KR102660522B1 - Digital twin-based MPC (Model Predictive Control) system for optimizing factory facility energy use - Google Patents

Abstract

The present invention relates to a digital twin-based MPC system for optimizing energy use of factory facilities, which is designed to perform digital twin-based MPC (Model Predictive Control) to optimize energy use of factory facilities. As such, factory equipment; Equipment control device that controls the operation of the factory equipment; and an energy optimization device that controls the operation of the facility control device to optimize energy use of the factory facility.

Description

Digital twin-based MPC (Model Predictive Control) system for optimizing factory facility energy use}

The present invention relates to a digital twin-based MPC system for optimizing energy use of factory facilities. More specifically, it relates to a digital twin-based MPC (Model Predictive Control) system for optimizing energy use of factory facilities. This is about a digital twin-based MPC system designed to optimize energy use in factory facilities.

Energy is emerging as an essential entity for sustaining modern society, and the importance of energy is increasing exponentially to the point that no country in the world can sustain life without the use of energy.

Therefore, technologies related to energy saving that can reduce the amount through efficient use of energy and reduction of consumption are important. Saving energy can improve financial capital, environmental values, and human convenience, and direct consumers of energy are making efforts to save energy to reduce energy costs. In particular, energy conservation can be of great help in reducing the extent of climate change and can be the most economical solution to energy shortages.

Meanwhile, industrial energy consumption exceeds approximately 60% of national energy, and saving industrial energy in factories, etc. can have the greatest impact on the country's overall energy conservation. Accordingly, the need for and interest in managing factory energy efficiency is increasing.

For this purpose, technology is being used to establish and efficiently operate a Factory Energy Management System (FEMS). This factory energy management system is essential for efficient management of power usage for power facilities, minimizing work waiting time, optimal control of processes, and efficient operation of electrical energy.

Meanwhile, the above-mentioned background technology is technical information that the inventor possessed for deriving the present invention or acquired in the process of deriving the present invention, and cannot necessarily be said to be known technology disclosed to the general public before filing the application for the present invention. .

Korean Patent No. 10-2150810 (announced on October 26, 2020)

One aspect of the present invention is a digital twin-based MPC for optimizing energy use of factory facilities, which is designed to perform MPC (Model Predictive Control) based on Digital Twin to optimize energy use of factory facilities. Provides a system.

The technical problem of the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

A digital twin-based MPC system for optimizing energy use of factory equipment according to an embodiment of the present invention includes: factory equipment; Equipment control device that controls the operation of the factory equipment; and an energy optimization device that controls the operation of the facility control device to optimize energy use of the factory facility.

In one embodiment, the energy optimization device may perform Digital Twin-based MPC (Model Predictive Control) to optimize energy use of the factory equipment.

In one embodiment, the factory equipment may consist of an air conditioning system.

In one embodiment, the air conditioning system includes an air conditioning duct that provides a passage for air to move; An installation housing installed inside the air conditioning duct; A mounting portion connected to the installation housing; a drive motor installed at the front end of the mounting portion exposed from the installation housing; A head installed on the drive shaft of the drive motor by shaft coupling and driven to rotate; and a plurality of wings installed at regular intervals along the circumference of the head and rotating together as the head rotates to induce a flow of air.

In one embodiment, the wing includes a first plate fixed to one side of the head; a second plate mounted on the front end of the first plate; a third plate mounted on the front end of the second plate; a first variable connection part connecting the first plate and the second plate to each other; and a second variable connection part connecting the second plate and the third plate to each other.

In one embodiment, the first variable connection part includes: a one-side connection part that connects one side of each of the first plate and the second plate to each other; The other side connection part connects the other side of the first plate and the second plate to each other; and a gap cover made of an elastic material capable of expansion and contraction and installed to cover the upper and other sides of the opposing surfaces of the first plate and the second plate, respectively.

