WO2017113464A1 - Wirelessly rechargeable zigbee network wireless air pressure sensor - Google Patents

Abstract

A wirelessly rechargeable ZigBee network wireless air pressure sensor, comprising a ZigBee wireless communication module, an analog air pressure sensor, a wireless charging circuit, and an induction coil, wherein the analog air pressure sensor detects a change in the air pressure, generates an analog output signal, and transmits the analog output signal to the ZigBee wireless communication module; the signal output by the ZigBee wireless communication module is sent to a ZigBee wireless network by means of an antenna; the wireless charging circuit transfers energy to a Qi wireless charging transmitter by means of the induction coil; the wireless charging circuit is connected to a lithium battery; the lithium battery supplies power to the analog air pressure sensor by means of a boost circuit; the boost circuit supplies power to the ZigBee wireless communication module by means of a power supply conversion circuit. The air pressure sensor overcomes the defects that a sensor needs to be disassembled and assembled frequently for changing a rechargeable battery on site due to short battery life, achieves wireless charging of the air pressure sensor on site, and greatly prolongs the live-line continuous use time of the sensor.

Description

 Wireless charging ZigBee network wireless air pressure sensor

Technical field

The invention relates to a wireless charging ZigBee network wireless air pressure sensor, belonging to the ZigBee network wireless air pressure sensor innovation technology.

Background technique

Conventional air pressure measuring devices generally use mechanical barometers for direct measurement or single sensor measurements. Data acquisition is done by manual field readings. Mechanical barometer measurements are simple, but require a lot of labor and poor real-time performance in the data acquisition process. Human error is also prone to occur; when there is a large amount of air pressure on the site (such as a large number of airbags in the airbag construction technology), it takes a lot of time to read all the air pressure data. The wireless air pressure sensor network based on the ZigBee network mode can measure the air pressure of multiple measuring points and collect the air pressure data of each air pressure point through the ZigBee coordinator, and then display it through the PC interface, or through the network protocol converter. Send it to the cloud and view barometric data on your phone, tablet, and more.

ZigBee technology is an emerging wireless network technology with close proximity, low complexity, low power consumption, low data rate and low cost. ZigBee technology can give full play to its advantages in situations where data collection or monitoring is required, network data is small, equipment costs are low, data transmission security is high, equipment size is small, terrain is complex, and network coverage is required. . And the ZigBee Alliance has developed a globally open standard for designing reliable, cost-effective, low-power wireless network monitoring and control products.

The wireless sensor network composed of ZigBee technology is a medium- and short-range, low-rate wireless sensor network. Low RF transmission cost, each node requires only a small amount of energy; low power consumption, suitable for long-term battery power supply; can achieve point-to-multipoint, two-point peer-to-peer communication; with rapid network automatic configuration, automatic recovery function; The sensors can coordinate with each other to achieve data communication. It can be applied to industrial control, modern agricultural monitoring, digital home, intelligent building monitoring, environmental monitoring and other fields.

The air pressure sensor based on the ZigBee network is driven by a lithium ion battery. Due to the limited battery capacity, the primary charging sensor can only work for a limited time. Therefore, due to the poor battery life of the existing sensor at the use site, there is a problem that the sensor needs to be frequently disassembled to replace the rechargeable battery. With the continuous development and maturity of wireless charging technology, the problem of limited battery life of traditional industrial detection technology sensor node power supply is also solved. The wireless charging technology means that a device having a battery is charged by wirelessly acquiring electric power such as electromagnetic induction. The emergence of wireless charging technology, in order to solve the problem that the existing battery technology can not keep up with the development of electronic products, so that users get relatively convenient and fast charging needs; Second, the existing non-uniform electronic product power interface can be unified To solve the problem of versatility of charging equipment; third, wireless charging does not require an external charging interface, thereby solving the problem of water immersion in electronic products, and also preventing dust from entering electronic products.

Summary of the invention

It is an object of the present invention to provide a wireless air pressure sensor in a wirelessly chargeable ZigBee network mode. The invention solves the trouble that the battery life of the sensor is poor due to poor battery life and the need to frequently disassemble the sensor to replace the rechargeable battery, and realizes the function of charging the air pressure sensor on the spot by the wireless charging transmitter, thereby greatly improving the continuous use time of the sensor.

The technical solution of the present invention is: the wirelessly chargeable ZigBee network wireless air pressure sensor of the present invention comprises a ZigBee wireless communication module, an analog air pressure sensor, a wireless charging circuit and an induction coil, wherein the analog air pressure sensor detects the air pressure change to generate an analog output signal. Transmitted to the ZigBee wireless communication module, the signal output by the ZigBee wireless communication module is sent to the ZigBee wireless network via the antenna, the wireless charging circuit transmits energy through the induction coil and the Qi wireless charging transmitter, and the wireless charging circuit is connected with the lithium battery, and the lithium battery is passed through The voltage circuit supplies power to the analog air pressure sensor, and the boost circuit supplies power to the ZigBee wireless communication module through the power conversion circuit.

The technical solution adopted by the present invention compares with other technologies, and the present invention uses a Qi wireless charging transmitter to charge the sensor in the field. In addition to the advantages of waterproof and dustproof sensors, the invention can effectively solve the sensor in addition to outdoor use. The terminal node needs to constantly change the battery, and can ensure that the node does not lose power for a long time, and solves the problem that the sensor uses the site due to poor battery life and needs to frequently disassemble the sensor to replace the rechargeable battery, thereby realizing the charging of the air pressure sensor on site. The function of charging the transmitter greatly improves the continuous use time of the sensor; in addition, the invention can timely reflect the problem and the cause through the indicator light regardless of the failure of the battery or the charging power source, and can protect the central control chip from being damaged by the high voltage current. . The sensor of the invention can be applied to the airbag air pressure monitoring, on-site industrial control, tire pressure monitoring, environmental monitoring, medical treatment and the like in ship launching construction.

