KR20210016768A - Agricultural drone - Google Patents

Abstract

The present invention relates to a pest control drone and, more specifically, to a drone, which can easily replace a propeller, receive a fluid including chemicals in a body of the drone without a separate tank, spray the chemicals in multiple directions, and be easily moved on the ground. The drone includes: a body in which the fluid is stored; a propeller unit installed on the body to take off the body; a spray unit installed on the body to spray the fluid to the outside; and a control unit installed on the body to selectively control the driving of the propeller unit or the spray unit.

Description

Control drone {AGRICULTURAL DRONE}

The present invention relates to a control drone, specifically, it is easy to replace the propeller, can accommodate fluids including drugs inside the body of the drone without a separate tank, can be sprayed in multiple directions, and move on the ground. This is about an easy drone.

In general, drones are called in various terms for each situation, purpose, and country, and generally refers to an unmanned aerial vehicle (UAV) that can be controlled by radio waves. It is a generic term for an unmanned aerial vehicle in the shape of an airplane or helicopter that can be controlled.

Among these types of drones, control drones have the advantage of maintaining an appropriate altitude over a wide farmland and spraying an appropriate amount of drugs evenly.

Control drones take a method of combining medicine barrels in a separate type, and take a structure to spray the drug in the downward direction, in the lower part the leg structure corresponding to the foot, and the upper part in the complicated propeller structure for flight. It is a combined structure.

However, such a structure has a problem that effective flight is difficult due to the fact that the structure of the drone is caught in the branches of the fruit tree or the floor of the orchard in the forest ranch where fruit trees such as orchards are opened, and the drone has a more concise and mobile structure. I need this.

In the case of fruit trees, in most cases, the fruit is opened inside the tree, and the downward spray structure makes it difficult to directly spray the drug onto the fruit, and thus a drone to implement the upward spray function is required.

In addition, there is a need to improve the moving structure to prevent drones from getting caught on the orchard floor.

KR 10-2019-0076227

It is an object of the present invention to facilitate the replacement of propellers, to accommodate fluids including drugs inside the body of a drone without a separate tank, to be able to spray in multiple directions, and to be installed in a drone that is easy to move on the ground. It is to provide a propeller unit and an injection unit.

In order to achieve the above object, the present invention is a body in which the fluid is stored; A propeller unit installed on the body to take off the body; A spray unit installed on the body to spray fluid to the outside; And a control unit installed on the body and selectively controlling the driving of the propeller unit or the injection unit.

In the present invention, the body includes a fluid housing in which a fluid is injected and accommodated; And a pillar portion formed inside the fluid housing so that both sides of the fluid housing communicate with each other and to which the propeller unit is mounted or separated.

In the present invention, it further includes a protective member that is coupled or separated from the pillar portion.

In the present invention, the propeller unit includes a cylindrical portion that is open on both sides and coupled to or separated from the body; A support whose end is installed on the inner peripheral surface of the cylindrical portion; And a propeller installed on the support and disposed inside the cylindrical portion.

The present invention is installed on the body, the support is coupled or separated, and further includes a support rotating part for inclining the propeller by a predetermined angle by rotating the support.

In the present invention, a fastening protrusion is formed in a body or a propeller unit, and a slide groove is formed in which the fastening protrusion is inserted and fixed to the rest.

In the present invention, the spraying unit includes a nozzle part which is installed on the side of the body by being inclined by a predetermined angle with respect to the width direction of the body and exposed to the outside of the body; An air pump installed on the body to inject external air into the nozzle; And a fluid inlet pipe having one end disposed inside the body and the other end disposed in the nozzle part.

In the present invention, the injection unit further includes a nozzle rotating unit installed in the nozzle unit to rotate the nozzle unit.

The present invention further includes a moving member installed in the lower portion of the body.

In order to achieve another object, the present invention is a cylindrical portion that is open on both sides, coupled to or separated from the body; Supports having both ends installed on the inner peripheral surface of the cylindrical portion; It is installed on the support and includes a propeller disposed inside the cylindrical portion.

