CN208125730U - A kind of soil testing assemblies based on Internet of Things - Google Patents
A kind of soil testing assemblies based on Internet of Things Download PDFInfo
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- CN208125730U CN208125730U CN201820686823.8U CN201820686823U CN208125730U CN 208125730 U CN208125730 U CN 208125730U CN 201820686823 U CN201820686823 U CN 201820686823U CN 208125730 U CN208125730 U CN 208125730U
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- inserted link
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- cabinet
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Abstract
The utility model discloses a kind of soil testing assemblies based on Internet of Things,Cabinet is installed at the top of device noumenon,The upper and lower ends of cabinet two sides are equipped with snap ring,The back side of cabinet is equipped with strut,Solar panel is installed at the top of strut,The side of box house is equipped with battery,The top of battery side is equipped with memory module,The bottom of memory module is equipped with radio receiving transmitting module,The bottom of radio receiving transmitting module is equipped with ARM microprocessor,The bottom of cabinet is fixedly connected with inserted link one,Inserted link two,Inserted link three and inserted link four,The bottom end of inserted link one is equipped with HAD-100 soil moisture content sensor,The bottom end of inserted link two is equipped with SSP-0 soil temperature sensor,The bottom end of inserted link three is equipped with SSP-3 P in soil H sensor,The bottom end of inserted link four is equipped with YC-SC30A soil salinity sensor,The upper and lower ends of the utility model cabinet two sides are equipped with snap ring,The internal diameter of snap ring and the diameter of inserted link are identical,Convenient for the storage of inserted link,Enhance the practicability of device noumenon.
Description
Technical field
The utility model relates to a kind of soil testing assemblies technical field, specially a kind of Soil K+adsorption based on Internet of Things
Device.
Background technique
Soil is the basic eco-environmental elements for constituting the ecosystem, is the material base that the mankind depend on for existence and development, soil
Monitoring refers to through the measurement to the typical value for influencing soil environment quality factor, determines environmental quality and its variation tendency, is
Reinforcement Soil Pollution Control realizes agricultural product quality and safety, it will usually using soil testing assemblies soil detected, it is existing
Some detection devices are most, and structure is complicated, inconvenient to carry, and needs many more manipulations when detecting, and detection efficiency is lower, in addition,
Most of detection device also needs manually to be maked an inspection tour, not only using trouble, large labor intensity, is also inconvenient to manage, practicability compared with
Difference.
Therefore, it is necessary to design a kind of to solve problems based on the soil testing assemblies of Internet of Things.
Utility model content
The purpose of this utility model is to provide a kind of soil testing assemblies based on Internet of Things, to solve above-mentioned background skill
The problem of being proposed in art.
To achieve the above object, the utility model provides the following technical solutions:A kind of Soil K+adsorption dress based on Internet of Things
It sets, including device noumenon, cabinet, inserted link one, inserted link two, inserted link three, inserted link four, strut, solar panel, display screen, presses
Key, snap ring, handle, tip, HL504HP photosensitive sensor, battery, ARM microprocessor, radio receiving transmitting module, is deposited at LED light
Store up module, HAD-100 soil moisture content sensor, SSP-0 soil temperature sensor, SSP-3 P in soil H sensor, YC-SC30A soil
Earth salt sub-sensor, screw thread and monitor terminal, described device bodies top are equipped with the cabinet, the positive top of cabinet
The LED light is installed, the bottom of the LED light is equipped with the display screen, the bottom of the display screen be provided with it is described by
Key is equipped with the handle in the middle part of the cabinet top, and the upper and lower ends of the cabinet two sides are equipped with the snap ring, described
The back side of cabinet is equipped with the strut, and the top of the strut is equipped with the HL504HP photosensitive sensor, the strut
Top is equipped with the solar panel, and the side of the box house is equipped with the battery, the battery side
Top the memory module is installed, the bottom of the memory module is equipped with the radio receiving transmitting module, the wireless receipts
The bottom of hair module is equipped with the ARM microprocessor, and the bottom of the cabinet is fixedly connected with the inserted link one, the inserted link
Two, the inserted link three and the inserted link four, the top of the inserted link one, the inserted link two, the inserted link three and the inserted link four
It is provided with the screw thread, the bottom end of the inserted link one is equipped with the HAD-100 soil moisture content sensor, the bottom of the inserted link two
End is equipped with the SSP-0 soil temperature sensor, and the bottom end of the inserted link three is equipped with the SSP-3 P in soil H sensor,
The bottom end of the inserted link four is equipped with the YC-SC30A soil salinity sensor, and the inserted link one, described is plugged in the inserted link two
The bottom of bar three and the inserted link four is provided with the tip.