In one embodiment, the one side connection part includes a connection sphere formed in a circular sphere shape and disposed between the first plate and the second plate; A first sphere fastening part installed on one side of the front end of the first plate to connect the connecting sphere to be rotatable at the front end of the first plate; and a second sphere fastening part that is installed on one side of the rear end of the second plate while opposing the first ball fastening part and connects and installs the connecting sphere to be rotatable at the rear end of the second plate.

In one embodiment, the first sphere fastening part includes a sphere seating groove recessed in the front end of the first plate in a hemispherical shape so that half of the connecting sphere can be seated; a curved seating groove extending roundly along the inside of the first plate in response to the curvature of the spherical seating groove; a curved plate bent in a round shape corresponding to the curvature of the curved seating groove and seated inside the curved seating groove; A sphere support bar installed between the connecting sphere and the curved plate, and tightly fitting the curved plate to the inside of the curved seating groove as the connecting sphere is closely seated in the sphere seating groove; A seating groove opening communicated from the curved seating groove to the sphere seating groove so that the sphere support bar can move in an up and down direction as the connecting sphere rotates while the sphere support bar is disposed; a plurality of first magnetic bodies installed at regular intervals in the vertical direction along the inside of the curved seating groove; A plurality of plates are installed at regular intervals in the vertical direction along the rear end of the curved plate facing the first magnetic material and forming an opposite polarity to the first magnetic material, and are fastened to the first magnetic material to form the curved seating groove. a second magnetic body fastening the curved plate moved to the inside of; a plurality of third magnetic bodies installed at regular intervals in the vertical direction along one side and the other side of the front end of the curved seating groove where the seating groove opening is formed; And a plurality of pieces are installed at regular intervals in the vertical direction along one front side and the other side of the curved plate opposite to the third magnetic material while forming an opposite polarity to the third magnetic material, and are fastened to the third magnetic material. It may include a fourth magnetic body that fastens the curved plate moved to the front end of the curved seating groove.

In one embodiment, the mounting portion includes a mounting sphere formed in a circular sphere shape and rotatably connected to the installation housing; and a connecting rod formed at a front end of the mounting sphere exposed from the installation housing and on which the driving motor is installed.

In one embodiment, the installation housing includes: a housing body installed inside the air conditioning duct; a sphere installation groove formed at the front end of the housing body so that the mounting sphere can be connected and installed; A first driving unit installed inside the sphere installation groove to rotate and drive the mounting sphere connected to the sphere installation groove; It is installed on one side of the sphere installation groove so as to be perpendicular to the first driving part, and when the driving of the first driving part is terminated, the mounting sphere connected to the sphere installation groove is installed at a right angle to the rotational driving direction of the first driving part. a second driving unit that rotates; and a braking unit installed on the other side of the sphere installation groove to brake the mounting sphere to prevent it from moving.

In one embodiment, the first driving unit includes a driving unit installation groove that is recessed inside the spherical installation groove; A driving actuator installed inside the driving unit installation groove; a wheel housing installed on the drive shaft of the drive actuator; and is installed in the wheel housing to enable rotation, is received in the drive unit installation groove as the drive actuator is contracted, and is exposed from the drive unit installation groove as the drive actuator is extended and then comes into close contact with the mounting sphere. It may include a driving wheel that is then rotated and driven to rotate the mounting sphere.

In one embodiment, the braking unit includes a braking unit installation groove recessed on the other side of the sphere installation groove; A braking actuator installed inside the braking unit installation groove; and is installed on the drive shaft of the driving actuator, is received in the braking unit installation groove as the braking actuator is driven to contract, and is exposed from the braking unit installation groove as the braking actuator is extended and driven, and then comes into close contact with the mounting sphere. It may include a braking block that brakes the mounting sphere to prevent it from moving.

According to one aspect of the present invention described above, Digital Twin-based MPC (Model Predictive Control) can be performed to optimize energy use of factory equipment.

The effects of the present invention are not limited to the effects mentioned above, and various effects may be included within the scope apparent to those skilled in the art from the contents described below.

