CN217456373U - A unmanned aerial vehicle control mounting structure for storage logistics monitoring - Google Patents

Abstract

The application discloses an unmanned aerial vehicle monitoring and mounting structure for warehouse logistics monitoring, which relates to the technical field of mounting structures and comprises an unmanned aerial vehicle main body, wherein a monitoring component is mounted at the bottom of the unmanned aerial vehicle main body, when the monitoring component is assembled with the unmanned aerial vehicle main body, a positioning plate is inserted and connected in a T-shaped plate groove, a positioning lug can extrude an internal spring under the action of external force, so that the positioning lug is contracted into an adjusting groove, the spring is deformed under the condition of stress and generates opposite acting force, the positioning lug can be ejected out of the adjusting groove, the positioning plate can be driven to move upwards in the T-shaped plate groove, a positioning column at the top of the T-shaped plate groove can be ejected into a positioning through hole at the inner side of the T-shaped groove, the monitoring component can be limited and fixed at the bottom of a remote sensing unmanned aerial vehicle, and the monitoring component can be rapidly disassembled and assembled by the unmanned aerial vehicle main body, the stability of the connection between the two can also be improved.

Description

A unmanned aerial vehicle control mounting structure for storage logistics monitoring

Technical Field

The utility model belongs to the technical field of the mounting structure technique and specifically relates to an unmanned aerial vehicle control mounting structure for storage logistics monitoring is related to.

Background

An unmanned aircraft, abbreviated as "drone", and abbreviated in english as "UAV", is an unmanned aircraft that is operated by a radio remote control device and a self-contained program control device, or is operated autonomously, either completely or intermittently, by an onboard computer. Along with the continuous development of the express delivery industry, remote sensing unmanned aerial vehicles have been adopted to carry out remote monitoring management on storage logistics centers. At present, the remote sensing unmanned aerial vehicle's that warehouse logistics used structure is too single, and unmanned organism and surveillance camera head majority adopt modes such as bolts to carry out the composite mounting, and this kind of traditional connected mode makes unmanned organism and surveillance camera head's equipment convenient and fast inadequately, increases user's the use degree of difficulty, is unfavorable for unmanned aerial vehicle to rise to the air fast and monitors for warehouse logistics.

SUMMERY OF THE UTILITY MODEL

In order to improve the above-mentioned problem, the utility model provides an unmanned aerial vehicle control mounting structure for storage logistics monitoring.

The utility model provides an unmanned aerial vehicle control mounting structure for storage logistics monitoring adopts following technical scheme: an unmanned aerial vehicle monitoring and mounting structure for warehouse logistics monitoring comprises an unmanned aerial vehicle main body, wherein a monitoring assembly is mounted at the bottom of the unmanned aerial vehicle main body, a remote sensing camera is arranged at the bottom of the monitoring assembly, T-shaped plate grooves are formed in two sides of the top of the monitoring assembly, and two groups of positioning through holes are formed in two sides of the top of each T-shaped plate groove;

the bottom of unmanned aerial vehicle main part is provided with the chassis, the locating plate is all installed to the bottom both sides on chassis.

Based on the technical characteristics: when the control subassembly is assembled with the unmanned aerial vehicle main part, at first with the bottom on chassis of two sets of locating plate bolt fastening, then with two sets of locating plates difference ann insert in the T type board groove of control subassembly, locating lug can extrude inside spring under the effect of external force this moment, make locating lug shrink to the inside of adjustment tank, and the spring takes place to deform and produces opposite effort under the condition of atress, can follow the ejecting of adjustment tank inside with locating lug, can drive the locating plate in the inside rebound of T type board groove, can push into the positioning hole of T type inboard side in the reference column top at T type board groove top this moment, thereby can be with the spacing bottom of fixing at remote sensing unmanned aerial vehicle of control subassembly, when realizing that the unmanned aerial vehicle main part carries out quick assembly disassembly operation to the control subassembly, can also promote the stability of connecting between the two.

As an unmanned aerial vehicle control mounting structure for storage logistics monitoring, wherein: the bottom both sides on chassis all are provided with the connecting block, first fixed screw has still been seted up to the bottom of connecting block.

Based on the technical characteristics: through connecting block and first fixed screw structure, the user can carry out dismouting change operation to it according to the in service behavior of locating plate.

As an unmanned aerial vehicle control mounting structure for storage logistics monitoring, wherein: two groups of positioning columns are respectively installed on two sides of the top of the positioning plate, positioning convex blocks are arranged on two sides of the bottom of the positioning plate, and a groove is formed between the two groups of positioning convex blocks.

Based on the technical characteristics: when the locating plate is connected in the inside in T type plate groove, through reference column and location lug structure, can promote the stability that locating plate and T type plate groove are connected.

