CN216036291U - Aerial robot external packing structure - Google Patents

Abstract

The utility model relates to the technical field of packaging boxes, in particular to an aerial robot outer packaging structure; the damping device comprises an outer shell, a supporting frame and a damping component; the support frame is fixedly connected with the outer shell and is positioned inside the outer shell; damping component includes interior casing, shock absorber support, spring and telescopic link, the telescopic link is connected with the support frame, and set up on the support frame, shock absorber support is connected with the telescopic link, the both ends of spring respectively with support frame and shock absorber support butt, and the cover is established on the telescopic link, interior casing and shock absorber support fixed connection, through the support frame, promote the holistic bearing of aerial robot extranal packing structure, and then avoid shell body atress to warp, through the telescopic link, make shock absorber support can follow the direction removal of telescopic link, through the spring, make shock absorber support can reduce vibrations when taking place to rock, and then make interior casing reduce vibrations, thereby realize avoiding aerial robot to take place to rock, cause the condition that aerial robot damaged.

Description

Aerial robot external packing structure

Technical Field

The utility model relates to the technical field of packaging boxes, in particular to an aerial robot outer packaging structure.

Background

The existing aerial robot outer package jolts in the transportation process, so that the aerial robot in the existing aerial robot outer package jolts, the aerial robot can be damaged, and unnecessary economic loss is caused.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an aerial robot outer packaging structure, and aims to solve the problem that in the prior art, the aerial robot outer packaging structure jolts in the transportation process, so that unnecessary economic loss is caused.

In order to achieve the purpose, the utility model provides an aerial robot outer packaging structure, which comprises an outer shell, a supporting frame and a damping assembly, wherein the outer shell is provided with a plurality of supporting holes; the support frame is fixedly connected with the outer shell and is positioned inside the outer shell; damping component includes interior casing, shock absorber support, spring and telescopic link, the telescopic link with the support frame is connected, and sets up on the support frame, shock absorber support with the telescopic link is connected, and is located the telescopic link is kept away from one side of support frame, the both ends of spring respectively with the support frame with the shock absorber support butt, and the cover is established on the telescopic link, and be located the support frame with between the shock absorber support, interior casing with shock absorber support fixed connection, and set up on the shock absorber support.

The support frame with shock-absorbing support all is made by plastics, because the bearing capacity of plastics is higher than paper, so the support frame can support the shell body avoids shell body atress deformation, the shell body with interior casing is made by paper, and paper light in weight can reduce aerial robot outer packaging structure's weight, through the support frame promotes aerial robot outer packaging structure holistic bearing, through the telescopic link makes shock-absorbing support can follow the direction of telescopic link removes, through the spring weakens the vibrations that shock-absorbing support takes place are moved, and then make interior casing reduces vibrations to the realization avoids aerial robot to shake, causes the condition that aerial robot damaged.

The telescopic rod comprises a connecting seat and a connecting rod, the connecting seat is fixedly connected with the supporting frame and is positioned on one side of the supporting frame, which is close to the damping support; the connecting rod is connected with the connecting seat in a sliding mode, fixedly connected with the damping support and located on one side, close to the damping support, of the connecting seat.

The connecting seat is fixedly bonded with the supporting frame and is positioned on one side, close to the damping support, of the supporting frame, the connecting rod is connected with the connecting seat in a sliding mode and is fixedly bonded with the damping support and is positioned on one side, close to the damping support, of the connecting seat, and the telescopic rod can stretch out and draw back through the sliding connection of the connecting seat and the connecting rod.

The outer shell is provided with a first observation window, the first observation window penetrates through the outer shell, and the first observation window is arranged on the outer shell.

Through the first observation window, a customer can see the condition inside the outer shell, and therefore the purpose that the customer can see the robot in the air inside the outer shell is achieved.

The aerial robot outer packaging structure further comprises a first plastic film, wherein the first plastic film is fixedly connected with the outer shell and is positioned on one side, close to the first observation window, of the outer shell.

First plastic film is made by plastics, has good light transmissivity, first plastic film with the shell body bonding is fixed, and is located the shell body is close to one side of first observation window, through first plastic film not only makes the customer can see the inside condition of shell, can also be right the inside of shell is protected.

Wherein, the interior casing has the second observation window, the second observation window runs through interior casing, the second observation window sets up on the interior casing.

