KR20190043789A - Simulation method and system for facility - Google Patents

Abstract

The present invention relates to simulation method and system for a facility. More particularly, a first input unit receives a type of a facility to be simulated and at least one design condition for the facility. A control unit simulates a facility object based on the at least one design condition. A second input unit receives at least one environmental condition for the facility object. The control unit applies the at least one environmental condition to the facility object to generate a simulation file. An output unit displays the simulation file. Therefore, the simulation method and system for a facility of the present invention simulates a facility to be simulated by variously changing the design conditions and environmental conditions of the facility, such that a user can check in advance the situation change of the facility under various conditions before building the facility.

Description

[0001] DESCRIPTION [0002] Simulation methods and systems for facilities [0003]

The present invention relates to a method and a system for simulating a facility, and more particularly, to a method and system for simulating a facility capable of simulating a facility in advance by variously changing an internal design condition or an external environment for a facility such as a greenhouse or a pension company .

In the agricultural and livestock sectors, facilities such as greenhouses for cultivating crops and pig farming pigs have a great influence on the efficiency of the work and the cost of cultivation or rearing. Therefore, it is important to construct facilities with different design conditions depending on the region or climate.

For example, a comparison of the cultivation of crops at Daegwallyeong in Pyeongchang, Gangwon Province, and the cultivation of crops at Haenam in Jeollanam Province reveals that there are various differences from region to climate.

If Daegwallyeong makes a greenhouse and grows crops, it can not be predicted that the situation or problems occurring in the greenhouse will occur in the same greenhouse in Haenam. In addition, it is difficult to predict how changes in regions, climate, etc. will cause substantial changes in crop cultivation or livestock breeding.

Therefore, before constructing a facility such as a greenhouse or a pilgrimage site, it is necessary to reflect various types of conditions such as local conditions and climate around the planned construction site, change it, and confirm the expected situation in the construction of the facility .

However, in most cultivators or livestock farmers, the standardized facilities are constructed directly on the land in the general form without such confirmation, and the operation cost of the facilities is increased due to unforeseen circumstances during construction, A problem has occurred.

Korean Patent Registration No. 10-1720755 (Feb. Korean Patent Registration No. 10-1595243 (Feb.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a method of simulating facilities that can improve operating costs or operation efficiency by variously changing internal design conditions and external environment conditions of a facility, ≪ / RTI >

A method for simulating a facility according to an embodiment of the present invention includes the steps of receiving a type of facility to be simulated and at least one design condition for the facility, A second input unit receiving at least one environmental condition for the facility object, the control unit applying the at least one environmental condition to the facility object to generate a simulation file, and the output unit And displaying the simulation file.

The step of receiving the types of the facilities to be simulated and the at least one design condition for the facilities to be simulated by the first input unit may be performed in the case where the facility to be simulated is a greenhouse, the total length, the interlocking, A side curtain, a ventilation fan, a bed, an internal circulation fan, and a radiator.

Wherein the step of simulating the facility object based on the at least one design condition comprises the steps of invoking the greenhouse block file pre-stored in the storage unit according to the types and interlocking of facilities among design conditions input to the first input unit, Placing a greenhouse block object based on one design condition, invoking a first greenhouse ancillary file previously stored in the storage associated with the door, side windows, ceiling, horizontal and side curtains, ventilation fans, The method comprising the steps of: placing at least one object of the door, side window, ceiling, horizontal and side curtain, and ventilation fan on the greenhouse block object based on one design condition; For at least one object of the door, side window, ceiling, horizontal and side curtain, ventilation fan disposed in the greenhouse block object Activating a second greenhouse ancillary file previously stored in the storage associated with the bed, placing a bed object in the greenhouse block object based on the at least one design condition, The method comprising: calling a third greenhouse ancillary file previously stored in the storage associated with the circulating fan, placing an internal circulating fan object in the greenhouse block object based on the at least one design condition; And placing a radiator object in the greenhouse block object based on the at least one design condition.

Wherein the step of invoking a second greenhouse ancillary file pre-stored in the storage associated with the bed and placing a bed object in the greenhouse block object based on the at least one design condition comprises: And placing a crop object in the bed object by calling the crop state file showing the crop state of each crop according to the growth cycle.

Wherein the step of invoking a third greenhouse ancillary file pre-stored in the storage associated with the internal circulating fan, and placing an internal circulating fan object in the greenhouse block object based on the at least one design condition, May be arranged so as to face different directions in the same direction of the power or block.