As an unmanned aerial vehicle control mounting structure for storage logistics monitoring, wherein: the positioning column is matched with the positioning through hole structure, and the positioning column is in insertion fit with the positioning through hole.

Based on the technical characteristics: because of reference column and positioning hole structure phase-match, and reference column and positioning hole be the grafting cooperation, when the locating plate is connected in the inside in T type board groove, can effectively avoid both to take place the circumstances not hard up, skew when connecting.

As an unmanned aerial vehicle control mounting structure for storage logistics monitoring, wherein: a second fixing screw hole is formed in the groove, and a fixing bolt is connected to the inside of the second fixing screw hole in a threaded mode.

Based on the technical characteristics: through the inside with the fixed screw of the first fixed screw of fixing bolt threaded connection and the fixed screw of second, conveniently fix two sets of locating plate bolt in the bottom both sides on chassis, cooperation groove structure can also play the effect of accomodating and hiding fixing bolt, can effectively avoid fixing bolt in the convex condition in locating plate bottom.

As an unmanned aerial vehicle control mounting structure for storage logistics monitoring, wherein: the bottom of the positioning lug is provided with an adjusting groove, two sides of the inside of the adjusting groove are provided with slide bars, the slide bars are in sliding fit with the positioning lug, and springs are further mounted outside the slide bars.

Based on the technical characteristics: through adjustment tank, slide bar and spring structure, the locating lug can carry out self-adaptation elastic adjustment according to the connected condition of locating plate and T type plate groove.

To sum up, the utility model discloses a following at least one beneficial effect: when the control subassembly is assembled with the unmanned aerial vehicle main part, at first with the bottom on chassis of two sets of locating plate bolt fastening, then with two sets of locating plates difference ann insert in the T type board groove of control subassembly, locating lug can extrude inside spring under the effect of external force this moment, make locating lug shrink to the inside of adjustment tank, and the spring takes place to deform and produces opposite effort under the condition of atress, can follow the ejecting of adjustment tank inside with locating lug, can drive the locating plate in the inside rebound of T type board groove, can push into the positioning hole of T type inboard side in the reference column top at T type board groove top this moment, thereby can be with the spacing bottom of fixing at remote sensing unmanned aerial vehicle of control subassembly, when realizing that the unmanned aerial vehicle main part carries out quick assembly disassembly operation to the control subassembly, can also promote the stability of connecting between the two.

Drawings

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

fig. 2 is a schematic structural diagram of the main body of the unmanned aerial vehicle of the present invention;

fig. 3 is a schematic structural diagram of the monitoring assembly of the present invention;

fig. 4 is a schematic view of the positioning bump structure of the present invention.

Description of reference numerals:

1. an unmanned aerial vehicle main body; 2. a monitoring component; 3. a chassis; 4. positioning a plate; 5. connecting blocks; 6. a first fixing screw hole; 7. a positioning column; 8. positioning the bump; 9. a groove; 10. a second fixing screw hole; 11. fixing the bolt; 12. a remote sensing camera; 13. a T-shaped plate groove; 14. positioning the through hole; 15. an adjustment groove; 16. a slide bar; 17. a spring.

Detailed Description

The present invention will be described in further detail with reference to the accompanying fig. 1-4.

Please refer to fig. 1-3, the utility model provides a pair of an unmanned aerial vehicle control mounting structure for storage logistics monitoring, including unmanned aerial vehicle main part 1, the bottom of unmanned aerial vehicle main part 1 is provided with chassis 3, and locating plate 4 is all installed to chassis 3's bottom both sides, and chassis 3's bottom both sides all are provided with connecting block 5, and first fixed screw 6 has still been seted up to connecting block 5's bottom, and the user can carry out the dismouting change operation to it according to locating plate 4's in service behavior.

Monitoring subassembly 2 is installed to the bottom of unmanned aerial vehicle main part 1, and monitoring subassembly 2's bottom is provided with remote sensing camera 12, and T template groove 13 has all been seted up to monitoring subassembly 2's top both sides, and two sets of positioning hole 14 have been seted up respectively to T template groove 13's top both sides.

Referring to fig. 2-4, two sets of positioning columns 7 are respectively installed on two sides of the top of the positioning plate 4, the positioning columns 7 are structurally matched with the positioning through holes 14, the positioning columns 7 are in insertion fit with the positioning through holes 14, when the positioning plate 4 is connected inside the T-shaped plate grooves 13, the situation that the positioning plate 4 is loosened and offset when the positioning plate is connected with the T-shaped plate grooves can be effectively avoided, positioning convex blocks 8 are arranged on two sides of the bottom of the positioning plate 4, adjusting grooves 15 are formed in the bottoms of the positioning convex blocks 8, sliding rods 16 are arranged on two sides of the inside of the adjusting grooves 15, the sliding rods 16 are in sliding fit with the positioning convex blocks 8, springs 17 are further installed outside the sliding rods 16, and the positioning convex blocks 8 can perform self-adaptive elastic adjustment according to the connection situation of the positioning plate 4 and the T-shaped plate grooves 13.

