CN210036813U - Remote environment measuring system - Google Patents

Abstract

The utility model discloses a remote environment measuring system, which comprises a measuring mechanism, a measuring device and a receiving device; the measuring mechanism comprises a mechanism body and an environment measuring sensor arranged on the mechanism body, wherein the environment measuring sensor comprises a wind vane, a compass, a level gauge and an anemometer; the measuring device comprises an environment measuring module, a key processing module, a power management module, a display module and a first wireless module; the input end of the environment measuring module is connected with the environment measuring sensor, and the output end of the environment measuring module is electrically connected with the display module and the first wireless module; the output end of the key processing module is electrically connected with the display module and the power management module; the output end of the power management module is electrically connected with the display module and the first wireless module; the receiving device comprises a PC communication module and a second wireless module which are electrically connected with each other. This novel system small in size easily carries and installs, but remote wireless control's characteristic is particularly suitable for the outdoor use occasion that needs remove in the certain limit.

Description

Remote environment measuring system

Technical Field

The utility model relates to an environmental measurement technical equipment specifically indicates a long-range environmental measurement system.

Background

The general environment measuring instrument comprises an environment measuring sensor module, a control module, a display module and a portable battery module, wherein the control module acquires data of the environment measuring sensor at regular time and sends the data to the display module to display a measuring result after the data is processed.

The existing environment measuring instrument can only achieve independent measurement of one or more environment parameters, integrated measurement cannot be achieved in a unified device, the environment measuring instrument is inconvenient to carry and install and is not suitable for being used in mobile environments such as the field, and the problem to be solved urgently is to be solved by designing a remote environment measuring system suitable for the mobile environment.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a long-range environment measurement system, small in size easily carries and installs, but long-range wireless control's characteristic is particularly suitable for the outdoor use occasion that needs remove in the certain limit.

In order to achieve the above purpose, the solution of the present invention is:

a remote environment measuring system comprises a measuring mechanism, a measuring device and a receiving device; the measuring mechanism comprises a mechanism body and an environment measuring sensor arranged on the mechanism body, wherein the environment measuring sensor comprises a wind vane, a north pointer, a level meter and an anemometer which are uniformly arranged on the mechanism body; the measuring device is arranged on the mechanism body and comprises an environment measuring module, a key processing module, a power management module, a display module and a first wireless module; the input end of the environment measuring module is connected with the environment measuring sensor, and the output end of the environment measuring module is electrically connected with the display module and the first wireless module; the output end of the key processing module is electrically connected with the display module and the power management module; the output end of the power management module is electrically connected with the display module and the first wireless module; the receiving device comprises a PC communication module and a second wireless module which are electrically connected with each other.

The system comprises at least two measuring devices and at least two receiving devices, wherein the at least two measuring devices are used for forming a multi-terminal measuring network and are provided with at least two measuring mechanisms in one-to-one correspondence.

The mechanism body comprises a support frame and a connecting rod, the connecting rod is installed on the support frame through a universal mechanism, and an environment measuring sensor is arranged on the connecting rod.

Each sensing component of the environment measuring sensor is detachably arranged on the mechanism body.

The measuring device is arranged on the mechanism body through a detachable mechanism.

After adopting above-mentioned scheme, this novel remote environment measurement system, for prior art's beneficial effect lie in: this novel measurement system has integrated environmental parameter and has measured, long-range wireless control, further has the long-range environmental measurement system of functions such as many network measurement, power, small in size easily carries and installs, but long-range wireless control's characteristic is particularly suitable for the outdoor use occasion that needs remove in the certain limit, uses very simply, convenient.

Drawings

FIG. 1 is a functional block diagram of the novel remote environmental measurement system;

FIG. 2 is a schematic view of the measuring device on a measuring mechanism;

FIG. 3 is a remote environment measurement system networking diagram;

FIG. 4 is a power management module work flow diagram;

FIG. 5 is a display module workflow diagram;

fig. 6 is a first wireless module workflow diagram;

fig. 7 is a receiving apparatus operation flowchart.

Description of the reference symbols

A mechanism body 1, a support frame 11, a connecting rod 12, an environment measuring sensor 2,

a wind vane 21, a compass 22, a level 23, an anemometer 24,

a measuring device 3, a measuring device one 301, a measuring device two 302, a measuring device three 303,

measuring device four 304, environment measuring module 31, key processing module 32,

a power management module 33, a display module 34, a first wireless module 35,

a receiving device 4, a receiving device one 401, a receiving device two 402, a receiving device three 403,

a fourth receiving device 404, a PC communication module 41 and a second wireless module 42.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and embodiments.

The present disclosure relates to a remote environment measuring system, as shown in fig. 1 to 7, including a measuring mechanism, a measuring device 3 and a receiving device 4. The measuring mechanism comprises a mechanism body 1 and an environment measuring sensor 2 arranged on the mechanism body 1.