The step of receiving the type of the facility to be simulated and at least one design condition for the facility to which the first input unit is to be simulated is a step of receiving the standard design type, the type, the exterior wall, the roof, , A dressing system, an exhaust system, a feeder, and a breeding density.

Wherein the step of simulating the facility object based on the at least one design condition comprises the steps of: loading a standard pension file stored in the storage unit according to the type of the facilities and the standard design type among the design conditions inputted from the first input unit; Placing a python object, invoking a first python accessory file previously stored in the storage in association with the loading method and the exhausting method, and inserting the python object into the pit object based on the at least one design condition, Determining whether or not to activate at least one object among punctures, slots, and pans disposed in the python object based on a design condition input to the first input unit; Invoking a second python accessory file previously stored in said storage unit in association with said second python accessory file, Placing a feed object in the cigarette object, and invoking a third cigarette attach file pre-stored in the storage associated with the cage density, and placing the pig object in the cigarette object based on the at least one design condition Step < / RTI >

The receiving of the at least one environmental condition for the facility object by the second input unit may receive at least one environmental condition of the wind direction, the wind speed, the temperature, the humidity, and the rainfall.

Wherein the controller applies the at least one environmental condition to the facility object to generate a simulation file, the temperature and humidity of the at least one environmental condition being applied in a two-dimensional cross-section or a contour form, Or in a wire form.

And the transmitting unit may transmit the simulation file generated from the control unit to the preset external terminal.

And the second input unit may re-input at least one environmental condition for the facility object when the location of the external terminal is moved.

A simulation system for a facility according to another embodiment of the present invention includes a first input unit for receiving at least one design condition of a facility to be simulated and a facility to be simulated, a second input unit for receiving at least one environmental condition for the facility, A control unit for simulating a facility object based on the at least one design condition and generating the simulation file by applying the at least one environmental condition to the facility object, and an output unit for displaying the simulation file.

And a transmission unit for transmitting the simulation file generated from the control unit to a preset external terminal.

As described above, the method and the system for simulating the facilities according to the present invention can simulate the design conditions and the environmental conditions of the facilities to be simulated, so that the user can check the state of the facilities under various conditions in advance have.

In addition, the method and system for simulating the facilities according to the present invention can greatly improve the working efficiency and reduce the operating cost by simulating the design conditions and the environmental conditions for the facilities to be simulated.

1 is a block diagram of a facility simulation system according to an embodiment of the present invention.
2 is a schematic diagram of a facility simulation system in accordance with another embodiment of the present invention.
3 is a flowchart of a method of simulating facilities according to another embodiment of the present invention.
4 is a flowchart showing detailed steps of performing a simulation for manufacturing a greenhouse object.
5 is a flowchart showing detailed steps of performing a simulation for constructing a housing object.
6 is a view showing a process of arranging greenhouse block objects.
7 is a view showing an accessory showing the opening and closing rates of the side window and the ceiling object.
8 is a view showing a state of the horizontal curtain object according to the opening / closing rate.
9 is a view showing a side curtain object according to the opening / closing rate.
10 is a view showing a state in which a ventilation fan object is installed.
FIG. 11 is a view showing a state in which punctures are arranged in a middle chamber in a pig object. FIG.
FIG. 12 is a view showing a state in which entrance slots are arranged in a ceiling in a pig object.
FIG. 13 shows a state in which a chimney fan is disposed in a pig object.
14 shows a state in which a sidewall fan is disposed at a sidewall position in the pig object.
15 is a view showing an arrangement state of the feeders.
16 is a diagram illustrating a method of applying environmental conditions to a facility object.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art, however, that these examples are provided to further illustrate the present invention, and the scope of the present invention is not limited thereto.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, in which: It is to be noted that components are denoted by the same reference numerals even though they are shown in different drawings, and components of different drawings can be cited when necessary in describing the drawings. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the following detailed description of the principles of operation of the preferred embodiments of the present invention, it is to be understood that the present invention is not limited to the details of the known functions and configurations, and other matters may be unnecessarily obscured, A detailed description thereof will be omitted.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to include an element does not exclude other elements unless specifically stated otherwise, but may also include other elements.

Also, the terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms may be used for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises", "having", and the like are intended to specify the presence of stated features, integers, steps, operations, elements, components, or combinations thereof, , Steps, operations, components, parts, or combinations thereof, as a matter of principle.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be construed as meaning consistent with meaning in the context of the relevant art and are not to be construed as ideal or overly formal in meaning unless expressly defined in the present application .

