KR102121379B1 - Control System of Plant with High Temperature and High Pressure Process Using Energy Harvesting - Google Patents

Abstract

The present invention relates to a control system of a plant with a high temperature and high pressure process using energy harvesting which supplies energy unused in a high temperature and high pressure process of the plant as energy harvesting, for power required for a measurement instrument which can operate sensing and control by utilizing a configuration unit capable of the energy harvesting of the plant; and removes physical electrical wires connected to the measurement instrument, thereby reducing measurement instrument O&M cost added for maintenance of a conventional plant and constructing a new plant to reduce construction costs.

Description

Control system of plant with high temperature and high pressure process using energy harvesting

The present invention relates to a control system technology of a plant having a high-temperature and high-pressure process using energy harvesting, and more particularly, to a measuring instrument capable of sensing and controlling by utilizing a configuration unit capable of energy harvesting of the plant. By supplying unused energy to energy harvesting in the high-temperature and high-pressure process of the plant, and removing the physical electric cable connected to the instrument, it reduces the O&M cost of the instrument added for the maintenance of the existing plant and builds a new plant. It relates to a control system of a plant having a high temperature and high pressure process using energy harvesting that can reduce the construction cost.

The new technology of the 4th Industrial Revolution became a global unfold, but even under such circumstances, the energy industry, the national key industry, was conservative in the application of technology. In recent years, according to environmentally-friendly demands, such as prevention of global warming, so-called renewable energy expectations are rising. Renewable energy can also produce electricity in the form of a distributed power source in close proximity to the consumer of electricity, taking additional environmental considerations into account, and has advantages in terms of transmission loss and security of power supply.

The demand for renewable energy began in earnest as a result of the petroleum wave, and currently, development for commercialization of renewable energy such as photovoltaic power generation, recycled energy such as waste power generation, energy new business fields represented by fuel cell vehicles and electric vehicles is in progress. have.

However, the existing power generation system is disadvantageous to access to the management device through the Internet, and when installing the power generation system, the user cannot communicate with the management device without setting to access the Internet. In order to reflect the equipment for the installation, the burden of installing personnel, time, and cost in the power plant increases.

The plant system collects various data from instruments installed in facilities (main machines, auxiliary equipment, etc.) and operates through control systems (PLC, HMI, etc.). The installed instrument needs power, and this power is supplied through a separate power supply. The measuring instrument measures the temperature, pressure, etc. using the supplied electric energy and connects it to the PLC with electric energy. Electric energy connected to PLC is converted into numerical data and used for plant O&M.

In order to operate such a plant, an instrument is installed to grasp the state of the facility (main unit, auxiliary equipment, etc.), and a separate power supply, electricity supply, and measurement signal (electric energy) are used to supply power to the instrument. Electric cables must be installed to transmit to the control system. Due to this, the number of management items in the installation and operation of the plant increases, which increases the cost. In particular, the plant related to high temperature, high pressure, and explosive gas must be manufactured by explosion-proof. At this time, the power supply of the instrument and the electric wire are also installed by explosion-proof. However, the installation cost is more expensive than non-explosion proof.

In Korean Patent Publication No. 10-1818354, an energy harvesting is possible and a movable sensor module, and an air conditioner for measuring air temperature and/or humidity information using the same and controlling air conditioning based thereon, and Disclosed is a control method. However, the description of the control system of a plant having a high temperature and high pressure process using the energy harvesting of the present invention has not been disclosed.

In Korean Patent Registration No. 10-1882968, the piezoelectric harvesting device that does not require operating power can be used to wirelessly control the light and heat of the household, and it is possible to effectively monitor and save energy in the household by measuring the remote meter reading in real time. It relates to an electric energy management and control system. Since a separate battery and electricity supply is not required internally by using a piezoelectric wireless switch, electric energy management and control system using piezoelectric and wireless communication technology that is easy to install for wireless control even in locations where power supply is difficult is disclosed. have. However, the description of the control system of a plant having a high temperature and high pressure process using the energy harvesting of the present invention has not been disclosed.

