阅读说明：本技术 一种供热装置智能安全监测控制系统及方法 (Intelligent safety monitoring control system and method for heat supply device ) 是由 支建伟 韩磊 许新平 于 2020-12-29 设计创作，主要内容包括：本发明涉及一种供热装置智能安全监测控制系统及方法,由供热装置、监测模块、分控制节点、用户节点和智能控制系统组成,供热装置通过供热管道和分控制节点以及用户节点连接,监测模块和智能控制系统通过传感装置和供热管道连接；所述监测模块包括定位传感器、信号接收器、显示屏和用户端,定位传感器安装在传感器装置内,传感器装置分布在供热管道各端口上,定位传感器通过信号接收器和监测模块连接,监测模块内设置图像分析装置和数据处理装置,通过图像分析装置和数据处理装置生成红外成像,红外成像利用显示屏显示推送给客户端。本发明通过智能管理系统和监测模块一方面及时发现供热系统出现的问题,另一方面实现智能化管理,降低管理监测成本。(The invention relates to an intelligent safety monitoring control system and method for a heating device, which consists of the heating device, a monitoring module, a sub-control node, a user node and an intelligent control system, wherein the heating device is connected with the sub-control node and the user node through a heating pipeline; the monitoring module comprises a positioning sensor, a signal receiver, a display screen and a user side, the positioning sensor is installed in a sensor device, the sensor device is distributed on each port of the heat supply pipeline, the positioning sensor is connected with the monitoring module through the signal receiver, an image analysis device and a data processing device are arranged in the monitoring module, infrared imaging is generated through the image analysis device and the data processing device, and the infrared imaging is pushed to the client side through the display screen. According to the intelligent heat supply system, the problems of the heat supply system are found in time through the intelligent management system and the monitoring module, intelligent management is achieved, and management and monitoring cost is reduced.)

1. The intelligent heating device safety monitoring control system is characterized by comprising a heating device (100), a monitoring module (200), branch control nodes (300), user nodes (400) and an intelligent control system (500), wherein the heating device (100) is connected with the branch control nodes (300) and the user nodes (400) through a heating pipeline (102), and the monitoring module (200) is connected with the intelligent control system (500) through a sensing device (501) and the heating pipeline (102).

2. The intelligent heating device safety monitoring control system and the intelligent heating device safety monitoring control method according to claim 1, wherein the monitoring module (200) comprises a positioning sensor (503), a signal receiver (513), a display screen (204) and a user terminal (205), the positioning sensor (503) is installed in the sensor device (501), the sensor device (501) is distributed on each port of the heating pipeline (102), the positioning sensor (503) is connected with the monitoring module (200) through the signal receiver (513), an image analysis device (201) and a data processing device (202) are arranged in the monitoring module (200), an infrared image (203) is generated through the image analysis device (201) and the data processing device (202), and the infrared image (203) is displayed by the display screen (204) and pushed to the client terminal (205).

3. A heating installation intelligent safety monitoring control system and method according to claim 1, characterized in that the intelligent control system (500) comprises a sensor device (501), a signal sensing device (510), an a/D converter (511), an amplifier (512), a signal receiver (513) and a control unit (514); the sensor device (501) is composed of a positioning sensor (503) and a pressure sensor (502), the positioning sensor (503) and the pressure sensor (502) are installed on each port of the heat supply pipeline (102), the pressure sensor (502) at one end of the information sensing equipment (510) is connected with the intelligent control system (500), and the other end of the information sensing equipment (510) is connected with the control unit (514) through an A/D converter (511), an amplifier (512) and a signal receiver (513).

4. The intelligent heating device safety monitoring and control system and method according to claim 3, wherein the control unit (514) is connected with the master control point (210) through a signal (515), the master control point (210) is provided with a master control valve (211), the master control valve (211) is connected with the branch control nodes (300) through a heating pipeline (102), the branch control nodes (300) are provided with branch control valves (311), the branch control valves (311) are connected with the user nodes (400) through the heating pipeline (102), the user nodes (400) are provided with heating valves (411), and the heating valves (411) are connected with the users (410) through heating channels (401).