In order to achieve another object, the present invention is inclined by a predetermined angle with respect to the width direction of the body in which the fluid is stored therein and installed on the side of the body to be exposed to the outside of the body; An air pump installed on the body to inject external air into the nozzle; And a fluid inlet pipe having one end disposed inside the body and the other end disposed in the nozzle part.

In the control drone according to the present invention, a separate tank and a structure for mounting the tank to the control drone may be excluded because fluid including drugs is stored therein.

In addition, it is easy to replace and maintain the propeller through the propeller unit that is coupled to or separated from the body.

In addition, the injection nozzle may be rotated upward or downward through the injection unit, so that the injection range of the fluid may be expanded.

In addition, the control drone can be easily moved on the ground through the moving member.

1 is a plan view of a control drone according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of a control drone based on the propeller unit shown in FIG. 1.
3 is a perspective view of the propeller unit shown in FIG. 1.
4 and 5 are perspective and cross-sectional views sequentially illustrating the mounting portion shown in FIG. 2.
6A and 6B are diagrams illustrating a state in which the propeller units shown in FIG. 2 are sequentially coupled to the mounting unit.
7 is a diagram showing an operating state of the propeller unit shown in FIG. 1.
8 is a cross-sectional view of a control drone based on the injection unit shown in FIG. 1.
9 and 10 are cross-sectional views of the nozzle portion shown in FIG. 8, showing a rotational state of the spray nozzle.
11 is an AA section diagram shown in FIG. 9.
12 is a bottom view of the control drone shown in FIG. 1.
13 is a perspective view of a protective member coupled to the pillar portion shown in FIG. 1.
14A and 14B are a front view and a bottom view of the protection member shown in FIG. 13 sequentially.
15A and 15B are diagrams illustrating a state in which the protective members shown in FIG. 13 are sequentially coupled to the pillars.

In order to describe in detail enough to enable a person of ordinary skill in the art to easily implement the technical idea of the present invention, a most preferred embodiment of the present invention will be described with reference to the accompanying drawings.

First of all, in adding reference numerals to elements of each drawing, it should be noted that the same elements have the same numerals as possible even if they are indicated on different drawings.

In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

Hereinafter, a control drone according to an embodiment of the present invention will be described with reference to FIGS. 1 to 13.

1 is a plan view of a control drone according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of a control drone based on the propeller unit shown in FIG. 1, and FIG. 3 is a perspective view of the propeller unit shown in FIG.

1 to 3, the control drone 100 includes a body 110 in which fluid is stored, a propeller unit 120 installed in the body 110 to take off the body 110, and the body A spray unit 130 installed at 110 to spray fluid to the outside, and a control unit 140 installed at the body 110 to selectively control the driving of the propeller unit 120 or the spray unit 130 Includes.

Here, the fluid may be defined as a liquid containing drugs such as pesticides including water.

The body 110 has a hollow shape to accommodate fluid, has an almond-shaped streamlined structure to reduce air resistance during flight, and uses a known lightweight material having a certain rigidity such as plastic resin and aluminum material. Can be produced by

More specifically, the body 110 is formed in the fluid housing 111 so that both sides of the fluid housing 111 and the fluid housing 111 are in communication with each other and the propeller unit ( 120) includes a column part 112 to be mounted or separated.

The upper part of the fluid housing 111 has a control room 113 recessed, and the control room 113 supplies power to the electronic equipment of the control drone 100, including the propeller unit 120 and the spray unit 130. A battery 10 for supplying and the control unit 140 are mounted.

The battery 10 may be a known battery such as a disposable battery or a rechargeable lithium battery, and when rechargeable, it is separated from the control room 113 and separately charged, or installed in the control room 113. Charging can be done through the USB terminal or the power connector.

The control room 113 may be opened and closed through the cover 113a to prevent foreign substances from flowing into the control room 113 during normal operation or when the control drone 100 is operated.

The cover 113a may be hinged to the control room 113 or installed in the control room 113 through a known fixing member such as a bolt.

The fluid housing 111 is provided with an antenna 114 for receiving a driving signal of the control drone 100 through a remote controller or a user's terminal.

An injection hole 115 for introducing a fluid into the fluid housing 111 is formed in the upper portion of the fluid housing 111, and the injection hole 115 is opened and closed through a lid 115a.

