CN212568030U - Sampling device based on loose ground body of unmanned aerial vehicle control - Google Patents
Sampling device based on loose ground body of unmanned aerial vehicle control Download PDFInfo
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- CN212568030U CN212568030U CN202021574419.5U CN202021574419U CN212568030U CN 212568030 U CN212568030 U CN 212568030U CN 202021574419 U CN202021574419 U CN 202021574419U CN 212568030 U CN212568030 U CN 212568030U
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Abstract
The utility model discloses a sampling device for monitoring loose rock-soil bodies based on an unmanned aerial vehicle, which comprises an unmanned aerial vehicle system, a sampling system and an adjustable video monitoring system; the sampling system is arranged right below the unmanned aerial vehicle system and used for acquiring a sampling sample of a sampling target site; the adjustable video monitoring system is arranged at the front end of the unmanned aerial vehicle system and is used for accurately searching a sampling part of a sampling target field and shooting a sampling picture in real time; unmanned aerial vehicle system, sampling system and adjustable video monitoring system electricity are connected, carry on the mode of sample grab handle through unmanned aerial vehicle, realize carrying on the sample work of ground body sample fast, economically with the help of the quick, flexible, nimble characteristics of unmanned aerial vehicle.
Description
Technical Field
The utility model relates to a geological survey technical field, concretely relates to sampling device based on loose ground body of unmanned aerial vehicle control.
Background
Since the late twentieth century, with the continuous advance of infrastructure construction and urbanization process in China, the engineering construction field has been unprecedentedly developed. The sampling test is a basic work of geological exploration and geotechnical engineering design and is an important link for smoothly constructing various engineering facilities.
The rock-soil body can be named accurately through a sampling test, and the physical property characteristics and the mechanical parameters of the corresponding rock-soil body can be obtained. The sampling work is an important prerequisite of the test work, and the corresponding indoor test work can be carried out only by obtaining the corresponding rock and soil mass sample.
The existing sampling device adopts a push-pull sampling device, the structure installation is complex due to the arrangement, the operation steps are multiple, and the efficiency of sampling work is reduced.
At present, the sampling device on the unmanned aerial vehicle is not provided with a protection measure for the sampling hand grab, so that serious influence on the flight of the unmanned aerial vehicle due to the shaking of the sampling hand grab can be caused.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a sampling device and method based on loose ground body of unmanned aerial vehicle control, it aims at solving the technical problem that low and sample grab handle of sample work efficiency produced the interference to unmanned aerial vehicle among the prior art.
The utility model discloses a following technical scheme realizes:
a sampling device for monitoring loose rock-soil mass based on an unmanned aerial vehicle comprises an unmanned aerial vehicle system and a sampling system;
the sampling system comprises a fixed support, a sampling grab handle, a lifting rope, a grab handle storage bin and a lifting rope winding roller;
the fixed support is arranged right below the unmanned aerial vehicle system, and the lifting rope winding drum is arranged in the fixed support;
the grab bucket hand storage bin is positioned right below the lifting rope winding roller and is connected with the fixed support;
one end of the lifting rope is arranged on the lifting rope winding drum, and the other end of the lifting rope penetrates through the grab bucket hand storage bin to be connected with the sampling grab bucket hand.
This scheme adopts through setting up sampling system under the unmanned aerial vehicle system, and this sampling system adopts the cooperation mode of lifting rope hoist cylinder, lifting rope and sample grab bucket hand, can also be fast and safe sample under the complicated condition of topography.
Furthermore, the sampling grab handle is arranged in the grab handle storage bin when in a non-sampling state; and the sampling grab handle is withdrawn to the inside of the grab handle storage bin after sampling is finished.
According to the scheme, a grab bucket hand storage bin is further arranged between the lifting rope winding drum and the sampling grab bucket hand, and the grab bucket hand storage bin is used for placing and fixing the sampling grab bucket hand when the sampling is not performed and after the sampling is completed; adopt to set up grab bucket hand collecting storage can effectually avoid the grab bucket hand of taking a sample when not taking a sample or the sample is accomplished the back, because the rocking of sample grab bucket hand leads to the fact to rock and disturb unmanned aerial vehicle flight.
Furthermore, the hand grip storage bin is provided with a shape structure similar to the shape of the sampling hand grip.
Furthermore, the sampling grab handle adopts a multi-valve automatic opening and closing grab bucket.
Furthermore, the sampling system also comprises a winch remote control switch, a winch power system and a transmission belt;
the winch power system is arranged in the fixed support and connected with the lifting rope winding roller through a transmission belt;
the winch remote control switch is arranged on the outer side of the fixed support and is electrically connected with the winch power system.