In Korean Patent Publication No. 2018-0073495, the plant module has a beam-shaped base plate and/or frame, and a plurality of equipment including a machine, particularly a turbo machine, is mounted on the base plate and/or frame, and a plurality The sensor of is mechanically connected to the base plate and/or frame, and is electrically connected to a data processing unit that receives and processes the data detected by the sensor, the sensor being a vibration sensor and/or a distance or displacement sensor and/or a tilt Alternatively, it may be a rotation sensor, and the data collected by the data processing unit discloses a plant module having a sensor device suitable for providing information regarding a person's long-term operation in a module and/or long-term operation of the device. However, the description of the control system of the present invention and a control system of a plant having a high temperature and high pressure process using energy harvesting including an energy harvesting source has not been disclosed.

Plants are generally connected to a number of processes, and in particular, plants with high temperature and high pressure processes have a lot of unused heat and pressure that can be used as an energy source for energy harvesting. Since the electrical energy supplied to the measuring instrument is sufficient for pharmacopeia, there is no need to construct an expensive power generation system.

Therefore, by using the energy harvesting configuration unit of the plant of the present invention, the power required for the instrument that can be operated for sensing and control is supplied to the energy harvesting of unused energy in the high temperature and high pressure process of the plant. , By removing the physical electric wire connected to the instrument, it is possible to reduce the O&M cost of the instrument added for maintenance of the existing plant, and to construct a new plant to reduce the construction cost. Development is necessary.

Korean Registered Patent Publication No. 10-1818354 Korean Registered Patent Publication No. 10-1882968 Korean Patent Publication No. 2018-0073495

Accordingly, the present invention is to control a plant having a high-temperature and high-pressure process using energy harvesting that can supply power to a measuring instrument capable of operating sensing and control by utilizing a configuration unit capable of energy harvesting of the plant. It aims at the development of the system.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

The control system of a plant having a high temperature and high pressure process using energy harvesting to solve the above object includes a reaction unit 100 generating high temperature and/or high pressure; Measuring unit 200 for measuring the reaction unit; A harvesting element unit 300 for obtaining energy from the reaction unit; A local control unit 400 controlling the reaction unit and the harvesting element unit; And a control system unit 500 that receives the information of the local control unit and/or the measurement unit and controls the system using the information.

In addition, the harvesting element portion may use energy harvesting, which is a thermoelectric element portion and/or a piezoelectric element portion.

In addition, the thermoelectric element unit encloses a thermoelectric element in which a P-type thermoelectric semiconductor element and an N-type thermoelectric semiconductor element are alternately placed on the reaction unit through an electrode and an insulator to form a plate-shaped thermoelectric power generation unit. can do.

In addition, the piezoelectric element portion may have a thin plate-shaped body fixedly attached to a pipe formed on one side of the reaction unit, and may be in the form of a jacket embedding a plurality of piezoelectric elements along the pipe surface.

In addition, the thermoelectric element unit may be formed by alternately forming a first high-temperature flow passage through which the high-temperature fluid of the reaction unit passes and a second low-temperature flow passage through which the low-temperature fluid of the reaction unit passes between the plate-shaped thermoelectric power generation units.

In addition, the piezoelectric element unit may be generated by sound pressure or vibration according to the flow of fluid on the piping, and the electromotive force thereby may be supplied to the power storage unit.

In addition, the measuring unit is a thermometer measuring the temperature of the reaction unit and / or the pipe communicating with the reaction unit; Flow meter for measuring the flow rate; And a pressure measuring instrument for measuring the pressure.

In addition, the local control unit is an energy conversion unit 401 for calculating the energy production information through the power generation through the harvesting element unit of the pipe communicating with the reaction unit and / or the reaction unit through the sensing information of the measuring unit; An energy storage unit 402 for storing energy information calculated through the energy conversion unit; And an energy supply unit 403 supplying energy to the measuring unit using the energy information of the energy storage unit.

In addition, a data conversion unit 404 for converting the energy information through the energy conversion unit, the energy storage unit and the energy supply unit to transmit to the control system; A data processing unit 405 for processing the transmission data generated through the data conversion unit; And a data transmission unit 406 for transmitting the transmission data to the control system unit.

In addition, the control system unit data receiving unit 501 for receiving the transmission data from the local control unit; A system data processor 502 for processing data to utilize the transmitted data for system control; And an upper system connection unit 503 for processing control information of the plant using the data processed by the system data processing unit.

In addition, the control system unit may further include an algorithm server that generates control data using any one or more of a mathematical model, a statistical model, an analysis model, a data model, and artificial intelligence.

In addition, energy generated through the harvesting element may be supplied to the measuring unit.