5. A heating device intelligent safety monitoring control system and method according to claim 3, characterized in that the heating device (100) is composed of a heating box (101), a heating pipeline (102) and a heating main valve (103), the heating box (101) is provided with the heating main valve (103), and the heating main valve (103) is connected with each device through the heating pipeline (102).

6. The intelligent heating device safety monitoring and control system and method according to claim 3, wherein the main heating valve (103), the main control valve (211), the sub-control valves (311) and the heating valve (411) are all provided with a positioning sensor (503) and a pressure sensor (502).

7. A heating device intelligent safety monitoring control system and method according to claim 4, characterized in that each floor is equipped with a sub-control node (300) and a user node (400), and the lower end of the user node (400) is connected with a plurality of users (410) through a heating channel (401).

8. A heating device intelligent safety monitoring control system and method according to claim 4, characterized in that the branch control node (300) controls the opening and closing of the branch control valve (311) through the control system (500), the user node (400) controls the opening and closing of the heating valve (411) through the control system (500), the branch control node (300) and the user node (400) are both arranged on the heating pipeline (102), and the branch control node (300) and the user node (400) are connected with the control unit (514) in the control system (500) through signals (515).

Technical Field

The invention relates to the technical field of heating, in particular to an intelligent safety monitoring control system and method for a heating device.

Background

With the rapid development of economy and the improvement of the living standard of people, the demand of people for domestic hot water and heating hot water is continuously increased. According to statistical data, the proportion of the building energy consumption in China to the total social energy consumption is 22-25%, wherein about 40% of the building energy consumption is used for building heating, and the energy consumption of central heating by adopting a heat supply network or central heating by a community in northern urban areas accounts for about 60% of the building heating energy consumption. With the improvement of living standard, many newly-built communities in Yangtze river basin begin to adopt centralized heat supply at present, and many cities plan large-scale centralized heat supply networks. Therefore, the region with the demand of centralized heating is more and more extensive. In addition, the building area is rapidly increased, the heating demand is greatly increased, and the national pressure of energy conservation and emission reduction is increased day by day.

At present, the heat supply is generally that a boiler burns fossil fuel to produce low-temperature hot water (60-90 ℃) for directly supplying to users for heating, or a heat supply station is utilized to convert the hot water (primary side hot water) with the temperature of about 130 ℃ in a centralized heat supply network into the low-temperature hot water (secondary side hot water) for supplying to the users for heating. At present, a heat storage heat source is generally adopted as a heat supply source to supply heat in the existing heat supply system, and the switching of the heat supply source needs manpower and manual work to realize. Therefore, when the heat storage heat source fails and can not provide energy continuously, or when one heat source can not meet the requirement for reducing the heat supply cost, the heat source can not be switched in time, and certain inconvenience is caused to life. Especially in cold winter, if the heat source breaks down or can not continuously provide the heat source in the heat supply process, if the heat source is not switched in time, the heat stop phenomenon can not only occur, but also certain loss can be caused because the heat supply device is damaged by cold weather. In addition, the monitoring and the control of the heating device are completed manually, so that the problems of the heating system are not easy to find in time on the one hand, and the manual management monitoring is high in cost and low in efficiency and is not easy to manage on the other hand.

