JP2009012487A - Aircraft - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an aircraft capable of easily changing a payload box according to purpose of use. <P>SOLUTION: In this aircraft, the payload box 400 mounted with various equipment including a camera, is installed in an aircraft body 100 on which a kite wing 300 and a propeller 500 are installed. The aircraft is characterized in that an installation hole section open toward an installation portion of the other is arranged in any one of the payload box 400 or the aircraft body 100, and the other is provided with a slide section 420 that can be slid and inserted into the installation hole section. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an aircraft, and more particularly, to a wireless aircraft capable of wireless control.

  As a wireless aircraft, for example, as disclosed in Japanese Patent Application Laid-Open No. 2003-228561, a aircraft body in which a propeller is rotatably mounted and a kite wing is attached is known.

  In the wireless aircraft described in Patent Document 1, a payload box containing a camera or the like is attached to the front part of the airframe body, and various images can be taken in a flight state by wireless operation with this camera. It was possible. In addition, by installing a collector for collecting dust or the like contained in the outside air during flight in this payload box, the situation of the outside air in the flight area can be determined.

However, in the wireless aircraft described in Patent Document 1, the fuselage body and the payload box are fixed by the connecting pins, and the payload box cannot be easily replaced. In particular, wireless aircraft such as those described above are used in disaster areas, and quick response is required for use in such disasters. In order to respond accurately on the spot, depending on the purpose of use. It was necessary to prepare multiple wireless aircraft.
Japanese Patent No. 2699263

  Accordingly, the present invention has been made in view of the above circumstances, and an object of the present invention is to provide an aircraft capable of easily changing the payload box according to the purpose of use.

  The present invention has been made to solve the above problems, and an aircraft according to the present invention has a payload box in which various equipment such as a camera is mounted on a main body in which a kite wing and a propeller are mounted. In one of the payload box and the fuselage main body, a mounting hole that opens toward the other mounting portion is provided, and the other slide is slidably inserted into the mounting hole. A portion is provided.

  In an aircraft having the above structure, the payload box can be detached from the fuselage body by detaching the slide part from the attachment hole part, while the slide body is inserted and attached to the attachment hole part. The payload box can be attached to the machine body. For this reason, the payload box on which the device according to the purpose is mounted can be easily attached to the main body. For this reason, it is possible to respond promptly according to the purpose of use in a disaster area with high urgency.

  In the aircraft having the above-described configuration, it is preferable to employ a configuration in which the slide portion is provided with a locking unit for preventing the payload box from being inadvertently detached from the main body. Thereby, for example, there is an advantage that the payload box can be prevented from being carelessly detached during the flight. The locking means can adopt various configurations. For example, a hole portion into which a pin can be inserted is formed in the slide portion, or a recess portion into which a retractable ball is fitted is slid. It can be formed by various means such as forming on the slide part, or forming a detachable locking part on the slide part.

  Further, in the aircraft according to the present invention, a pair of left and right mounting hole portions are provided on the front surface of the main body, and a pair of the slide portions project from the back side of the payload box. It is preferable to adopt. As described above, since the mounting hole portion and the slide portion are provided as a pair on the left and right sides, there is an advantage that attachment of the payload box and the main body is more reliable.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is a schematic side view of an aircraft according to an embodiment of the present invention. FIG. 2 is a schematic plan view of the embodiment, and illustration of the kite wing and the support is omitted. FIG. 3 is a schematic side view of the aircraft of the embodiment, showing a state in which the payload box is detached. FIG. 4 is a schematic enlarged cross-sectional side view of the main part of the slide part of the aircraft of the embodiment. FIG. 5 is an explanatory view seen from the front for explaining the propeller guard portion of the airframe body of the embodiment. FIG. 6 is an enlarged explanatory view of a main part viewed from the back for explaining the propeller guard part of the airframe body of the embodiment.

  The wireless aircraft of the present embodiment is detachably attached to the fuselage main body 100, a kite wing 300 fixed to the fuselage main body 100 via a plurality of support posts 210 and 220, and a front portion of the fuselage main body 100. A payload box 400.