The lid 115a may be hinged to the fluid housing 111 or installed on the fluid housing 111 through screw coupling.

The pillar part 112 is integrally formed with the fluid housing 111 through an injection method, and a passage is formed so that an electric wire through which power is transmitted from the battery 10 can be buried.

The pillar unit 112 includes a mounting unit 150 to which the propeller unit 120 is coupled or separated, and the propeller unit 120 is coupled to the mounting unit 150 to change the direction of the control drone 100 For this purpose, the propeller 123 installed on the propeller unit 120 may be selectively inclined by a predetermined angle.

The control drone 100 flies by thrust generated by the rotation of the propeller 123, where the pillar part 112 is formed in a cylindrical shape along the width direction of the fluid housing 111. In this case, since the flow of air due to the rotation of the propeller 123 is limited in the vertical direction, the control drone 100 can take off and land, but it may be difficult to change the direction.

In order to solve this problem, the column part 112 includes an inclined part 160 extending from both sides of the mounting part 150 to the upper and lower surfaces of the fluid housing 111.

The diameter (d1) of the mounting portion 150 corresponds to the diameter (d3) of the propeller unit 120 so that the propeller unit 120 is disposed, and the upper surface of the fluid housing 111 in the mounting portion 150 The diameter d2 of the inclined portion 160 increases and expands toward the bottom.

That is, the inclined portion 160 is formed in the shape of a truncated cone, and the inclined portion 160 is formed at a certain angle from the mounting portion 150 so that the flow of air by the rotation of the propeller 123 is vertically It is prevented from being restricted, and according to the inclination of the propeller 123, it is possible to change the direction of the control drone 100 forward or backward or left and right.

4 and 5 are perspective and cross-sectional views of the mounting unit shown in Fig. 2 in sequence, and Figs. 6a and 6 are views illustrating a state in which the propeller units shown in Fig. 2 are sequentially coupled to the mounting unit.

1 to 6B, the propeller unit 120 has both sides open and the body 110, more specifically, a cylindrical portion 121 coupled or separated from the mounting portion 150, both ends of the cylinder It includes a support 122 installed on the inner circumferential surface of the portion 121, and the propeller 123 installed on the support 122 and disposed inside the cylindrical portion 121.

The propeller 123 is installed on the propeller rotation shaft 124a of the propeller motor 124, and the propeller motor 124 is fixed to the support member 122.

As described above, in order to tilt the propeller 123 when the direction of the control drone 100 is changed, the control drone 100 is installed on the body 110, more specifically, the mounting part 150 The support 122 is coupled or separated, and further includes a support rotating part 170 for inclining the propeller 123 by a predetermined angle by rotating the support 122.

Insertion grooves (122a) are formed in the support (122) along the longitudinal direction of the support (122) at both ends of the support (122), a fixing bar (125) through the cylindrical portion (121) It is installed in the insertion groove (122a) in a state disposed outside the cylindrical portion (121).

In addition, the fixing bar 125 is coupled to the support rotating part 170 and rotated so that the support 122 rotates so that the propeller 123 is inclined by a certain angle.

In order to separate the fixing bar 125 from the support rotating part 170, an elastic member 122c is inserted into the insertion groove 122a, and an end of the fixing bar 125 is inserted into the elastic member 122c. It is fixed, wherein the elastic member 122c may be a known spring including a compression spring.

A guide hole (122b) communicating with the insertion groove (122a) is formed on the side of the support (122) along the length direction of the support (122), and a rod (125a) formed on one side of the fixing bar (125) ) Is disposed in the guide hole 122b.

That is, when an external force is applied to the rod 125a so that the fixing bar 125 moves to the inside of the insertion groove 122a along the guide hole 122b, the elastic member 122c is compressed and deformed to cause the fixing bar. (125) is separated by being withdrawn from the support rotating part (170).

In addition, when the external force applied to the rod 125a is released, the elastic member 122c is restored to its original state by the elastic force of the elastic member 122c, so that the fixing bar 125 is moved to its original position.

The support rotating part 170 includes a support rotating shaft 171 to which the fixing bar 125 is coupled or separated, and a support motor 172 installed on the support rotating shaft 171.

