CN105783078A - Heat energy area heating control system and method - Google Patents

Abstract

The invention relates to a heat energy area heating control system and method. The system comprises hardware equipment and software equipment. The hardware equipment comprises a gas-fired boiler, an auxiliary power distribution cabinet, a heat energy area heating controller and an indoor temperature wireless monitor. The software equipment comprises a heat energy monitoring and management platform. The heat energy area heating control system is easy to operate and reasonable in design. By the adoption of the heat energy area heating controller, all devices in a boiler room can be monitored and controlled in real time, real-time data of all the devices are collected, and the data are displayed and recorded. The heat energy area heating controller can regulate and control the devices automatically according to instructions of the upper-layer heat energy monitoring and management platform, furnace firemen can manually operate any device through the heat energy area heating controller when necessary, and therefore the operating efficiency of single device bodies and the entire heating system can be improved.

Description

Heating power energy regional heating control system and method thereof

[ technical field ] A method for producing a semiconductor device

The invention relates to a heating power energy regional heating control system and a heating power energy regional heating control method, and belongs to the technical field of intelligent heating.

[ background of the invention ]

The utility model discloses a heat supply system, including ordinary boiler, the platform is equipped with the instruction, the heat supply data lack the heat supply trade expert to it is to. Heat source, accessory equipment, a controller, a platform and a management method in the existing heating industry are all in independent states, and do not have integral interaction and linkage functions, the equipment is operated without data support and operated by manual experience, the deviation of the operation of each equipment and the optimal working condition is large, the operation efficiency of single equipment is low, so that the efficiency of an integral heating system is extremely low, a heat strategy is not targeted, the real-time adjustment according to the actual building heat load requirement cannot be realized, the monitoring of the indoor temperature of a user is not realized, and whether the heating quality reaches the standard or not cannot be ensured. On the basis, blind energy conservation is not based and unscientific, and causes low professional level and high mobility of the furnace personnel and high labor cost of heat supply enterprises.

[ summary of the invention ]

The invention aims to: aiming at the defects and shortcomings of the prior art, the system and the method for controlling the regional heat supply of the thermal energy are provided, the aim is to perform fine management and energy conservation on the whole heat supply system on the premise of reasonable and scientific heat supply, and the efficiency of the heat supply system is greatly improved.

In order to achieve the purpose, the invention adopts the technical scheme that:

a heating power energy regional heating control system comprises hardware equipment and software equipment, wherein the hardware equipment comprises a gas boiler, an auxiliary power distribution cabinet, a heating power energy regional heating controller and an indoor temperature wireless monitor, and the software equipment comprises a heating power energy monitoring and managing platform;

wherein,

the gas boiler supplies heat for the whole system;

the thermal energy monitoring and management platform collects building information and then calculates real-time thermal load demand of the building, a background transversely/longitudinally compares similar project management experiences, and a heat supply expert online combines project characteristics such as project energy consumption high/low peak so as to obtain an optimal heat supply strategy according with the building and sends the heat supply strategy to a thermal energy regional heat supply controller in a network transmission mode;

the system comprises a heat energy source area heat supply controller, an auxiliary power distribution cabinet, a heat energy source monitoring management platform, a heat energy source area heat supply controller, a water/electricity/gas/heat flow meter parameter, a valve opening, an equipment start-stop state, water temperature, pressure, user indoor temperature, real-time outdoor meteorological data and other heat supply data, wherein the heat energy source area heat supply controller is used for receiving an optimal heat supply strategy sent by the heat energy source monitoring management platform, translating the received optimal heat supply strategy into a control instruction, calculating and compiling the control instruction through a control logic, and then translating the control instruction into a corresponding control signal, and sending the control signal to the auxiliary power distribution cabinet through various communication protocols;

the auxiliary power distribution cabinet is used for receiving a control signal sent by the thermal energy regional heat supply controller, and sending the control signal to the controlled equipment through an intermediate relay, wherein the signal is stable, safe and free of interference. Meanwhile, the auxiliary power distribution cabinet sends a signal fed back by the controlled equipment to the heat energy regional heat supply controller through an intermediate relay;

the indoor temperature wireless monitor is used for summing and processing indoor temperature, humidity, indoor temperature wireless detector equipment number, data uploading time, electric quantity and historical information of a heating user. And uploading the data to a thermal energy monitoring and management platform through GPRS signals.