  The fuselage main body 100 includes a pair of fuselage portions 110 provided in parallel with a certain gap in the lateral direction, and a pair of fuselage portions 110 provided to connect the pair of fuselage portions 110 at a position ahead of the center portion of the fuselage portion 110. A cylindrical propeller guard part 120 and a horizontal tail 130 provided to connect the rear end part of the fuselage part 110 are provided. The fuselage part 110 is a rear part to which the horizontal tail 130 is connected. The portion bent upward at the rear side functions as the vertical tail 111, and the horizontal tail 130 is located above the vertical tail 111. Is provided. The rear end portions of the vertical tail 111 and the horizontal tail 130 are provided as movable wings, and the movable wings are provided so as to be tiltable by a control means described later. The body body 100 is made of a synthetic resin such as FRP.

  The fuselage main body 100 has a frame connecting portion 111a to which a rear end portion of a frame 310 of a kite wing 300, which will be described later, is connected. A cylindrical portion 111a having a hole portion 310 into which 310 can be inserted and attached is formed as the frame connecting portion.

  The payload box 400 contains a variety of equipment. For example, a camera for capturing images during flight, and collection for collecting dust contained in the outside air at the flight destination. Built-in equipment.

  In addition, the payload box 400 includes a box main body 410 in which equipment such as the camera is incorporated, and a pair of left and right slide portions 420 protruding from the box main body 410 toward the body main body 100 side (rear side). Yes. The box body 410 is made of a synthetic resin such as FRP, and the slide part 420 is made of a metal member such as aluminum.

  The pair of body parts 110 of the body 100 are provided with mounting holes 101 that open toward the payload box 400 side (front side) and into which the slide part 420 can be inserted and attached (see FIG. 4). ). Further, the slide portion 420 and the mounting hole portion 101 are provided with locking means 102 and 420a for locking the both so that they are not carelessly detached. Specifically, for example, as shown in FIG. 4, a recessed portion 420 a is provided at a predetermined position of the slide portion 420 of the payload box 400, and the recessed portion 420 a is provided in the mounting hole portion 101 of the body body 100. The ball member 102 that fits into the recessed portion 420a is attached at a position corresponding to, and the ball member 102 is always elastically pressed toward the recessed portion 420a by the spring member 103 having a predetermined elastic force. Thus, the payload box 400 and the main body 100 are configured not to be inadvertently detached.

  Further, a propeller shaft 510 of a propeller 500 for obtaining a propulsive force is rotatably supported on the airframe main body 100. The propeller shaft 510 is rotatably supported inside the airframe main body 100. A rotation driving means 520 for rotating the shaft 510 is incorporated. In the present embodiment, the rotation driving means 520 includes an electric motor 520 that is driven by a battery (not shown) and applies a rotational force to the propeller shaft 510.

  The main body 100 includes control means (not shown) for controlling the rotation driving means 520, and is provided so that the rotation of the propeller 500 is controlled by the control of the control means. The control means is provided so as to control each movable wing of the vertical tail 111 and the horizontal tail 130. Aircraft body 100 is provided with receiving means (not shown) for receiving signals from operators on the ground, and the control means is provided to control each part by signals from the receiving means. It has been. Airframe body 100 includes devices such as a GPS circuit, a magnetic azimuth meter, an airspeed meter, and transmission means for transmitting information on these devices to the ground (all not shown).

  The propeller guard portion 120 of the fuselage main body 100 has a substantially cylindrical shape and a guard main body 121 provided on the outer periphery of the propeller 500 so that other members do not come into contact with the position propeller 500, and a cylindrical shape of the guard main body 121. The shaft support portion 123 is located substantially at the center and supports the propeller shaft 510, and the connecting portion 125 connects the guard body 121 and the shaft support portion 123 (see FIG. 5). The shaft support portion 123 and the connecting portion 125 are provided in front of the propeller guard portion 120, and the propeller 500 is disposed on the rear side of the shaft support portion 123 and the connecting portion 125. Further, the shaft support portion 123 incorporates an electric motor 520 for rotating the propeller shaft 510, and a cap 600 for fixing the electric motor 520 is detachably attached to the front surface of the shaft support portion 123. ing.

