CN216869633U - Agricultural environment big data acquisition device - Google Patents

Abstract

The utility model provides a big data acquisition device of agricultural environment belongs to data acquisition technical field, and aim at solves the problem that the function singleness and the collection index that prior art exists are few. The utility model comprises the following steps: a collection box; the meteorological resource data acquisition unit is arranged on the acquisition box; acquiring meteorological data of the area through the meteorological data acquisition unit; the land resource data acquisition unit is detachably carried in the acquisition box and at least comprises a soil temperature and humidity acquisition structure and a soil sampling structure; the temperature and humidity data of different depths of the soil are collected through the soil temperature and humidity collecting structure, and samples of different depths of the soil are collected through the soil sampling structure. The utility model realizes the acquisition of meteorological resource data and land resource data, and the acquisition of the meteorological resource data avoids the problem of simultaneous working of human and machine; the collection of land resource data realizes the collection and sampling of temperature and humidity information of different soil depths.

Description

Agricultural environment big data acquisition device

Technical Field

The utility model belongs to the technical field of data acquisition, and particularly relates to an agricultural environment big data acquisition device.

Background

The agricultural big data is a data set which is generated after self characteristics such as agricultural regionality, seasonality, diversity, periodicity and the like are fused, has wide sources, various types, complex structure and potential value, and is difficult to process and analyze by a common method. The method reserves the basic characteristics of huge scale, various types, low value density, high processing speed, high accuracy, high complexity and the like of big data, and extends and deepens the information flow in agriculture; according to the industry chain division of agriculture, the agricultural big data are mainly focused in the fields of agricultural environment and resources, agricultural production, agricultural market, agricultural management and the like at present. The agricultural natural resource and environment data mainly comprise land resource data, water resource data, meteorological resource data, biological resource data and disaster data.

In the prior art, the agricultural natural resource and environment data acquisition structures comprise a plurality of structures; the Chinese patent with the publication number of CN211121334U discloses a technical scheme of an agricultural environment data acquisition device; the data acquisition device comprises a main rod, wherein a threaded cylinder rod is connected to the center of the bottom of the main rod, a soil pH value sensor is installed at the bottom of the threaded cylinder rod, a supporting sleeve is sleeved at the bottom of the main rod and close to the outer wall of the threaded cylinder rod, one end of a supporting rod is welded on the outer wall of the supporting sleeve, a supporting base is welded at the other end of the supporting rod, a main control box is connected to the supporting sleeve above the main rod through a hoop, an installation sleeve is sleeved at the outer wall of the main rod above the main control box and is connected with a solar cell panel installation rod through a bolt, and a solar cell panel is installed on the solar cell panel installation rod. The function is single, and the collected indexes are few.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an agricultural environment big data acquisition device, which solves the problems of single function and few acquisition indexes in the prior art.

In order to achieve the above object, the present invention provides an agricultural environment big data acquisition device, comprising:

a collection box;

the meteorological resource data acquisition unit is arranged on the acquisition box; acquiring meteorological data of the area through the meteorological resource data acquisition unit;

the land resource data acquisition unit is detachably carried in the acquisition box and at least comprises a soil temperature and humidity acquisition structure and a soil sampling structure; the temperature and humidity data of different depths of the soil are collected through the soil temperature and humidity collecting structure, and samples of different depths of the soil are collected through the soil sampling structure.

Soil humiture collection structure includes:

the side wall of the drilling barrel is provided with a through groove extending from one end to the other end;

the inner cylinder core is arranged in the drilling cylinder, the inner cylinder core is provided with a guide hole which is eccentric along the axial direction and a plurality of radial adjusting holes which are uniformly distributed, and the plurality of adjusting holes are respectively communicated with the guide hole;

the collecting body is arranged in each adjusting hole and is in sliding fit with the adjusting hole along the axial direction of the adjusting hole;

and the pushing structure is arranged in the guide hole and is in sliding fit with the guide hole, and the acquisition body in each adjusting hole is pushed by the pushing structure to extend or retract relative to the through groove of the drill cylinder.

Soil humiture collection structure still includes:

the action rod is arranged at the handheld end of the drill cylinder and is vertical to the drill cylinder;

and the first display screen is arranged at the upper end of the drill cylinder, is electrically connected with each acquisition body respectively and displays acquisition results.

The drill barrel comprises:

the through groove is arranged on one side of the cylinder body and extends from one end to the other end;

and the drill bit is coaxially arranged at the action end of the lower end of the cylinder body.