A heating system and method for controlling the heating system with application number CN201910725453.3, including heat source, controller, heat exchange device, user terminal and heating network; the heat source is provided with a plurality of heat sources, the heat sources are respectively connected with the heat exchange device, and at least one of the heat sources is used for supplying energy to the heat supply system; the heat exchange device is used for allowing hot fluid from the heat source to flow to the user side under the action of the heat exchange device and then to flow back to the heat source from the user side; the system comprises a user side and a secondary heat supply system, wherein the user side comprises a primary user side and a secondary heat supply system, the secondary heat supply system is connected in parallel to a water return pipe of a heat supply network, the secondary heat supply system is provided with the secondary user side, and the secondary heat supply system supplies heat to the secondary user side by using heat energy of the water return pipe; the heat supply network comprises a water inlet pipe and a water return pipe, and the two ends of the water inlet pipe and the two ends of the water return pipe are respectively and fixedly connected with the heat exchange device and the user side.

The invention can effectively utilize the heat of the returned water after heat supply by setting the temperature of the returned water, thereby being more environment-friendly and energy-saving, and in addition, the invention can store the redundant energy. But in the use process, on the one hand, the monitoring and the control of the heating device are manually completed, so that the intelligent data management is not facilitated, and on the other hand, the manual management monitoring cost is high and the efficiency is low, so that the problems of the heating system can not be found in time.

Disclosure of Invention

In view of the above, the present invention provides an intelligent monitoring and controlling system and method for a heating apparatus, which mainly uses intelligent monitoring and controlling for the heating apparatus, and realizes intelligent management of the heating apparatus through the intelligent monitoring system and the controlling system, thereby improving the working efficiency and realizing the safety monitoring and controlling at the same time.

The invention relates to an intelligent safety monitoring control system and method for a heating device.

Furthermore, the monitoring module comprises a positioning sensor, a signal receiver, a display screen and a user side, the positioning sensor is installed in the sensor device, the sensor device is distributed on each port of the heat supply pipeline, the positioning sensor is connected with the monitoring module through the signal receiver, an image analysis device and a data processing device are arranged in the monitoring module, infrared imaging is generated through the image analysis device and the data processing device, and the infrared imaging is displayed and pushed to the client side through the display screen.

Further, the intelligent control system comprises a sensor device, a signal sensing device, an A/D converter, an amplifier, a signal receiver and a control unit; the sensor device consists of a positioning sensor and a pressure sensor, the positioning sensor and the pressure sensor are installed on each port of the heat supply pipeline, the pressure sensor at one end of the information sensing equipment is connected with the intelligent control system, and the other end of the information sensing equipment is connected with the control unit through an A/D converter, an amplifier and a signal receiver.

Further, the control unit is connected with a master control point through a signal, a master control valve is arranged on the master control point, the master control valve is connected with branch control nodes through a heat supply pipeline, branch control valves are arranged on the branch control nodes and connected with user nodes through the heat supply pipeline, a heating valve is installed on the user nodes, and the heating valve is connected with users through a heating channel.

Furthermore, the heat supply device consists of a heat supply box, a heat supply pipeline and a heat supply main valve, wherein the heat supply box is provided with the heat supply main valve, and the heat supply main valve is connected with each device through the heat supply pipeline.

Furthermore, a positioning sensor and a pressure sensor are arranged on the heat supply main valve, the main control valve, the sub-control valves and the heat supply valve.

Furthermore, each floor is provided with a sub-control node and a user node, and the lower end of the user node is connected with a plurality of users through a heating channel.

Furthermore, the branch control nodes control the opening and closing of the branch control valves through the control system, the user nodes control the opening and closing of the heating valves through the control system, the branch control nodes and the user nodes are arranged on the heating pipeline, and the branch control nodes and the user nodes are connected with the control unit in the control system through signals.

The intelligent safety monitoring control system and method for the heating device provided by the invention have the following beneficial effects.

1. The invention provides an intelligent safety monitoring control system and method for a heat supply device, which consists of the heat supply device, a monitoring module, sub-control nodes, user nodes and an intelligent control system; the monitoring module is connected with the positioning sensor through the signal receiver, the image analysis device and the data processing device are arranged in the monitoring module, the infrared imaging is generated through the image analysis device and the data processing device, the display screen is used for displaying and pushing the infrared imaging to the client side, and the fact that the pipeline is maintained and replaced accurately is achieved by timely monitoring the heat supply pipeline.