Through the second observation window, a customer can see the condition inside the inner shell, so that the customer can see the robot in the air inside the inner shell.

The shock absorption assembly further comprises a second plastic film, the second plastic film is fixedly connected with the inner shell and is positioned on one side, close to the second observation window, of the inner shell.

The second plastic film is made of plastic and has good light transmittance, the second plastic film is fixedly bonded with the inner shell and is positioned on one side of the inner shell close to the second observation window, and a customer can see the condition inside the inner shell and can protect the inside of the inner shell through the second plastic film.

The aerial robot outer packaging structure further comprises a first sealing element, wherein the first sealing element is connected with the outer shell in a rotating mode and is arranged on the outer shell.

The first sealing element is rotatably connected with the outer shell and arranged on the outer shell, and the opening of the outer shell can be sealed through the first sealing element, so that the aim of integrally sealing the outer shell is fulfilled.

The shock absorption assembly further comprises a second sealing member, the second sealing member is rotatably connected with the inner shell and is arranged on the inner shell.

The second sealing member with interior casing rotates to be connected, and sets up on the interior casing, through the second sealing member, make the opening part of interior casing can seal, thereby realize with the whole sealed purpose of interior casing.

The utility model relates to an aerial robot outer packaging structure which comprises an outer shell, a supporting frame and a damping assembly, wherein the outer shell is provided with a plurality of supporting holes; the support frame is fixedly connected with the outer shell and is positioned inside the outer shell; the shock absorption assembly comprises an inner shell, a shock absorption support, a spring and a telescopic rod, wherein the telescopic rod is connected with the support and is arranged on the support, the shock absorption support is connected with the telescopic rod and is positioned on one side of the telescopic rod, which is far away from the support, two ends of the spring are respectively abutted against the support and the shock absorption support, are sleeved on the telescopic rod and are positioned between the support and the shock absorption support, the inner shell is fixedly connected with the shock absorption support and is arranged on the shock absorption support, the support and the shock absorption support are both made of plastics, and the support can support the outer shell to avoid the outer shell from being stressed and deformed due to the fact that the bearing capacity of the plastics is higher than that of paper, the outer shell and the inner shell are made of paper, the weight of the paper is light, and the weight of the outer packing structure of the aerial robot can be reduced, through the support frame promotes the holistic bearing of aerial robot extranal packaging structure, through the telescopic link makes shock-absorbing support can follow the direction of telescopic link removes, through the spring weakens shock-absorbing support takes place moves, and then makes interior casing reduces vibrations to the realization is avoided aerial robot to take place vibrations, is caused the condition that aerial robot damaged.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic installation diagram of an aerial robot outer packaging structure provided by the utility model.

Fig. 2 is a schematic structural diagram of the outer casing provided by the utility model.

Fig. 3 is a schematic view of the supporting frame structure provided by the present invention.

Fig. 4 is a schematic structural view of a spring shock-absorbing bracket provided by the utility model.

Fig. 5 is an enlarged view of fig. 4 at a.

Fig. 6 is a schematic diagram of the spring structure provided by the present invention.

Fig. 7 is a schematic structural view of the connecting seat and the connecting rod provided by the utility model.

In the figure: 1-outer shell, 11-first observation window, 2-support frame, 3-damping component, 31-inner shell, 311-second observation window, 32-damping bracket, 33-spring, 34-telescopic rod, 341-connecting seat, 342-connecting rod, 35-second plastic film, 36-second sealing element, 4-first plastic film and 5-first sealing element.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Referring to fig. 1 to 6, the present invention provides an aerial robot outer packaging structure, which includes an outer housing 1, a supporting frame 2 and a damping assembly 3; the support frame 2 is fixedly connected with the outer shell 1 and is positioned inside the outer shell 1; damping component 3 includes interior casing 31, shock absorber support 32, spring 33 and telescopic link 34, telescopic link 34 with support frame 2 is connected, and sets up on the support frame 2, shock absorber support 32 with telescopic link 34 is connected, and is located telescopic link 34 keeps away from one side of support frame 2, the both ends of spring 33 respectively with support frame 2 with shock absorber support 32 butt, and the cover is established on telescopic link 34, and be located support frame 2 with between the shock absorber support 32, interior casing 31 with shock absorber support 32 fixed connection, and set up on the shock absorber support 32.