Each of the collection bodies includes:

the adjusting rod is in sliding fit with the adjusting hole, and one end of the adjusting rod, which is positioned in the adjusting hole, is of a wedge-shaped block structure with a large lower end; the wedge-shaped block structure is matched with the pushing structure, and the adjusting rod is pushed to move along the axial direction of the adjusting rod through the pushing structure;

the second adjusting spring is sleeved on the adjusting rod and is positioned between the wedge-shaped block structure of the adjusting rod and the outlet end of the adjusting hole;

and the first temperature sensor and the first humidity sensor are arranged at one end, positioned at the outer part of the adjusting hole, of the adjusting rod, and the first temperature sensor and the first humidity sensor are respectively and electrically connected with the first display screen.

The pushing structure includes:

a pushing rod in sliding fit with the guide hole, wherein a wedge-shaped groove matched with the wedge-shaped block structure is formed in the corresponding position of the pushing rod and the adjusting rod of the acquisition body;

and the first adjusting spring is arranged between the lower end face of the push rod and the bottom face of the guide hole, when the first adjusting spring is in a free state, the plurality of wedge-shaped grooves in the push rod are respectively matched with the wedge-shaped blocks at the ends of the plurality of adjusting rods, and the first temperature sensor and the first humidity sensor at the ends of each adjusting rod are positioned in the drill cylinder.

The soil sampling structure includes:

a sampling cartridge;

the spiral sampling rod is arranged in the sampling cylinder;

the handle is arranged at the upper end part of the spiral sampling rod;

and the two limiting rods are arranged below the outer end face of the sampling cylinder, and the two limiting rods are perpendicular to the axial direction of the sampling cylinder and are symmetrically arranged.

The soil temperature and humidity acquisition structure comprises a drill cylinder and a soil sampling structure, wherein the inner part of the acquisition box comprises a first snap ring and a second snap ring, the drill cylinder of the soil temperature and humidity acquisition structure is clamped on the first snap ring, and the sampling through card of the soil sampling structure is clamped on the second snap ring.

The meteorological resource data acquisition unit comprises an atmospheric pressure sensor, a second temperature sensor, a second humidity sensor, a wind speed sensor, a wind direction sensor, a full-automatic tracking solar radiation instrument, a data memory and a second display screen which are arranged on a box body of the acquisition box;

respectively acquiring atmospheric pressure, ambient temperature, ambient humidity, ambient wind speed, ambient wind direction, total solar radiation, direct radiation value, scattered radiation, sunshine time and solar altitude angle information through an atmospheric pressure sensor, a second temperature sensor, a second humidity sensor, a wind speed sensor, a wind direction sensor and a full-automatic tracking solar radiation instrument;

the collected information is stored in the data storage device and is displayed in real time through the second display screen.

The utility model has the beneficial effects that: the agricultural environment big data acquisition device provided by the utility model realizes the acquisition of meteorological resource data and land resource data, the acquisition of the meteorological resource data can be acquired by adopting an acquisition structure carried on an acquisition box and stored by a data storage device, and meanwhile, the meteorological resource data can be displayed by a second display screen, so that the data can be checked in real time, and the problem of simultaneous work of a human and a machine is avoided; the method comprises the steps that the soil resource data are collected through a temperature and humidity collecting structure of soil, temperature and humidity information of different soil depths is collected, and meanwhile, the data are displayed in real time through a first display screen; in addition, the collecting body of the soil temperature and humidity collecting structure adopts a structure which is telescopic relative to the drill cylinder, so that the service life of the device is prolonged to a greater extent, and meanwhile, the accuracy of a measuring result can be ensured.

Drawings

FIG. 1 is a schematic view of an external structure of an agricultural environment big data acquisition device according to the present invention;

FIG. 2 is a schematic view of the internal structure of a big data acquisition device for agricultural environment according to the present invention;

FIG. 3 is a schematic diagram of a soil temperature and humidity acquisition structure in the agricultural environment big data acquisition device of the present invention;

FIG. 4 is a sectional view of a soil temperature and humidity acquisition structure in the agricultural environment big data acquisition device of the present invention;

FIG. 5 is a greatly enlarged fragmentary view of FIG. 4;

FIG. 6 is a schematic diagram of a structure of a soil temperature and humidity acquisition structure in an agricultural environment big data acquisition device of the present invention in a dry state pushed by pressing;

FIG. 7 is an enlarged view of a portion of FIG. 6;

