CN106855704A - A data collector that connects construction equipment information to the cloud - Google Patents

Abstract

The invention discloses a kind of data acquisition unit in Architectural Equipment information access high in the clouds, Architectural Equipment operation information can in real time easily be accessed into high in the clouds, and be adapted to different applied environments, it is ensured that data are reliably uploaded incessantly.The data acquisition unit includes：Equipment accesses circuit, controller, high in the clouds access circuit and power supply circuit；Wherein, the equipment accesses circuit and is connected with gateway and controller respectively, and the high in the clouds is accessed circuit and is connected with cloud device by network, and the power supply circuit is each power elements of data acquisition unit by the controller；The controller is used to access circuit acquisition Architectural Equipment information by equipment according to first data transmission agreement, and the Architectural Equipment information is sent into cloud device by high in the clouds access circuit according to the second Data Transport Protocol.

Description

A data collector that connects construction equipment information to the cloud

technical field

The invention relates to the technical field of data collection, in particular to a data collector for connecting construction equipment information to the cloud.

Background technique

Building energy consumption in developed countries generally accounts for about 33% of the country's total energy consumption. With the acceleration of a country's urbanization process and the improvement of people's quality of life, the building area is increasing year by year, and building energy consumption is gradually increasing. Building energy consumption will become the weakness of the country's economic development, and building energy conservation will become an important way to save energy and reduce emissions. content.

Building energy conservation should start from two aspects of "opening up sources of income and reducing expenditure". Open source is to vigorously develop the building application of renewable energy such as solar energy and wind energy. Savings is the efficient and optimal use of traditional building equipment such as lighting, HVAC, and power equipment. Photovoltaic building microgrid can realize the coordinated operation of source and load at the same time, which is an important form of building energy saving and has been vigorously promoted by the government and enterprises.

With the large-scale promotion and application of solar buildings, it is necessary to carry out operation and maintenance, fault diagnosis and system optimization of photovoltaic building micro-grids, and conduct energy consumption analysis. The traditional monitoring network is an independent system inside the building. Investment and monitoring information are only owned by the building owner, forming an information island. maintenance costs. The intelligent building operation and maintenance cloud platform can cope with the rapid growth of the number of photovoltaic buildings, and can store, process, statistically analyze and make decisions on the massive data of photovoltaic building equipment operation, which is the development direction of photovoltaic building operation and maintenance. How to conveniently and quickly transmit the equipment information of the photovoltaic building micro-grid to the cloud platform, and conduct centralized operation and maintenance based on big data analysis is an urgent problem to be solved.

Contents of the invention

One of the purposes of the present invention is at least to provide a data collector for connecting construction equipment information to the cloud in view of the problems existing in the above-mentioned prior art, which can conveniently connect construction equipment operation information to the cloud in real time, and can adapt to different The application environment ensures uninterrupted and reliable uploading of data, provides a data basis for big data analysis and optimization decision-making, and then improves the operation and maintenance management level of photovoltaic building microgrids.

In order to achieve the above object, the technical scheme adopted in the present invention is:

A data collector for connecting construction equipment information to the cloud, which includes: a device access circuit, a controller, a cloud access circuit, and a power supply circuit;

Wherein, the device access circuit is connected to the gateway and the controller respectively, the cloud access circuit is connected to the cloud device through the network, and the power supply circuit supplies power to each component of the data collector through the controller;

The controller is used to obtain construction equipment information through the equipment access circuit according to the first data transmission protocol, and send the construction equipment information to the cloud equipment through the cloud access circuit according to the second data transmission protocol.

Preferably, the shown controller adopts STM32 chip.

Preferably, the data collector further includes a gateway, one end of which is connected to the construction equipment through the first bus, and the other end is connected to the controller through the equipment access circuit, so as to transmit the construction equipment information to the controller.

Preferably, the gateway uses an intelligent node unit FT3150, which includes a neuron processor Neuron3150, a clock reset circuit, an FT-X1 transceiver, an electromagnetic interference isolation unit, a coupling circuit, and FLASH; wherein the coupling circuit is connected to the building microgrid Supervisory system bus or directly to the field bus of individual building equipment, the Neuron processor Neuron 3150 is connected to the equipment access circuit and communicates by way of serial peripheral interface SPI.

Preferably, the device access circuit includes an AT89S52 microcontroller connected to the gateway and a MAX485 chip connected to the controller.