A control method of a heating control system of a heating energy area comprises the following steps:

the method comprises the following steps: the building information including building function types, building heights, building structure forms, building outer window materials, building heat preservation forms, building heat transfer coefficients, building heat supply areas, building heating forms and building geographical position data are summarized through the thermal energy monitoring and management platform, and real-time thermal loads of the building physics theory are calculated through the summarized data. Combining with background horizontal/longitudinal comparison similar project management experience, and combining project energy consumption high/low peak and other project characteristics on line by a heat supply expert to obtain an optimal heat supply strategy according with the building;

step two: the heating power energy regional heating controller monitors heating data such as water/electricity/gas/heat flow meter parameters, valve opening, equipment starting and stopping states, water temperature, pressure, user indoor temperature, real-time outdoor weather related data and the like in a heating system in real time, and feeds back the heating data to the upper heating power energy monitoring and management platform through network transmission;

step three: the heat supply strategy formulated by the heat energy monitoring and management platform is transmitted to a heat energy regional heat supply controller in a network transmission mode, the heat energy regional heat supply controller translates the received heat supply strategy into a control instruction, translates the control instruction into a corresponding control signal after calculation and compilation by the control logic of the controller, and transmits the control signal to the auxiliary power distribution cabinet through various communication protocols;

step four: after receiving the control signal, the auxiliary power distribution cabinet issues a stable, safe and interference-free signal to controlled equipment such as a boiler, a water pump and a valve through an intermediate relay, and real-time operation data, real-time equipment state and an early warning alarm signal acquired by the controlled equipment in the operation process are transmitted to a heating power energy area heat supply controller through the auxiliary power distribution cabinet in real time;

step five: the heat energy regional heating controller carries out interface display, history recording, alarm recording and alarm prompting on data generated in all heating systems, and uploads all operation parameters, equipment starting and stopping, equipment states and equipment alarms to the heat energy monitoring and management platform, so that the platform is more efficient and accurate in data summarization, sorting, analysis and comparison as the whole heating data;

step six: the thermal energy monitoring and management platform combines the comprehensive data of building function types, building heights, building structure forms, building outer window materials, building heat preservation forms, building heat transfer coefficients, building heat supply areas, building heating forms and project geographic positions through the heat supply data, the user indoor temperatures and the outdoor meteorological data which are received in real time, calibrates and calculates the real-time heat load requirements of different buildings of each project again, and corrects the heat supply strategy through expert online analysis, so that the heat supply efficiency is improved to the maximum degree.

After the method is adopted, the invention has the beneficial effects that:

1. a gas boiler is used as a heat source, so that the monomer efficiency of the heat source part is improved;

2. the system comprises a thermal energy regional heat supply controller, a monitoring management platform, a heating system and a control system, wherein the thermal energy regional heat supply controller is used for monitoring and controlling all devices in a boiler room in real time, acquiring real-time data of all the devices, displaying and recording the data, and automatically adjusting and controlling the devices according to instructions of the upper thermal energy monitoring management platform;

3. the collected data are classified, summarized, compared and analyzed by combining a thermal energy monitoring and management platform, and heat supply experts make, correct and guide heat supply strategies for different projects on line according to the data;

4. the thermal energy monitoring and management platform combines the comprehensive data of building function types, building heights, building structure forms, building outer window materials, building heat preservation forms, building heat transfer coefficients, building heat supply areas, building heating forms and project geographic positions through the heat supply data, the user indoor temperatures and the outdoor meteorological data which are received in real time, calibrates and calculates the real-time heat load requirements of different buildings of each project again, and corrects the heat supply strategy through expert online analysis, so that the heat supply efficiency is improved to the maximum degree.

[ description of the drawings ]

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, and are not to be considered limiting of the invention, in which:

FIG. 1 is a schematic diagram of the system architecture of the present invention.

[ detailed description ] embodiments

The present invention will now be described in detail with reference to the drawings and specific embodiments, wherein the exemplary embodiments and descriptions are provided only for the purpose of illustrating the present invention and are not to be construed as limiting the present invention.