Figure 1 is a diagram illustrating the schematic configuration of a digital twin-based MPC system for optimizing energy use of factory facilities according to an embodiment of the present invention.
FIG. 2 is a diagram showing one embodiment of the factory equipment of FIG. 1.
FIG. 3 is a diagram showing the air conditioning system of FIG. 2.
Figure 4 is a diagram showing the wing of Figure 3.
Figures 5 to 7 are views showing one side connection part of Figure 4.
Figure 8 is a diagram showing the first concrete fastening part of Figure 5.

The detailed description of the present invention described below refers to the accompanying drawings, which show by way of example specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the invention are different from one another but are not necessarily mutually exclusive. For example, specific shapes, structures and characteristics described herein may be implemented in one embodiment without departing from the spirit and scope of the invention. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description that follows is not intended to be taken in a limiting sense, and the scope of the invention is limited only by the appended claims, together with all equivalents to what those claims assert, if properly described. Similar reference numbers in the drawings refer to identical or similar functions across various aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

Figure 1 is a diagram illustrating the schematic configuration of a digital twin-based MPC system for optimizing energy use of factory facilities according to an embodiment of the present invention.

Referring to FIG. 1, the digital twin-based MPC system 10 for optimizing energy use of factory equipment according to an embodiment of the present invention includes factory equipment 100, equipment control device 200, and energy optimization device 300. ) includes.

Factory equipment 100 is a general term for various types of equipment provided in a factory, and any equipment required for factory operation can be applied regardless of its name.

In one embodiment, factory equipment 100 may consist of an air conditioning system as shown in FIG. 2 .

The equipment control device 200 controls the operation of the factory equipment 100.

The energy optimization device 300 controls the operation of the facility control device 200 to optimize energy use of factory facilities.

In one embodiment, the energy optimization device 300 may perform Digital Twin-based MPC (Model Predictive Control) to optimize energy use of factory equipment.

The digital twin-based MPC system 10 for optimizing energy use of factory facilities according to an embodiment of the present invention having the configuration described above is a digital twin-based MPC for optimizing energy use of factory facilities. (Model Predictive Control) can be performed.

FIG. 3 is a diagram showing the air conditioning system of FIG. 2.

Referring to FIG. 3, the air conditioning system 100 includes an air conditioning duct 110, an installation housing 120, a mounting portion 130, a driving motor 140, a head 150, and wings 400.

The air conditioning duct 110 provides a passage for air to move.

The installation housing 120 is installed inside the air conditioning duct 110.

In one embodiment, the installation housing 120 may include a housing body 121, a spherical installation groove 122, a first driving unit 123, a second driving unit 124, and a braking unit 125.

The housing body 121 is installed inside the air conditioning duct 110.

The sphere installation groove 122 is formed at the front end of the housing body 121 so that the mounting sphere 131 can be connected and installed.

The first driving unit 123 is installed inside the sphere installation groove 122 and rotates the mounting sphere 131 connected to the sphere installation groove 122.

In one embodiment, the first driving unit 123 may include a driving unit installation groove 1231, a driving actuator 1232, a wheel housing 1233, and a driving wheel 1234.

The drive unit installation groove 1231 is recessed inside the spherical installation groove 122.

The drive actuator 1232 is installed inside the drive unit installation groove 1231.

The wheel housing 1233 is installed on the drive shaft of the drive actuator 1232.

The drive wheel 1234 is installed in the wheel housing 1233 to enable rotation, and is stored in the drive unit installation groove 1231 as the drive actuator 1232 is contracted and driven, and the drive actuator 1232 is extended and driven. Accordingly, after being exposed from the driving unit installation groove 1231, it comes into close contact with the mounting sphere 131 and is rotated to rotate the mounting sphere 131.

The second driving unit 124 is installed on one side of the spherical installation groove 122 at a right angle to the first driving unit 123, and is connected to the spherical installation groove 122 when the first driving unit 123 is finished driving. The mounting sphere 131 is driven to rotate at right angles to the rotational driving direction of the first driving unit 123.