DRAWINGS

Figure 1 is a schematic block diagram of the present invention.

detailed description

Example:

The principle block diagram of the present invention is shown in FIG. 1. The wirelessly charged ZigBee network wireless air pressure sensor is characterized by comprising a ZigBee wireless communication module, an analog air pressure sensor, a wireless charging circuit and an induction coil, wherein the analog air pressure sensor detects the air pressure change. The analog output signal is transmitted to the ZigBee wireless communication module, and the signal output by the ZigBee wireless communication module is sent to the ZigBee wireless network via the antenna, the wireless charging circuit transmits energy through the induction coil and the Qi wireless charging transmitter, and the wireless charging circuit is connected to the lithium battery. The lithium battery supplies power to the analog air pressure sensor through the boost circuit, and the boost circuit supplies power to the ZigBee wireless communication module through the power conversion circuit.

In this embodiment, the charging control circuit includes a charging control chip, and the charging control chip transmits energy through the induction coil and the Qi wireless charging transmitter.

In this embodiment, the ZigBee wireless communication module includes a radio frequency front end amplifying circuit and a radio frequency communication circuit, and the radio frequency communication circuit includes a microprocessor and an RF transceiver, and the analog air pressure sensor detects the air pressure change to generate an analog output signal through the A/D conversion port. Transmitted to the microprocessor, the signal output by the microprocessor is sent by the RF transceiver and the RF amplifying circuit to the ZigBee wireless network via the antenna.

In this embodiment, the boosting circuit supplies power to the radio frequency communication circuit and the radio frequency front end amplifying circuit through the power conversion circuit.

In this embodiment, the microprocessor is connected to the indication module.

In this embodiment, the indication module includes a power status indicator, a network status indicator, and an operation status indicator.

In this embodiment, the wireless charging circuit realizes the transmission of electric energy through the induction coil and the Qi wireless charging transmitter through a wireless manner.

In this embodiment, the induction coil is an induction coil of the type 760308101303 manufactured by Würth, Germany. The above Qi wireless charging transmitter is a Qi standard using the Wireless Charging Alliance (WPC).

The working principle of the invention is as follows: as shown in FIG. 1 , when the lithium battery is low in power, the battery is charged by using the Qi wireless charging transmitter. When charging, the wireless charging transmitter is connected to the external power source and connected through the Würth induction coil. The charging control chip determines whether the lithium battery is charged after the judgment of the charging control chip. If the voltage state provided by the adapter meets the charging standard, the charging control chip charges the lithium battery according to the set charging current. After the lithium battery is full, the charging control chip The charging mode is automatically terminated. When the system enters the normal working process, after the lithium battery is turned on, the voltage of 3.7V is changed to the standard 5V voltage by the booster circuit. After a voltage of 5V is passed through the 3.3V voltage conversion circuit, the voltage is supplied to the RF communication circuit and the RF. The front-end amplifier circuit works normally; the other 5V voltage is used for the analog air pressure sensor to work normally. .

The embodiments of the present invention have been described in detail above with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described above, and various modifications may be made within the scope of the knowledge of those skilled in the art.

Claims (9)

1. A wirelessly chargeable ZigBee network wireless air pressure sensor, comprising a ZigBee wireless communication module, an analog air pressure sensor, a wireless charging circuit and an induction coil, wherein the analog air pressure sensor detects a change in air pressure to generate an analog output signal for transmission to a ZigBee wireless communication Module, the signal output by the ZigBee wireless communication module is sent to the ZigBee wireless network via the antenna, the wireless charging circuit transmits energy through the induction coil and the Qi wireless charging transmitter, and the wireless charging circuit is connected with the lithium battery, and the lithium battery passes the boosting circuit to simulate the air pressure. The sensor is powered, and the boost circuit supplies power to the ZigBee wireless communication module through the power conversion circuit.
2. The wirelessly chargeable ZigBee network wireless air pressure sensor according to claim 1, wherein the charging control circuit comprises a charging control chip, and the charging control chip transmits energy through the induction coil and the Qi wireless charging transmitter.
3. The wirelessly chargeable ZigBee network wireless air pressure sensor according to claim 1, wherein the ZigBee wireless communication module comprises a radio frequency front end amplifying circuit and a radio frequency communication circuit, and the radio frequency communication circuit comprises a microprocessor and an RF transceiver, and the analog air pressure is The sensor detects the change of the air pressure and generates an analog output signal to the microprocessor through the A/D conversion port. The signal output by the microprocessor is sent by the RF transceiver and the RF amplifying circuit to the ZigBee wireless network via the antenna.
4. The wirelessly chargeable ZigBee network wireless air pressure sensor according to claim 3, wherein the boosting circuit supplies power to the radio frequency communication circuit and the radio frequency front end amplifying circuit through the power conversion circuit.
5. The wirelessly chargeable ZigBee network wireless air pressure sensor of claim 3 wherein said microprocessor is coupled to an indicator module.
6. The wirelessly chargeable ZigBee network wireless air pressure sensor according to claim 5, wherein the indication module comprises a power status indicator, a network status indicator, and an operation status indicator.
7. The wirelessly chargeable ZigBee network wireless air pressure sensor according to any one of claims 1 to 6, wherein the wireless charging circuit realizes the transmission of electric energy by means of an induction coil and a Qi wireless charging transmitter.
8. The wirelessly chargeable ZigBee network wireless air pressure sensor according to claim 7, wherein said induction coil is an induction coil of the type 760308101303.
9. The wirelessly chargeable ZigBee network wireless air pressure sensor according to claim 7, wherein said Qi wireless charging transmitter is a Qi standard using a wireless charging alliance.