The support motor 172 is disposed inside the motor housing 151 formed in the mounting part 150 to maintain airtightness.

In the motor housing 151, the cover 113a may be hinged or bolted to the mounting part 150 to be opened and closed at the mounting part 150, thereby securing airtightness and maintaining the support motor 172.

In order for the fixing bar 125 to be coupled to the support rotation shaft 171, a coupling groove 171a is formed at an end of the support rotation shaft 171 along the longitudinal direction of the support rotation shaft 171, and the coupling groove The fixing bar 125 is inserted into (171a).

Here, the end of the fixing bar 125 is formed in a hemispherical shape so that the fixing bar 125 can be easily inserted into the coupling groove 171a.

In order to transmit the rotational force of the support motor 172 to the support 122, cross-sections of the coupling groove 171a, the fixing bar 125, and the insertion groove 122a are formed in a polygonal shape including a square.

That is, the coupling groove (171a), the fixing bar (125), the insertion groove (122a) is coupled to each other, so that the rotational force of the support motor 172 is transmitted to the support (122).

In order to be fixed by coupling and fixing the propeller unit 120 to the mounting part 150, a fastening protrusion is formed on the body 110, more specifically the mounting part or the propeller unit, and the fastening protrusion is inserted and fixed to the rest. A slide groove is formed.

Hereinafter, for ease of description, the fastening protrusion 127 is formed in the propeller unit 120, and the slide groove 152 is formed in the mounting portion 150 as a reference.

The fastening protrusion 127 is formed on the outer circumferential surface of the cylindrical part 121, and the slide groove 152 is formed on the inner circumferential surface of the mounting part 150 along the circumferential direction of the mounting part 150, and the fastening protrusion The 127 is moved in close contact with the inner circumferential surface of the mounting part 150 and is inserted into the slide groove 152.

Here, since the diameters d1 and 3 of the cylindrical portion 121 and the mounting portion 150 correspond to each other, the cylindrical portion 121 may be difficult to be inserted into the mounting portion 150 by the fastening protrusion 127 It is preferable that the cylindrical portion 121 is made of a plastic resin material having elasticity.

That is, when the cylindrical part 121 is inserted into the mounting part 150 by an external force and the fastening protrusion 127 is pressed while moving in close contact with the inner circumferential surface of the mounting part 150, the elastic force of the cylindrical part 121 Accordingly, the shape of the cylindrical portion 121 is deformed.

In addition, when the fastening protrusion 127 reaches and is inserted into the slide groove 152, it is restored to its original state by the elastic force of the cylindrical part 121, so that the cylindrical part 121 is fixed to the mounting part 150. Is maintained.

Here, when the fastening protrusion 127 is in close contact with the inner circumferential surface of the mounting part 150, the fixing bar 125 is also moved to the inner circumferential surface of the insertion groove 122a and is in close contact with the inner circumferential surface of the mounting part 150. .

When the cylindrical portion 121 is rotated by an external force while the fastening protrusion 127 is inserted into the slide groove 152 so that the fixing bar 125 can be inserted into the coupling groove 171a, the The fastening protrusion 127 is moved along the slide groove 152 so that the fixing bar 125 may be inserted into the coupling groove 171a.

In the upper and lower portions of the mounting part 150, a locking protrusion 153 is formed on an inner circumferential surface of the mounting part 150 along the circumferential direction of the mounting part 150, and the cylindrical part 121 is the locking protrusion 153 By being disposed therebetween, the propeller unit 120 may be more stably connected to the mounting part 150 to be maintained.

In order to separate the propeller unit 120 from the mounting portion 150, a handle portion 128 is formed on the cylindrical portion 121, and the handle portion 128 is formed in a pair so that the cylinders face each other. It may be formed by bending from the inner peripheral surface of the portion 121.

That is, while the user pulls the rod 125a to separate the fixing bar 125 from the coupling groove 171a, the support 122 is rotated so that the fastening protrusion 127 becomes the slide groove 152 ) And the fixing bar 125 is in close contact with the inner circumferential surface of the mounting part 150.

