanger Simulation figure layer according to operational order for obtaining operational order Pipe submodel；Multi-pass pipe submodel is used for the target pore information being associated in Heat-Exchanger Simulation figure layer, target pore information For the pore information of ipsilateral pore corresponding to the multiple-way duct that need to be connected to；

Parsing module, for parsing multi-pass pipe submodel, generation includes the underlying model call instruction of pore information, and Underlying model call instruction is transferred to Modeling Server；Underlying model call instruction is used to indicate Modeling Server and calls correspondence Multi-pass tube bottom layer model；Multi-pass tube bottom layer model in heat exchanger underlying model for being connected to the corresponding pipe of each pore information Road.

A kind of computer equipment, including memory and processor, memory are stored with computer program, and processor executes meter The step of above method is realized when calculation machine program.

A kind of heat exchanger multi-pass pipe simulation modeling system further includes that connection computer is set including above-mentioned computer equipment Standby Modeling Server.

Modeling Server is Amesim server in one of the embodiments,.

A kind of computer readable storage medium is stored thereon with computer program, when computer program is executed by processor The step of realizing the above method.

A technical solution in above-mentioned technical proposal is had the following advantages and beneficial effects:

In Heat-Exchanger Simulation figure layer, receives operational order and generate multi-pass pipe submodel, multi-pass pipe submodel is used for The target pore information being associated in Heat-Exchanger Simulation figure layer, target pore information are ipsilateral corresponding to the multiple-way duct that need to be connected to The pore information of pore, parsing multi-pass pipe submodel generate include pore information underlying model call instruction, and by bottom Model call instruction is transferred to Modeling Server, to indicate that Modeling Server calls corresponding multi-pass tube bottom layer model, modeling clothes Business device is connected to the corresponding pipeline of each pore information by multi-pass tube bottom layer model in heat exchanger underlying model, the application by Easily operated and intuitive multi-pass pipe submodel is created on the two-dimensional surface of Heat-Exchanger Simulation figure layer, then assists multi-pass pipe Model analyzing is the instruction that can be used for the corresponding multi-pass tube bottom layer model of control model server calls, is realized through multi-pass pipe Submodel assists establishing multi-pass tube bottom layer model, avoid directly operating on Modeling Server and caused by it is cumbersome Problem, so as to conveniently and efficiently be connected to multiple-way duct in simulation modeling.

Detailed description of the invention

Fig. 1 is the applied environment figure of heat exchanger multi-pass pipe emulation modelling method in one embodiment；

Fig. 2 is the flow diagram of heat exchanger multi-pass pipe emulation modelling method in one embodiment；

Fig. 3 is the schematic diagram of Heat-Exchanger Simulation figure layer in one embodiment；

Fig. 4 is the flow diagram that multichannel submodel step is generated in one embodiment；

Fig. 5 is the flow diagram that initial submodel step is generated in one embodiment；

Fig. 6 is the flow diagram of pore information association step in one embodiment；

Fig. 7 is the schematic diagram of the Heat-Exchanger Simulation figure layer in one embodiment after connecting leg；

Fig. 8 is the structural block diagram of heat exchanger multi-pass pipe simulation modeling device in one embodiment；

Fig. 9 is the internal structure chart of computer equipment in one embodiment.

Specific embodiment

It is with reference to the accompanying drawings and embodiments, right in order to which the objects, technical solutions and advantages of the application are more clearly understood The application is further elaborated.It should be appreciated that specific embodiment described herein is only used to explain the application, not For limiting the application.

Heat exchanger multi-pass pipe emulation modelling method provided by the present application, can be applied in application environment as shown in Figure 1. Wherein, terminal 102 is communicated with Modeling Server 104 by network by network.Wherein, terminal 102 can be, but not limited to It is various personal computers, laptop and tablet computer, server 104 can use independent server either multiple clothes The server cluster of business device composition is realized.

In one embodiment, as shown in Fig. 2, providing a kind of heat exchanger multi-pass pipe emulation modelling method, in this way Applied to being illustrated for the terminal in Fig. 1, comprising the following steps:

Step S210 obtains operational order, generates multi-pass pipe auxiliary mould in Heat-Exchanger Simulation figure layer according to operational order Type；Multi-pass pipe submodel is used for the target pore information being associated in Heat-Exchanger Simulation figure layer, and target pore information is to need to be connected to Multiple-way duct corresponding to ipsilateral pore pore information.