As shown in fig. 1, a heat energy district heating control system includes hardware devices and software devices, wherein the hardware devices include a gas boiler, an auxiliary power distribution cabinet, a heat energy district heating controller and an indoor temperature wireless monitor, and the software devices include a heat energy monitoring management platform;

wherein,

the gas boiler supplies heat for the whole system;

the thermal energy monitoring and management platform collects building information and then calculates real-time thermal load demand of the building, a background transversely/longitudinally compares similar project management experiences, and a heat supply expert online combines project characteristics such as project energy consumption high/low peak so as to obtain an optimal heat supply strategy according with the building and sends the heat supply strategy to a thermal energy regional heat supply controller in a network transmission mode;

the system comprises a heat energy source area heat supply controller, an auxiliary power distribution cabinet, a heat energy source monitoring management platform, a heat energy source area heat supply controller, a water/electricity/gas/heat flow meter parameter, a valve opening, an equipment start-stop state, water temperature, pressure, user indoor temperature, real-time outdoor meteorological data and other heat supply data, wherein the heat energy source area heat supply controller is used for receiving an optimal heat supply strategy sent by the heat energy source monitoring management platform, translating the received optimal heat supply strategy into a control instruction, calculating and compiling the control instruction through a control logic, and then translating the control instruction into a corresponding control signal, and sending the control signal to the auxiliary power distribution cabinet through various communication protocols;

the auxiliary power distribution cabinet is used for receiving a control signal sent by the thermal energy regional heat supply controller, and sending the control signal to the controlled equipment through an intermediate relay, wherein the signal is stable, safe and free of interference. Meanwhile, the auxiliary power distribution cabinet sends a signal fed back by the controlled equipment to the heat energy regional heat supply controller through an intermediate relay;

the indoor temperature wireless monitor is used for summing and processing indoor temperature, humidity, indoor temperature wireless detector equipment number, data uploading time, electric quantity and historical information of a heating user. And uploading the data to a thermal energy monitoring and management platform through GPRS signals.

A control method of a heating control system of a heating energy area comprises the following steps:

the method comprises the following steps: the building information including building function types, building heights, building structure forms, building outer window materials, building heat preservation forms, building heat transfer coefficients, building heat supply areas, building heating forms and building geographical position data are summarized through the thermal energy monitoring and management platform, and real-time thermal loads of the building physics theory are calculated through the summarized data. Combining with background horizontal/longitudinal comparison similar project management experience, and combining project energy consumption high/low peak and other project characteristics on line by a heat supply expert to obtain an optimal heat supply strategy according with the building;

step two: the heating power energy regional heating controller monitors heating data such as water/electricity/gas/heat flow meter parameters, valve opening, equipment starting and stopping states, water temperature, pressure, user indoor temperature, real-time outdoor weather related data and the like in a heating system in real time, and feeds back the heating data to the upper heating power energy monitoring and management platform through network transmission;

step three: the heat supply strategy formulated by the heat energy monitoring and management platform is transmitted to a heat energy regional heat supply controller in a network transmission mode, the heat energy regional heat supply controller translates the received heat supply strategy into a control instruction, translates the control instruction into a corresponding control signal after calculation and compilation by the control logic of the controller, and transmits the control signal to the auxiliary power distribution cabinet through various communication protocols;

step four: after receiving the control signal, the auxiliary power distribution cabinet issues a stable, safe and interference-free signal to controlled equipment such as a boiler, a water pump and a valve through an intermediate relay, and real-time operation data, real-time equipment state and an early warning alarm signal acquired by the controlled equipment in the operation process are transmitted to a heating power energy area heat supply controller through the auxiliary power distribution cabinet in real time;

step five: the heat energy regional heating controller carries out interface display, history recording, alarm recording and alarm prompting on data generated in all heating systems, and uploads all operation parameters, equipment starting and stopping, equipment states and equipment alarms to the heat energy monitoring and management platform, so that the platform is more efficient and accurate in data summarization, sorting, analysis and comparison as the whole heating data;

step six: the thermal energy monitoring and management platform combines the comprehensive data of building function types, building heights, building structure forms, building outer window materials, building heat preservation forms, building heat transfer coefficients, building heat supply areas, building heating forms and project geographic positions through the heat supply data, the user indoor temperatures and the outdoor meteorological data which are received in real time, calibrates and calculates the real-time heat load requirements of different buildings of each project again, and corrects the heat supply strategy through expert online analysis, so that the heat supply efficiency is improved to the maximum degree.

The above description is only a preferred embodiment of the present invention, and all equivalent changes or modifications of the structure, characteristics and principles described in the present invention are included in the scope of the present invention.