The present invention reflects various types of conditions such as the area around the planned construction site or the climate to various facilities before building the facilities mainly used in farmhouses or farmhouses such as greenhouses or pig farms to actually construct the land, And more particularly, to a method and a system for simulating a facility so as to confirm in advance.

Hereinafter, a facility simulation system 100 according to an embodiment of the present invention will be described in detail with reference to FIG.

1 is a block diagram of a facility simulation system according to an embodiment of the present invention.

1, the facility simulation system 100 of the present invention includes a first input unit 120, a second input unit 140, a control unit 160, an output unit 180, and a storage unit 170 .

The first input unit 120 receives a type of facility to be simulated and at least one design condition for the facility. When the type of the facility to which the first input unit 120 is input is a greenhouse, at least one of a total length, an interlocking door, a door, a side window, a ceiling, a horizontal and a side curtain, a ventilation fan, a bed, Can be input. The type, the type, the exterior wall, the roof, the shaft transporting method, the dressing method, the exhausting method, the feeder, and the breeding density when the type of the facility to which the first input unit 120 is input is a piggy bank Can be input.

The second input unit 140 receives at least one environmental condition for a facility object simulated by the control unit 160. At this time, at least one environmental condition for the facility object may include at least one of wind direction, wind speed, temperature, humidity, and rainfall. Also, when the simulation file generated by the controller 160 is transferred to the predetermined external terminal 10, the second input unit 140 can re-input at least one environmental condition for the facility object.

The control unit 160 simulates the facility object based on at least one design condition inputted by the first input unit 120 and generates the simulation file by applying the at least one environmental condition to the facility object. At this time, the generated simulation file may be a three-dimensional modeling file of the facility object, and at least one environmental condition is applied to the facility object. In case of temperature and humidity, a two-dimensional cross- Or contour, and the wind speed can be applied to a facility object in the form of a vector or a stream line.

The output unit 180 displays the simulation file.

The storage unit 170 stores the greenhouse block file, which is a file related to the greenhouse, the first to fourth greenhouse ancillary files, and the crop status file, and also stores the python standard file, which is a file related to the python, . At this time, the first greenhouse ancillary file indicates the position, the number, the opening and closing of the doors, the side windows, the ceiling, the horizontal and side curtains, and the ventilation fan object. The second greenhouse ancillary file represents the location and number associated with the bed object, the third greenhouse athan file represents the location and number associated with the inner circulating fan object, , And number. In addition, the storage unit 170 may store an IP address of an external terminal for transmitting a simulation file generated by applying at least one environmental condition to a facility object.

At this time, the pilger's standard file is a file according to the standard design type, and shows a predetermined standard design in 2009 or 2016. In addition, the first python attachment file indicates the position and number of the middle punched hole, the ceiling entry slot, the chimney fan, and the sidewall fan object related to the dressing method and the exhausting method, and the second python attachment file indicates the arrangement state , And the third pork subassembly indicates the number of pigs involved in breeding density.

The simulation system of the facility according to another embodiment of the present invention includes the first input unit 120, the second input unit 140, the control unit 160, the output unit 180, and the storage unit 170 , As shown in FIG. 2, in addition to the same configuration as the transmitting unit 190 shown in FIG.

The transmission unit 190 transmits the simulation file generated from the control unit 160 to the external terminal 10 previously set. At this time, the external terminal 10 is in the form of an HMD (Head Mounted Display) and may be worn on the head of the user, or may be in the form of a general PC, tablet PC, smart phone or the like having an IP address.

Hereinafter, a method of simulating a facility according to another embodiment of the present invention will be described in detail with reference to FIG.

3 is a flowchart of a method of simulating facilities according to another embodiment of the present invention.

As shown in FIG. 3, the first input unit 120 receives the types of facilities to be simulated and at least one design condition for the facilities (S210). At this time, if the facility to be designed is a greenhouse, design conditions including at least one of total length, interlocking, door, side window, ceiling, horizontal and side curtain, ventilation fan, bed, internal circulation fan, Can receive. A design condition including at least one of a standard design type, a kind, an outer wall, a roof, an axial transfer method, a dressing method, an exhaust method, a feed rate, and a breeding density can be inputted .

The control unit 160 simulates a facility object based on the at least one design condition input to the first input unit 120 (S220).