The mechanism body 1 is a component mainly used for bearing the environment measuring sensor 2, the environment measuring sensor 2 comprises a wind vane 21, a north pointer 22, a level meter 23, an anemometer 24, a temperature and humidity sensor and the like which are uniformly arranged on the mechanism body 1, and three measuring functions of environment wind direction, wind speed and temperature and humidity are mainly integrated.

The mechanism body 1 in a preferred embodiment comprises a support frame 11 and a connecting rod 12, wherein the connecting rod 12 is mounted on the support frame 11 through a universal mechanism, and the sensing parts of the environment measuring sensor 2 are arranged on the connecting rod 12 side by side. The universal mechanism part realizes that the connecting rod 12 can be freely rotated and adjusted in three directions, and the north arrow 22 and the level gauge 23 can be correctly pointed through adjustment, so that the wind vane 21 and other sensors can accurately measure environmental data. Furthermore, each sensing component of the environment measuring sensor 2 is detachably mounted on the mechanism body 1, specifically, two detachable parts of the related detachable mechanism can be respectively arranged on the mechanism body 1 and the sensing component, and only simple disassembling operation is needed when the sensor needs to be replaced, so that the environment measuring sensor is simple, convenient and practical.

The measuring device 3 is arranged on the mechanism body 1, specifically at the central position of the connecting rod 12. Similarly, the measuring device 3 is also preferably mounted on the mechanism body 1 through a detachable mechanism, which is convenient for detachment and replacement.

The measuring device 3 includes an environment measuring module 31, a key processing module 31, a power management module 33, a display module 34, and a first wireless module 35. The input end of the environment measuring module 31 is connected with each sensing component of the environment measuring sensor 2, and the output end of the environment measuring module 31 is electrically connected with the display module 34 and the first wireless module 35. The output end of the key processing module 31 is electrically connected with the display module 34 and the power management module 33; the output of the power management module 33 is electrically connected to the display module 34 and the first wireless module 35. The reception device 4 includes a PC communication module 41 and a second wireless module 42 electrically connected to each other. The measuring device 3 and the receiving device 4 realize wireless communication through the first wireless module 35 and the second wireless module 42.

Preferably, the system comprises at least two measuring devices 3 and at least two receiving devices 4 to form a multi-terminal measuring network. Correspondingly, the at least two measuring devices 3 have at least two measuring mechanisms in a one-to-one correspondence. In practical use, networking of a plurality of wireless networks can be realized by setting the wireless frequency F and the device wireless ID of the measuring device 3, and the wireless frequency F and the device wireless ID to be received of the receiving device 4, and referring to fig. 3, the measuring device 3 is provided with four groups, namely a measuring device one 301, a measuring device two 302, a measuring device three 303 and a measuring device four 304; four groups of receiving devices are correspondingly arranged, namely a receiving device I401, a receiving device II 402, a receiving device III 403 and a receiving device IV 404, and networking is realized by setting different radio frequencies F1 and F2.

As shown in fig. 1, the measurement device 3 functionally includes an environment measurement module 31, a key processing module 31, a power management module 33, a display module 34, and a first wireless module 35. The measuring device 3 is responsible for measuring the environment information and sending out the measured data by wireless, and processes the control command sent by the receiving device 4, thus realizing the remote control of the device. The measuring device 3 can be set to a low power consumption mode in which it does not accept remote control and a normal mode in which it accepts remote control. In the low power consumption mode, the first wireless module 35 enters the low power consumption mode after sending one data packet each time to save power; in the normal mode, the first wireless module 35 enters the receiving mode to receive the control command after sending one data packet each time.

The environment measuring module 31 is connected to each sensing component of the environment measuring sensor 2, and starts the sensors such as wind direction, wind speed, temperature and humidity at intervals to measure environment information S101 such as wind direction, wind speed, temperature and humidity of the environment. The environment information S101 is transmitted to the display module 34 for display and the first wireless module 35 for wireless transmission.

The key processing module 32 includes a key, and can recognize short-press and long-press operations of the key. In general, when the key pressing time is within 20ms, the key processing module 32 ignores the key operation; when the key depression time is between 20ms and 1s, the key processing module 32 recognizes a short-press operation and issues a short-key command C101 to the display module 34; when the key depression time is 1s or more, the key processing module 32 recognizes the long-press operation, and issues a long-key command C102 to the power management module 33.

