CN212363099U - Grain quantity online detection system based on vision technology - Google Patents

Abstract

The utility model relates to a grain quantity on-line measuring system based on vision technique, including two mesh cameras, adjusting module, communication module, temperature and humidity sensor and gas sensor, two mesh cameras are used for acquireing the data of grain quantity in the grain depot, adjusting module is used for adjusting two mesh cameras's position and shooting angle, communication module is used for transmission signal, temperature and humidity sensor is used for acquireing the temperature in the grain depot, humidity data, gas sensor is used for acquireing the gas data in the grain depot; the adjustment module includes a first movement mechanism. This grain quantity on-line measuring system based on vision technique adopts binocular camera and visual identification and calculation technique, to irregular grain face automatic generation grain face curve, and the temperature and humidity sensor, the gas sensor who installs additional simultaneously on binocular camera can real-time collection storehouse interior grain big data, with information such as grain quantity real-time conveying to the terminal.

Description

Grain quantity online detection system based on vision technology

Technical Field

The utility model belongs to grain depot detecting system field, concretely relates to grain quantity on-line measuring system based on vision technique.

Background

Laser radar is a short for laser detection and ranging system. Lidar is a product of a combination of laser technology and radar technology. The device consists of a transmitter, an antenna, a receiver, a tracking frame, information processing and the like. The transmitter is various lasers, such as a carbon dioxide laser, a neodymium-doped yttrium aluminum garnet laser, a semiconductor laser, a wavelength tunable solid laser and the like; the antenna is an optical telescope; the receiver employs various forms of photodetectors such as photomultiplier tubes, semiconductor photodiodes, avalanche photodiodes, infrared and visible light multiplexed detection devices, and the like. The laser radar adopts two working modes of pulse or continuous wave, and the detection method includes direct detection and heterodyne detection.

At present, an online grain quantity detection system for measuring by using a laser radar is already applied to a national grain storage warehouse demonstration warehouse, and the laser radar technology measurement has the defects that the system is only suitable for measuring regular grain surfaces, the volume error of grain piles is large when the grain surface piles are unequal, and the like.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a simple structure, reasonable in design's a grain quantity on-line measuring system based on vision technique for solving above-mentioned problem.

The utility model discloses a following technical scheme realizes above-mentioned purpose:

the utility model provides a grain quantity on-line measuring system based on vision technique, includes binocular camera, adjusting module, communication module, temperature and humidity sensor and gas sensor, the binocular camera is used for acquireing the data of grain quantity in the grain depot, adjusting module is used for adjusting the position and the shooting angle of binocular camera, communication module is used for transmission signal, temperature and humidity sensor is used for acquireing the temperature in the grain depot, humidity data, gas sensor is used for acquireing the gas data in the grain depot.

As a further optimization scheme of the utility model, the adjusting module includes first moving mechanism, connect the second moving mechanism on first moving mechanism, connect the connecting plate on the second moving mechanism, connect altitude mixture control motor and a plurality of gag lever post on the connecting plate, connect the first lead screw of altitude mixture control motor output shaft, locate the carriage release lever on the first lead screw, swing joint is at the connecting rod of carriage release lever lower extreme, connect the bracing piece on the connecting rod, connect the angle modulation motor of bracing piece one end, connect the gear of angle modulation motor output shaft and connect the ring gear on the carriage release lever outer wall, two mesh cameras are connected at the lower extreme of connecting rod, gear and ring gear meshing.

As the utility model discloses a further optimization scheme, first moving mechanism and second moving mechanism all include the installing support, connect driving motor and a plurality of guide bar on the installing support, connect the second lead screw on the driving motor output shaft and install the slider on the second lead screw, be equipped with on the slider with guide bar matched with guiding hole.

As a further optimization scheme of the utility model, first moving mechanism and second moving mechanism are crisscross distribution, and the slider in the first moving mechanism and the installing support in the second moving mechanism are connected.

As the utility model discloses a further optimization scheme, a plurality of gag lever post evenly distributed is around altitude mixture control motor, be equipped with a plurality of and gag lever post matched with spacing hole on the carriage release lever, be equipped with on the carriage release lever with first lead screw matched with screw.

As the utility model discloses a further optimization scheme, be equipped with the removal cavity in the carriage release lever, remove cavity and screw intercommunication, the lower extreme of first lead screw is connected with the anticreep dish, and first lead screw and anticreep dish all are located the removal cavity.