In this embodiment, the supporting frame 2 is bonded and fixed to the outer casing 1 and located inside the outer casing 1, the telescopic rod 34 is bonded and fixed to the supporting frame 2 and disposed on the supporting frame 2, the shock absorbing bracket 32 is bonded and fixed to the telescopic rod 34 and located on a side of the telescopic rod 34 away from the supporting frame 2, two ends of the spring 33 are respectively abutted to the supporting frame 2 and the shock absorbing bracket 32 and sleeved on the telescopic rod 34 and located between the supporting frame 2 and the shock absorbing bracket 32, the inner casing 31 is bonded and fixed to the shock absorbing bracket 32 and disposed on the shock absorbing bracket 32, the supporting frame 2 and the shock absorbing bracket 32 are both made of plastic, and since the bearing capacity of the plastic is higher than that of the paper, the supporting frame 2 can support the outer casing 1 to prevent the outer casing 1 from being deformed due to force, the shell body 1 with interior casing 31 is made by paper, and paper light in weight can reduce aerial robot outer packaging structure's weight, through support frame 2 promotes the holistic bearing of aerial robot outer packaging structure, through telescopic link 34 makes shock-absorbing support 32 can follow the direction of telescopic link 34 is removed, through spring 33 weakens the vibrations that shock-absorbing support 32 took place move, and then make interior casing 31 reduces vibrations to the realization is avoided aerial robot to take place vibrations, is caused the condition that aerial robot damaged.

Further, referring to fig. 7, the telescopic rod 34 includes a connecting seat 341 and a connecting rod 342, the connecting seat 341 is fixedly connected with the supporting frame 2 and is located at one side of the supporting frame 2 close to the shock absorbing bracket 32; the connecting rod 342 is slidably connected to the connecting seat 341, is fixedly connected to the shock absorbing bracket 32, and is located at one side of the connecting seat 341 close to the shock absorbing bracket 32.

In this embodiment, the connection seat 341 is fixedly bonded to the support frame 2 and located on one side of the support frame 2 close to the shock absorbing bracket 32, the connection rod 342 is slidably connected to the connection seat 341 and fixedly bonded to the shock absorbing bracket 32 and located on one side of the connection seat 341 close to the shock absorbing bracket 32, and the connection seat 341 and the connection rod 342 are slidably connected to each other, so that the telescopic rod 34 can be extended and retracted.

Further, referring to fig. 2, the outer casing 1 has a first observation window 11, the first observation window 11 penetrates through the outer casing 1, and the first observation window 11 is disposed on the outer casing 1.

In the present embodiment, the first observation window 11 allows a customer to see the inside of the outer case 1, thereby allowing the customer to see the robot in the air inside.

Further, please refer to fig. 1, the aerial robot outer packaging structure further includes a first plastic film 4, and the first plastic film 4 is fixedly connected to the outer housing 1 and is located on one side of the outer housing 1 close to the first observation window 11.

In this embodiment, the first plastic film 4 is made of plastic and has good light transmittance, the first plastic film 4 is fixedly bonded to the outer casing 1 and is located on the side of the outer casing 1 close to the first observation window 11, and a customer can see the inside of the outer casing 1 and can protect the inside of the outer casing 1 through the first plastic film 4.

Further, referring to fig. 3, the inner housing 31 has a second observation window 311, the second observation window 311 penetrates through the inner housing 31, and the second observation window 311 is disposed on the inner housing 31.

In the present embodiment, the second observation window 311 allows a customer to see the inside of the inner case 31, thereby allowing the customer to see the robot in the air inside.

Further, referring to fig. 2, the shock absorbing assembly 3 further includes a second plastic film 35, and the second plastic film 35 is fixedly connected to the inner housing 31 and is located on a side of the inner housing 31 close to the second viewing window 311.

In this embodiment, the second plastic film 35 is made of plastic and has good light transmittance, and the second plastic film 35 is bonded and fixed to the inner case 31 and is located on the side of the inner case 31 close to the second observation window 311, so that a customer can see the inside of the inner case 31 and protect the inside of the inner case 31 by the second plastic film 35.

Further, referring to fig. 1, the aerial robot outer packaging structure further includes a first sealing member 5, and the first sealing member 5 is rotatably connected to the outer housing 1 and disposed on the outer housing 1.