The power management module 33 manages the functions of the measurement device 3, such as turning on and off, charging of the battery built in the device, and measurement of the battery capacity. The power management module 33 receives a key command from the key processing module 32. As shown in fig. 4, when the measurement apparatus is in a shutdown and uncharged state, if the long key command C102 is received, the power management module 33 first checks whether the battery power is sufficient, and if so, sends a startup signal S102 and starts up; otherwise, a low power signal S104 is sent out, and the computer is not started. When the mobile terminal is in a power-on state, if a long key command C102 is received, the power management module 33 sends a power-off signal S103, and the mobile terminal is powered off after a period of time delay; if the battery is low, the power management module 33 sends a low power signal S104 to shut down after a time delay. The power supply management module 33 manages the power supply state PS at all times, when the charger is connected with the measuring device 3, the power supply management module 33 updates the power supply state PS to be in charging and charges the built-in battery, and when the battery is fully charged, the power supply state PS is updated to be charging completion; when the charger turns off the measuring device 3, the power supply state PS is updated to be uncharged, and charging of the internal battery is stopped.

The display module 34 displays the power state PS of the measurement apparatus and the environmental information S101. In order to save power, the display module will display the content under some special conditions. As shown in fig. 5, in the shutdown state, if a startup signal S102 sent by the power management module 33 is received, the display is turned off after the startup is performed for a period of time; if a short key command C101 of the key processing module 32 is received, the display is turned off after the battery power is displayed for a certain period of time. In the power-on state, if a low-power signal S104 sent by the power management module 33 is received, the display is turned off after a period of low power is displayed; if a short key command C101 of the key processing module P102 is received, the battery power and the environmental information S101 are displayed for a period of time, and then the display is closed; if the power management module 33 sends a shutdown signal S103, the display is turned off after a period of shutdown. When the charger is connected, the display is closed after a period of time in the charging process is displayed; and when the charger is disconnected, the display is closed after the display is not charged for a period of time.

The first wireless module 35 is used for communication between the measurement device 3 and the receiving device 4, and can realize multi-network networking and identification functions of different devices by setting the frequency of wireless communication and device ID. As shown in fig. 6, the first wireless module 35 executes a data transmission procedure at intervals, before starting to transmit data, the first wireless module 35 enters a receiving mode and tries to receive all signals in the same wireless network to determine whether other devices are in a transmitting state, and if signals of other devices are received, which indicates that the wireless network is in a working state, waits for a short period of time to start the receiving process again; if no signal from other device is received, indicating that the wireless network is in the idle state, the first wireless module 35 will fill a transmission packet and enter the transmission mode to transmit the packet. After the transmission is completed, if the measuring device is set to the normal mode, the receiving mode is entered, and if the measuring device is set to the low power consumption mode, the low power consumption mode is entered. Each data includes information such as a header, a trailer, a packet length, a device ID, environment information S101, a power state PS, and packet verification, and the specific content may be adjusted according to the complexity of the wireless network, such as part of information such as enhancement verification or removal verification.

The receiving device 4 includes a PC communication module 41(P201) and a second wireless module 42 (P202). The PC communication module 41 receives the control command sent by the PC and forwards the control command through the second wireless module 42. Work flow as shown in fig. 7, if the second wireless module 42 receives the data packet, it checks whether the device ID in the data packet is the wireless ID of the device that needs to be received, and whether the packet check information is correct. After the check is passed, the second wireless module 42 forwards the data packet to the PC through the PC communication module 41, and the data packet is processed and displayed by the PC.

The foregoing is only a preferred embodiment of the present invention and all equivalent changes and modifications made within the scope of the present invention are intended to be covered by the appended claims.

Claims (5)

1. A remote environment measuring system, characterized by: comprises a measuring mechanism, a measuring device and a receiving device; the measuring mechanism comprises a mechanism body and an environment measuring sensor arranged on the mechanism body, wherein the environment measuring sensor comprises a wind vane, a north pointer, a level meter and an anemometer which are uniformly arranged on the mechanism body; the measuring device is arranged on the mechanism body and comprises an environment measuring module, a key processing module, a power management module, a display module and a first wireless module; the input end of the environment measuring module is connected with the environment measuring sensor, and the output end of the environment measuring module is electrically connected with the display module and the first wireless module; the output end of the key processing module is electrically connected with the display module and the power management module; the output end of the power management module is electrically connected with the display module and the first wireless module; the receiving device comprises a PC communication module and a second wireless module which are electrically connected with each other.

2. A remote environment measuring system as defined in claim 1, wherein: the system comprises at least two measuring devices and at least two receiving devices, wherein the at least two measuring devices are used for forming a multi-terminal measuring network and are provided with at least two measuring mechanisms in one-to-one correspondence.

3. A remote environment measuring system as defined in claim 1, wherein: the mechanism body comprises a support frame and a connecting rod, the connecting rod is installed on the support frame through a universal mechanism, and an environment measuring sensor is arranged on the connecting rod.

4. A remote environment measuring system as claimed in claim 1 or 3, wherein: each sensing component of the environment measuring sensor is detachably arranged on the mechanism body.

5. A remote environment measuring system as defined in claim 1, wherein: the measuring device is arranged on the mechanism body through a detachable mechanism.

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