  In addition, between the cap 600 and the shaft support portion 123, the front column 210 located on the front side of the plurality of columns 210 and 220 is sandwiched. In the present embodiment, the front support column 210 is formed by bending one elongated metal member at the center portion and sandwiching the center portion between the cap 600 and the shaft support portion 123. Two are provided so as to protrude upward.

  As shown in FIG. 5, the shaft support 123 is provided with a groove 123 a into which the front column 210 is fitted in order to fix the front column 210 in a predetermined position. When the cap 600 is attached to the shaft support portion 123 in a state of being fitted in the groove portion 123a, the cap body 600 is fixed to the body body 100. In addition, a plurality of the groove portions 123 a are provided in the shaft support portion 123, and specifically, provided in two places above and below the shaft support portion 123. For this reason, it is provided so that the angle of attack of the kite wing 300 can be changed depending on which groove part 123a is fixed in a state where the front column 210 is fitted. The shaft support portion 123 is formed with a female screw portion 123b to which the male screw portion of the cap 600 is screwed.

  Further, the propeller guard portion 120 is provided so that a plurality of (four in this embodiment) rear-side struts 220 located on the rear side among the plurality of struts 210 and 220 can be fixed. Specifically, the lower end of the rear column 220 is bent forward, and the lower part of the rear end of the guard body 121 of the propeller guard 120 is arranged on the rear side as shown in FIG. Holes 121a into which the lower end portions of the support columns 220 are inserted and attached are formed, and caps are formed below the rear end portions of the guard body 121 with the lower end portions of the rear support columns 220 inserted and attached to the hole portions 121a. By attaching 610, the rear column 220 is fixed to the propeller guard 120. The guard body 121 is formed with a female screw part 121b to which the male screw part of the cap 610 is screwed.

  In addition, a pair of wheels are rotatably supported at the lower part of the main body 100, and in this embodiment, the wheels 140 are attached to the body 110 of the main body 100, respectively. Here, the wheel 140 is attached slightly forward of the propeller guard 120.

  The kite wing 300 is composed of a frame made up of a plurality of frames 310 and a flexible sheet 320 stretched around the frame, and the frame 310 is made of a hard synthetic resin material or the like. In addition, the equality sheet 320 can be made of a synthetic resin sheet such as nylon.

  The plurality of (six in this embodiment) frames 310 are connected to each other at the tip, and are arranged in a fan-like shape centered on the tip (see FIG. 2). (See dashed line). Each frame 310 is connected to the columns 210 and 220 at a substantially central portion in the front-rear direction. In this embodiment, among the six frames 310, two frames 310 from the center and two outermost ones are connected to the rear column 220, and the other two frames are connected. The front column 210 is connected. Of the six frames 310, the rear column 220 connected to the two outermost frames 310 is provided such that the upper end, which is the connection portion with the frame 310, is located on the rear side. And is connected to the frame 310 on the rear side of the other columns 210 and 220. Of the plurality of frames 310, the rear end portions of the two frames 310 from the center are inserted and attached to the cylindrical portion 111 a of the vertical tail 111.

  The columns 210 and 220 and the frame 310 are connected to each other so as to be rotatable. Specifically, the front column 210 and the frame 310 are separated from the body body 100. The rear column 220 and the frame 310 are coupled so that the rear column 220 detached from the main body 100 can be rotated forward.

  Since the wireless aircraft of the present embodiment is configured as described above, it has the following advantages.