The second input unit 140 receives at least one environmental condition for the inside and the outside of the facility object (S230). At this time, the input environmental condition may include at least one of wind direction, wind speed, temperature, humidity, and rainfall.

Thereafter, the controller 160 applies the at least one environmental condition to the facility object to generate a simulation file (S240). At this time, the temperature and humidity of the at least one environmental condition are applied to a facility object in the form of a two-dimensional cross section or a contour, and the wind speed may be in the form of a vector or a stream line It can be applied to facility objects.

The output unit 180 displays the simulation file (S250).

Also, the transmitter 190 may transmit the simulation file generated from the controller 160 to the predetermined external terminal 10. At this time, the external terminal 10 may be in the form of an HMD and may be worn on the user's head, or may be in the form of a general PC, tablet PC, smart phone, or the like having an IP address.

If the position of the external terminal 10 is changed due to movement of the user after wearing the HMD, the second input unit 140 may re-input at least one environmental condition for the facility.

Hereinafter, the detailed process of simulating a facility object based on at least one design condition will be described according to the types of facilities.

First, when a facility to be simulated is a greenhouse, a simulation step of a greenhouse object will be described in detail with reference to FIG.

4 is a flowchart showing detailed steps of performing a simulation for manufacturing a greenhouse object.

4, a greenhouse block file pre-stored in the storage unit 170 is placed according to the types and interlocking of the facilities among the design conditions input to the first input unit 120 (S221a) . For example, if the facility type is greenhouse and there are three interlocking, L block, M block, and R block file among the greenhouse block files previously stored in the storage unit can be called up and arranged.

Thereafter, a first greenhouse ancestor file pre-stored in the storage 170 is associated with the door, side windows, ceiling, horizontal and side curtains, ventilation fan objects, Side windows, a ceiling, a horizontal and a side curtain, and a ventilating fan in the greenhouse block object to match the design conditions of the greenhouse block object (S222a).

Determines whether or not to activate at least one of the door, the side window, the ceiling, the horizontal and side curtains, and the ventilation fan disposed on the greenhouse block object based on the design condition input to the first input unit 120 S223a).

The second greenhouse ancestor file previously stored in the storage unit 170 in association with the bed, and arranges the bed object in the greenhouse block object according to at least one design condition inputted (S224a). In particular, after placing the bed object in the greenhouse block object, the crop object file indicating the state of the crop according to the growth cycle may be retrieved from the storage unit 170, and the crop object may further be arranged in the bed object.

A third greenhouse ancillary file pre-stored in the storage unit 170 in association with an internal circulating fan, and an internal circulation fan is connected to the greenhouse block object to meet at least one design condition input to the first input unit 120 (S225a). At this time, the internal circulation fans may be arranged so as to face different directions in the same direction of power or each block.

A fourth greenhouse ancestor file pre-stored in the storage unit 170 in association with the radiator and arranges the radiator object in the greenhouse block object based on at least one design condition input to the first input unit 120 S226a).

Next, the simulation step of the pig object will be described in detail with reference to FIG. 5 when the facility to be simulated is a pig.

5 is a flowchart showing detailed steps of performing a simulation for manufacturing a pilgrim object.

As shown in FIG. 5, the pilgrim standard file stored in advance in the storage unit is loaded according to the kind of the facility and the standard design type in the design conditions inputted to the first input unit 120, and the pilgrim object is arranged (S221b).

Slots, and slots in the python object based on at least one design condition input to the first input unit 120 by calling a first python attachment file stored in the storage unit in association with the input method and the exhaust method, And arranges at least one object among the fans (S222b).

In operation S223b, it is determined whether to activate at least one of the perforations, the slots, and the pans disposed in the pilgrimage object based on the design conditions input to the first input unit 120.

A second pug file attached to the storage unit 170 is loaded in association with the feeding, and a feeding object is placed in the pug object according to the at least one design condition (S224b).

The third pork sub-file stored in the storage unit 170 is related to the density of the meat, and a pig object is placed in the puck object to match the at least one design condition (S225b).

Hereinafter, the case of directly performing a simulation of a facility object according to the present invention will be described in detail.