Further, the solar panel and the battery and the HL504HP photosensitive sensor, the ARM
Microprocessor, the radio receiving transmitting module, the memory module, the HAD-100 soil moisture content sensor, SSP-0 soil
Earth temperature sensor, the SSP-3 P in soil H sensor and the YC-SC30A soil salinity sensor are electrically connected, described
ARM microprocessor is electrically connected the display screen and the LED light.
Further, the surface mount of the handle has rubber pad.
Further, the strut is fixedly connected with the HL504HP photosensitive sensor by fastener.
Further, the HAD-100 soil moisture content sensor, the SSP-0 soil temperature sensor, the SSP-3
It is used cooperatively between P in soil H sensor and the YC-SC30A soil salinity sensor.
Further, lead between the cabinet and the inserted link one, the inserted link two, the inserted link three and the inserted link four
Cross the connection that is screwed.
Further, the outside of described device ontology is provided with monitor terminal, and the ARM microprocessor and monitor terminal are logical
Cross the radio receiving transmitting module connection.
Compared with prior art, the utility model has the beneficial effects that:Soil testing assemblies of this kind based on Internet of Things, dress
It sets bodies top and cabinet is installed, the positive top of cabinet is equipped with LED light, and the bottom of LED light is equipped with display screen, display screen
Bottom be provided with key, handle is installed, the surface mount of handle has rubber pad, and soft comfortable is prevented in the middle part of cabinet top
Cunning is wear-resisting, conveniently lifts and presses;The upper and lower ends of cabinet two sides are equipped with snap ring, the diameter phase of the internal diameter and inserted link of snap ring
Together, convenient for the storage of inserted link, the practicability of device noumenon is enhanced;The back side of cabinet is equipped with strut, the top installation of strut
There is HL504HP photosensitive sensor, strut is fixedly connected with HL504HP photosensitive sensor by fastener, HL504HP light sensor
Light of the device for real-time monitoring ambient enviroment is strong and weak, when monitoring lower than setting value, will send a signal to the micro- place ARM
Device is managed, ARM microprocessor can start LED light immediately upon receipt of the signals and work, efficient quick, while saving the energy,
It is also convenient for night illumination, improves the practicability of device noumenon;Solar panel is installed at the top of strut, box house
Side is equipped with battery, and the top of battery side is equipped with memory module, facilitates the real-time storage of detection data, avoids
The loss of information improves the safety that device noumenon uses;The bottom of memory module is equipped with radio receiving transmitting module, device sheet
The outside of body is provided with monitor terminal, and ARM microprocessor is connect with monitor terminal by radio receiving transmitting module, radio receiving transmitting module
Signal between ARM microprocessor and monitor terminal can mutually be transmitted, to facilitate staff to device noumenon
Distant supervision and control is carried out, it is flexible and efficient, labor intensity is being reduced, while mitigating staff's burden, is also improving it
Working efficiency;The bottom of radio receiving transmitting module is equipped with ARM microprocessor, and the bottom of cabinet is fixedly connected with inserted link one, inserted link
Two, inserted link three and inserted link four, inserted link one, inserted link two, inserted link three and inserted link four top be provided with screw thread, cabinet and inserted link one,
Connection is threadably secured between inserted link two, inserted link three and inserted link four, it is solid secured, it is easy to operate, facilitate installation, disassembly, receipts
It receives and carries;The bottom end of inserted link one is equipped with HAD-100 soil moisture content sensor, and the bottom end of inserted link two is equipped with SSP-0 soil
Temperature sensor, the bottom end of inserted link three are equipped with SSP-3 P in soil H sensor, and the bottom end of inserted link four is equipped with YC-SC30A soil
Salt sub-sensor, HAD-100 soil moisture content sensor, SSP-0 soil temperature sensor, SSP-3 P in soil H sensor and YC-