The control system of a plant having a high-temperature and high-pressure process using energy harvesting according to the present invention can efficiently generate thermoelectric power in a fluid having a temperature difference according to the thermoelectric element unit, easy maintenance, relatively low installation space, and conventional power generation It has the effect of providing a stable power supply at a lower cost than the device.

In addition, since there is no need for an electric energy supply line and an electrical signal data line to install a measuring instrument for constructing a control system of a plant having a high-temperature and high-pressure process using energy harvesting, there is an economic effect of reducing the installation cost by simplifying the plant configuration. .

In addition, there is an economic effect of reducing operating costs by eliminating the need for an electric energy supply line and an electric signal data line during plant O&M.

1 is a control system diagram of a plant having a high temperature and high pressure process using energy harvesting applied to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in describing the present invention, when it is determined that detailed descriptions of related well-known structures or functions may obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

The data acquisition of the present invention is connected to the plant unit of the group unit through Bluetooth, etc., collects status information from the field device, and transmits an operation command to the field device.

To this end, the data acquisition may include a device capable of wirelessly connecting a plant unit to collect driving status information and transmit control data for outputting an operation command.

The control system of a plant having a high temperature and high pressure process using energy harvesting includes a reaction unit 100 generating high temperature and/or high pressure; Measuring unit 200 for measuring the reaction unit; A harvesting element unit 300 for obtaining energy from the reaction unit; A local control unit 400 controlling the reaction unit and the harvesting element unit; And a control system unit 500 that receives the information of the local control unit and/or the measurement unit and controls the system using the information.

In addition, the harvesting element portion may use energy harvesting, which is a thermoelectric element portion and/or a piezoelectric element portion.

In addition, the thermoelectric element unit encloses a thermoelectric element in which a P-type thermoelectric semiconductor element and an N-type thermoelectric semiconductor element are alternately placed on the reaction unit through an electrode and an insulator to form a plate-shaped thermoelectric power generation unit. can do.

In addition, the piezoelectric element portion may have a thin plate-shaped body fixedly attached to a pipe formed on one side of the reaction unit, and may be in the form of a jacket embedding a plurality of piezoelectric elements along the pipe surface.

The piezoelectric element part may be basically opened in a pipeline of a predetermined fluid provided in one of a plant structure, device, or piping.

One or more instruments for measuring the characteristics of the piping to the pipe circumference, comprising: a pair of connection flanges that are flange-connected to each of the upstream and downstream sides of the branched portion in the middle of the pipeline, and a branch portion of the pipeline between the respective connection flanges And an inner tube through which fluid can flow.

The bypass pipe having a flow path that diverges from the upstream position of the inner tube to the outer space isolated from the inner tube and rejoins at a downstream position of the inner tube, and is within the flow path of the bypass tube and is rotatable around the inner tube. It may include a rotating body that is installed and rotates on one side of the inner tube installed to allow flow on the flow path of the bypass tube.

It may include a power generating device that is fixed to at least one side of the inner circumferential surface, the outer circumferential surface of the rotator or a constitutional surface constituting the flow path, and generates electricity by rotation of the rotator.

It may be provided with at least one of a power generation sensor or a power storage unit that is electrically connected to the power generation device to obtain information on the power generation state by the power generation device.

At least one of the power generation sensor or the power storage unit may sense the situation around the branched or connected pipeline by acquiring power generation information by the power generation device.

The power storage device may be connected to the instrument to supply the instrument driving power.

The power generation sensor may be provided in or between the flange structure of the pipeline, and the formation position is not limited as long as it can be electrically connected to the power generation device to obtain information on the power generation state.

The power storage device may be provided in the measuring device, but the attachment location outside the measuring device is not limited to the formation position if the power storage device and the measuring device are electrically connected.

In addition, the thermoelectric element unit may be formed by alternately forming a first high-temperature flow passage through which the high-temperature fluid of the reaction unit passes and a second low-temperature flow passage through which the low-temperature fluid of the reaction unit passes between the plate-shaped thermoelectric power generation units.

At the same time, the high temperature fluid is introduced into the first space in the first high temperature flow path and the first high temperature flow channel is discharged from the first high temperature flow path, and the low temperature fluid is flowed in from the second low temperature flow path to the second low temperature flow path. When discharged from the furnace, thermal energy is generated by a temperature difference between the high-temperature fluid and the low-temperature fluid in a thermoelectric device comprising alternating P-type thermoelectric semiconductor elements and N-type thermoelectric semiconductor elements enclosed in an electrothermal plate of a plate-shaped thermoelectric power unit. It can be converted into electrical energy to generate electromotive force and generate electricity.