Table 1 below is a table showing a configuration of a user interface implemented for performing a simulation of a facility according to the present invention.

file
(file) edit
(edit) modelling
(modeling) Preferences
(data) analysis
(analysis) Help
(help) Heat Load Model Agricultural facility display Load Model Loading language New Modified Environmental condition Save Loading data About program temporary storage Save Model temporary storage Transfer IP settings way of expression
Selection Shortcuts Save Save as to make Backup Preferences Save as edit print Save print
Preferences

As shown in Table 1, the user interface for implementing the simulation of the facilities according to the present invention can be composed of six pull-down menus of file, edit, modeling, configuration, analysis, and help.

The first input unit 120 receives at least one type of facility and at least one design condition for the facility using the user interface.

Hereinafter, the facility to be simulated will be divided according to the type of each facility.

Example 1 (Type of Facilities In the greenhouse )

If the greenhouse is inputted to the first input unit 120, then it is inputted whether the total length is 50 m or 100 m, whether the greenhouse block is single-unit or interlocked, and if the greenhouse block is interlocked, The number of doors, the opening and closing of the side windows, the opening and closing of the ceiling, the installation of the horizontal curtains and side curtains, the installation of the ventilation fan by the upper or lower position, the type and installation position of the bed, At least one of the installation state and the installation number of the duct circulator is inputted.

Then, the control unit 160 loads the greenhouse block file from the storage unit 170 and arranges the greenhouse block object.

Particularly, the design conditions inputted to the first input unit 120 are 50 m in total length of the greenhouse, the number of the greenhouse blocks to be interlocked is 3, the side window closing rate and the ceiling opening / closing rate 50 % Is input, the installation of horizontal and side curtains, the ventilation fan is provided with two upper small fans, the lower sub-fan is installed, the bed is input as a kind of short double bed, , And three duct circulators are assumed to be installed.

First, the control unit 160 loads a greenhouse block file from the storage unit 170, and arranges L blocks, M blocks, and R block objects. However, since the greenhouse block file is opened with the reference point of the greenhouse block object aligned to the coordinates (0, 0, 0), the L block, the M block, and the R block object are all located on the basis of the origin.

Therefore, as shown in FIG. 6A, the L block object is first arranged, and then, as shown in FIG. 6B, the M block object is moved in the x-axis direction (interlock number -2) And then the R block object is placed at a position shifted by (interlocking number -1) x 800 in the x axis direction as shown in Fig. 6 (c).

When the arrangement of the greenhouse block objects is completed, the first to fourth greenhouses ancillary files previously stored in the storage unit 170 are called up, and based on at least one design condition input to the first input unit 120, 1 Entrance door, side windows, ceiling, horizontal and side curtains, ventilation fan objects included in the greenhouse fitting file, the bed object contained in the second greenhouse fitting file, the internal circulating fan object contained in the third greenhouse fitting file, the fourth greenhouse And greenhouse accessory objects such as radiator objects included in the accessory file are respectively placed in the greenhouse block objects. Accordingly, if a greenhouse accessory object received through the first input unit 120 is not received or is not installed, the greenhouse accessory object is deactivated.

Particularly, in the case of a door object, when the design condition input through the first input unit 120 exceeds the total number of greenhouse block objects or if there is no separate design condition, it is equal to the total number of greenhouse block objects So that the number is assigned to each greenhouse block object.

In the case of a side window object, it is not arranged in the M block object among the L block, M block, and R block object disposed before. As shown in FIG. 7, the opening and closing of the side window object is determined and displayed according to the design conditions input through the first input unit 120. [ In particular, when the opening / closing rate of the side window object is 50%, the side window object showing the 0%, 10%, and 100% opening / closing rates is deleted by 3 in each of the L block object and the R block object.

Also, in the case of the ceiling object, all the ceiling objects excluding the ceiling object representing the opening / closing rate inputted through the first input unit 120 are removed as in the case of the side window object.

One horizontal curtain object may be placed in the L block, and an interlock number-2 in the M block and one R block may be disposed, and may be set to 0% or 100%. Fig. 8 (a) shows a horizontal curtain object having an opening / closing rate of 0%, and Fig. 8 (b) shows a horizontal curtain object having an opening / closing rate of 100%.

For example, when the horizontal curtain object input through the first input unit 120 is 0%, the horizontal curtain object set to the remaining 100% is not arranged but deleted.

The number of side curtain objects is set to three in the L block and the number of the (total interlocking number-2) x 2 in the M block, and three in the R block can be set to 0% or 100%. 9 (a) shows a side curtain object with an opening / closing rate of 0%, and Fig. 9 (b) shows a side curtain object with an opening / closing rate of 100%.