It is used cooperatively between SC30A soil salinity sensor, HAD-100 soil moisture content sensor is used for the height of real-time monitoring soil moisture
Low, SSP-0 soil temperature sensor is used for the height of the real-time monitoring soil moisture, and SSP-3 P in soil H sensor for supervising in real time
The size of P in soil H value is surveyed, YC-SC30A soil salinity sensor is used for the size of real-time monitoring soil salt content, four phases
Mutually cooperation, greatly strengthens the detection effect of device noumenon, avoids the drawbacks of existing detection device needs many more manipulations, improve
The working efficiency of device noumenon;Inserted link one, inserted link two, inserted link three and inserted link four bottom be provided with tip, facilitate insertion soil,
It is simple and practical.
Detailed description of the invention
Fig. 1 is the schematic view of the front view of the utility model;
Fig. 2 is the schematic diagram of internal structure of the utility model;
Fig. 3 is the working principle structural schematic diagram of the utility model;
In appended drawing reference:1- device noumenon;2- cabinet;3- inserted link one;4- inserted link two;5- inserted link three;6- inserted link four;7- branch
Bar;8- solar panel;9- display screen;10- key;11-LED lamp;12- snap ring;13- handle;14- tip;15-
HL504HP photosensitive sensor;16- battery;17-ARM microprocessor;18- memory module;19- radio receiving transmitting module;20-
HAD-100 soil moisture content sensor;21-SSP-0 soil temperature sensor;22-SSP-3 P in soil H sensor;23-YC-SC30A
Soil salinity sensor;24- screw thread;25- monitor terminal.
Specific embodiment
The following will be combined with the drawings in the embodiments of the present invention, carries out the technical scheme in the embodiment of the utility model
Clearly and completely describe, it is clear that the described embodiments are only a part of the embodiments of the utility model, rather than whole
Embodiment.Based on the embodiments of the present invention, those of ordinary skill in the art are without making creative work
Every other embodiment obtained, fall within the protection scope of the utility model.
Fig. 1-3 is please referred to, the utility model provides a kind of technical solution:A kind of soil testing assemblies based on Internet of Things,
Including device noumenon 1, cabinet 2, inserted link 1, inserted link 24, inserted link 35, inserted link 46, strut 7, solar panel 8, display
Shield 9, key 10, LED light 11, snap ring 12, handle 13, tip 14, HL504HP photosensitive sensor 15, battery 16, the micro- place ARM
Manage device 17, radio receiving transmitting module 18, memory module 19, HAD-100 soil moisture content sensor 20, SSP-0 soil temperature sensor
21, SSP-3 P in soil H sensor 22, YC-SC30A soil salinity sensor 23, screw thread 24 and monitor terminal 25, device noumenon 1
Top is equipped with cabinet 2, and the positive top of cabinet 2 is equipped with LED light 11, and the bottom of LED light 11 is equipped with display screen 9, display
The bottom of screen 9 is provided with key 10, handle 13 is equipped in the middle part of 2 top of cabinet, the upper and lower ends of 2 two sides of cabinet are equipped with card
Ring 12, the back side of cabinet 2 are equipped with strut 7, and the top of strut 7 is equipped with HL504HP photosensitive sensor 15, the top of strut 7
Solar panel 8 is installed, the side inside cabinet 2 is equipped with battery 16, and the top of 16 side of battery, which is equipped with, deposits
Module 19 is stored up, the bottom of memory module 19 is equipped with radio receiving transmitting module 18, and it is micro- that the bottom of radio receiving transmitting module 18 is equipped with ARM
Processor 17, the bottom of cabinet 2 are fixedly connected with inserted link 1, inserted link 24, inserted link 35 and inserted link 46, inserted link 1, inserted link two
4, the top of inserted link 35 and inserted link 46 is provided with screw thread 24, and the bottom end of inserted link 1 is equipped with HAD-100 soil moisture content sensor
20, the bottom end of inserted link 24 is equipped with SSP-0 soil temperature sensor 21, and the bottom end of inserted link 35 is equipped with SSP-3 P in soil H biography
Sensor 22, the bottom end of inserted link 46 are equipped with YC-SC30A soil salinity sensor 23, inserted link 1, inserted link 24,35 and of inserted link
The bottom of inserted link 46 is provided with tip 14.