It should be noted that the terminal is equipped with air-conditioning system simulation software, air-conditioning system simulation software can be used as with The interactive interface that Modeling Server interacts, air-conditioning system simulation software can be used for establishing the two-dimensional model of air-conditioning, this Application heat exchanger multi-pass pipe emulation modelling method is built upon the basis that air-conditioning system simulation software establishes air-conditioning heat exchanger function On.Heat-Exchanger Simulation figure layer is the two-dimensional model for the air-conditioning heat exchanger established using air-conditioning system simulation software, such as Fig. 3 institute State, by heat exchanger project two dimension modeling plane on, by two dimension model plane on pore indicate heat exchanger pipeline and Pipeline puts in order.

The operational order for receiving extraneous input, generates multi-pass pipe submodel in Heat-Exchanger Simulation figure layer.Show at one In example, operational order is the instruction of mouse input, i.e., the object needed for being chosen using cursor completes building for multi-pass pipe submodel It is vertical.In yet another example, operational order is the shortcut command of keyboard input, i.e., chooses institute using the shortcut command of keyboard input The object needed completes the foundation of multi-pass pipe submodel.In another example, operational order is the instruction of touch-screen input, i.e., sharp Object needed for being chosen with the shortcut command of touch-screen input completes the foundation of multi-pass pipe submodel.

In one embodiment, operational order includes submodel creation instruction and pore associated instructions.

It should be noted that submodel creation instruction is used to indicate starting and generates multi-pass pipe submodel program, one In a example, merging is auxiliary for starting generation multi-pass pipe on the interface that air-conditioning system simulation software establishes heat exchanger tube simulation model The option for helping model program immediately enters when the option is triggered and generates multi-pass pipe submodel program, starts to generate multi-pass Pipe submodel.In another example, multi-pass pipe creation instruction is write-in air-conditioning system simulation software character Command, the character Order association generation multi-pass pipe submodel program, receive the character Command of extraneous input in air-conditioning system simulation software When, it immediately enters and generates multi-pass pipe submodel program.

Pore associated instructions are assisted for choosing ipsilateral pore, and by the pore information of the ipsilateral pore of selection and multi-pass pipe Model is associated.

Based on the above-mentioned description as described in operational order, in one example, as shown in figure 4, operational order is obtained, according to behaviour Instruct the step of multi-pass pipe submodel is generated in Heat-Exchanger Simulation figure layer, comprising:

Step 410, submodel creation instruction is obtained, it is raw in Heat-Exchanger Simulation figure layer according to submodel creation instruction At initial submodel.

It should be noted that the edit format of submodel creation instruction can be varied, now provide in one example A kind of feasible mode, but it is not limited to this kind of mode, submodel creation instruction includes that the first pore chooses instruction and multi-pass Pipe creation instruction.It should be noted that the creation instruction of multi-pass pipe is used to indicate starting and generates multi-pass pipe submodel program, one In a example, merging is auxiliary for starting generation multi-pass pipe on the interface that air-conditioning system simulation software establishes heat exchanger tube simulation model The option for helping model program immediately enters when the option is triggered and generates multi-pass pipe submodel program, starts to generate multi-pass Pipe submodel.In another example, multi-pass pipe creation instruction is write-in air-conditioning system simulation software character Command, the character Order association generation multi-pass pipe submodel program, receive the character Command of extraneous input in air-conditioning system simulation software When, it immediately enters and generates multi-pass pipe submodel program.

Pore chooses instruction for choosing the ipsilateral pore for each pipeline for needing to create multi-pass pipe, in one example, manages Choose the instruction that instruction is mouse input in hole.In yet another example, pore chooses the shortcut command that instruction is keyboard input.

Based on the above-mentioned description as described in submodel creation instruction, in one example, as shown in figure 5, obtaining auxiliary mould Type creation instruction instructs the step of generating initial submodel in Heat-Exchanger Simulation figure layer according to submodel creation, comprising:

Step 510, it obtains the first pore and chooses instruction, first in the ipsilateral pore of confirmation command is chosen according to the first pore Pore.