And, when the user presses the handle portion 128 into the inside of the cylindrical portion 121, the cylindrical portion 121 is deformed and the fastening protrusion 127 is withdrawn from the slide groove 152, and the propeller unit 120 may be separated from the mounting portion 150.

Terminals 129 and 154 are installed in the cylindrical part 121 and the mounting part 150 so that the power of the battery 10 can be transmitted to the propeller motor 124, and the propeller unit 120 is attached to the mounting part 150 When coupled to ), the terminals 129 and 154 may contact each other.

Here, the positions of the terminals 129 and 154 are installed in the cylindrical portion 121 and the mounting portion 150 based on the position where the fixing bar 125 is inserted into the coupling groove 171a.

The propeller unit 120 may have a grid-shaped net installed on one side of the cylindrical part 121, may be made of iron or plastic resin material, and the net may be disposed above the propeller 123. By being installed on the cylindrical part 121, it is possible to prevent the propeller 123 from being damaged by an unspecified obstacle such as a tree branch when the control drone 100 is in flight.

7 is a diagram showing an operating state of the propeller unit shown in FIG. 1.

Referring to FIGS. 1 to 7, the pillar part 112 may be formed in a plurality of columns and formed in the fluid housing 111 along the longitudinal direction of the fluid housing 111, and a plurality of the propeller units 120 It may be installed on the pillar portion 112 according to the number of the pillar portion 112.

As shown in FIG. 8, a part of the propeller unit 120 moves the control drone 100 forward and backward, and the rest switches the direction of movement of the control drone 100 left and right.

For example, if the propeller units 1 and 4 are forward and backward propeller units, the support 122 is disposed on the mounting unit 150 along a direction perpendicular to the longitudinal direction of the fluid housing 111. Is installed on the mounting part 150 to manufacture the control drone 100.

In addition, if No. 2 and No. 3 are left and right switching propeller units, the support 122 is installed in the mounting unit 150 along the longitudinal direction of the fluid housing 111 so that the control drone ( 100) can be produced.

8 is a cross-sectional view of a control drone based on the spray unit shown in FIG. 1, FIGS. 9 and 10 are cross-sectional views of the nozzle part shown in FIG. 8, showing the rotational state of the spray nozzle, and FIG. 11 is shown in FIG. AA section diagram.

The injection unit 130 is injected in an air static pressure injection method in which a fluid is sucked and injected by a suction pressure implemented according to a moving speed of the external air injected from the air pump 132.

1 to 11, the injection unit 130 is inclined by a certain angle with respect to the width direction of the body 110 and is installed on the side of the body 110 to the outside of the body 110. The exposed nozzle part 131, the air pump 132 installed on the body 110 to inject external air into the nozzle part 131, one end is disposed inside the body 110, and the other end And a fluid inlet pipe 133 installed in the nozzle part 131.

The nozzle part 131 may be formed of a plurality of nozzles and may be installed to be spaced apart from each other at a predetermined interval on the side surface of the fluid housing 111 along the longitudinal direction of the fluid housing 111.

The air pump 132 is installed inside the control room 113, and the air pump 132 sucks external air through an air intake pipe 132a installed in the air pump 132 and exposed to the outside. .

The nozzle part 131 is connected to the air pump 132 and communicates with a venturi pipe 134 through which external air is introduced, and a flow path 135 formed in the venturi pipe 134, and the width of the body 110 It includes a spray nozzle 136 inclined by a predetermined angle with respect to the direction.

The fluid inlet pipe 133 is branched into first and second fluid inlet pipes 133a and b and installed in the venturi pipe 134, and the first fluid inlet pipe 133a is the diameter of the flow path 135 It is installed so as to communicate with the center of this decreasing shaft diameter part (135a).

In addition, the second fluid inlet pipe (133b) is from the shaft diameter portion (135a) along the flow direction of the fluid passing through the venturi pipe (134) to an enlarged portion (135b) in which the diameter of the flow path (135) is enlarged. It is installed to communicate.

That is, external air flows to the venturi pipe 134 through the air discharge pipe 132b connected between the air pump 132 and the venturi pipe 134, and the flow rate of the external air passing through the venturi pipe 134 Accordingly, a fluid flows along the fluid inlet pipe 133 due to a pressure difference generated in the flow path 135 and flows into the flow path 135, and the fluid flowing into the flow path 135 is mixed with external air. It is sprayed to the outside through the spray nozzle 136.