Claims (2)

1. A heating power energy regional heating control system is characterized in that: the system comprises hardware equipment and software equipment, wherein the hardware equipment comprises a gas boiler, an auxiliary power distribution cabinet, a thermal energy regional heat supply controller and an indoor temperature wireless monitor, and the software equipment comprises a thermal energy monitoring and management platform;

wherein,

the gas boiler supplies heat for the whole system;

the thermal energy monitoring and management platform collects building information and then calculates real-time thermal load demand of the building, a background transversely/longitudinally compares similar project management experiences, and a heat supply expert online combines project characteristics such as project energy consumption high/low peak so as to obtain an optimal heat supply strategy according with the building and sends the heat supply strategy to a thermal energy regional heat supply controller in a network transmission mode;

the system comprises a heat energy source area heat supply controller, an auxiliary power distribution cabinet, a heat energy source monitoring management platform, a heat energy source area heat supply controller, a water/electricity/gas/heat flow meter parameter, a valve opening, an equipment start-stop state, water temperature, pressure, user indoor temperature, real-time outdoor meteorological data and other heat supply data, wherein the heat energy source area heat supply controller is used for receiving an optimal heat supply strategy sent by the heat energy source monitoring management platform, translating the received optimal heat supply strategy into a control instruction, calculating and compiling the control instruction through a control logic, and then translating the control instruction into a corresponding control signal, and sending the control signal to the auxiliary power distribution cabinet through various communication protocols;

the auxiliary power distribution cabinet is used for receiving a control signal sent by the thermal energy regional heat supply controller, and sending the control signal to the controlled equipment through an intermediate relay, wherein the signal is stable, safe and free of interference. Meanwhile, the auxiliary power distribution cabinet sends a signal fed back by the controlled equipment to the heat energy regional heat supply controller through an intermediate relay;

the indoor temperature wireless monitor is used for summing and processing indoor temperature, humidity, indoor temperature wireless monitor equipment number, data uploading time, electric quantity and historical information of a heating user, and uploading the data to a heating power energy monitoring and management platform through GPRS signals.

2. A control method of a heating power energy regional heating control system is characterized by comprising the following steps: the method comprises the following steps:

the method comprises the following steps: the building information including building function types, building heights, building structure forms, building outer window materials, building heat preservation forms, building heat transfer coefficients, building heat supply areas, building heating forms and building geographical position data are summarized through the thermal energy monitoring and management platform, and real-time thermal loads of the building physics theory are calculated through the summarized data. Combining with background horizontal/longitudinal comparison similar project management experience, and combining project energy consumption high/low peak and other project characteristics on line by a heat supply expert to obtain an optimal heat supply strategy according with the building;

step two: the heating power energy regional heating controller monitors heating data such as water/electricity/gas/heat flow meter parameters, valve opening, equipment starting and stopping states, water temperature, pressure, user indoor temperature, real-time outdoor weather related data and the like in a heating system in real time, and feeds back the heating data to the upper heating power energy monitoring and management platform through network transmission;

step three: the heat supply strategy formulated by the heat energy monitoring and management platform is transmitted to a heat energy regional heat supply controller in a network transmission mode, the heat energy regional heat supply controller translates the received heat supply strategy into a control instruction, translates the control instruction into a corresponding control signal after calculation and compilation by the control logic of the controller, and transmits the control signal to the auxiliary power distribution cabinet through various communication protocols;

step four: after receiving the control signal, the auxiliary power distribution cabinet issues a stable, safe and interference-free signal to controlled equipment such as a boiler, a water pump and a valve through an intermediate relay, and real-time operation data, real-time equipment state and an early warning alarm signal acquired by the controlled equipment in the operation process are transmitted to a heating power energy area heat supply controller through the auxiliary power distribution cabinet in real time;

step five: the heat energy regional heating controller carries out interface display, history recording, alarm recording and alarm prompting on data generated in all heating systems, and uploads all operation parameters, equipment starting and stopping, equipment states and equipment alarms to the heat energy monitoring and management platform, so that the platform is more efficient and accurate in data summarization, sorting, analysis and comparison as the whole heating data;

step six: the thermal energy monitoring and management platform combines the comprehensive data of building function types, building heights, building structure forms, building outer window materials, building heat preservation forms, building heat transfer coefficients, building heat supply areas, building heating forms and project geographic positions through the heat supply data, the user indoor temperatures and the outdoor meteorological data which are received in real time, calibrates and calculates the real-time heat load requirements of different buildings of each project again, and corrects the heat supply strategy through expert online analysis, so that the heat supply efficiency is improved to the maximum degree.