It should be noted that the first pore can arbitrarily be chosen, it can also choose regularly, for example, being emulated in air-conditioning system The operator that meets of software watches on the display interface of habit, one for choosing the top in multiple ipsilateral pores to be connected to Pore, or a pore of bottom in multiple ipsilateral pores to be connected to is chosen, or choose multiple ipsilateral pores to be connected to One pore of middle rightmost, or choose a pore of leftmost in multiple ipsilateral pores to be connected to.

Step 520, the creation instruction of multi-pass pipe is obtained, the pipe for instructing and generating for being associated with the first pore is created according to multi-pass pipe The initial submodel of hole information.

It should be noted that after choosing to the first pore, according to the multi-pass pipe creation instruction got, immediately first The sub- multi-pass pipe submodel of Area generation first of pore attachment.In one example, the creation instruction of multi-pass pipe is obtained, according to more In the step of siphunculus creation instruction generates the initial submodel for the pore information for being associated with the first pore: being selected according to position The white space near the first pore is instructed to generate initial submodel.It should be noted that in this example, triggering starting Generating multi-pass pipe submodel program is composition operation, i.e., a pore need to be first selected, then in the blank area of the pore attachment A model initial position is chosen in domain, and just triggering starting generates multi-pass pipe submodel program.

Step 420, pore associated instructions are obtained, according to the corresponding target pore information of pore associated instructions to initial auxiliary Model is updated, and generates multi-pass pipe submodel.

It should be noted that the edit format of pore associated instructions is varied, now providing one kind in one example can Row but the mode for being not limited to this kind, pore associated instructions include that at least two pores choose instruction；

Based on the above-mentioned description as described in pore chooses instruction, in one example, refer to as shown in fig. 6, obtaining pore association It enables, initial submodel is updated according to the corresponding target pore information of pore associated instructions, generate multi-pass pipe and assist mould The step of type, comprising:

Step S610, obtains the second pore and chooses instruction, chooses the in the ipsilateral pore of confirmation command according to the second pore Two pores, and initial submodel is updated according to the pore information of the second pore, generate the second sub- submodel；

Step S620, obtains third pore and chooses instruction, chooses the in the ipsilateral pore of confirmation command according to third pore Three pores, and the second sub- submodel is updated according to the pore information of third pore, generate the sub- submodel of third；

Step S630, until generating multi-pass pipe submodel.

It should be noted that successively choosing instruction selection generating initial submodel according to the pore got and corresponding to Ipsilateral pore, according to the sequence of selection by the corresponding pore information of ipsilateral pore to last sub- multi-pass pipe submodel, directly To generation multi-pass pipe submodel.

Multi-pass pipe submodel is used to be associated in Heat-Exchanger Simulation figure layer the ipsilateral pore for needing to establish the multiple-way duct being connected to Pore information, in the operation interface of air-conditioning system simulation software, multi-pass pipe submodel is shown as figure, the figure and each Connection is generated between ipsilateral pore respectively.In the program layer of air-conditioning system simulation software, multi-pass pipe submodel captures pipe Hole information, and indicate to establish corresponding multi-pass pipe between the pipeline that multichannel need to be connected to.

The display form of multi-pass pipe submodel can be varied, and one of which described below is feasible but is not limited to this kind Mode, in one embodiment, multi-pass pipe submodel be rectangular model；

Multi-pass pipe submodel form not will cause the concrete operations difference for establishing multi-pass pipe submodel simultaneously, but generate The principle of multi-pass pipe submodel is identical, when multi-pass pipe submodel is rectangular model, in one example, obtains the second pipe Instruction is chosen in hole, chooses the second pore in the ipsilateral pore of confirmation command according to the second pore, and according to the pore of the second pore In the step of information is updated initial submodel, generates the second sub- submodel:

The second pore of confirmation command is chosen according to the second pore, the first sub- rectangular model is extended into the second pore, and root The first sub- rectangular model is updated according to the pore information of the second pore, generates the second sub- rectangular model.

It should be noted that the size that the first sub- rectangular model is shown in operation interface is small, choosing to the second pore When, the size that the first sub- rectangular model is shown in operation interface can become larger, and be embodied in first the second pore and extend.