Set up recess 9 between two sets of locating convex block 8, can play to accomodate hidden effect to fixing bolt 11, can effectively avoid fixing bolt 11 in the convex condition in locating plate 4 bottom, the fixed screw 10 of second has been seted up to recess 9's inside, the inside of the fixed screw 10 of second still threaded connection has fixing bolt 11, through the inside with the first fixed screw 6 of 11 threaded connection of fixing bolt and the fixed screw 10 of second, conveniently with two sets of locating plate 4 bolt fastening in the bottom both sides on chassis 3, the user can carry out dismouting change operation to it according to locating plate 4's in service behavior.

The working principle is as follows: when the monitoring component 2 is assembled with the unmanned aerial vehicle main body 1, firstly, two groups of positioning plates 4 are fixed at the bottom of the chassis 3 through bolts, then, two groups of positioning plates 4 are respectively inserted into the T-shaped plate grooves 13 of the monitoring component 2, at the moment, the positioning lugs 8 can extrude the internal springs 17 under the action of external force, so that the positioning lugs 8 are contracted into the adjusting grooves 15, the springs 17 deform under the stress condition and generate opposite acting force, the positioning lugs 8 can be ejected out of the adjusting grooves 15, the positioning plates 4 can be driven to move upwards in the T-shaped plate grooves 13, at the moment, the positioning columns 7 at the tops of the T-shaped plate grooves 13 can be ejected into the positioning through holes 14 at the inner sides of the T-shaped grooves, so that the monitoring component 2 can be limited and fixed at the bottom of the remote sensing unmanned aerial vehicle, and the unmanned aerial vehicle main body 1 can carry out quick dismounting operation on the monitoring component 2, the stability of connection between the two can be improved;

through the connection structure who adopts this scheme, storage logistics center can carry out dismouting connection and maintenance change operation to monitoring subassembly 2 according to remote sensing unmanned aerial vehicle's in service behavior to this promotes remote sensing unmanned aerial vehicle to storage logistics center remote monitoring's work efficiency.

Above is the preferred embodiment of the utility model, not limit according to this the utility model discloses a protection scope, the event: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (6)

1. The utility model provides an unmanned aerial vehicle control mounting structure for storage logistics monitoring, includes unmanned aerial vehicle main part (1), its characterized in that: the unmanned aerial vehicle comprises an unmanned aerial vehicle main body (1), and is characterized in that a monitoring assembly (2) is mounted at the bottom of the unmanned aerial vehicle main body (1), a remote sensing camera (12) is arranged at the bottom of the monitoring assembly (2), T-shaped plate grooves (13) are formed in two sides of the top of the monitoring assembly (2), and two groups of positioning through holes (14) are formed in two sides of the top of each T-shaped plate groove (13);

the bottom of unmanned aerial vehicle main part (1) is provided with chassis (3), locating plate (4) are all installed to the bottom both sides on chassis (3).

2. An unmanned aerial vehicle monitoring and mounting structure for warehouse logistics monitoring according to claim 1, wherein: the bottom both sides of chassis (3) all are provided with connecting block (5), first fixed screw (6) have still been seted up to the bottom of connecting block (5).

3. An unmanned aerial vehicle monitoring and mounting structure for warehouse logistics monitoring according to claim 1, wherein: two groups of positioning columns (7) are respectively installed on two sides of the top of the positioning plate (4), positioning convex blocks (8) are respectively arranged on two sides of the bottom of the positioning plate (4), and a groove (9) is formed between the two groups of positioning convex blocks (8).

4. An unmanned aerial vehicle monitoring and mounting structure for warehouse logistics monitoring according to claim 3, wherein: the positioning column (7) is structurally matched with the positioning through hole (14), and the positioning column (7) is in insertion fit with the positioning through hole (14).

5. An unmanned aerial vehicle monitoring and mounting structure for warehouse logistics monitoring according to claim 3, wherein: a second fixing screw hole (10) is formed in the groove (9), and a fixing bolt (11) is connected to the inner portion of the second fixing screw hole (10) in a threaded mode.

6. An unmanned aerial vehicle monitoring and mounting structure for warehouse logistics monitoring according to claim 3, wherein: adjustment groove (15) have been seted up to the bottom of location lug (8), the inside both sides of adjustment groove (15) are provided with slide bar (16), slide bar (16) are sliding fit with location lug (8), spring (17) are still installed to the outside of slide bar (16).

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