Further, the unmanned aerial vehicle system comprises a body, a horn with a motor, a propeller, an airborne antenna and an undercarriage;
the airborne antenna is installed at the top of the machine body, the machine arms with the motors are fixed on the outer sides of the periphery of the machine body, the undercarriage is fixed on two sides of the lower portion of the machine body, and the propellers are connected with the machine arms with the motors in a buckling mode.
Furthermore, the fixed support is a hollow quadrilateral component, is arranged between the undercarriage on two sides under the fuselage and is fixedly connected with the fuselage and the undercarriage.
Furthermore, the sampling device for monitoring the loose rock-soil body by the unmanned aerial vehicle also comprises an adjustable video monitoring system;
the adjustable video monitoring system comprises a camera cloud deck, a link component and a monitoring camera;
the camera cloud deck is fixedly installed on the unmanned aerial vehicle system and is positioned at the front end of the fixed support;
one end of the link component is movably connected with the camera holder, the other end of the link component is movably connected with the monitoring camera, and the link component is used for the monitoring camera to rotate in the horizontal and vertical directions.
Further, the sampling system is used for acquiring a sampling sample of a sampling target site;
the adjustable video monitoring system is used for accurately searching a sampling part of a sampling target field and carrying out real-time shooting and state monitoring on a sampling picture;
the unmanned aerial vehicle system, the sampling system and the adjustable video monitoring system are electrically connected.
According to the scheme, a matching mode of an unmanned aerial vehicle system, a sampling system and an adjustable video monitoring system is adopted, the adjustable video monitoring system is used for accurately searching a sampling part of a sampling target field and shooting a sampling picture in real time, and then the sampling system is used for obtaining a sampling sample of the sampling target field, so that sampling work is completed; the sampling work under the circumstances such as the topography is complicated, the traffic is inconvenient and the environment is dangerous can be accomplished safely and fast more, can improve the work efficiency of sampling work.
Compared with the prior art, the utility model, following advantage and beneficial effect have:
1. according to the scheme, a grab bucket hand storage bin is further arranged between the lifting rope winding drum and the sampling grab bucket hand, and the grab bucket hand storage bin is used for placing and fixing the sampling grab bucket hand when the sampling is not performed and after the sampling is completed; adopt to set up grab bucket hand collecting storage can effectually avoid the grab bucket hand of taking a sample when not taking a sample or the sample is accomplished the back, because the rocking of sample grab bucket hand leads to the fact to rock and disturb unmanned aerial vehicle flight.
2. According to the scheme, a matching mode of an unmanned aerial vehicle system, a sampling system and an adjustable video monitoring system is adopted, the adjustable video monitoring system is used for accurately searching a sampling part of a sampling target field and shooting a sampling picture in real time, and then the sampling system is used for obtaining a sampling sample of the sampling target field, so that sampling work is completed; the sampling work under the circumstances such as the topography is complicated, the traffic is inconvenient and the environment is dangerous can be accomplished safely and fast more, can improve the work efficiency of sampling work.
Drawings
The accompanying drawings, which are included to provide a further understanding of the embodiments of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the principles of the invention. In the drawings:
fig. 1 is a schematic structural diagram of the present invention.
Fig. 2 is a schematic structural diagram of the sampling system of the present invention.
Fig. 3 is a schematic structural view of the sampling gripper of the present invention.
Fig. 4 is a schematic structural diagram of the adjustable video monitoring system of the present invention.
Reference numbers and corresponding part names:
1-an unmanned aerial vehicle system; 11-a fuselage; 12-horn with motor; 13-a propeller; 14-an airborne antenna; 15-a landing gear; 2-a sampling system; 21-fixing a bracket; 22-remote control switch of the winch; 23-a winch power system; 24-a drive belt; 25-a sampling grab handle; 26-a lifting rope; 27-a grab handle storage bin; 28-a sling hoisting drum; 3-a video monitoring system; 31-a camera pan-tilt; 32-a link member; 33-monitoring camera.
Detailed Description
To make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the following examples and drawings, and the exemplary embodiments and descriptions thereof of the present invention are only used for explaining the present invention, and are not intended as limitations of the present invention.
In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, it will be apparent to one of ordinary skill in the art that: it is not necessary to employ these specific details to practice the invention. In other instances, well-known structures, circuits, materials, or methods have not been described in detail so as not to obscure the present invention.