Further, it obtains third pore and chooses instruction, the in the ipsilateral pore of confirmation command is chosen according to third pore Three pores, and the second sub- submodel is updated according to the pore information of third pore, generate the sub- submodel of third；Directly Into the step of generating multi-pass pipe submodel:

Confirmation command third pore is chosen according to third pore, if third pore is distributed in the one of the second sub- rectangular model Side is then updated the second sub- submodel according to the pore information of third pore, generates the sub- submodel of third；Or, if Third pore is distributed in the extending direction of the second sub- rectangular model, then prolongs the second sub- rectangular model to the direction of third pore It stretches, and the second sub- submodel is updated according to the pore information of third pore, generate the sub- submodel of third.

Pore information is the pipeline that air-conditioning system simulation software uses it to that identification need to be connected to, in one embodiment, pore Information includes pore serial number and pore attribute.When creating Heat-Exchanger Simulation figure layer, air-conditioning system simulation software heat exchanging device is imitative The pore shown in true figure layer is numbered, and pore serial number is the number that air-conditioning system simulation software carries out pore.It is changing The pore shown in hot device emulation figure layer, can regard a root canal road as in the projection of operation interface, therefore in Heat-Exchanger Simulation figure layer The pore of display represents the both ends in a root canal road, and pore attribute is the end on observation from pipeline, and the front end or rear end of pipeline can also It is interpreted as in heat exchanger one end, the end on observation of Xiang Guandao, the front or the back side of heat exchanger.In another example, pore is believed Breath may also include pore refrigerant flow direction.Pore refrigerant flow direction refers to that refrigerant is flowed into or flowed out from the pore.

In order to enable Heat-Exchanger Simulation figure layer is shown neatly, checked convenient for operator, in one embodiment multi-pass pipe Submodel is in Heat-Exchanger Simulation figure layer in the region that each ipsilateral pore surrounds.

Step S220, parsing multi-pass pipe submodel generate include pore information underlying model call instruction, and the bottom of by Layer model call instruction is transferred to Modeling Server；It is corresponding more that underlying model call instruction is used to indicate Modeling Server calling Siphunculus underlying model；Multi-pass tube bottom layer model in heat exchanger underlying model for being connected to the corresponding pipeline of each pore information.

It should be noted that parsing multi-pass pipe submodel, generates the underlying model call instruction comprising pore information, and Underlying model call instruction is transferred to Modeling Server；Underlying model call instruction is used to indicate Modeling Server and calls correspondence Multi-pass tube bottom layer model；Multi-pass tube bottom layer model in heat exchanger underlying model for being connected to the corresponding pipe of each pore information Road.

Modeling Server calls corresponding more after getting underlying model call instruction according to underlying model call instruction Siphunculus underlying model, and utilize pipeline as defined in multi-pass tube bottom layer model connection pore information.

The above-mentioned simulation modeling process for merely illustrating multi-pass pipe is only during creating heat exchanger connecting leg simulation model A part, creation heat exchanger connecting leg simulation model process further includes the connection of two-way pipeline, the connection of pipeline and liquid-dividing head, pipeline With the connection of gas collecting tube, this three kinds connection operations can refer to traditional technology, and the application is not described in detail, and to be introduced in the application After the creation for completing multi-pass pipe, how to restore to the connection of two-way pipeline, be illustrated for having created after tee tube, In After generating rectangular model, confirmation command third pore is chosen again according to third pore；It receives the 4th pore and chooses instruction, according to 4th pore chooses the 4th pore of confirmation command Heat-Exchanger Simulation figure layer, establishes single-stranded between third pore and the 4th pore Connection association.

It is more to receive operational order generation in Heat-Exchanger Simulation figure layer for the application heat exchanger multi-pass pipe emulation modelling method Siphunculus submodel, multi-pass pipe submodel are used for the target pore information being associated in Heat-Exchanger Simulation figure layer, target pore letter Breath is the pore information of ipsilateral pore corresponding to the multiple-way duct that need to be connected to, and it includes pore that parsing multi-pass pipe submodel, which generates, The underlying model call instruction of information, and underlying model call instruction is transferred to Modeling Server, to indicate Modeling Server Corresponding multi-pass tube bottom layer model is called, Modeling Server is connected to respectively by multi-pass tube bottom layer model in heat exchanger underlying model The corresponding pipeline of pore information, the application are easily operated and intuitive by creating on the two-dimensional surface of Heat-Exchanger Simulation figure layer Multi-pass pipe submodel, then resolving to multi-pass pipe submodel can be used for the corresponding multi-pass pipe of control model server calls The instruction of underlying model realizes through multi-pass pipe submodel and assists establishing multi-pass tube bottom layer model, avoids directly building Operated on mould server and caused by cumbersome problem, so as to conveniently and efficiently be connected to Multipath tube in simulation modeling Road.