As the utility model discloses a further optimization scheme, the diameter of anticreep dish is less than the internal diameter of removing the cavity, and the diameter of anticreep dish is greater than the diameter of screw.

As a further optimization scheme of the utility model, the upper end of connecting rod is connected with interior capstan, the lower extreme of carriage release lever be equipped with interior capstan to complex interior spiral groove.

The beneficial effects of the utility model reside in that:

1) the utility model adopts a binocular camera and a visual identification and calculation technology, automatically generates a grain surface curve aiming at irregular grain surfaces, and simultaneously, a temperature and humidity sensor and a gas sensor which are additionally arranged on the binocular camera can collect grain big data in a bin in real time and transmit information such as grain quantity to a terminal in real time;

2) the utility model can adjust the position and the shooting angle of the binocular camera, when adjusting the position of the binocular camera, the binocular camera can move along the X axis, the Y axis and the Z axis, when adjusting the position of the binocular camera to move on the Z axis, the altitude adjusting motor works and drives the first lead screw to rotate, the first lead screw drives the movable rod to move upwards or downwards on the first lead screw after rotating, and drives the binocular camera connected at the bottom of the movable rod to move in the same direction and at the same distance, when adjusting the position of the binocular camera to move on the X axis and the Y axis, the adjustment is carried out through the first movable mechanism and the second movable mechanism, the working principle of the first movable mechanism and the second movable mechanism is the same, the second lead screw is driven to rotate through the driving motor, the driving slide block moves along the direction of the lead screw after rotating the second lead screw, because the first movable mechanism and the second movable mechanism are distributed in a cross way, therefore, the binocular camera can be adjusted to move on an X axis and a Y axis, when the shooting angle is adjusted, the angle adjusting motor works and drives the gear to rotate, the moving rod is limited by the limiting rod to rotate, and the moving rod is movably connected with the connecting rod, so that the gear can move along the outer teeth of the annular gear and drive the binocular camera to rotate together, the function of adjusting the shooting angle of the binocular camera is achieved, the binocular camera can be used in different grain depots, and when the number of grains in the grain depots changes, the binocular camera can be adjusted adaptively through the adjusting module;

3) the utility model discloses simple structure, stability is high, reasonable in design, the realization of being convenient for.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a schematic structural diagram of the adjusting module of the present invention;

fig. 3 is a schematic structural diagram of the moving mechanism of the present invention.

In the figure: 1. a binocular camera; 2. an adjustment module; 201. a first moving mechanism; 202. a second moving mechanism; 203. a connecting plate; 204. a height adjustment motor; 205. a limiting rod; 206. a first lead screw; 207. a travel bar; 208. moving the chamber; 209. a tray is prevented from falling; 210. an inner rotating disc; 211. a connecting rod; 212. a support bar; 213. an angle adjustment motor; 214. a gear; 215. a ring gear; 216. mounting a bracket; 217. a drive motor; 218. a guide bar; 219. a second lead screw; 220. a slider; 3. a communication module; 4. a temperature and humidity sensor; 5. a gas sensor.

Detailed Description

The present application will now be described in further detail with reference to the drawings, it should be noted that the following detailed description is given for illustrative purposes only and is not to be construed as limiting the scope of the present application, as those skilled in the art will be able to make numerous insubstantial modifications and adaptations to the present application based on the above disclosure.

Example 1

As shown in fig. 1-3, an online grain quantity detection system based on a visual technology includes a binocular camera 1, an adjusting module 2, a communication module 3, a temperature and humidity sensor 4 and a gas sensor 5, wherein the binocular camera 1 is used for acquiring data of the grain quantity in a grain depot, the adjusting module 2 is used for adjusting the position and shooting angle of the binocular camera 1, the communication module 3 is used for transmitting signals, the temperature and humidity sensor 4 is used for acquiring temperature and humidity data in the grain depot, the gas sensor 5 is used for acquiring gas data in the grain depot, the communication module 3 can send the data acquired by each module to a terminal, and the terminal can inform the working state of each module;

