WO2019080170A1 - Unmanned aerial vehicle having multi-buffering landing gear - Google Patents

Abstract

An unmanned aerial vehicle having a multi-buffering landing gear, comprising a vehicle body (1), a propeller (3), and a landing gear (2). The landing gear (2) comprises at least three supporting rods (21) hingedly connected to the side surfaces of the vehicle body (1). The horizontal height of the ends of the supporting rods (21) against the vehicle body (1) is higher than that of the other ends of the supporting rods (21). Supporting feet (22) are provided at the ends of the supporting rods (21) against the vehicle body (1). The supporting feet (22) are vertically arranged. First elastic mechanisms (11) are provided between the supporting rods (21) and the side surfaces of the vehicle body (1). One end of each first elastic mechanism (11) is fixedly connected to the vehicle body (1), and the other end thereof is fixedly connected to the lower surface of each supporting rod (21).

Description

Multi-stage buffer landing gear drone Technical field

The invention relates to the field of drones, in particular to a multi-stage buffer landing gear drone.

Background technique

UAVs are unmanned aircraft operated by radio remote control equipment and self-provided program control devices. Civil drones have important applications in aerial photography, agriculture, plant protection, disaster relief, etc.; drones need to take off and land. The shock absorber is used to protect the fuselage. The current landing gear is mostly a fixed landing gear. When the drone is landing, the landing gear transmits the vibration generated when the landing gear is in contact with the ground, causing shock and damage to the fuselage. .

Summary of the invention

Based on this, it is necessary to provide a multi-stage cushioning landing gear drone comprising a fuselage, a propeller and a landing gear, the landing gear comprising at least three support bars hinged to the side of the fuselage, a horizontal height of one end of the support rod away from the fuselage is higher than a horizontal height of the other end thereof, and an end of the support rod away from the fuselage is provided with a leg, the leg is vertically disposed, and the support rod is A first elastic mechanism is disposed between the sides of the fuselage, and one end of the first elastic mechanism is fixedly connected to the body, and the other end thereof is fixedly connected to the lower surface of the support rod.

When the drone landed, the foot first touched the ground, and then the foot will drive the support rod hinged to the fuselage to swing. Because of the limitation of the first elastic mechanism, the support rod can only swing within a certain range, so the body does not touch. The ground, while the hinge structure and the vibration damping of the spring can reduce the vibration of the fuselage. Because the level of the support rod away from the end of the fuselage is higher than the level of the other end, the level of the support rod away from the end of the fuselage is lower than the level of the other end, when landing, support The force of the rod on the fuselage of the drone is a pulling force away from the fuselage, which is generated when the landing of the support rod away from the end of the fuselage is lower than the level of the other end. The squeezing force can prevent the support rod from being pressed inward and causing damage to the internal structure of the drone.

Preferably, the legs are spring pieces.

As a component that is in direct contact with the opposite side, the foot directly reduces the impact of the ground on the fuselage by bending.

Preferably, a side of the leg away from the support rod is provided with a sharp portion.

The sharp legs can be inserted into the ground when landing, and the legs of the present invention are directly inserted into the ground compared to the legs that are not inserted into the ground, and the reaction force of the ground in the vertical upward direction of the legs is reduced, correspondingly It can reduce the vibration of the foot; at the same time, the diameter of the sharp part is smaller, and the sharp part is softer than other parts of the foot, which makes the cushioning effect better.

Further, a second elastic mechanism is further included, and one end of the elastic mechanism is fixedly disposed on a lower surface of the support rod, and the other end thereof is disposed on a lower surface of the leg.

The second elastic mechanism connected between the support rod and the leg can strengthen the leg to avoid deformation of the leg due to excessive impact force when the drone is dropped, so that the foot loses the buffering effect; meanwhile, the second elastic mechanism is As a strengthening mechanism, it can also undergo elastic deformation and play a buffering role.

Further, the second elastic mechanism is a spring piece.

The spring piece can provide good support while being elastic.

Preferably, the first elastic mechanism is a spring.

The spring has good compression and tensile properties, which can reduce the pulling and squeezing of the support rod to the drone when the drone is landing.

Preferably, the number of the support bars is at least four.

Three support rods ensure the balance of the drone behind the fuselage. Four support rods can be installed to prevent one of the support rods from being damaged, and the drone can still maintain balance when it is landed.

The principle and effect of the present invention will be further described below in conjunction with the above technical solutions:

The invention adopts a multi-stage buffer structure from the support leg to the support rod and from the support rod to the fuselage, and when the drone is landed, the vibration generated by the contact between the landing gear and the ground can be reduced and transmitted to the fuselage to protect the fuselage; When the foot is lowered, it can be inserted into the ground. Compared with the leg that is not inserted into the ground, the foot of the invention is directly inserted into the ground, and the force of the ground in the vertical upward direction of the leg is reduced, and the corresponding force can be reduced. Reduce the vibration of the feet.