The application heat exchanger multi-pass pipe emulation modelling method in order to better understand, it is now imitative with heat exchanger shown in Fig. 3 Tee tube is created in true figure layer, and realizes and the application is illustrated for the connecting leg of completion:

It is built being established between tee tube and serial number 7,8 and 9 pipeline between serial number 1,2 and 3 pipeline in Fig. 3 Vertical tee tube, remaining pipes establish single-link connection, one of operating procedure are as follows:

The upside liquid-dividing head in Heat-Exchanger Simulation model is chosen, No. 2 pores are then chosen, establishes upside liquid-dividing head and No. 2 The front connection (as shown on the solid line in figure 3) of pore, successively chooses No. 2 pores and No. 1 pore, establishes No. 2 pores and No. 1 pore The back side be connected to (as shown by the dotted line in fig. 3), successively choose No. 1 pore and gas collecting tube, establishing No. 1 pore and gas collecting tube just Face connection is connected to the single-link of gas collecting tube to No. 1 pore to establish from upside liquid-dividing head to No. 2 pores again again；

Downside liquid-dividing head is chosen, No. 4 pores are then chosen, downside liquid-dividing head is established and is connected to the front of No. 4 pores, then select 6 are taken, No. 4 pores is established and is connected to the back side of No. 6 pores；

Establish front tee tube between 6,7 and No. 8 pores, choose No. 6 pores, choose No. 5 pores and No. 6 pores it Between white space, generate initial rectangular model, then choose No. 8 pores, initial rectangular model extends to No. 8 pore directions Between No. 7 pores and No. 8 pores, No. 8 pores are connected to the initial rectangular model after extending, and are then being chosen No. 7 pores, are being established The connection of initial rectangular model after No. 7 pores and extension, to establish the front tee tube square of 6,7 and No. 8 pores of association Then shape model successively chooses No. 8 pores, No. 10 pores, No. 9 pores and gas collecting tube, establishes No. 8 pores, No. 10 pores, 9 The connection of the single-link of number pore and gas collecting tube (is connected between No. 8 pores and No. 10 pores for the back side, No. 10 pores and No. 9 pores For front connection, No. 9 pores are that the back side is connected to gas collecting tube), No. 7 pores, No. 5 pores and No. 3 pores are then successively chosen, are built (No. 7 pores are connected to No. 5 pores for the back side, No. 5 pores and No. 3 for vertical No. 7 pores, No. 5 pores and No. 3 pore single-links connections Pore front)；

The back side tee tube between No. 1 pore, No. 2 pores and No. 3 pores is established, No. 3 pores are chosen, is choosing No. 3 pipes White space between hole and No. 4 pores, establishes initial rectangular module, then chooses No. 1 pore, initial rectangular model is to No. 1 Pore direction extends between No. 1 pore and No. 2 pores, and No. 1 pore is connected to the initial rectangular model after extending, and is then selecting No. 2 pores are taken, the connection of the initial rectangular model after establishing No. 2 pores and extending, to establish 1,2 and No. 3 pore of association Back side tee tube rectangular model

Finally the Heat-Exchanger Simulation figure layer (as shown in Figure 7) that the step is connected to is parsed, the knot after parsing Fruit is transferred to Modeling Server, so that Modeling Server generates heat exchanger underlying model.

It should be understood that although each step in the flow chart of Fig. 1,3-6 is successively shown according to the instruction of arrow, It is these steps is not that the inevitable sequence according to arrow instruction successively executes.Unless expressly stating otherwise herein, these steps There is no stringent sequences to limit for rapid execution, these steps can execute in other order.Moreover, in Fig. 1,3-6 extremely Few a part of step may include that perhaps these sub-steps of multiple stages or stage are not necessarily same to multiple sub-steps Moment executes completion, but can execute at different times, and the execution sequence in these sub-steps or stage is also not necessarily It successively carries out, but in turn or can be handed over at least part of the sub-step or stage of other steps or other steps Alternately execute.