FIG. 8 is a schematic diagram of a soil sampling structure in the agricultural environment big data acquisition device of the present invention;

wherein: 1. the device comprises a collection box 101, a first snap ring 102, a second snap ring 2, a land resource data collection unit 201, a soil temperature and humidity collection structure 202, a soil sampling structure 203, a drill barrel 204, a barrel 205, a through groove 206, a drill bit 207, an action rod 208, an inner barrel core 209, an adjusting hole 210, a guide hole 211, an adjusting rod 212, a second adjusting spring 213, a first temperature sensor 214, a first humidity sensor 215, a push rod 216, a first adjusting spring 217, a sampling barrel 218, a spiral sampling rod 219, a limiting rod 220, a handle 3, a meteorological resource data collection unit 301, an atmospheric pressure sensor 302, a second temperature sensor 303, a second humidity sensor 304, a wind speed sensor 305, a wind direction sensor 306, a full-automatic tracking solar radiation instrument 307 and a second display screen.

Detailed Description

The following further describes embodiments of the present invention with reference to the drawings.

Referring to fig. 1 and 2, the agricultural environment big data acquisition device of the utility model comprises:

a collection box 1;

a meteorological resource data acquisition unit 3 arranged on the acquisition box 1; acquiring meteorological data of the area through the meteorological resource data acquisition unit 3;

the land resource data acquisition unit 2 is detachably carried in the acquisition box 1, and the land resource data acquisition unit 2 at least comprises a soil temperature and humidity acquisition structure 201 and a soil sampling structure 202; the temperature and humidity data of different depths of the soil are collected through the soil temperature and humidity collecting structure 201, and samples of different depths of the soil are collected through the soil sampling structure 202.

Referring to fig. 3 to 7, the soil temperature and humidity collecting structure 201 includes:

the drilling barrel 203 is provided with a through groove 205 extending from one end to the other end on the side wall of the drilling barrel 203;

an inner cylinder core 208 arranged inside the drill cylinder 203, wherein the inner cylinder core 208 is provided with a guide hole 210 which is eccentric along the axial direction and a plurality of radial adjusting holes 209 which are uniformly distributed, and the plurality of adjusting holes 209 are respectively communicated with the guide hole 210;

a collection body which is arranged in each adjusting hole 209 and is in sliding fit with the adjusting hole 209 along the axial direction of the adjusting hole 209;

and a pushing structure which is arranged in the guide hole 210 and is in sliding fit with the guide hole 210, and the pushing structure is used for pushing the collection body in each adjusting hole 209 to extend or retract relative to the through groove 205 of the drill cylinder 203.

Soil humiture collection structure 201 still includes:

an action rod 207 of the vertical drill cylinder 203 arranged at the handheld end of the drill cylinder 203;

and the first display screen is arranged at the upper end of the drilling barrel 203, is electrically connected with each acquisition body respectively, and displays acquisition results.

The drill cylinder 203 comprises:

the through groove 205 is arranged on one side of the cylinder 204 and extends from one end to the other end;

and a drill bit 206 coaxially disposed at the lower, active end of the barrel 204.

Each of the collection bodies includes:

an adjusting rod 211 in sliding fit with the adjusting hole 209, wherein one end of the adjusting rod 211, which is positioned in the adjusting hole 209, is a wedge-shaped block structure with a large lower end; the wedge-shaped block structure is matched with the pushing structure, and the adjusting rod 211 is pushed by the pushing structure to move along the axial direction of the adjusting rod;

a second adjusting spring 212 which is sleeved on the adjusting rod 211 and is positioned between the wedge block structure of the adjusting rod 211 and the outlet end of the adjusting hole 209;

and a first temperature sensor 213 and a first humidity sensor 214 which are arranged at one end of the adjusting rod 211, which is positioned outside the adjusting hole 209, wherein the first temperature sensor 213 and the first humidity sensor 214 are respectively and electrically connected with the first display screen.

The pushing structure includes:

a pushing rod 215 in sliding fit with the guide hole 210, wherein a wedge-shaped groove matched with a wedge-shaped block structure is formed in the corresponding position of the pushing rod 215 and the adjusting rod 211 of the acquisition body;

and a first adjusting spring 216 arranged between the lower end surface of the pushing rod 215 and the bottom surface of the hole of the guide hole 210, when the first adjusting spring 216 is in a free state, the plurality of wedge-shaped grooves on the pushing rod 215 are respectively matched with the wedge-shaped blocks at the ends of the plurality of adjusting rods 211, and the first temperature sensor 213 and the first humidity sensor 214 at the end of each adjusting rod 211 are both positioned in the drill cylinder 203.