DRAWINGS

1 is a schematic structural view 1 of a multi-stage buffer landing gear drone according to an embodiment of the present invention;

Description of the reference signs:

The body 1, the first elastic mechanism 11, the landing gear 2, the support rod 21, the legs 22, the second elastic mechanism 23, and the propeller 3.

Detailed ways

In order to facilitate the understanding of those skilled in the art, the present invention will be further described in detail below with reference to the accompanying drawings and embodiments.

1, a multi-stage cushioning landing gear drone including a fuselage 1, a propeller 3 and a landing gear 2, the landing gear 2 Including at least three support rods 21 hinged to the side of the fuselage 1, the level of the support rod 21 away from the end of the fuselage 1 is higher than the level of the other end thereof, a support leg 22 is disposed at an end of the support body 21 away from the body 1 , and the leg 22 is vertically disposed. A first elastic mechanism 11 is disposed between the support bar 21 and a side surface of the body 1 . One end of an elastic mechanism 11 is fixedly coupled to the body 1, and the other end thereof is fixedly coupled to the lower surface of the support rod 21.

When the drone is landing, the leg 22 first comes into contact with the ground, and then the leg 22 drives the support rod 21 hinged to the fuselage 1 to swing. Because of the limitation of the first elastic mechanism 11, the support rod 21 can only swing within a certain range, so The fuselage 1 does not touch the ground, and the vibration of the fuselage 1 can be alleviated by the hinge structure and the vibration damping effect of the spring.

In one embodiment, the legs 22 are spring tabs.

As a member that is in direct contact with the opposite side, the leg 22 directly reduces the impact of the ground on the body 1 by bending.

In one embodiment, the side of the leg 22 away from the support rod 21 is provided with a sharp portion.

The sharp legs 22 can be inserted into the ground when landing, and the legs 22 of the present invention are directly inserted into the ground compared to the legs 22 that are not inserted into the ground, and the reaction of the ground to the vertical upward direction of the legs 22 Reducing, correspondingly, can reduce the vibration of the leg 22; at the same time, the diameter of the sharp portion is smaller, and the sharp portion is softer than other portions of the leg 22, so that the cushioning effect is better.

One of the embodiments further includes a second elastic mechanism 23, one end of the elastic mechanism is fixedly disposed on the lower surface of the support rod 21, and the other end is disposed on the lower surface of the leg 22.

The second elastic mechanism 23 connected between the support rod 21 and the leg 22 can strengthen the leg 22 to avoid deformation of the leg 22 due to excessive impact force when the drone is dropped, so that the leg 22 loses the cushioning effect; The second elastic mechanism 23 can also elastically deform itself as a reinforcing mechanism, and functions as a buffer.

In one embodiment, the second elastic mechanism 23 is a spring piece.

The spring piece can provide good support while being elastic.

In one embodiment, the first elastic mechanism 11 is a spring.

The spring has good compression and tensile properties, which can reduce the pulling and squeezing of the support rod 21 to the drone when the drone is landing.

In one embodiment, the number of the support bars 21 is at least four.

The three support rods 21 can ensure the balance of the drone behind the fuselage 1. The four support rods 21 can prevent one of the support rods 21 from being damaged, and the drone can still maintain balance when it is landed.

The above-described embodiments are merely illustrative of several embodiments of the present invention, and the description thereof is more specific and detailed, but is not to be construed as limiting the scope of the invention. It should be noted that a number of variations and modifications may be made by those skilled in the art without departing from the spirit and scope of the invention. Therefore, the scope of the invention should be determined by the appended claims.

Claims (7)

1. A multi-stage cushioning landing gear drone comprising a fuselage, a propeller and a landing gear, characterized in that the landing gear comprises at least three support bars, the support bars being hinged to a side of the fuselage, a horizontal height of one end of the support rod away from the fuselage is higher than a horizontal height of the other end thereof, and an end of the support rod away from the fuselage is provided with a leg, the leg is vertically disposed, and the support rod is A first elastic mechanism is disposed between the sides of the fuselage, and one end of the first elastic mechanism is fixedly connected to the body, and the other end thereof is fixedly connected to the lower surface of the support rod.
2. The multi-stage cushioning landing gear drone according to claim 1, wherein said legs are spring pieces.
3. The multi-stage cushioning landing gear drone according to claim 1, wherein a side of the leg away from the support rod is provided with a sharp portion.
4. The multi-stage cushioning landing gear drone according to any one of claims 1 to 3, further comprising a second elastic mechanism, one end of the elastic mechanism being fixedly disposed on a lower surface of the support rod, The other end is disposed on a lower surface of the leg.
5. The multi-stage cushioning landing gear drone according to claim 4, wherein the second elastic mechanism is a spring piece.
6. A multi-stage cushioning landing gear drone according to claim 1 wherein said first resilient means is a spring.
7. The multi-stage cushioning landing gear drone according to claim 1, wherein the number of said support bars is at least four.

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