In one embodiment, as shown in figure 8, providing a kind of heat exchanger multi-pass pipe simulation modeling device, comprising:

Model creation module 81 generates in Heat-Exchanger Simulation figure layer more for obtaining operational order according to operational order Siphunculus submodel；Multi-pass pipe submodel is used for the target pore information being associated in Heat-Exchanger Simulation figure layer, target pore letter Breath for ipsilateral pore corresponding to the multiple-way duct that need to be connected to pore information；

Parsing module 83, for parsing multi-pass pipe submodel, generation includes the underlying model call instruction of pore information, And underlying model call instruction is transferred to Modeling Server；Underlying model call instruction is used to indicate Modeling Server calling pair The multi-pass tube bottom layer model answered；Multi-pass tube bottom layer model in heat exchanger underlying model for being connected to the corresponding pipe of each pore information Road.

Specific restriction about heat exchanger multi-pass pipe simulation modeling device may refer to above for heat exchanger multi-pass pipe The restriction of emulation modelling method, details are not described herein.Modules in above-mentioned heat exchanger multi-pass pipe simulation modeling device can be complete Portion or part are realized by software, hardware and combinations thereof.Above-mentioned each module can be embedded in the form of hardware or independently of calculating In processor in machine equipment, it can also be stored in a software form in the memory in computer equipment, in order to processor It calls and executes the corresponding operation of the above modules.

In one embodiment, a kind of computer equipment is provided, which can be terminal, internal structure Figure can be as shown in Figure 8.The computer equipment includes processor, the memory, network interface, display connected by system bus Screen and input unit.Wherein, the processor of the computer equipment is for providing calculating and control ability.The computer equipment is deposited Reservoir includes non-volatile memory medium, built-in storage.The non-volatile memory medium is stored with operating system and computer journey Sequence.The built-in storage provides environment for the operation of operating system and computer program in non-volatile memory medium.The calculating The network interface of machine equipment is used to communicate with external terminal by network connection.When the computer program is executed by processor with Realize a kind of heat exchanger multi-pass pipe emulation modelling method.The display screen of the computer equipment can be liquid crystal display or electronics Ink display screen, the input unit of the computer equipment can be the touch layer covered on display screen, are also possible to computer and set Key, trace ball or the Trackpad being arranged on standby shell, can also be external keyboard, Trackpad or mouse etc..

In one embodiment, a kind of heat exchanger multi-pass pipe simulation modeling system is provided, is set including above-mentioned computer It is standby, it further include the Modeling Server for connecting computer equipment.In one example, Modeling Server is Amesim server.

It will be understood by those skilled in the art that structure shown in Fig. 8, only part relevant to application scheme is tied The block diagram of structure does not constitute the restriction for the computer equipment being applied thereon to application scheme, specific computer equipment It may include perhaps combining certain components or with different component layouts than more or fewer components as shown in the figure.

In one embodiment, a kind of computer equipment, including memory and processor are provided, is stored in memory Computer program, the processor perform the steps of when executing computer program

Operational order is obtained, multi-pass pipe submodel is generated in Heat-Exchanger Simulation figure layer according to operational order；Multi-pass pipe Submodel is used for the target pore information being associated in Heat-Exchanger Simulation figure layer, and target pore information is the multiple-way duct that need to be connected to The pore information of corresponding ipsilateral pore；

Parse multi-pass pipe submodel, generate include pore information underlying model call instruction, and by underlying model tune Modeling Server is transferred to instruction；Underlying model call instruction is used to indicate Modeling Server and calls corresponding multi-pass tube bottom layer Model；Multi-pass tube bottom layer model in heat exchanger underlying model for being connected to the corresponding pipeline of each pore information.

In one embodiment, a kind of computer readable storage medium is provided, computer program is stored thereon with, is calculated Machine program performs the steps of when being executed by processor

Operational order is obtained, multi-pass pipe submodel is generated in Heat-Exchanger Simulation figure layer according to operational order；Multi-pass pipe Submodel is used for the target pore information being associated in Heat-Exchanger Simulation figure layer, and target pore information is the multiple-way duct that need to be connected to The pore information of corresponding ipsilateral pore；

Parse multi-pass pipe submodel, generate include pore information underlying model call instruction, and by underlying model tune Modeling Server is transferred to instruction；Underlying model call instruction is used to indicate Modeling Server and calls corresponding multi-pass tube bottom layer Model；Multi-pass tube bottom layer model in heat exchanger underlying model for being connected to the corresponding pipeline of each pore information.