Referring to fig. 8, the soil sampling structure 202 includes:

a sampling cartridge 217;

a helical sampling rod 218 disposed within the sampling cartridge 217;

a handle 220 disposed at an upper end of the screw sampling rod 218;

and two limiting rods 219 arranged below the outer end face of the sampling cylinder 217, wherein the two limiting rods 219 are perpendicular to the axial direction of the sampling cylinder 217 and are symmetrically arranged.

The collection box 1 comprises a first snap ring 101 and a second snap ring 102, a drill cylinder 203 of the soil temperature and humidity collection structure 201 is clamped on the first snap ring 101, and a sampling through clamp of the soil sampling structure 202 is clamped on the second snap ring 102.

The meteorological resource data acquisition unit 3 comprises an atmospheric pressure sensor 301, a second temperature sensor 302, a second humidity sensor 303, a wind speed sensor 304, a wind direction sensor 305, a full-automatic tracking solar radiation instrument 306, a data storage and a second display screen 307 which are arranged on the box body of the acquisition box 1; in this embodiment, the fully automatic tracking solar radiation instrument 306 is a fully automatic tracking solar radiation instrument 306 of the type TBS-YG5, of the sunny science and technology development ltd, ca;

respectively collecting atmospheric pressure, ambient temperature, ambient humidity, ambient wind speed, ambient wind direction, total solar radiation, direct radiation value, scattered radiation, sunshine duration and solar altitude information through an atmospheric pressure sensor 301, a second temperature sensor 302, a second humidity sensor 303, a wind speed sensor 304, a wind direction sensor 305 and a full-automatic tracking solar radiation meter 306;

the collected information is stored in a data storage and displayed in real time by a second display screen 307.

The using process of the utility model is as follows: when in use, the meteorological data acquisition unit 3 carried on the acquisition box 1 body realizes the acquisition, storage and display of meteorological data; for the soil resource data acquisition unit, the soil temperature and humidity acquisition structure 201 and the soil sampling structure 202 adopt a split structure design, so that a synchronous acquisition effect can be realized, and the soil sampling structure 202 adopts a spiral sampling structure for sampling, so that the collection of samples of soil bodies with different depths is realized; in the collection process of the soil temperature and humidity collection structure 201, the aim of extending downwards in the soil body is achieved through the drill barrel 203, the upper end portion of a push rod 215 is manually pressed, the lower end of the push rod 215 presses a first adjusting spring 216 to compress, meanwhile, a wedge-shaped groove in the push rod 215 and a wedge-shaped block structure at the end portion of an adjusting rod 211 on each collection body further push the adjusting rod 211 to slide outwards, a first temperature sensor 213 and a first humidity sensor 214 at the end portion of the adjusting rod 211 are driven to extend out of a through groove 205 of the drill barrel 203, a second adjusting spring 212 is compressed under the extrusion effect of the wedge-shaped block structure and an inner ring at the hole end portion of an adjusting hole 209, and the first temperature sensor 213 and the first humidity sensor 214 at the end portion of the adjusting rod 211 collect the temperature and the humidity of the soil at the corresponding depth; after the collection is finished, the upper end of the pushing rod 215 is stopped to apply force, the pushing rod 215 is lifted upwards under the restoring force of the first adjusting spring 216, meanwhile, the wedge-shaped hole in the adjusting rod 211 gradually releases the extrusion on the wedge-shaped block structure, and the adjusting rod 211 moves inwards under the action of the second adjusting spring 212 to drive the first temperature sensor 213 and the first humidity sensor 214 at the end of the adjusting rod 211 to contract back into the drill cylinder 203.

Claims (9)

1. The utility model provides an agricultural environment big data acquisition device which characterized in that includes:

a collection box (1);

a meteorological resource data acquisition unit (3) arranged on the acquisition box (1); the meteorological data of the area are collected through the meteorological resource data collecting unit (3);

the land resource data acquisition unit (2) is detachably carried in the acquisition box (1), and the land resource data acquisition unit (2) at least comprises a soil temperature and humidity acquisition structure (201) and a soil sampling structure (202); temperature and humidity data of different depths of soil are collected through the soil temperature and humidity collecting structure (201), and samples of different depths of soil are collected through the soil sampling structure (202).