Throughout the specification, reference to "one embodiment," "an embodiment," "one example," or "an example" means: the particular features, structures, or characteristics described in connection with the embodiment or example are included in at least one embodiment of the present invention. Thus, the appearances of the phrases "one embodiment," "an embodiment," "one example" or "an example" in various places throughout this specification are not necessarily all referring to the same embodiment or example. Furthermore, the particular features, structures, or characteristics may be combined in any suitable combination and/or sub-combination in one or more embodiments or examples. Further, those of ordinary skill in the art will appreciate that the illustrations provided herein are for illustrative purposes and are not necessarily drawn to scale. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.
[ examples ] A method for producing a compound
A sampling device for monitoring loose rock-soil mass based on an unmanned aerial vehicle comprises an unmanned aerial vehicle system 1 and a sampling system 2;
the sampling system 2 comprises a fixed bracket 21, a sampling grab handle 25, a lifting rope 26, a grab handle storage bin 27 and a lifting rope winding roller 28;
the fixed support 21 is arranged right below the unmanned aerial vehicle system 1, and the lifting rope winding drum 28 is arranged inside the fixed support 21;
the grab hand storage bin 27 is positioned under the lifting rope winding roller 28 and is connected with the fixed bracket 21;
one end of the lifting rope 26 is arranged on the lifting rope winding drum 28, and the other end of the lifting rope passes through the grab handle storage bin 27 to be connected with the sampling grab handle 25.
This scheme adopts through setting up sampling system under the unmanned aerial vehicle system, and this sampling system adopts the cooperation mode of lifting rope hoist cylinder, lifting rope and sample grab bucket hand, can also be fast and safe sample under the complicated condition of topography.
Further, the sampling grab handle 25 is arranged in the grab handle storage bin 27 when in a non-sampling state; after the sampling is completed, the sampling grab handle 25 is retracted into the grab handle storage 27.
According to the scheme, a grab bucket hand storage bin is further arranged between the lifting rope winding drum and the sampling grab bucket hand, and the grab bucket hand storage bin is used for placing and fixing the sampling grab bucket hand when the sampling is not performed and after the sampling is completed; adopt to set up grab bucket hand collecting storage can effectually avoid the grab bucket hand of taking a sample when not taking a sample or the sample is accomplished the back, because the rocking of sample grab bucket hand leads to the fact to rock and disturb unmanned aerial vehicle flight.
Further, the grapple bucket 27 has a shape structure similar to the shape of the sampling grapple 25, and in the present embodiment, as shown in fig. 1, the grapple bucket 27 has a hollow circular truncated cone shape.
Further, the sampling grab handle 25 adopts a multi-flap automatic opening and closing grab.
Further, the sampling system 2 further comprises a winch remote control switch 22, a winch power system 23 and a transmission belt 24;
the winch power system 23 is arranged in the fixed support 21, and the winch power system 23 is connected with the lifting rope winding roller 28 through a transmission belt 24;
the winch remote control switch 22 is installed on the outer side of the fixing support 21, and the winch remote control switch 22 is electrically connected with the winch power system 23.
As shown in fig. 1, 2, and 3, in this embodiment, the fixing bracket 21 mainly realizes connection between the sampling system 2 combination device and the unmanned aerial vehicle system 1 and position fixing of the winch remote switch 22, the winch power system 23, and the lifting rope winch drum 28; the winch power system 23 provides power, is connected with the lifting rope winch roller 28 through the transmission belt 24, realizes rotation of the lifting rope winch roller 28, and further completes sampling work by lifting or lowering the lifting rope 26 and the sampling grab handle 25 when sampling or sampling is completed; the winch remote control switch 22 mainly realizes that an unmanned aerial vehicle sampling operator remotely controls a winch power system 23 by using a signal communication transmission system, and remotely controls the lifting, lowering and other postures of a lifting rope 26 and a sampling grab bucket hand 25; the lifting rope 26 is mainly connected with the sampling grab handle 25, so that the sampling grab handle 25 can be placed to a ground sampling point in the air; the sampling grab bucket hand 25 adopts a multi-flap automatic open-close grab bucket and has the function of grabbing samples on the ground; grab bucket hand collecting storage 27 mainly places and fixes the sample grab bucket hand, accomplishes the time interval at non-sample time interval and sample and all ensures the sample grab bucket hand inside it to avoid rocking of sample grab bucket hand to lead to the fact to rock and disturb to unmanned aerial vehicle flight.
Further, the hoist rope 26 is bolted to the hoist rope drum 28 and the sampling grapple 25.
Further, the unmanned aerial vehicle system 1 includes a body 11, an arm 12 with a motor, a propeller 13, an airborne antenna 14, and a landing gear 15;
the airborne antenna 14 is installed on the top of the machine body 11, the machine arm 12 with the motor is fixed on the outer side of the periphery of the machine body 11, the undercarriage 15 is fixed on two sides of the lower portion of the machine body 11, and the propeller 13 is connected with the machine arm 12 with the motor in a buckling mode.