Preferably, the cloud access circuit adopts GPRS circuit, WIFI circuit, or LAN circuit.

Preferably, the data collector further includes a memory for storing construction equipment information, building environment information, data collector environment information, and data collector operating status information.

Preferably, the data collector further includes an alarm unit, which is used to send out an alarm message through sound, light, or electrical signal when the data collector fails.

Preferably, the data collector further includes an environment monitoring unit, which is used to monitor the environment around the data collector in real time and obtain environmental information of the data collector.

Preferably, the building equipment information includes building environment information, and the building environment information includes one or more of temperature, humidity, irradiance, wind speed, and wind direction of the building environment.

In summary, due to the adoption of the above technical solution, the present invention at least has the following beneficial effects:

1. The present invention can connect construction equipment operation information to the cloud in real time without affecting the real-time and stable operation of the building microgrid, and realize the storage of massive data of construction equipment in the cloud, which provides the possibility for big data analysis and optimization decision-making.

2. The present invention directly communicates with construction equipment through Lonworks bus and RS485 bus, which has strong equipment compatibility and convenient access.

3. The present invention can be connected to the cloud through various methods such as GPRS, WIFI, LAN, etc., adapting to different application environments, and ensuring uninterrupted and reliable uploading of data.

4. The invention makes the photovoltaic building microgrid shift from independent operation and maintenance to cloud centralized operation and maintenance, which helps to improve the operation and maintenance level of the photovoltaic building microgrid and promotes the popularization and application of the photovoltaic building microgrid.

Description of drawings

Fig. 1 is a schematic structural diagram of a data collector for accessing construction equipment information to the cloud according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of the application of a data collector in a data collection system according to another embodiment of the present invention;

3 is a schematic structural diagram of a gateway in a data collector according to an embodiment of the present invention;

Fig. 4 is a schematic diagram of a circuit structure of a data collector according to another embodiment of the present invention.

In the figure: 1. Gateway, 2. Data collector, 3. Cloud platform, 4. Smart node unit FT3150, 5. Neuron processor Neuron 3150, 6. Clock reset circuit, 7. FT-X1 transceiver, 8. Electromagnetic interference isolation unit, 9. Coupling circuit, 10. FLASH, 11. AT89S52 microcontroller, 12. MAX485 chip, 13. Clock circuit, 14. EEPROM, 15. JTAG interface, 16. GPRS circuit, 17. WiFi circuit, 18. LAN circuit, 19. power supply circuit, 20. environmental monitoring unit, 21. alarm unit, 22. STM32 chip.

detailed description

In the following, the present invention will be further described in detail in conjunction with the accompanying drawings and embodiments, so as to make the purpose, technical solutions and advantages of the present invention more clear. It should be understood that the specific embodiments described here are only used to explain the present invention, not to limit the present invention.

As shown in FIG. 1 , a data collector for accessing construction equipment information to the cloud according to an embodiment of the present invention includes: an equipment access circuit, a controller, a cloud access circuit, and a power supply circuit. Wherein, the device access circuit (for example, 485 interface circuit) is connected to the gateway and the controller respectively, the cloud access circuit is connected to the cloud device through the network, and the power supply circuit is the data collector through the controller. Each component is powered; the controller is used to obtain construction equipment information through the equipment access circuit according to the first data transmission protocol, and send the construction equipment information to the cloud equipment through the cloud access circuit according to the second data transmission protocol. In this embodiment, the gateway device is set outside the data collector. In other embodiments, the gateway may also be included within the data collector.

Fig. 2 is a schematic structural diagram of the application of the data collector in the data collection system according to another embodiment of the present invention. As shown in Figure 2, building equipment information is transmitted on the Lonworks bus (a field bus structure) with the Lontalk protocol. First, the Lontalk protocol is converted to the 485 bus protocol by the gateway 1, then the 485 protocol is converted to the TCP/IP protocol by the data collector 2, and then the network (for example, local area network, metropolitan area network, wide area network, and the Internet) is passed through the TCP/IP protocol. etc.) to transmit the construction equipment information to the cloud platform 3 (for example, a cloud device including a plurality of cluster servers).