  That is, since the propeller guard portion 120 that guards the outer periphery of the propeller 500 is provided, the safety is high, and the propeller guards 120 and 220 for attaching the kite blades 300 can be fixed to the propeller guard portion 120. Therefore, the entire body 100 can be miniaturized and can be transported in a small space. In particular, the pillars 210 and 220 can be detached from the airframe body 100, and the kite wing 300 can be transported in a folded state. Further, after the conveyance, the kite wing 300 can be widened and the columns 210 and 220 can be fixed to the main body 100, so that the vehicle can be started easily and quickly. In addition, by selecting the mounting position of the front column 210 from the plurality of grooves 123a, the angle of attack of the kite wing 300 can be changed, and accurate flight according to the weather condition can be performed.

  In addition, the fuselage main body 100 includes a pair of fuselage portions 110 positioned on the left and right sides of the propeller 500, and the pair of fuselage portions 110 are connected to each other by a horizontal tail 130 on the rear side. It is possible to realize stable flight as compared with the case where the horizontal tail 130 is provided.

  Since the payload box 400 is detachably provided, the payload box 400 on which necessary equipment is mounted can be attached. Further, since the payload box 400 can be attached by inserting and attaching the slide portion 420 of the payload box 400 to the mounting hole 101 of the aircraft body 100, the payload box 400 can be easily and reliably attached to the aircraft body 100. . In addition, since the slide unit 420 is provided with locking means 102 and 420a for preventing the payload box 400 from being inadvertently detached from the body 100, the payload box 400 is careless during flight. Can be prevented from leaving.

  In addition, although the said Example has the said structure, it can change a design suitably within the range which this invention intends. That is, in the above-described embodiment, the case where the main body 100 is integrally formed has been described. However, the present invention is not limited to this, and for example, the body portion, the propeller guard portion, and the vertical portion of the main body. It is also within the intended scope of the present invention that the tail is composed of a separate body, and the fuselage, propeller guard, and vertical tail are integrally connected to form a body. Further, when connecting the propeller guard part and the body part, a pair of left and right legs are provided protruding from the lower part of the guard body of the propeller guard part, and the pair of body parts are connected to the pair of leg parts. It is also possible to provide it. In addition, a pair of left and right leg portions projecting from the lower portion of the box body of the payload box and a pair of slide portions are attached to the pair of leg portions can be appropriately changed in design.

1 is a schematic side view of an aircraft according to an embodiment of the present invention. It is a schematic plan view of the embodiment. It is a schematic side view of the aircraft of the embodiment. It is a rough principal part expanded sectional side view in the slide part of the aircraft of the Example. It is explanatory drawing seen from the front for demonstrating the propeller guard part of the airframe main body of the Example. It is the principal part expansion explanatory drawing seen from the back surface for demonstrating the propeller guard part of the body main body of the Example.

Explanation of symbols

100 Airframe body 101 Mounting hole 102 Locking means (ball member)
103 Spring 110 Body portion 111 Vertical tail 111a Tube portion (frame connecting portion)
120 Propeller guard part 121 Guard body 121a Hole part 121b Female thread part 123 Shaft support part 123a Groove part 123b Female thread part 125 Connecting part 130 Horizontal tail 140 Wheel 210 Front side post 220 Rear side post 300 Kite blade 310 Frame 320 Sheet 400 Payload box 410 Box body 420 Slide portion 420a Locking means (recessed portion)
500 Propeller 510 Propeller shaft 520 Rotation drive means (electric motor)
600 Cap 610 Cap

Claims (3)

An aircraft in which a payload box on which various equipment such as a camera is mounted is mounted on a fuselage body to which a kite wing and a propeller are attached,
Either one of the payload box or the main body is provided with a mounting hole that opens toward the other mounting part, and the other is provided with a slide part that can be slid into the mounting hole. A radio-controlled aircraft characterized by that. The aircraft of claim 1,
The aircraft, wherein the slide portion is provided with a locking means for preventing the payload box from being inadvertently detached from the main body. The aircraft according to claim 1 or 2,
The aircraft is characterized in that a pair of left and right mounting holes are provided on the front surface of the main body, and a pair of the sliding portions protrude from the back side of the payload box.