Further, solar panel 8 and battery 16 and HL504HP photosensitive sensor 15, ARM microprocessor 17,
Radio receiving transmitting module 18, memory module 19, HAD-100 soil moisture content sensor 20, SSP-0 soil temperature sensor 21, SSP-3
P in soil H sensor 22 and YC-SC30A soil salinity sensor 23 are electrically connected, and ARM microprocessor 17 is electrically connected display screen 9
With LED light 11, solar panel 8 and battery 16 are HL504HP photosensitive sensor 15, ARM microprocessor 17, wireless receiving and dispatching
Module 18, memory module 19, HAD-100 soil moisture content sensor 20, SSP-0 soil temperature sensor 21, SSP-3 P in soil H are passed
Electric energy needed for the work of sensor 22 and YC-SC30A soil salinity sensor 23 provides, ARM microprocessor 17 control 9 He of display screen
The work of LED light 11.
Further, the surface mount of handle 13 has rubber pad, soft comfortable, and anti-skid wearable is conveniently lifted and pressed.
Further, strut 7 is fixedly connected with HL504HP photosensitive sensor 15 by fastener, HL504HP light sensor
Light of the device 15 for real-time monitoring ambient enviroment is strong and weak, and when monitoring lower than setting value, it is micro- will to send a signal to ARM
Processor 17, ARM microprocessor 17 can start the work of LED light 11 immediately upon receipt of the signals, and efficient quick is saving the energy
While, it is also convenient for night illumination, improves the practicability of device noumenon 1.
Further, HAD-100 soil moisture content sensor 20, SSP-0 soil temperature sensor 21, SSP-3 P in soil H are passed
It is used cooperatively between sensor 22 and YC-SC30A soil salinity sensor 23, HAD-100 soil moisture content sensor 20 is for real-time
The height of soil moisture is monitored, SSP-0 soil temperature sensor 21 is used for the height of the real-time monitoring soil moisture, SSP-3 soil
PH sensor 22 is used for the size of real-time monitoring P in soil H value, and YC-SC30A soil salinity sensor 23 is used for real-time monitoring soil
The size of salt content, four cooperate, and greatly strengthen the detection effect of device noumenon 1, avoid existing detection device
The drawbacks of needing many more manipulations, improves the working efficiency of device noumenon 1.
Further, connect between cabinet 2 and inserted link 1, inserted link 24, inserted link 35 and inserted link 46 by the way that screw thread 24 is fixed
It connects, it is solid secured, it is easy to operate, facilitate installation, disassembly, storage and carrying.
Further, the outside of device noumenon 1 is provided with monitor terminal 25, and ARM microprocessor 17 and monitor terminal 25 are logical
The connection of radio receiving transmitting module 18 is crossed, radio receiving transmitting module 18 can be by the signal between ARM microprocessor 17 and monitor terminal 25
Mutually transmitted, so that staff is facilitated to carry out Distant supervision and control to device noumenon 1, it is flexible and efficient, reducing labor
Fatigue resistance also improves its working efficiency while mitigating staff's burden.