Here, the second drive unit 124 has the same configuration as the above-described first drive unit 123, and includes the drive unit installation groove 1231, drive actuator 1232, wheel housing 1233, and drive unit of the first drive unit 123. Since the wheel 1234 and the like can be applied equally, their description will be omitted to avoid duplication of explanation.

The braking unit 125 is installed on the other side of the sphere installation groove 122 and brakes the mounting sphere 131 to prevent it from moving.

In one embodiment, the braking unit 125 may include a braking unit installation groove 1251, a braking actuator 1252, and a braking block 1253.

The braking unit installation groove 1251 is recessed on the other side of the spherical installation groove 122.

The braking actuator 1252 is installed inside the braking unit installation groove 1251.

The braking block 1253 is installed on the drive shaft of the driving actuator 1232, and is received in the brake installation groove 1251 as the braking actuator 1252 is contracted and driven, and as the braking actuator 1252 is extended and driven, After being exposed from the eastern installation groove 1251, it comes into close contact with the mounting sphere 131 and prevents the mounting sphere 131 from moving.

The mounting portion 130 is connected to and installed in the installation housing 120.

In one embodiment, the mounting portion 130 may include a mounting sphere 131 and a connecting stand 132.

The mounting sphere 131 is formed in a circular sphere shape and is rotatably connected to the installation housing 120.

The connection stand 132 is formed at the front end of the mounting sphere 131 exposed from the installation housing 120, and the drive motor 140 is installed.

The drive motor 140 is installed at the front of the mounting portion 130 exposed from the installation housing 120.

The head 150 is installed on the drive shaft of the drive motor 140 by shaft coupling and driven to rotate.

A plurality of wings 400 are installed at regular intervals along the circumference of the head 150, and rotate together as the head 150 rotates to induce a flow of air.

The air conditioning system 100 having the above-described configuration can maximize the air conditioning efficiency of the factory by controlling the amount of air flow and varying the wind transmission direction in various ways.

Figure 4 is a diagram showing the wing of Figure 3.

Referring to FIG. 4, the wing 400 includes a first plate 410, a second plate 420, a third plate 430, a first variable connection part 440, and a second variable connection part 450. do.

The first plate 410 is fixedly installed on one side of the head 150.

The second plate 420 is seated on the front end of the first plate 410 by the first variable connection part 440.

The third plate 430 is seated on the front end of the second plate 420 by the second variable connection part 450.

The first variable connection part 440 connects the first plate 410 and the second plate 420 to each other.

In one embodiment, the first variable connection part 440 may include one side connection part 441, the other side connection part 442, and a gap cover 443.

The one-side connection portion 441 connects one side of the first plate 410 and the second plate 420 to each other.

The other side connection portion 442 connects the other sides of the first plate 410 and the second plate 420 to each other.

The gap cover 443 is made of an elastic material capable of expanding and contracting and is installed to cover the upper and other sides of the opposing surfaces of the first plate 410 and the second plate 420, respectively.

The second variable connection part 450 connects the second plate 420 and the third plate 430 to each other.

The wing 400 having the above-described configuration can change its structural characteristics such as expanding or contracting its shape, thereby maximizing the air conditioning efficiency of the factory by variously varying the wind strength and transmission direction. .

Figures 5 to 7 are views showing one side connection part of Figure 4.

Referring to FIGS. 5 to 7 , one side connection part 441 includes a connection sphere 4411, a first sphere fastening part 500, and a second sphere fastening part 4412.

The connection sphere 4411 is formed in a circular sphere shape and is disposed between the first plate 410 and the second plate 420.

The first sphere fastening part 500 is installed on one side of the front end of the first plate 410 and connects the connecting sphere 4411 to be rotatable at the front end of the first plate 410.