The ventilation fan object can be set to be installed or uninstalled. When the ventilation fan object is set to be installed, the ventilation fan object is divided into a small fan and a large fan, and the installation position is set to the upper and lower positions, and the installation number can also be set. If the ventilation fan object is not set through the input design condition, or if the design condition is not input, all the ventilation fan objects in the olive block object are removed. Also, when only one ventilation fan object of the ventilation fan object or one of the large ventilation fan objects is input to be placed in the design condition, the remaining ventilation fan objects that are not selected are also removed. In addition, the installation position of the ventilation fan object may be set at the upper and lower portions of the greenhouse block object, respectively. If the ventilation fan object is overlapped with the entrance door position of the greenhouse block object, the ventilation fan object is not disposed.

For example, FIG. 10 (a) shows one small fan at the upper part and one large fan at the lower part for the L block, M block and R block, which are the greenhouse block objects formed by the three linked houses. However, in this case, as the door is formed in the M block of the three interlocking house, the large fan object can be removed under the M block as shown in FIG. 10 (b).

The bed object is included in the second green house ancestor file previously stored in the storage unit 170 and is divided into a short bed, a short double bed, a toll bed, and a toll double bed according to the width and the length, And the number of arrangements arranged in one greenhouse block object can also be inputted through design conditions.

In particular, after placing the bed object in the greenhouse block object, the crop object file may be placed on the bed object by calling from the storage unit 170 a crop state file showing the state of the crop by the growth cycle. At this time, the crop state file includes crop objects having different growth states according to stages of the plant, the fruit growing stage, and the harvest stage.

The internal circulation fan objects may be included in the third greenhouse ancillary file previously stored in the storage unit 170 and arranged at a height of 0.5 m, 1 m, 1.5 m from the top of the bed object in the center of the greenhouse block object. In addition, the installation direction of the internal circulation fan objects may be installed in the same direction as the power normal direction or the power supply reverse direction, or may be installed in different directions for different installed greenhouse block objects, for example, in the L block, And can be installed in the forward direction in the R block.

The radiator object is included in the fourth greenhouse attachment file previously stored in the storage unit 170, and the installation position and the number can be inputted through the design condition. In addition, the number of duct circulators to be installed together with the radiator object and the duct connecting method including the serial-parallel type can also be inputted through the design conditions.

Example 2 (Type of Facilities If you are a pensioner )

When the first input unit 120 receives a money item, at least one of the type of the standard design, the type of the product, the type of the outer wall, the roof, the shaft transfer method, the dressing method, the exhaust system, .

The standard design diagram is stored in advance in the storage unit 170 for the 2009 version and the 2016 version, and if one of the standard designs for the 2009 or 2016 standard design is selected and input, You can load the python standard file, which represents the year standard design, and place the python object.

The breed represents the kind of pigs desired to breed in the pig farm, and the kind of piglet or breeding pig and the kind of sow can be selected and inputted. At this time, piglets represent piglets, and breeding pigs represent pigs in which the skeleton and muscle tissue grow vigorously at a weight of 20 to 60 kg, and the sows represent the mother pig.

The exterior wall represents the exterior finish of the python, and red brick or THK 150 designated panels can be entered.

The roof is installed or not installed, and if installed, a THK 150 designated panel can be input.

The axial transfer method indicates a method of transferring excrement of swine to the outside of a pig house, and one of scraper, transfer pit, and conveyor can be selected and inputted. At this time, when the minute pit is input, one of 1500 mm or 1800 mm depth is selected and inputted to the lower part of the python object.

The puncture, slot, and fan objects are included in the first python attachment file stored in the storage unit 170 in association with the input method and the exhaust method for the air in the python object, and the design conditions input through the first input unit 120 Can be placed in the python object. 11 shows a state in which punctures are arranged in a cigarette pile in a pilgrimage object, FIG. 12 shows a state in which entry slots are arranged in a ceiling in a pilgrimage object, FIG. 13 shows a state in which a pilgrim pan is arranged in a pilgrim object And Fig. 14 shows a state in which the sidewall pan is disposed at the side wall position in the pig object.

The feed object is included in the second piggy bank attachment file pre-stored in the storage 170, in association with feeding the feed to pigs in the pig house. In this drawing object, one of the design conditions input through the first input unit 120, whether the side wall fan is arranged in front, whether the side wall fan is arranged in the front zigzag or whether the side wall fan is arranged on the side, As such, it can be deployed.