Working principle:Soil testing assemblies of this kind based on Internet of Things, before use, first with handle 13 by inserted link 1,
Inserted link 24, inserted link 35 and inserted link 46 inject in the soil for needing to detect and fixation, then by solar panel 8
Position is adjusted, and guarantees that it receives the area of sunlight maximum, when in use, the electric energy that solar panel 8 is generated in fine day,
A part is stored in battery 16, and a part is directly used in the work of device noumenon 1, when HAD-100 soil moisture content sensor
20, SSP-0 soil temperature sensor 21, SSP-3 P in soil H sensor 22 and YC-SC30A soil salinity sensor 23 detect
When the related data of soil, coherent signal can be sent to ARM microprocessor 17, ARM microprocessor 17 upon receipt of the signals,
On the one hand it directly stores it in memory module 19, it is on the other hand sent to monitor terminal by radio receiving transmitting module 18
25 check for staff, when HL504HP photosensitive sensor 15 monitors the bright intensity of ambient enviroment lower than setting value, just
ARM microprocessor 17 can be sent a signal to, ARM microprocessor 17 can start the progress of LED light 11 immediately upon receipt of the signals
Illumination, this soil testing assemblies based on Internet of Things are not only easy to operate, convenient for management, and flexibly and fast, and safety is real
With work efficiency is high, and detection effect is good, and labor intensity is low, and intelligence degree is high, convenient for collecting and carrying.
While there has been shown and described that the embodiments of the present invention, for the ordinary skill in the art,
It is understood that these embodiments can be carried out with a variety of variations in the case where not departing from the principles of the present invention and spirit, repaired
Change, replacement and variant, the scope of the utility model is defined by the appended claims and the equivalents thereof.
Claims (7)
1. a kind of soil testing assemblies based on Internet of Things, including device noumenon (1), cabinet (2), inserted link one (3), inserted link two
(4), inserted link three (5), inserted link four (6), strut (7), solar panel (8), display screen (9), key (10), LED light (11),
Snap ring (12), handle (13), tip (14), HL504HP photosensitive sensor (15), battery (16), ARM microprocessor (17),
Radio receiving transmitting module (18), memory module (19), HAD-100 soil moisture content sensor (20), SSP-0 soil temperature sensor
(21), SSP-3 P in soil H sensor (22), YC-SC30A soil salinity sensor (23), screw thread (24) and monitor terminal (25),
It is characterized in that:It is equipped with the cabinet (2) at the top of described device ontology (1), the positive top installation of cabinet (2) is
It states LED light (11), the bottom of the LED light (11) is equipped with the display screen (9), and the bottom of the display screen (9) is provided with
The key (10) is equipped with the handle (13) in the middle part of cabinet (2) top, and up and down the two of cabinet (2) two sides
End is equipped with the snap ring (12), and the back side of the cabinet (2) is equipped with the strut (7), the top installation of the strut (7)
There is the HL504HP photosensitive sensor (15), the solar panel (8), the case are installed at the top of the strut (7)
The internal side of body (2) is equipped with the battery (16), and the top of battery (16) side is equipped with the storage mould
The bottom of block (19), the memory module (19) is equipped with the radio receiving transmitting module (18), the radio receiving transmitting module (18)
Bottom be equipped with the ARM microprocessor (17), the bottom of the cabinet (2) is fixedly connected with the inserted link one (3), described
Inserted link two (4), the inserted link three (5) and the inserted link four (6), the inserted link one (3), the inserted link two (4), the inserted link three
(5) it is provided with the screw thread (24) with the top of the inserted link four (6), the bottom end of the inserted link one (3) is equipped with the HAD-
100 soil moisture content sensors (20), the bottom end of the inserted link two (4) are equipped with the SSP-0 soil temperature sensor (21), institute
The bottom end for stating inserted link three (5) is equipped with the SSP-3 P in soil H sensor (22), and the bottom end installation of the inserted link four (6) is
It states YC-SC30A soil salinity sensor (23), the inserted link one (3), the inserted link two (4), the inserted link three (5) and described
The bottom of inserted link four (6) is provided with the tip (14).