2. The invention provides an intelligent safety monitoring control system and method for a heating device, which realize the intelligent management of the heating device through a sensor device, a signal sensing device, an A/D converter, an amplifier, a signal receiver and a control unit in an intelligent control system, wherein pressure sensors are arranged on a main heating valve, a main control valve, a sub-control valve and a heating valve, and the accurate management and control of heat are realized through a main control point, sub-control nodes and user nodes when the flow change in a pipeline is detected in time.

3. According to the intelligent safety monitoring control system and method for the heating device, the sub-control nodes and the user nodes are used, so that the users can independently heat, on one hand, other users cannot be influenced when the heating faults of the users occur, and on the other hand, the faults are more easily found, and the maintenance is convenient in time.

Drawings

Fig. 1 is a general diagram of an intelligent safety monitoring control system and method for a heating device according to the present invention;

FIG. 2 is a diagram of a heating apparatus according to the intelligent safety monitoring and controlling system and method of the heating apparatus of the present invention;

FIG. 3 is a flow chart of an intelligent safety monitoring control system and a monitoring module of the heating device according to the present invention;

FIG. 4 is a diagram of a control unit of an intelligent safety monitoring control system and method for a heating device according to the present invention;

fig. 5 is a flow chart of an intelligent safety monitoring control system and an intelligent control system method for a heating device according to the present invention.

Wherein: 100. the system comprises a heating device, 101, a heating box, 102, a heating pipeline, 103, a heating main valve, 200, a monitoring module, 201, an image analysis device, 202, a data processing device, 203, infrared imaging, 204, a display screen, 205, a client, 210, a main control point, 211, a main control valve, 300, a sub-control node, 311, a sub-control valve, 400, a user node, 401, a heating channel, 410, a user, 411, a heating valve, 500, an intelligent control system, 501, a sensor device, 502, a pressure sensor, 503, a positioning sensor, 510, a signal sensing device, 511, an A/D converter, 512, an amplifier, 513, a signal receiver, 514, a control unit, 515 and a signal.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments.

Referring to fig. 1 and 4, the system and method for monitoring and controlling the intelligent safety of a heating device according to the present invention includes a heating device 100, a monitoring module 200, a sub-control node 300, a user node 400 and an intelligent control system 500, wherein the heating device 100 is connected to the sub-control node 300 and the user node 400 through a heating pipeline 102, and the monitoring module 200 and the intelligent control system 500 are connected to the heating pipeline 102 through a sensing device 501.

Referring to fig. 3, the monitoring module 200 includes a positioning sensor 503, a signal receiver 513, a display screen 204 and a user terminal 205, the positioning sensor 503 is installed in the sensor device 501, the sensor device 501 is distributed on each port of the heat supply pipeline 102, the positioning sensor 503 is connected to the monitoring module 200 through the signal receiver 513, an image analysis device 201 and a data processing device 202 are arranged in the monitoring module 200, an infrared image 203 is generated through the image analysis device 201 and the data processing device 202, and the infrared image 203 is displayed and pushed to the client terminal 205 by the display screen 204.

Referring to fig. 5, the intelligent control system 500 includes a sensor device 501, a signal sensing apparatus 510, an a/D converter 511, an amplifier 512, a signal receiver 513, and a control unit 514; the sensor device 501 is composed of a positioning sensor 503 and a pressure sensor 502, the positioning sensor 503 and the pressure sensor 502 are installed on each port of the heat supply pipeline 102, the pressure sensor 502 is connected with the intelligent control system 500 at one end of an information sensing device 510, and the other end of the information sensing device 510 is connected with a control unit 514 through an A/D converter 511, an amplifier 512, a signal receiver 513.