Those of ordinary skill in the art will appreciate that realizing all or part of the process in above-described embodiment method, being can be with Relevant hardware is instructed to complete by computer program, the computer program can be stored in a non-volatile computer In read/write memory medium, the computer program is when being executed, it may include such as the process of the embodiment of above-mentioned each method.Wherein, To any reference of memory, storage, database or other media used in each embodiment provided herein, Including non-volatile and/or volatile memory.Nonvolatile memory may include read-only memory (ROM), programming ROM (PROM), electrically programmable ROM (EPROM), electrically erasable ROM (EEPROM) or flash memory.Volatile memory may include Random access memory (RAM) or external cache.By way of illustration and not limitation, RAM is available in many forms, Such as static state RAM (SRAM), dynamic ram (DRAM), synchronous dram (SDRAM), double data rate sdram (DDRSDRAM), enhancing Type SDRAM (ESDRAM), synchronization link (Synchlink) DRAM (SLDRAM), memory bus (Rambus) direct RAM (RDRAM), direct memory bus dynamic ram (DRDRAM) and memory bus dynamic ram (RDRAM) etc..

Each technical characteristic of above embodiments can be combined arbitrarily, for simplicity of description, not to above-described embodiment In each technical characteristic it is all possible combination be all described, as long as however, the combination of these technical characteristics be not present lance Shield all should be considered as described in this specification.

The several embodiments of the application above described embodiment only expresses, the description thereof is more specific and detailed, but simultaneously The limitation to claim therefore cannot be interpreted as.It should be pointed out that coming for those of ordinary skill in the art It says, without departing from the concept of this application, various modifications and improvements can be made, these belong to the protection of the application Range.Therefore, the scope of protection shall be subject to the appended claims for the application patent.

Claims (14)

1. a kind of heat exchanger multi-pass pipe emulation modelling method, which comprises the following steps:

Operational order is obtained, multi-pass pipe submodel is generated in Heat-Exchanger Simulation figure layer according to the operational order；It is described more Siphunculus submodel is used for the target pore information being associated in the Heat-Exchanger Simulation figure layer, and the target pore information is the company of need The pore information of ipsilateral pore corresponding to logical multiple-way duct；

Parse the multi-pass pipe submodel, generate include the pore information underlying model call instruction, and by the bottom Layer model call instruction is transferred to Modeling Server；The underlying model call instruction is used to indicate the Modeling Server and calls Corresponding multi-pass tube bottom layer model；The multi-pass tube bottom layer model in heat exchanger underlying model for being connected to each pore letter Cease corresponding pipeline.

2. heat exchanger multi-pass pipe emulation modelling method according to claim 1, which is characterized in that the operational order includes Submodel creation instruction and pore associated instructions；

The step of obtaining operational order, generating multi-pass pipe submodel in Heat-Exchanger Simulation figure layer according to the operational order, Include:

The submodel creation instruction is obtained, it is raw in the Heat-Exchanger Simulation figure layer according to submodel creation instruction At initial submodel；

The pore associated instructions are obtained, according to the corresponding target pore information of the pore associated instructions to described initial Submodel is updated, and generates the multi-pass pipe submodel.

3. heat exchanger multi-pass pipe emulation modelling method according to claim 2, which is characterized in that the submodel creation Instruction includes that the first pore chooses instruction and the creation instruction of multi-pass pipe；

The submodel creation instruction is obtained, it is raw in the Heat-Exchanger Simulation figure layer according to submodel creation instruction The step of at initial submodel, comprising:

It obtains first pore and chooses instruction, according to first in ipsilateral pore described in first pore selection confirmation command Pore；

The multi-pass pipe creation instruction is obtained, the pipe for being associated with first pore is generated according to multi-pass pipe creation instruction The initial submodel of hole information.