2. a kind of soil testing assemblies based on Internet of Things according to claim 1, it is characterised in that:The solar-electricity
Pond plate (8) and the battery (16) and the HL504HP photosensitive sensor (15), the ARM microprocessor (17), the nothing
Line transceiver module (18), the memory module (19), the HAD-100 soil moisture content sensor (20), the SSP-0 soil temperature
Degree sensor (21), the SSP-3 P in soil H sensor (22) and the YC-SC30A soil salinity sensor (23) electrically connect
It connects, the ARM microprocessor (17) is electrically connected the display screen (9) and the LED light (11).
3. a kind of soil testing assemblies based on Internet of Things according to claim 1, it is characterised in that:The handle (13)
Surface mount have rubber pad.
4. a kind of soil testing assemblies based on Internet of Things according to claim 1, it is characterised in that:The strut (7)
It is fixedly connected with the HL504HP photosensitive sensor (15) by fastener.
5. a kind of soil testing assemblies based on Internet of Things according to claim 1, it is characterised in that:The HAD-100
Soil moisture content sensor (20), the SSP-0 soil temperature sensor (21), the SSP-3 P in soil H sensor (22) and institute
It states and is used cooperatively between YC-SC30A soil salinity sensor (23).
6. a kind of soil testing assemblies based on Internet of Things according to claim 1, it is characterised in that:The cabinet (2)
Pass through the screw thread between the inserted link one (3), the inserted link two (4), the inserted link three (5) and the inserted link four (6)
(24) it is fixedly connected.
7. a kind of soil testing assemblies based on Internet of Things according to claim 1, it is characterised in that:Described device ontology
(1) outside is provided with monitor terminal (25), and the ARM microprocessor (17) and monitor terminal (25) pass through the wireless receiving and dispatching
Module (18) connection.
Priority Applications (1)
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CN201820686823.8U CN208125730U (en) | 2018-05-09 | 2018-05-09 | A kind of soil testing assemblies based on Internet of Things |
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CN201820686823.8U CN208125730U (en) | 2018-05-09 | 2018-05-09 | A kind of soil testing assemblies based on Internet of Things |
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CN201820686823.8U Expired - Fee Related CN208125730U (en) | 2018-05-09 | 2018-05-09 | A kind of soil testing assemblies based on Internet of Things |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109490513A (en) * | 2018-12-27 | 2019-03-19 | 广州市合信环保科技有限公司 | A kind of soil environment quality automatic monitoring method and its device for heavy metal pollution |
CN110763821A (en) * | 2019-09-20 | 2020-02-07 | 河南锐利特计算机科技有限公司 | Method and device for measuring water-holding capacity of field |
US20210069695A1 (en) * | 2019-09-06 | 2021-03-11 | The Regents Of The University Of California | Cloud-enabled passive wireless ionic sensing in small vials |
CN113295844A (en) * | 2021-04-13 | 2021-08-24 | 广东白云学院 | Agricultural product quality safety monitoring equipment based on Internet of things |
-
2018
- 2018-05-09 CN CN201820686823.8U patent/CN208125730U/en not_active Expired - Fee Related
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109490513A (en) * | 2018-12-27 | 2019-03-19 | 广州市合信环保科技有限公司 | A kind of soil environment quality automatic monitoring method and its device for heavy metal pollution |
US20210069695A1 (en) * | 2019-09-06 | 2021-03-11 | The Regents Of The University Of California | Cloud-enabled passive wireless ionic sensing in small vials |
US11529632B2 (en) * | 2019-09-06 | 2022-12-20 | The Regents Of The University Of California | Cloud-enabled passive wireless ionic sensing in small vials |
CN110763821A (en) * | 2019-09-20 | 2020-02-07 | 河南锐利特计算机科技有限公司 | Method and device for measuring water-holding capacity of field |
CN113295844A (en) * | 2021-04-13 | 2021-08-24 | 广东白云学院 | Agricultural product quality safety monitoring equipment based on Internet of things |
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