Further, the fixed bracket 21 is a hollow quadrilateral member, and the fixed bracket 21 is installed between the landing gears 15 on both sides right below the fuselage 11 and is fixedly connected with the fuselage 11 and the landing gears 15.
As shown in fig. 1, in this embodiment, the unmanned aerial vehicle system 1 further includes auxiliary hardware devices such as flight control, communication, battery, and the function of the unmanned aerial vehicle system 1 mainly lies in providing a carrying platform capable of realizing flexible maneuvering flight for the sampling system 2 and the adjustable video monitoring system 3.
Furthermore, the arm 12 with motor includes at least one, and is fixed on the outer side of the periphery of the body 11 according to a certain angle and an equal interval distribution.
Further, the sampling device for monitoring the loose rock-soil mass by the unmanned aerial vehicle also comprises an adjustable video monitoring system 3;
the adjustable video surveillance system 3 comprises a camera head 31, a link member 32 and a surveillance camera 33;
the camera cloud deck 31 is fixedly installed on the unmanned aerial vehicle system 1 and is positioned at the front end of the fixed support 21;
one end of the link member 32 is movably connected with the camera pan/tilt head 31, and the other end is movably connected with the monitoring camera 33, and the link member 32 is used for monitoring the rotation of the camera 33 in the horizontal and vertical directions.
As shown in fig. 1 and 4, in the present embodiment, the adjustable control system 3 mainly includes a camera pan-tilt 31, a link member 32, and a monitoring camera 33, and realizes the confirmation of the sampling location and the monitoring of the sampling state by using the remote control camera pan-tilt 31; the camera pan-tilt 31 mainly realizes that a sampling person controls the posture of the monitoring camera 33 by using a remote controller, and ensures the stability of the monitoring camera 33; the link component 32 is used for implementing accurate execution of mechanical action of the attitude adjustment instruction of the camera pan-tilt 31 and driving the monitoring camera 33 to perform attitude adjustment; the monitoring camera 33 is used for accurately searching a ground sampling part and shooting a real-time picture of a sampling state to realize state monitoring.
Further, the sampling system 2 is used for acquiring a sampling sample of a sampling target site;
the adjustable video monitoring system 3 is used for accurately searching a sampling part of a sampling target field and carrying out real-time shooting and state monitoring on a sampling picture;
the unmanned aerial vehicle system 1, the sampling system 2 and the adjustable video monitoring system 3 are electrically connected.
According to the scheme, a matching mode of an unmanned aerial vehicle system, a sampling system and an adjustable video monitoring system is adopted, the adjustable video monitoring system is used for accurately searching a sampling part of a sampling target field and shooting a sampling picture in real time, and then the sampling system is used for obtaining a sampling sample of the sampling target field, so that sampling work is completed; the sampling work under the circumstances such as the topography is complicated, the traffic is inconvenient and the environment is dangerous can be accomplished safely and fast more, can improve the work efficiency of sampling work.
The utility model discloses a theory of operation is: the method comprises the following steps:
s1: selecting a takeoff field of the unmanned aerial vehicle; selecting a flat open field at the periphery of the sampling target field as a take-off field of the unmanned aerial vehicle;
s2: assembling the unmanned aerial vehicle before flying; installing a sampling system 2 and an adjustable video monitoring system 3 on the unmanned aerial vehicle, and carrying out equipment inspection;
s3: controlling the unmanned aerial vehicle to fly to the upper part of a sampling target field; confirming the surrounding environment and then descending the height of the unmanned aerial vehicle according to the monitoring picture of the monitoring camera 33, and then adjusting the lens of the monitoring camera 33 downwards through the linking component 32, so as to ensure that the monitoring camera 33 integrally monitors the picture of the sampling target site, and accurately positioning the target sampling site according to the picture shot by the monitoring camera 33;
s4: when the sampling target site is ensured to be positioned under the unmanned aerial vehicle, hovering the unmanned aerial vehicle, and starting a winch power system 23;
s5: by starting the winch power system 23, the conveying belt 24 drives the lifting rope winch drum 28 to rotate, the lifting rope 26 is lowered by the rotation of the lifting rope winch drum 28, the sampling grab handle 25 falls down from the inside of the grab handle storage bin 27 and is slowly lowered to the ground for sampling;
s6: after the sampling of the sampling grab handle 25 is confirmed to be normal by using the picture shot by the monitoring camera 33 and the sampling is completed, the winch power system 23 is started, the conveying belt 24 drives the lifting rope winch drum 28 to rotate, the lifting rope 26 is slowly lifted through the rotation of the lifting rope winch drum 28, and the sampling grab handle 25 is lifted into the grab handle storage bin 27;
s7: control unmanned aerial vehicle and return to take out the sample in the sample grab handle 25, accomplish the sample work of device promptly.