2. An agricultural environment big data collection device according to claim 1, wherein the soil temperature and humidity collection structure (201) comprises:

the drilling device comprises a drilling barrel (203), wherein a through groove (205) extending from one end to the other end is formed in the side wall of the drilling barrel (203);

the inner cylinder core (208) is arranged in the drill cylinder (203), the inner cylinder core (208) is provided with a guide hole (210) which is eccentric along the axial direction and a plurality of radial adjusting holes (209) which are uniformly distributed, and the plurality of adjusting holes (209) are respectively communicated with the guide hole (210);

a collection body which is arranged in each adjusting hole (209) and is in sliding fit with the adjusting hole (209) along the axial direction of the adjusting hole (209);

and the pushing structure is arranged in the guide hole (210) and is in sliding fit with the guide hole (210), and the collection body in each adjusting hole (209) is pushed by the pushing structure to extend or retract relative to the through groove (205) of the drill barrel (203).

3. An agricultural environment big data collection device according to claim 2, wherein the soil temperature and humidity collection structure (201) further comprises:

an action rod (207) of the vertical drill barrel (203) arranged at the handheld end of the drill barrel (203);

and the first display screen is arranged at the upper end of the drilling barrel (203), is electrically connected with each acquisition body respectively and displays acquisition results.

4. An agricultural environment big data collection device according to claim 2 or 3, wherein the drill barrel (203) comprises:

the through groove (205) is arranged on one side of the cylinder body (204) and extends from one end to the other end;

and a drill bit (206) coaxially arranged at the lower end action end of the cylinder body (204).

5. An agricultural environment big data collection device according to claim 2 or 3, wherein each collection body comprises:

the adjusting rod (211) is in sliding fit with the adjusting hole (209), and one end, located in the adjusting hole (209), of the adjusting rod (211) is a wedge-shaped block structure with a large size at the lower end; the wedge-shaped block structure is matched with the pushing structure, and the adjusting rod (211) is pushed by the pushing structure to move along the axial direction of the adjusting rod;

the second adjusting spring (212) is sleeved on the adjusting rod (211) and is positioned between the wedge-shaped block structure of the adjusting rod (211) and the outlet end of the adjusting hole (209);

and the first temperature sensor (213) and the first humidity sensor (214) are arranged at one end, positioned outside the adjusting hole (209), of the adjusting rod (211), and the first temperature sensor (213) and the first humidity sensor (214) are electrically connected with the first display screen respectively.

6. An agricultural environment big data collection device according to claim 5, wherein the pushing structure comprises:

a pushing rod (215) in sliding fit with the guide hole (210), wherein a wedge-shaped groove matched with the wedge-shaped block structure is formed in the corresponding position of the pushing rod (215) and the adjusting rod (211) of the acquisition body;

and a first adjusting spring (216) arranged between the lower end surface of the push rod (215) and the bottom surface of the guide hole (210), when the first adjusting spring (216) is in a free state, a plurality of wedge-shaped grooves on the push rod (215) are respectively matched with wedge-shaped blocks at the ends of a plurality of adjusting rods (211), and a first temperature sensor (213) and a first humidity sensor (214) at the end of each adjusting rod (211) are both positioned in the drill barrel (203).

7. An agricultural environment big data collection device according to claim 1, wherein the soil sampling structure (202) comprises:

a sampling cartridge (217);

a helical sampling rod (218) disposed within the sampling cartridge (217);

a handle (220) disposed at an upper end of the screw sampling rod (218);

and two limiting rods (219) arranged below the outer end face of the sampling cylinder (217), wherein the two limiting rods (219) are perpendicular to the axial direction of the sampling cylinder (217) and are symmetrically arranged.

8. The agricultural environment big data acquisition device according to claim 1, wherein the collection box (1) comprises a first snap ring (101) and a second snap ring (102) inside, a drill cylinder (203) of the soil temperature and humidity acquisition structure (201) is clamped on the first snap ring (101), and a sampling through clamp of the soil sampling structure (202) is clamped on the second snap ring (102).

9. An agricultural environment big data acquisition device according to claim 1, characterized in that the meteorological resource data acquisition unit (3) comprises an atmospheric pressure sensor (301), a second temperature sensor (302), a second humidity sensor (303), a wind speed sensor (304), a wind direction sensor (305), a full-automatic tracking solar radiometer (306), a data memory and a second display screen (307) which are arranged on the body of the acquisition box (1);

respectively collecting atmospheric pressure, ambient temperature, ambient humidity, ambient wind speed, ambient wind direction, total solar radiation, direct radiation value, scattered radiation, sunshine duration and solar altitude angle information through an atmospheric pressure sensor (301), a second temperature sensor (302), a second humidity sensor (303), a wind speed sensor (304), a wind direction sensor (305) and a full-automatic tracking solar radiation instrument (306);

the collected information is stored in a data storage and displayed in real time by a second display screen (307).

Images