In one embodiment, the first sphere fastening part 500 includes a sphere seating groove 510, a curved seating groove 520, a curved plate 530, a sphere support bar 540, and a seating groove opening 550. , may include a first magnetic material 560, a second magnetic material 570, a third magnetic material 580, and a fourth magnetic material 590.

The sphere seating groove 510 is recessed in the front end of the first plate 410 in a hemispherical shape so that half of the connecting sphere 4411 can be seated.

The curved seating groove 520 extends roundly along the inside of the first plate 410 to correspond to the curvature of the spherical seating groove 510.

The curved plate 530 is bent in a round shape corresponding to the curvature of the curved seating groove 520 and is seated inside the curved seating groove 520.

The sphere support bar 540 is installed between the connection sphere 4411 and the curved plate 530, and as the connection sphere 4411 is closely seated in the sphere seating groove 510, the curved plate 530 is curved. It is closely adhered to the inside of the mold seating groove (520).

The seating groove opening 550 forms a communication line from the curved seating groove 520 to the spherical seating groove 510 so that the spherical support bar 540 can move up and down as the connecting sphere 4411 rotates at the same time. do.

A plurality of first magnetic materials 560 are installed at regular intervals in the vertical direction along the inside of the curved seating groove 520.

The second magnetic material 570 forms an opposite polarity to the first magnetic material 560 and is installed in plural pieces at regular intervals in the vertical direction along the rear end of the curved plate 530 facing the first magnetic material 560. The curved plate 530 is fastened to the first magnetic body 560 and moved to the inside of the curved seating groove 520.

A plurality of third magnetic bodies 580 are installed at regular intervals in the vertical direction along one side and the other side of the front end of the curved seating groove 520 where the seating groove opening 550 is formed.

The fourth magnetic material 590 forms an opposite polarity to the third magnetic material 580 and is spaced at regular intervals in the vertical direction along one front side and the other side of the curved plate 530 facing the third magnetic material 580. A plurality of them are installed, and are fastened to the third magnetic material 580 to fasten the curved plate 530 moved to the front end of the curved seating groove 520.

The second sphere fastening part 4412 is installed on one side of the rear end of the second plate 420 while opposing the first sphere fastening part 500, and allows the connection sphere 4411 to be rotated at the rear end of the second plate 420. Connect and install to

Here, the second spherical fastening part 4412 has a structure that is anteroposteriorly symmetrical to the above-described first spherical fastening part 500, and includes a curved seating groove 520 of the spherical seating groove 510, a curved plate 530, The spherical support bar 540, the seating groove opening 550, the first magnetic material 560, the second magnetic material 570, the third magnetic material 580, and the fourth magnetic material 590 can be applied in the same way. To avoid duplication, the explanation will be omitted.

The wing 400 having the above-described configuration extends or contracts in length as shown in FIG. 6, or varies the connection angle between the two plates as shown in FIG. 7, thereby generating wind induced. Not only the amount but also the direction of the wind can be varied.

The above-described embodiments are for illustrative purposes, and those skilled in the art will recognize that the above-described embodiments can be easily modified into other specific forms without changing the technical idea or essential features of the above-described embodiments. You will understand. Therefore, the above-described embodiments should be understood in all respects as illustrative and not restrictive. For example, each component described as single may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope sought to be protected through this specification is indicated by the patent claims described later rather than the detailed description above, and should be interpreted to include the meaning and scope of the claims and all changes or modified forms derived from the equivalent concept. .

10: Digital twin-based MPC system for optimizing factory facility energy use
100: Factory equipment
200: Facility control device
300: Energy optimization device