the binocular camera 1 and the visual identification and calculation technology are adopted, a grain surface curve is automatically generated aiming at irregular grain surfaces, identification, calculation and generation can be carried out on a terminal, meanwhile, a temperature and humidity sensor 4 and a gas sensor 5 which are additionally arranged on the binocular camera 1 can collect grain big data in a bin in real time, information such as grain quantity, temperature, humidity and gas components in the grain big data can be transmitted to the terminal in real time, the problem that accurate measurement cannot be carried out when grain surface pile heights are different is solved, and the application range is wider;

the adjusting module 2 comprises a first moving mechanism 201, a second moving mechanism 202 connected to the first moving mechanism 201, a connecting plate 203 connected to the second moving mechanism 202, a height adjusting motor 204 and a plurality of limiting rods 205 connected to the connecting plate 203, a first screw rod 206 connected to an output shaft of the height adjusting motor 204, a moving rod 207 arranged on the first screw rod 206, a connecting rod 211 movably connected to the lower end of the moving rod 207, a supporting rod 212 connected to the connecting rod 211, an angle adjusting motor 213 connected to one end of the supporting rod 212, a gear 214 connected to an output shaft of the angle adjusting motor 213 and a ring gear 215 connected to the outer wall of the moving rod 207, the binocular camera 1 is connected to the lower end of the connecting rod 211, and the gear 214 is meshed with the ring gear 215;

the moving rod 207 is limited by the limiting rod 205 to rotate, so that when the height adjusting motor 204 drives the first lead screw 206 to rotate, the first lead screw 206 can only move upwards or downwards along the first lead screw 206, and because the moving rod 207 is limited to rotate, the ring gear 215 connected to the moving rod is also in a fixed state, and the connecting rod 211 and the moving rod 207 are movably connected, so that when the angle adjusting motor 213 drives the gear 214 to rotate, the gear 214 moves around the ring gear 215 to drive the connecting rod 211 and the binocular camera 1 connected to the lower end of the connecting rod to rotate at a certain angle, thereby achieving adjustment;

the first moving mechanism 201 and the second moving mechanism 202 both comprise a mounting bracket 216, a driving motor 217 and a plurality of guide rods 218 connected to the mounting bracket 216, a second screw rod 219 connected to an output shaft of the driving motor 217, and a sliding block 220 mounted on the second screw rod 219, wherein the sliding block 220 is provided with a guide hole matched with the guide rods 218;

the first moving mechanism 201 and the second moving mechanism 202 are distributed in a crisscross manner, a sliding block 220 in the first moving mechanism 201 is connected with a mounting bracket 216 in the second moving mechanism 202, the first moving mechanism 201 can drive the second moving mechanism 202 to move along an X axis or a Y axis, and the second moving mechanism 202 can drive the binocular camera 1 to move along the Y axis or the X axis;

a plurality of limiting rods 205 are uniformly distributed around the height adjusting motor 204, a plurality of limiting holes matched with the limiting rods 205 are formed in the moving rod 207, and screw holes matched with the first screw rods 206 are formed in the moving rod 207; a moving chamber 208 is arranged in the moving rod 207, the moving chamber 208 is communicated with the screw hole, the lower end of the first screw rod 206 is connected with an anti-falling disc 209, and the first screw rod 206 and the anti-falling disc 209 are both positioned in the moving chamber 208; the diameter of the anti-falling disc 209 is smaller than the inner diameter of the moving chamber 208, and the diameter of the anti-falling disc 209 is larger than that of the screw hole; the upper end of the connecting rod 211 is connected with an inner rotating disc 210, and the lower end of the moving rod 207 is provided with an inner rotating groove which is matched with the inner rotating disc 210;

the adjusting module 2 can adjust the position and the shooting angle of the binocular camera 1, when the position of the binocular camera 1 is adjusted, the binocular camera 1 can move along the X axis, the Y axis and the Z axis, when the position of the binocular camera 1 is adjusted to move on the Z axis, the height adjusting motor 204 works and drives the first screw rod 206 to rotate, the first screw rod 206 drives the moving rod 207 to move upwards or downwards on the first screw rod 206 after rotating, and drives the binocular camera 1 connected to the bottom of the moving rod 207 to move in the same direction and at the same distance, when the position of the binocular camera is adjusted to move on the X axis and the Y axis, the adjusting module is adjusted by the first moving mechanism 201 and the second moving mechanism 202, the working principle of the first moving mechanism 201 and the second moving mechanism 202 is the same, the second screw rod 219 is driven to rotate by the driving motor 217, the second screw rod 219 drives the sliding block 220 to move along the direction of the screw rods, because the first moving mechanism 201 and the second moving mechanism 202 are distributed in a cross way, therefore, the binocular camera 1 can be adjusted to move on an X axis and a Y axis, when the shooting angle is adjusted, the angle adjusting motor 213 works and drives the gear 214 to rotate, the movable rod 207 is limited by the limiting rod 205 to rotate, and the movable rod 207 is movably connected with the connecting rod 211, so the gear 214 can move along the outer teeth of the annular gear 215 and drive the binocular camera 1 to rotate together, thereby the function of adjusting the shooting angle of the binocular camera 1 is achieved, the binocular camera can be used in different grain warehouses, and when the amount of grains in the grain warehouses changes, the binocular camera 1 can be adjusted adaptively through the adjusting module 2.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (8)