In addition, the power generation system may be configured by using the thermoelectric element portion to induce high temperature water of the reaction unit as the high temperature fluid into the first space, and at the same time to induce cold water of the reaction unit to the second space as the low temperature fluid. .

In addition, unlike the conventional plant power generation system, the overall structure without evaporator, first turbine, first generator, heater, second turbine, second generator, regenerator, condenser, first working fluid pump, second working fluid pump, etc. This simplifies and avoids the cost increase, and there is no moving parts, and maintenance is not hassle, making the system practical.

In addition, by using the thermoelectric element portion to drive the steam after driving the steam turbine for power generation as the high temperature fluid, the power generation system may be configured to direct cold water to the second space as the low temperature fluid. Such a configuration can generate power by efficiently recovering heat energy, unlike draining cold water as a coolant that has been heated by taking heat from steam in a condenser in a conventional power plant and draining it into a cold storage tank such as the sea.

In addition, by using the thermoelectric element portion, steam or hot water discharged from various plants as the high temperature fluid is introduced into the first space, and at the same time, cold water as the low temperature fluid is introduced into the second space. Therefore, it may be possible to efficiently recover and generate heat energy.

In addition, the piezoelectric element unit may be generated by sound pressure or vibration according to the flow of fluid on the piping, and the electromotive force thereby may be supplied to the power storage unit.

In addition, the measuring unit is a thermometer measuring the temperature of the reaction unit and / or the pipe communicating with the reaction unit; Flow meter for measuring the flow rate; And a pressure measuring instrument for measuring the pressure.

In addition, the local control unit is an energy conversion unit 401 for calculating the energy production information through the power generation through the harvesting element unit of the pipe communicating with the reaction unit and / or the reaction unit through the sensing information of the measuring unit; An energy storage unit 402 for storing energy information calculated through the energy conversion unit; And an energy supply unit 403 supplying energy to the measuring unit using the energy information of the energy storage unit.

The control system of a plant with high-temperature and high-pressure processes using energy harvesting can mean a new and renewable energy distributed power generation facility using solar power, wind power, water power, etc., which is installed near the power demand and needs power. Power can be supplied to the demand area.

Here, when the power generation facility is a photovoltaic generator, for example, a facility such as a solar cell, a solar cell module, an inverter, a power conversion device, or a storage battery can be built near a power demand, and when it is a wind power generator, for example, a rotor , Blades, gearboxes, generators, etc. can be built near the electricity demand.

In addition, the power generation system acquires and stores distributed power generation operation data (eg, each facility and the operating state of each facility) generated through execution of distributed power generation, and wirelessly transmits the stored distributed power generation operation data when entering the communication area. It can provide a function such as.

The power generation system may include a power generation control unit, a data management unit, a data storage unit, an aircraft authentication unit, a control logic management unit, and a data transmission/reception unit.

The power generation control unit may provide a function for controlling the operation of various facilities constituting the power generation system according to the control logic for operating the distributed power stored in the control logic management unit described later.

In addition, a data conversion unit 404 for converting the energy information through the energy conversion unit, the energy storage unit and the energy supply unit to transmit to the control system; A data processing unit 405 for processing the transmission data generated through the data conversion unit; And a data transmission unit 406 for transmitting the transmission data to the control system unit.

In addition, the control system unit data receiving unit 501 for receiving the transmission data from the local control unit; A system data processor 502 for processing data to utilize the transmitted data for system control; And an upper system connection unit 503 for processing control information of the plant using the data processed by the system data processing unit.

The local control unit and the control system unit of the group unit may be connected to each other in a daisy chain form within the corresponding group. In addition, data acquisition involves connecting multiple units of group units through multiple transceivers, and multiple data acquisitions are installed according to the site, and such multiple data acquisitions are configured such that the main server is a tree-structured distributed control server. I can do it.

Data acquisition supports communication by providing a data transceiving unit to transmit and receive status information and operation commands of field devices collected through the main server and the integrated DB.

On the other hand, the data acquisition may be provided with a network connection unit to be connected to the Ethernet network so that the operator can check the operation status of the data acquisition through the monitor terminal at the control unit.