In the present embodiment, the first sealing member 5 is rotatably connected to the outer housing 1 and provided on the outer housing 1, and the opening of the outer housing 1 can be sealed by the first sealing member 5, thereby achieving the purpose of sealing the entire outer housing 1.

Further, referring to fig. 1, the shock absorbing assembly 3 further includes a second sealing member 36, wherein the second sealing member 36 is rotatably connected to the inner housing 31 and is disposed on the inner housing 31.

In the present embodiment, the second sealing member 36 is rotatably connected to the inner housing 31 and provided on the inner housing 31, and the opening of the inner housing 31 can be sealed by the second sealing member 36, thereby achieving the purpose of sealing the entire inner housing 31.

The utility model relates to an aerial robot outer packaging structure, which comprises an outer shell 1, a support frame 2 and a damping assembly 3; the support frame 2 is fixedly connected with the outer shell 1 and is positioned inside the outer shell 1; the damping component 3 comprises an inner shell 31, a damping support 32, a spring 33 and an expansion link 34, the expansion link 34 is connected with the support frame 2 and is arranged on the support frame 2, the damping support 32 is connected with the expansion link 34 and is located on one side of the expansion link 34 far away from the support frame 2, two ends of the spring 33 are respectively abutted against the support frame 2 and the damping support 32 and are sleeved on the expansion link 34 and are located between the support frame 2 and the damping support 32, the inner shell 31 is fixedly connected with the damping support 32 and is arranged on the damping support 32, the support frame 2 and the damping support 32 are both made of plastics, and since the bearing capacity of the plastics is higher than that of the paper, the support frame 2 can support the outer shell 1 to avoid the outer shell 1 from being deformed under stress, and the outer shell 1 and the inner shell 31 are made of paper, paper light in weight can reduce aerial robot outer packaging structure's weight, through support frame 2 promotes the holistic bearing of aerial robot outer packaging structure, through telescopic link 34 makes shock-absorbing support 32 can be followed the direction of telescopic link 34 removes, through spring 33 weakens the vibrations that shock-absorbing support 32 took place are moved, and then make interior casing 31 reduces vibrations to the realization avoids aerial robot to take place vibrations, causes the condition that aerial robot damaged.

While the utility model has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the utility model.

Claims (8)

1. An aerial robot outer packaging structure is characterized by comprising an outer shell, a supporting frame and a damping assembly;

the support frame is fixedly connected with the outer shell and is positioned inside the outer shell;

damping component includes interior casing, shock absorber support, spring and telescopic link, the telescopic link with the support frame is connected, and sets up on the support frame, shock absorber support with the telescopic link is connected, and is located the telescopic link is kept away from one side of support frame, the both ends of spring respectively with the support frame with the shock absorber support butt, and the cover is established on the telescopic link, and be located the support frame with between the shock absorber support, interior casing with shock absorber support fixed connection, and set up on the shock absorber support.

2. An aerial robot overpack structure of claim 1,

the telescopic rod comprises a connecting seat and a connecting rod, the connecting seat is fixedly connected with the supporting frame and is positioned on one side of the supporting frame close to the damping support; the connecting rod is connected with the connecting seat in a sliding mode, fixedly connected with the damping support and located on one side, close to the damping support, of the connecting seat.

3. An aerial robot overpack structure of claim 1,

the shell body has first observation window, first observation window runs through the shell body, first observation window sets up on the shell body.

4. An aerial robot overpack structure of claim 3,

the aerial robot outer packaging structure further comprises a first plastic film, wherein the first plastic film is fixedly connected with the outer shell and is positioned on one side, close to the first observation window, of the outer shell.

5. An aerial robot overpack structure of claim 1,

the inner shell is provided with a second observation window, the second observation window penetrates through the inner shell, and the second observation window is arranged on the inner shell.

6. An aerial robot overpack structure of claim 5,

the shock absorption assembly further comprises a second plastic film, the second plastic film is fixedly connected with the inner shell and is positioned on one side, close to the second observation window, of the inner shell.

7. An aerial robot overpack structure of claim 1,

the aerial robot outer packaging structure further comprises a first sealing element, wherein the first sealing element is connected with the outer shell in a rotating mode and is arranged on the outer shell.

8. An aerial robot overpack structure of claim 1,

the shock absorption assembly further comprises a second sealing member, wherein the second sealing member is rotatably connected with the inner shell and is arranged on the inner shell.

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