In addition, the fluid inlet pipe 133 is branched into the first fluid inlet pipe 133a and the second fluid inlet pipe 133b so that more fluid may flow into the venturi pipe 134, The flow velocity is faster in the shaft diameter portion 135a communicating with the first fluid inlet pipe 133a than in the diameter diameter portion 135b communicating with the second fluid inlet pipe 133b, so that the fluctuation of external air is generated. Mixing can be made more smoothly.

The spray unit 130 further includes a nozzle rotating part 137 installed on the nozzle part 131 to rotate the nozzle part 131.

The nozzle rotating part 137 is installed in the rotary part 137a through which the injection nozzle 136 is installed to communicate the injection nozzle 136 and the flow path 135, and the venturi tube 134 is installed in the rotary part 137a. ) And a nozzle motor (137b) to rotate.

A nozzle rotation shaft (137c) of the nozzle motor (137b) is installed at the center of the rotary part (137a), and the injection nozzle (136) is composed of a plurality of the rotary part along the circumferential direction of the nozzle rotation shaft (137c). It is installed in (137a), the rotary part (137a) is formed with a through hole (137d) communicating with the injection nozzle (136).

That is, as the rotary part 137a is rotated by the rotation of the nozzle motor 137b, the injection nozzle 136 is turned upward or downward, so that the injection range of the fluid may be expanded.

As the through hole 137d is also rotated by the rotation of the rotary part 137a, the venturi tube 134 is a conical expansion channel connected to the channel 135 so that it communicates with the through hole 137d. 138) is formed.

That is, as shown in FIG. 12, the expansion passage 138 is formed in the venturi pipe 134 in a ring shape based on the cross section of the venturi pipe 134, and the through hole 137d is the expansion passage 138 ), the expansion passage 138 and the through hole 137d are in communication with each other as they are rotated.

The injection nozzle 136 may be formed in a plurality and be installed on the rotary part 137a so as to be disposed on the expansion passage 138.

12 is a bottom view of the control drone shown in FIG. 1.

Referring to FIG. 12, the control drone 100 further includes a moving member 180 installed under the body 110.

The moving member 180 is a configuration for easily moving the body 110 on the ground, and a known moving member such as a wheel or a caterpillar may be used.

The movable member 180 is axially coupled to the lower portion of the fluid housing 111, and consists of a plurality of movable members 180 and is spaced apart at a predetermined interval along the longitudinal direction of the fluid housing 111 to be installed in the fluid housing 111 to prevent the control. The drone 100 can stably move the ground.

Here, although not shown in the drawings, the moving member 180 may be rotated by a motor installed under the fluid housing 111 to be implemented in an electric manner.

The control unit 140 includes a communication unit and an operation unit, and the communication unit may receive driving signals of the propeller unit 120 and the injection unit 130 through a remote controller via the antenna 114, Known wireless methods including Wi-Fi and Bluetooth can be applied.

The operation unit drives the configuration based on the driving signal received through the communication unit.

That is, this can be performed according to a forward or reverse driving signal of the propeller motor 124 and the nozzle motor 137b, and the fluid can be sprayed through the injection nozzle 136 by driving the air pump 132. have.

13 is a perspective view of a protection member coupled to the pillar portion shown in FIG. 1, 14a and b are a front view and a bottom view of the protection member shown in FIG. 13 sequentially, and 15a and b are sequentially shown in FIG. 13 It is a diagram showing a state in which the protected member is coupled to the pillar.

The control drone 100 further includes a protection member 190 coupled to or separated from the pillar part 112, and the protection member 190 is attached to the propeller unit 120 from an unspecified obstacle such as a tree branch. This is a configuration for protecting the propeller unit 120.

More specifically, the protective member 190 is a protective cover 191 that is coupled to or separated from the upper or lower end of the column part 112, the protective cover 191 along the radial direction of the protective cover 191 It includes a partition wall 192 which is spaced apart from each other at regular intervals to be installed.

The partition wall 192 may be disposed inside the pillar part 112 and may be inclined by an angle corresponding to the inclined part 160 so as to be in close contact with the inclined part 160.