The above-mentioned embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above description is only the embodiments of the present invention, and is not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.
Claims (9)
1. A sampling device for monitoring loose rock-soil mass based on an unmanned aerial vehicle is characterized by comprising an unmanned aerial vehicle system (1) and a sampling system (2);
the sampling system (2) comprises a fixed support (21), a sampling grab handle (25), a lifting rope (26), a grab handle storage bin (27) and a lifting rope winding roller (28);
the fixed support (21) is arranged right below the unmanned aerial vehicle system (1), and the lifting rope winding roller (28) is arranged in the fixed support (21);
the grab handle storage bin (27) is positioned under the lifting rope winding roller (28) and is connected with the fixed support (21);
one end of the lifting rope (26) is arranged on the lifting rope winding drum (28), and the other end of the lifting rope passes through the grab handle storage bin (27) to be connected with the sampling grab handle (25).
2. The unmanned aerial vehicle-based sampling device for monitoring loose rock-soil mass according to claim 1, wherein the sampling grab handle (25) is arranged inside the grab handle storage bin (27) in a non-sampling state; and the sampling grab handle (25) is withdrawn to the inside of the grab handle storage bin (27) after sampling is finished.
3. The unmanned aerial vehicle-based sampling device for monitoring loose rock-soil mass according to claim 1, wherein the grapple receiving compartment (27) has a shape structure similar to the shape of the sampling grapple (25).
4. The sampling device for monitoring the loose rock-soil body based on the unmanned aerial vehicle as claimed in claim 1, wherein the sampling grab handle (25) adopts a multi-valve automatic open-close grab.
5. The sampling device for monitoring the loose rock-soil mass based on the unmanned aerial vehicle as claimed in claim 1, wherein the sampling system (2) further comprises a winch remote control switch (22), a winch power system (23) and a transmission belt (24);
the winch power system (23) is installed inside the fixed support (21), and the winch power system (23) is connected with the lifting rope winch drum (28) through a transmission belt (24);
the winch remote control switch (22) is installed on the outer side of the fixing support (21), and the winch remote control switch (22) is electrically connected with the winch power system (23).
6. The sampling device for monitoring the loose rock-soil mass based on the unmanned aerial vehicle is characterized in that the unmanned aerial vehicle system (1) comprises a machine body (11), a motor arm (12), a propeller (13), an airborne antenna (14) and a landing gear (15);
the airborne antenna (14) is installed at the top of the machine body (11), the machine arm (12) with the motor is fixed on the outer side of the periphery of the machine body (11), the undercarriage (15) is fixed on two sides of the lower portion of the machine body (11), and the propeller (13) is connected with the machine arm (12) with the motor in a buckling mode.
7. The sampling device for monitoring the loose rock-soil mass based on the unmanned aerial vehicle is characterized in that the fixed support (21) is a hollow quadrilateral component, and the fixed support (21) is installed between the landing gears (15) on two sides right below the body (11) and is fixedly connected with the body (11) and the landing gears (15).
8. The unmanned aerial vehicle-based sampling device for monitoring loose rock-soil mass according to claim 1, wherein the unmanned aerial vehicle-based sampling device for monitoring loose rock-soil mass further comprises an adjustable video monitoring system (3);
the adjustable video monitoring system (3) comprises a camera pan-tilt (31), a link member (32) and a monitoring camera (33);
the camera cloud deck (31) is fixedly installed on the unmanned aerial vehicle system (1) and is positioned at the front end of the fixed support (21);
one end of the link component (32) is movably connected with the camera holder (31), the other end of the link component is movably connected with the monitoring camera (33), and the link component (32) is used for the monitoring camera (33) to rotate in the horizontal and vertical directions.
9. The sampling device for monitoring the loose rock-soil mass based on the unmanned aerial vehicle is characterized in that the sampling system (2) is used for acquiring a sampling sample of a sampling target site;
the adjustable video monitoring system (3) is used for accurately searching a sampling part of a sampling target field and carrying out real-time shooting and state monitoring on a sampling picture;
the unmanned aerial vehicle system (1), the sampling system (2) and the adjustable video monitoring system (3) are electrically connected.
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CN111879554A (en) * | 2020-07-31 | 2020-11-03 | 中国电建集团成都勘测设计研究院有限公司 | Sampling device and method for monitoring loose rock-soil mass based on unmanned aerial vehicle |
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