Fig. 3 shows the structure of the gateway in the data collector according to an embodiment of the present invention. The gateway adopts intelligent node unit FT31504, which includes neuron processor Neuron 3150 5, clock reset circuit 6, FT-X1 transceiver 7, electromagnetic interference isolation unit 8, coupling circuit 9, and FLASH 10; wherein, coupling circuit 8 is connected to To the building micro-grid monitoring system bus or directly connected to the field bus of a single building device, the neuron processor Neuron 3150 5 is connected to the AT89S52 microcontroller 11 in the device access circuit, and through the SPI (Serial Peripheral Interface, serial peripheral interface ) way to communicate.

Fig. 4 shows the circuit structure of a data collector according to yet another embodiment of the present invention. As shown in Figure 4, the controller adopts STM32 chip 22, which is respectively connected to MAX485 chip 12, clock circuit 13, EEPROM 14, JTAG (Joint Test Action Group, joint test working group) interface 15, GPRS circuit 16, WiFi circuit 17, LAN circuit 18, power supply circuit 19, environment monitoring unit 20, and alarm unit 21.

Wherein, the power supply circuit 19 supplies power to each component of the data collector through the controller. The clock circuit 13 is used to provide a high-precision clock signal. The AT89S52 single-chip microcomputer 11 in the equipment access circuit performs 485 protocol conversion by controlling the MAX485 chip 12, and inputs the building equipment information data received through the gateway into the STM32 chip 22 through the equipment access circuit; the STM32 chip 22 further passes through the GPRS circuit 16, WiFi Cloud access circuits such as circuit 17 and LAN circuit 18 send building equipment information to cloud devices such as cloud platform 3 according to network communication protocols such as TCP/IP protocol, IPX/SPX protocol, and NetBEUI protocol.

The JTAG interface 15 can be used to write programs to the data collector. The environment monitoring unit 20 is used to monitor the environment around the data collector in real time, and acquire environmental information of the data collector. The alarm unit 21 is used for sending out alarm information through sound, light, or electric signal when the data collector fails. The EEPROM 14 can be used to store building equipment information, building environment information, data collector environment information, data collector operating status information and the like acquired by the STM32 chip 22 .

The above description is only a detailed description of specific embodiments of the present invention, rather than limiting the present invention. Various replacements, modifications and improvements made by those skilled in the relevant technical fields without departing from the principle and scope of the present invention shall be included in the protection scope of the present invention.

Claims (10)

1. A data collector for connecting building equipment information to the cloud, characterized in that the data collector includes: a device access circuit, a controller, a cloud access circuit, and a power supply circuit; Wherein, the device access circuit is connected to the gateway and the controller respectively, the cloud access circuit is connected to the cloud device through the network, and the power supply circuit supplies power to each component of the data collector through the controller; The controller is used to obtain construction equipment information through the equipment access circuit according to the first data transmission protocol, and send the construction equipment information to the cloud equipment through the cloud access circuit according to the second data transmission protocol. 2. The data collector according to claim 1, characterized in that, the shown controller adopts an STM32 chip. 3. The data collector according to claim 1, wherein the data collector further comprises a gateway, one end of which is connected to the building equipment through the first bus, and the other end is connected to the controller through the device access circuit, so as to Transfer building equipment information to the controller. 4. data collector according to claim 3, is characterized in that, described gateway adopts intelligent node unit FT3150, and it comprises neuron processor Neuron 3150, clock reset circuit, FT-X1 transceiver, electromagnetic interference isolation unit, Coupling circuit, and FLASH; wherein, the coupling circuit is connected to the building microgrid monitoring system bus or directly connected to the field bus of a single building device, and the neuron processor Neuron 3150 is connected to the device access circuit and uses the serial peripheral interface SPI way of communication. 5. The data collector according to claim 1, wherein the device access circuit comprises an AT89S52 microcontroller connected to the gateway and a MAX485 chip connected to the controller. 6. The data collector according to claim 1, wherein the cloud access circuit adopts a GPRS circuit, a WIFI circuit, or a LAN circuit. 7. The data collector according to claim 1, wherein the data collector further comprises a memory for storing construction equipment information, building environment information, data collector environment information, and data collector operating status information . 8. The data collector according to claim 1, characterized in that, the data collector further comprises an alarm unit, which is used to send an alarm message through sound, light, or electrical signal when the data collector fails. 9. The data collector according to claim 1, characterized in that, the data collector further comprises an environment monitoring unit, which is used to monitor the environment around the data collector in real time and obtain environmental information of the data collector. 10. The data collector according to claim 1, wherein the building equipment information includes building environment information, and the building environment information includes temperature, humidity, irradiance, wind speed, and wind direction of the building environment one or more.