Breeding density is the ratio of the number of pigs raised within the pig house to the ratio of one of 100%, 120% or 140%. In this manner, pig objects included in the third piggy bank attachment file previously stored in the storage unit 170 may be placed in the piggy bank object according to the density of the pigs fed through the design conditions. Thus, the number of pig objects to be placed is determined by dividing the pork area by the area per pig and multiplying by the input density. For example, when 120% of piglets are fed, the number of swine objects placed is 49.5 / 0.3 × 1.2 = 198 when the area of the pigeon object is 49.5 ㎡ and the area of double pigeon is 0.3 ㎡ .

The control unit 160 may simulate the facility object using the design condition inputted through the first input unit 120 and then the second input unit 140 may transmit the facility object At least one environmental condition to be applied to the environment.

At this time, the environmental condition can be input to whether it is applied to the inside of the facility object or externally. In the case of the wind direction, the north, north, south, east, northeast, east, east, south, , Southwest, West, Northwest, Northwest, North and North. 5 m / s, 7 m / s, 12 m / s, 25 m / s and 30 m / s in the case of wind speed, s, which can be divided into 7 types. The input environmental condition may be applied to the facility object generated by the control unit 160 and stored separately in the storage unit 170.

Thereafter, at least one environmental condition input from the second input unit 140 is applied to the simulated facility object to generate a simulation file. At this time, at least one environmental condition may be applied to the facility object as at least one of a contour, a section, a vector, and a wired form. Among the at least one environmental condition inputted through the second input unit 140, the temperature and the humidity can be applied to a facility object in contour or sectional form as shown in Figs. 16 (a) and 16 (b) And the wind speed can be applied to the facility object in a vector or wired form, as shown in Figs. 16 (c) and 15 (d).

In this manner, the simulation file generated by applying the environmental condition to the simulated facility object can be transmitted to the predetermined external terminal. At this time, when the external terminal is in the form of an HMD (Head Mounted Display), a user may wear the external terminal on his head and move the position inside or outside the simulated facility object using a joystick. In this way, when the external terminal moves, the second input unit 140 can re-input at least one environmental condition for the simulated facility object.

Alternatively, the external terminal may be in the form of a general PC, a tablet PC, a smart phone, or the like having an IP address that is not an HMD type. The IP address of the external terminal to which the simulation file is to be transmitted is stored in advance in the storage unit 170, and the generated simulation file can be transmitted to the corresponding IP address.

Thereafter, the output unit 180 displays the simulation file generated from the control unit 160. Accordingly, the user can easily check the facility object to which various design conditions and environmental conditions are applied through the output unit 180. [

Embodiments of the present invention may be implemented in the form of program instructions that can be executed on various computer means and recorded on a computer readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape, optical media such as CD-ROMs and DVDs, magnets such as floptical disks, Examples of program instructions, such as magneto-optical and ROM, RAM, flash memory and the like, can be executed by a computer using an interpreter or the like, as well as machine code, Includes a high-level language code. The hardware devices described above may be configured to operate as at least one software module to perform operations of one embodiment of the present invention, and vice versa.

As described above, the method and the system for simulating the facilities according to the present invention can simulate the design conditions and the environmental conditions of the facilities to be simulated, so that the user can check the state of the facilities under various conditions in advance have.

In addition, the method and system for simulating the facilities according to the present invention can greatly improve the working efficiency and reduce the operating cost by simulating the design conditions and the environmental conditions for the facilities to be simulated.

It will be apparent to those skilled in the relevant art that various modifications, additions and substitutions are possible, without departing from the spirit and scope of the invention as defined by the appended claims. The appended claims are to be considered as falling within the scope of the following claims.

120: first input unit 140: second input unit
160: control unit 170:
180: output unit 190:

Claims (14)