The protective cover 191 has a plate shape, and may be formed to correspond to the upper or lower diameter of the pillar part 112.

A fluid hole (191a) is formed in the protective cover 191 so that air flowing along the column part 112 by the propeller 123 can pass through the protective cover 191, and the protective cover ( It is formed between the partition walls 192 along the radial direction of 191.

That is, when a tree branch enters through the fluid hole 191a, the tree branch is caught in the partition wall 192, and the tree branch comes out of the fluid hole 191a again as the control drone 100 moves. The propeller 123 may be protected.

A seating portion 112a is recessed along the circumferential direction of the pillar portion 112 at the upper or lower end of the pillar portion 112, and the protective cover 191 is in close contact with the seating portion 112a to protect the A member 190 is coupled to the pillar part 112.

In addition, when the protective cover 191 is pulled through the fluid hole 191a, the protective cover 191 is detached from the seating portion 112a, thereby separating the protective member 190 from the column part 112 do.

As described above, in the control drone according to the present invention, a separate tank and a structure for mounting the tank to the control drone may be excluded since fluid including drugs is stored in the body.

In addition, it is easy to replace and maintain the propeller through the propeller unit that is coupled to or separated from the body.

In addition, the injection nozzle may be rotated upward or downward through the injection unit, so that the injection range of the fluid may be expanded.

In addition, the control drone can be easily moved on the ground through the moving member.

As described above, an optimal embodiment has been disclosed in the drawings and specifications. Although specific terms have been used herein, these are only used for the purpose of describing the present invention and are not used to limit the meaning or the scope of the present invention described in the claims. Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical scope of the present invention should be determined by the technical spirit of the appended claims.

100: control drone 110: body
120: propeller unit 130: spray unit
140: control unit

Claims (11)

A body in which fluid is stored;
A propeller unit installed on the body to take off the body;
A spray unit installed on the body to spray the fluid to the outside; And
A control unit installed on the body to selectively control driving of the propeller unit or the spray unit;
Control drone comprising a.
The method of claim 1,
The body
A fluid housing in which the fluid is injected and received; And
A pillar portion formed inside the fluid housing along the width direction of the fluid housing so that both sides of the fluid housing communicate with each other to connect or separate the propeller unit;
Control drone comprising a.
The method of claim 2,
A control drone further comprising a protective member coupled or separated from the pillar part.
The method of claim 1,
The propeller unit
Both sides are open, the cylindrical portion coupled to or separated from the body;
A support having both end portions installed on the inner peripheral surface of the cylindrical portion; And
A propeller installed on the support and disposed inside the cylindrical portion;
Control drone comprising a.
The method of claim 4,
A control drone that is installed on the body, the support is coupled or separated, and further comprises a support rotating part for inclining the propeller by a predetermined angle by rotating the support.
The method of claim 1,
A fastening protrusion is formed on the body or propeller unit,
A control drone in which a slide groove to which the fastening protrusion is inserted and fixed to the rest is formed.
The method of claim 1,
The injection unit
A nozzle unit that is inclined by a predetermined angle with respect to the width direction of the body and is installed on the side of the body to be exposed to the outside of the body;
An air pump installed on the body to inject external air into the nozzle; And
A fluid inlet pipe having one end disposed inside the body and the other end disposed in the nozzle unit;
Control drone comprising a.
The method of claim 7,
The injection unit
A control drone further comprising a nozzle rotation unit installed on the nozzle unit to rotate the nozzle unit.
The method of claim 1,
A control drone further comprising a moving member installed under the body.
Both sides are open, the cylindrical portion coupled to or separated from the body;
A support having both end portions installed on the inner peripheral surface of the cylindrical portion; And
A propeller installed on the support and disposed inside the cylindrical portion;
Propeller unit comprising a.
A nozzle part which is installed on the side of the body and exposed to the outside of the body by being inclined by a predetermined angle based on the width direction of the body in which the fluid is stored therein;
An air pump installed on the body to inject external air into the nozzle; And
A fluid inlet pipe having one end disposed inside the body and the other end disposed in the nozzle unit;
Injection unit comprising a.

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