1. The utility model provides an online detecting system of grain quantity based on vision technique which characterized in that: including two mesh cameras (1), adjusting module (2), communication module (3), temperature and humidity sensor (4) and gas sensor (5), two mesh cameras (1) are used for acquireing the data of grain quantity in the grain depot, adjusting module (2) are used for adjusting the position and the shooting angle of two mesh cameras (1), communication module (3) are used for transmission signal, temperature and humidity sensor (4) are used for acquireing the temperature in the grain depot, humidity data, gas sensor (5) are used for acquireing the gas data in the grain depot.

2. The on-line grain quantity detection system based on the vision technology as claimed in claim 1, wherein: the adjusting module (2) comprises a first moving mechanism (201), a second moving mechanism (202) connected to the first moving mechanism (201), a connecting plate (203) connected to the second moving mechanism (202), a height adjusting motor (204) and a plurality of limiting rods (205) connected to the connecting plate (203), a first screw rod (206) connected to an output shaft of the height adjusting motor (204), a moving rod (207) arranged on the first screw rod (206), a connecting rod (211) movably connected to the lower end of the moving rod (207), a supporting rod (212) connected to the connecting rod (211), an angle adjusting motor (213) connected to one end of the supporting rod (212), a gear (214) connected to an output shaft of the angle adjusting motor (213) and an annular gear (215) connected to the outer wall of the moving rod (207), wherein the binocular camera (1) is connected to the lower end of the connecting rod (211), the gear (214) meshes with a ring gear (215).

3. The on-line grain quantity detection system based on the vision technology as claimed in claim 2, wherein: the first moving mechanism (201) and the second moving mechanism (202) respectively comprise a mounting bracket (216), a driving motor (217) and a plurality of guide rods (218) which are connected to the mounting bracket (216), a second screw rod (219) which is connected to an output shaft of the driving motor (217) and a sliding block (220) which is installed on the second screw rod (219), and guide holes matched with the guide rods (218) are formed in the sliding block (220).

4. The on-line grain quantity detection system based on the vision technology as claimed in claim 3, wherein: the first moving mechanism (201) and the second moving mechanism (202) are distributed in a crisscross mode, and a sliding block (220) in the first moving mechanism (201) is connected with a mounting bracket (216) in the second moving mechanism (202).

5. The on-line grain quantity detection system based on the vision technology as claimed in claim 2, wherein: a plurality of gag lever post (205) evenly distributed is around altitude mixture control motor (204), be equipped with a plurality of and gag lever post (205) matched with spacing hole on carriage release lever (207), be equipped with on carriage release lever (207) with first lead screw (206) matched with screw.

6. The on-line grain quantity detection system based on the vision technology as claimed in claim 2, wherein: be equipped with in the carriage release lever (207) and remove cavity (208), remove cavity (208) and screw intercommunication, the lower extreme of first lead screw (206) is connected with anticreep dish (209), and first lead screw (206) and anticreep dish (209) all are located and remove cavity (208).

7. The on-line grain quantity detection system based on the vision technology as claimed in claim 6, wherein: the diameter of the anti-falling disc (209) is smaller than the inner diameter of the moving chamber (208), and the diameter of the anti-falling disc (209) is larger than that of the screw hole.

8. The on-line grain quantity detection system based on the vision technology as claimed in claim 2, wherein: the upper end of connecting rod (211) is connected with interior capstan (210), the lower extreme of carriage release lever (207) is equipped with and interior capstan (210) to the interior spiral groove of complex.

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