The control unit 514 is connected with the master control point 210 through a signal 515, a master control valve 211 is arranged on the master control point 210, the master control valve 211 is connected with the branch control nodes 300 through a heat supply pipeline 102, the branch control nodes 300 are provided with branch control valves 311, the branch control valves 311 are connected with the user nodes 400 through the heat supply pipeline 102, the user nodes 400 are provided with heating valves 411, and the heating valves 411 are connected with the users 410 through heating channels 401.

The heating device 100 is composed of a heating box 101, a heating pipeline 102 and a heating main valve 103, wherein the heating box 101 is provided with the heating main valve 103, and the heating main valve 103 is connected with each device through the heating pipeline 102. The purpose of the heat supply pipeline 102 is to facilitate the heat energy transfer of the heat supply tank 101, and the accuracy of heat transfer is better realized through the heat supply main valve 103.

And the main heating valve 103, the main control valve 211, the branch control valve 311 and the heating valve 411 are all provided with a positioning sensor 503 and a pressure sensor 502. The main heating valve 103, the main control valve 211, the sub-control valve 311 and the heating valve 411 are provided with the positioning sensor 503 and the pressure sensor 502, so that on one hand, the working condition of each valve can be monitored, and the valves can be maintained and replaced conveniently in the future, and on the other hand, the positioning sensor 503 and the pressure sensor 502 can accurately capture a data image generated in a place with problems, and intelligent management is facilitated.

Referring to fig. 1, each floor is provided with a sub-control node 300 and a user node 400, and the lower end of the user node 400 is connected to a plurality of users 410 through a heating passage 401.

Referring to fig. 4, the sub-control node 300 controls the opening and closing of the sub-control valve 311 through the control system 500, the user node 400 controls the opening and closing of the heating valve 411 through the control system 500, the sub-control node 300 and the user node 400 are both disposed on the heating pipeline 102, and the sub-control node 300 and the user node 400 are connected to the control unit 514 in the control system 500 through a signal 515. The control node 300 controls the opening and closing of the sub-control valve 311, and the user node 400 controls the opening and closing of the heating valve 411 through the control system 500, so that the sub-control node 300 and the user node 400 cooperate with each other to facilitate the independent use of heating of the user 410, and the problem of heating of one user 410 cannot be caused to affect other users.

According to the intelligent safety monitoring control system and method for the heat supply device, during working, heating air in a heat supply box 101 is conveyed to a user 410 through a heat supply pipeline 102 through a heat supply main valve 103, in the process, a monitoring module 200 is connected with a positioning sensor 503 through a signal receiver 513, an image analysis device 201 and a data processing device 202 are arranged in the monitoring module 200, an infrared imaging 203 is generated through the image analysis device 201 and the data processing device 202, the infrared imaging 203 is displayed and pushed to a client 205 through a display screen 204, and the heat supply pipeline 102 is monitored in time to facilitate accurate maintenance and replacement of the pipeline. Secondly, intelligent management of the heating device is realized through a sensor device 501, a signal sensing device 510, an A/D converter 511, an amplifier 512, a signal receiver 513 and a control unit 514 in the intelligent control system 500, a positioning sensor 503 and a pressure sensor 502 are arranged on a main heating valve 103, a main control valve 211, a branch control valve 311 and a heating valve 411, accurate management and control of heat are realized through a main control point 210, a branch control node 300 and a user node 400 by detecting flow change in a pipeline in time, the intelligent control system 500 can amplify signals in the heating pipeline 102 through the pressure sensor 502 by the A/D converter 511 through the amplifier 512 and then transmit the signals to the signal receiver 513, the signal receiver 513 receives the signals to the control unit 514, the control unit 514 controls the main control point 210, the branch control node 300 and the user node 400 through a signal 515, this allows the heating main valve 103, the main control valve 211, the sub control valves 311 and the heating valve 411 in each of the main control point 210, the sub control nodes 300 and the user nodes 400 to be freely opened and closed.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.