The distribution board of the harvesting element unit may be configured as any device as long as it can convert the DC current from the power generation unit into an alternating current. Preferably, the DC current produced in the case and the power generation unit in the case is alternating current. It may include an inverter for switching to, a transformer for converting the low-voltage AC current of the inverter to a high-voltage AC current, and a power transmission panel for transmitting the AC current of the transformer to the distribution network outside the case.

The switchboard may further include a current collector that collects direct current from the power generation unit.

In addition, the control system unit may further include an algorithm server that generates control data using any one or more of a mathematical model, a statistical model, an analysis model, a data model, and artificial intelligence.

At this time, the local control unit is grouped according to the site, and not only is connected to one transceiver, but is also connected to the other transceiver to be duplicated, so that an error or noise can be prevented from affecting adjacent groups, and communication reliability can be improved by redundancy.

Claims (12)

A reaction unit 100 generating high temperature and/or high pressure;
A measuring unit 200 measuring the reaction unit;
A harvesting element unit 300 for obtaining energy from the reaction unit;
A local control unit 400 controlling the reaction unit and the harvesting element unit;
A control system for a plant having a high temperature and high pressure process using energy harvesting, including; a control system unit 500 that receives information from the local control unit and/or the measurement unit and controls the system using the information. According to claim 1,
The harvesting element part is a thermoelectric element part and/or a control system for a plant having a high temperature and high pressure process using energy harvesting which is a piezoelectric element part. According to claim 2,
The thermoelectric element unit encapsulates a thermoelectric element in which a P-type thermoelectric semiconductor element and an N-type thermoelectric semiconductor element are alternately placed on the reaction unit through an electrode and an insulator, thereby forming energy in a plate-shaped thermoelectric power generation unit. Plant control system with high temperature and high pressure process using harvesting. According to claim 2,
The piezoelectric element portion has a thin plate-shaped body fixedly attached to a pipe formed on one side of the reaction unit, and a plant having a high-temperature and high-pressure process using energy harvesting, which is a jacket type incorporating a plurality of piezoelectric elements along the pipe surface. Control system. According to claim 3,
The thermoelectric element unit is a high temperature using energy harvesting formed by alternating a first high temperature flow path through which the high temperature fluid of the reaction unit passes and a second low temperature flow path through which the low temperature fluid of the reaction unit passes between the plate-shaped thermoelectric power generation units, Plant control system with high pressure process. The method of claim 4,
The piezoelectric element unit is a control system for a plant having a high temperature and high pressure process using energy harvesting, which is generated by sound pressure or vibration according to the flow of fluid on the piping and the electromotive force is supplied to the power storage unit. According to claim 1,
The measuring unit is a thermometer measuring the temperature of the reaction unit and / or the pipe communicating with the reaction unit;
Flow meter for measuring the flow rate; And
Pressure measuring instrument for measuring the pressure; Control system of a plant having a high-temperature, high-pressure process using energy harvesting. According to claim 1,
The local control unit is an energy conversion unit 401 which calculates energy production information through power generation through the harvesting element unit of the reaction unit and/or a pipe communicating with the reaction unit through sensing information of the measurement unit unit;
An energy storage unit 402 for storing energy information calculated through the energy conversion unit; And
Control system for a plant having a high-temperature, high-pressure process using energy harvesting, including; an energy supply unit 403 for supplying energy to the measuring unit using the energy information of the energy storage unit. The method of claim 8,
A data conversion unit 404 that converts energy information through the energy conversion unit, energy storage unit, and energy supply unit to be transmitted to the control system;
A data processing unit 405 for processing the transmission data generated through the data conversion unit; And
A control system for a plant having a high temperature and high pressure process using energy harvesting, including; a data transmission unit 406 for transmitting the transmission data to the control system unit. According to claim 1,
The control system unit is a data receiving unit 501 for receiving transmission data from the local control unit;
A system data processor 502 for processing data to utilize the transmitted data for system control; And
A control system for a plant having a high temperature and high pressure process using energy harvesting, including; an upper system connection unit 503 for processing control information of a plant using data processed by the system data processing unit. The method of claim 10,
The control system unit further includes an algorithm server generating control data using any one or more of a hydraulic model, a statistical model, an analysis model, a data model, and artificial intelligence, and a high temperature and high pressure process using energy harvesting. Plant control system. According to claim 1,
The energy generated through the harvesting element part is a control system of a plant having a high temperature and high pressure process using energy harvesting supplied to the measuring device part.

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