The first input unit receiving at least one design condition for the type of facility and the facility to be simulated;
The control unit simulating the facility object based on the at least one design condition;
A second input unit receiving at least one environmental condition for the facility object;
The control unit applying the at least one environmental condition to the facility object to generate a simulation file; And
The output unit displaying the simulation file;
The method comprising the steps of:
The method according to claim 1,
Wherein the step of receiving the type of the facility to be simulated and at least one design condition for the facility
A design condition including at least one of an overall length, an interlocking door, a door, a side window, a ceiling, a horizontal and a side curtain, a ventilation fan, a bed, an internal circulation fan, and a radiator is inputted when the facility to be simulated is a greenhouse A method of simulating facilities.
3. The method of claim 2,
Wherein the step of the controller simulating the facility object based on the at least one design condition
Calling a greenhouse block file pre-stored in the storage unit according to the types and interlocking of the facilities among the design conditions input to the first input unit, and arranging the greenhouse block objects based on the at least one design condition;
Wherein the first greenhouse ancillary file previously stored in the storage is associated with the door, side windows, ceiling, horizontal and side curtains, ventilation fan, Placing an object of at least one of a side window, a ceiling, a horizontal and a side curtain, and a ventilation fan;
Determining whether to activate at least one object among the door, the side window, the ceiling, the horizontal and side curtains, and the ventilation fan disposed in the greenhouse block object based on the design condition input to the first input unit;
Invoking a second greenhouse ancillary file pre-stored in the storage associated with the bed, and placing a bed object in the greenhouse block object based on the at least one design condition;
Calling a third greenhouse ancillary file pre-stored in the storage associated with the internal circulating fan, and placing an internal circulating fan object in the greenhouse block object based on the at least one design condition; And
Calling a fourth greenhouse ancillary file pre-stored in the storage associated with the heater, and placing a heater object in the greenhouse block object based on the at least one design condition;
The method comprising the steps < RTI ID = 0.0 > of: < / RTI >
The method of claim 3,
Invoking a second greenhouse ancillary file previously stored in the storage associated with the bed and placing a bed object in the greenhouse block object based on the at least one design condition
Further comprising placing the bed object in the greenhouse block object and then calling the crop state file showing the state of the crop by the growth cycle from the storage unit and arranging the crop object in the bed object. .
The method of claim 3,
Invoking a third greenhouse ancillary file pre-stored in the storage associated with the internal circulating fan and placing an internal circulating fan object in the greenhouse block object based on the at least one design condition
Wherein the internal circulation fan objects are disposed so as to face different directions in the same direction of power or block.
The method according to claim 1,
Wherein the step of receiving the type of the facility to be simulated and at least one design condition for the facility
A design condition including at least one of a standard design type, a kind, an outer wall, a roof, a shaft transfer method, a dressing method, an exhaust method, a feed rate, and a breeding density is inputted when the facility to be designed is a piggy bank A method of simulating a facility.
The method according to claim 6,
Wherein the step of the controller simulating the facility object based on the at least one design condition
Placing a pilgrimage object by calling a pilgrimage standard file pre-stored in the storage unit according to the type of facility and the type of standard design among the design conditions input from the first input unit;
A first python accessory file stored in the storage unit in association with the input method and the exhausting method, and arranging at least one object among the pit, slot, and pan in the python object based on the at least one design condition step;
Determining whether to activate at least one object among the punctures, slots, and pans disposed in the pilgrim object based on the design condition input to the first input unit;
Invoking a second python attachment file previously stored in the storage in association with the feeding, and placing a feeding object in the python object based on the at least one design condition; And
Invoking a third pork sub-file previously stored in the storage associated with the rearing density, and placing a pig object in the puck object based on the at least one design condition;
The method comprising the steps < RTI ID = 0.0 > of: < / RTI >
The method according to claim 1,
Wherein the receiving of the at least one environmental condition for the facility object by the second input unit
Wherein at least one environmental condition of the wind direction, the wind speed, the temperature, the humidity, and the rainfall amount is inputted.
9. The method of claim 8,
Wherein the step of generating the simulation file by applying the at least one environmental condition to the facility object
Wherein the temperature and humidity of at least one environmental condition are applied in a two-dimensional cross-section or a contour form, and the wind speed is applied in a vector or wire form.
The method according to claim 1,
Transmitting a simulation file generated from the control unit to a predetermined external terminal;
Further comprising the steps of:
11. The method of claim 10,
Receiving, when the location of the external terminal is moved, the second input unit re-inputting at least one environmental condition for the facility object;
Further comprising the steps of:
12. A computer-readable recording medium on which a program for executing a method according to any one of claims 1 to 11 is recorded.
A first input unit for receiving at least one design condition for a facility to be simulated and a facility to be simulated;
A second input for receiving at least one environmental condition for the facility;
A control unit for simulating a facility object based on the at least one design condition and generating the simulation file by applying the at least one environmental condition to the facility object; And
An output unit for displaying the simulation file;
A simulation system of a facility including
14. The method of claim 13,
A transmission unit for transmitting the simulation file generated from the control unit to a predetermined external terminal;
Wherein the system further comprises:

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