4. heat exchanger multi-pass pipe emulation modelling method according to claim 3, which is characterized in that the pore associated instructions It chooses and instructs including at least two pores；

The pore associated instructions are obtained, according to the corresponding target pore information of the pore associated instructions to described initial The step of submodel is updated, and generates the multi-pass pipe submodel, comprising:

It obtains the second pore and chooses instruction, according to the second pipe in ipsilateral pore described in second pore selection confirmation command Hole, and the initial submodel is updated according to the pore information of second pore, generate the second son auxiliary Model；

It obtains third pore and chooses instruction, according to the third pipe in ipsilateral pore described in third pore selection confirmation command Hole, and the described second sub- submodel is updated according to the pore information of the third pore, it is auxiliary to generate third Help model；Until generating the multi-pass pipe submodel.

5. heat exchanger multi-pass pipe emulation modelling method according to claim 3, which is characterized in that

The multi-pass pipe creation instruction is obtained, the pipe for being associated with first pore is generated according to multi-pass pipe creation instruction In the step of initial submodel of hole information:

The initial submodel is generated according to white space of the position selection instruction near first pore.

6. heat exchanger multi-pass pipe emulation modelling method according to claim 4 or 5, which is characterized in that the multi-pass pipe is auxiliary Helping model is rectangular model；

It obtains the second pore and chooses instruction, according to the second pipe in ipsilateral pore described in second pore selection confirmation command Hole, and the initial submodel is updated according to the pore information of second pore, generate the second son auxiliary In the step of model:

According to the second pore described in second pore selection confirmation command, the first sub- rectangular model is extended into second pipe Hole, and the described first sub- rectangular model is updated according to the pore information of second pore, generate the second sub- square Shape model.

7. heat exchanger multi-pass pipe emulation modelling method according to claim 6, which is characterized in that

It obtains third pore and chooses instruction, according to the third pipe in ipsilateral pore described in third pore selection confirmation command Hole, and the described second sub- submodel is updated according to the pore information of the third pore, it is auxiliary to generate third Help model；Until in the step of generating the multi-pass pipe submodel:

According to third pore described in third pore selection confirmation command, if the third pore is distributed in the described second sub- square The side of shape model is then updated the described second sub- submodel according to the pore information of the third pore, generates institute State the sub- submodel of third；Or, if the third pore is distributed in the extending direction of the described second sub- rectangular model, it will be described Second sub- rectangular model extends to the direction of the third pore, and according to the pore information of the third pore to described second Sub- submodel is updated, and generates the sub- submodel of the third.

8. heat exchanger multi-pass pipe emulation modelling method according to any one of claims 1 to 5, which is characterized in that the pipe Hole information includes pore serial number and pore attribute.

9. heat exchanger multi-pass pipe emulation modelling method according to any one of claims 1 to 5, which is characterized in that described more Siphunculus submodel is in the region that each ipsilateral pore surrounds.

10. a kind of heat exchanger multi-pass pipe simulation modeling device characterized by comprising

Model creation module generates multi-pass in Heat-Exchanger Simulation figure layer according to the operational order for obtaining operational order Pipe submodel；The multi-pass pipe submodel is used for the target pore information being associated in the Heat-Exchanger Simulation figure layer, described Target pore information is the pore information of ipsilateral pore corresponding to the multiple-way duct that need to be connected to；

Parsing module generates the underlying model calling comprising the pore information and refers to for parsing the multi-pass pipe submodel It enables, and the underlying model call instruction is transferred to Modeling Server；The underlying model call instruction is used to indicate described Modeling Server calls corresponding multi-pass tube bottom layer model；The multi-pass tube bottom layer model in heat exchanger underlying model for connecting Lead to the corresponding pipeline of each pore information.

11. a kind of computer equipment, including memory and processor, the memory are stored with computer program, feature exists In the step of processor realizes any one of claims 1 to 9 the method when executing the computer program.

12. a kind of heat exchanger multi-pass pipe simulation modeling system, which is characterized in that set including the computer described in claim 11 It is standby, it further include the Modeling Server for connecting the computer equipment.

13. heat exchanger multi-pass pipe simulation modeling system according to claim 12, which is characterized in that the Modeling Server For Amesim server.

14. a kind of computer readable storage medium, is stored thereon with computer program, which is characterized in that the computer program The step of method described in any one of claims 1 to 9 is realized when being executed by processor.