Claims (3)

factory equipment;
Equipment control device that controls the operation of the factory equipment; and
It includes an energy optimization device that controls the operation of the facility control device to optimize energy use of the factory facility,
The factory equipment is,
It consists of an air conditioning system,
The air conditioning system is,
Air conditioning ducts that provide a passage for air to move;
An installation housing installed inside the air conditioning duct;
A mounting portion connected to the installation housing;
a drive motor installed at the front end of the mounting portion exposed from the installation housing;
A head installed on the drive shaft of the drive motor by shaft coupling and driven to rotate; and
It includes a plurality of wings installed at regular intervals along the circumference of the head and rotating together as the head rotates to induce a flow of air,
The wings are,
a first plate fixedly installed on one side of the head;
a second plate mounted on the front end of the first plate;
a third plate mounted on the front end of the second plate;
a first variable connection part connecting the first plate and the second plate to each other; and
It includes a second variable connection part that connects the second plate and the third plate to each other,
The first variable connection unit,
One side connection portion connecting one side of the first plate and the second plate to each other;
The other side connection part connects the other side of the first plate and the second plate to each other; and
It includes a gap cover made of an elastic material capable of expansion and contraction and installed to cover the upper and other sides of the opposing surfaces of the first plate and the second plate, respectively,
The one side connection part is,
a connecting sphere formed in a circular sphere shape and disposed between the first plate and the second plate;
A first sphere fastening part installed on one side of the front end of the first plate to connect the connecting sphere to be rotatable at the front end of the first plate; and
It includes a second sphere fastening part that is installed on one side of the rear end of the second plate while opposing the first ball fastening part and connects and installs the connecting sphere to be rotatable at the rear end of the second plate,
The first concrete fastening part,
a sphere seating groove recessed in the front end of the first plate in a hemispherical shape so that half of the connecting sphere can be seated;
a curved seating groove extending roundly along the inside of the first plate in response to the curvature of the spherical seating groove;
a curved plate bent in a round shape corresponding to the curvature of the curved seating groove and seated inside the curved seating groove;
A sphere support bar installed between the connecting sphere and the curved plate, and tightly fitting the curved plate to the inside of the curved seating groove as the connecting sphere is closely seated in the sphere seating groove;
A seating groove opening formed in communication from the curved seating groove to the sphere seating groove so that the sphere support bar can move in an up and down direction as the connecting sphere rotates while the sphere support bar is disposed;
a plurality of first magnetic bodies installed at regular intervals in the vertical direction along the inside of the curved seating groove;
A plurality of plates are installed at regular intervals in the vertical direction along the rear end of the curved plate, which forms an opposite polarity to the first magnetic material and faces the first magnetic material, and is fastened to the first magnetic material to form the curved seating groove. a second magnetic body fastening the curved plate moved to the inside of;
a plurality of third magnetic bodies installed at regular intervals in the vertical direction along one side and the other side of the front end of the curved seating groove where the seating groove opening is formed; and
A plurality of plates are installed at regular intervals in the vertical direction along one front side and the other side of the curved plate, which forms an opposite polarity to the third magnetic material and faces the third magnetic material, and is fastened to the third magnetic material to form the curved plate. It includes a fourth magnetic body that fastens the curved plate moved to the front end of the shaped seating groove,
The mounting part,
A mounting sphere formed in a circular sphere shape and rotatably connected to the installation housing; and
It includes a connecting rod formed at the front end of the mounting sphere exposed from the installation housing and on which the driving motor is installed,
The installation housing is,
a housing body installed inside the air conditioning duct;
a sphere installation groove formed at the front end of the housing body so that the mounting sphere can be connected and installed;
A first driving unit installed inside the sphere installation groove to rotate and drive the mounting sphere connected to the sphere installation groove;
It is installed on one side of the sphere installation groove so as to be at a right angle to the first driving part, and when the driving of the first driving part is terminated, the mounting sphere connected to the sphere installation groove is installed at a right angle to the rotational driving direction of the first driving part. a second driving unit that rotates; and
A digital twin-based MPC system for optimizing energy use in factory facilities, including a braking unit installed on the other side of the sphere installation groove to brake the mounting sphere to prevent it from moving.
According to paragraph 1,
The energy optimization device,
A digital twin-based MPC system for optimizing energy use of factory facilities, which performs MPC (Model Predictive Control) based on Digital Twin to optimize energy use of factory facilities.
delete