EP3311898A1 - Hélicoptère jouet et son dispositif d'équilibrage - Google Patents

Hélicoptère jouet et son dispositif d'équilibrage Download PDF

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Publication number
EP3311898A1
EP3311898A1 EP17157098.9A EP17157098A EP3311898A1 EP 3311898 A1 EP3311898 A1 EP 3311898A1 EP 17157098 A EP17157098 A EP 17157098A EP 3311898 A1 EP3311898 A1 EP 3311898A1
Authority
EP
European Patent Office
Prior art keywords
rotor
fuselage
main body
rod
toy helicopter
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP17157098.9A
Other languages
German (de)
English (en)
Inventor
Shinji Todokoro
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Agatsuma Co Ltd
Original Assignee
Agatsuma Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Agatsuma Co Ltd filed Critical Agatsuma Co Ltd
Publication of EP3311898A1 publication Critical patent/EP3311898A1/fr
Withdrawn legal-status Critical Current

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Classifications

    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63HTOYS, e.g. TOPS, DOLLS, HOOPS OR BUILDING BLOCKS
    • A63H27/00Toy aircraft; Other flying toys
    • A63H27/12Helicopters ; Flying tops
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63HTOYS, e.g. TOPS, DOLLS, HOOPS OR BUILDING BLOCKS
    • A63H27/00Toy aircraft; Other flying toys
    • A63H27/02Model aircraft
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63HTOYS, e.g. TOPS, DOLLS, HOOPS OR BUILDING BLOCKS
    • A63H29/00Drive mechanisms for toys in general
    • A63H29/22Electric drives
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63HTOYS, e.g. TOPS, DOLLS, HOOPS OR BUILDING BLOCKS
    • A63H30/00Remote-control arrangements specially adapted for toys, e.g. for toy vehicles
    • A63H30/02Electrical arrangements
    • A63H30/04Electrical arrangements using wireless transmission

Definitions

  • these toy helicopters are radio controlled using infrared radiation or the like to operate in several ways or to rise, descend, hover, travel forwards and turn (for example, refer to Japanese Unexamined Patent Application No. 2010-075568 or JP-A-2010-075568 , Japanese Unexamined Patent Application No. 2007-191144 or JP-A-2007-191144 , and Japanese Unexamined Patent Application No. 2007-130200 or JP-A-2007-130200 ).
  • a toy helicopter described in JP-A-2010-075568 has main rotors provided left and right above a fuselage of the toy helicopter.
  • Rotor masts or shafts of the right rotor and the left rotor are provided right and left of the fuselage while being inclined in such a way that the rotor shafts open laterally greater at tops than at bottoms so that the rotor shafts are formed into a V-like shape. Consequently, the toy helicopter can rise, descend, hover, travel forwards and turn in the air stably with the simple construction.
  • a toy helicopter described in JP-A-2007-191144 has an auxiliary rotor above a main rotor which is provided on an upper portion of a fuselage of the toy helicopter in place of a stabilizer. Then, the auxiliary rotor is attached to a rotating shaft of the main rotor at such an angle that center axes of the auxiliary rotor and the main rotor intersect each other. Additionally, the auxiliary rotor is attached to the rotating shaft of the main rotor so that the center axis thereof can oscillate in an up-down direction. Further, the main rotor is attached to the rotating shaft thereof so that a pitch angle is variable which enables a horizontal height of the main rotor to differ between a front end and a rear blade end of the main rotor.
  • the main rotor and the auxiliary rotor are connected together by a linking device, whereby the pitch angle of the main rotor is changed based on the rotating position of the main rotor when the center axis of the auxiliary rotor oscillates relative to the rotating shaft of the main rotor.
  • the pitch angle is changed based on the rotating position of the main rotor by the auxiliary rotor which always rotates in a horizontal plane so that the inclined rotating shaft of the main rotor, that is, the inclined fuselage of the toy helicopter is corrected, thereby making it possible for the toy helicopter to rise, descend, hover, travel forwards and turn in a stable fashion.
  • the toy helicopters can easily be controlled to fly indoors in a stable fashion.
  • a balancing device for a toy helicopter having a support main body portion having a flat fixing plate and an oscillating support portion which is configured to oscillate relative to the support main body portion, wherein a long balance rod having a protuberant portion at each end thereof is supported at a central portion thereof by the oscillating support portion to thereby allow the balance rod to be attached to the support main body portion so as to oscillate.
  • the toy helicopter according to the invention has the long balance rod extending in the left-right direction of the fuselage and having the protuberant portion as each end thereof which is provided thereon so as to oscillate, the inclination of the fuselage to the left or right can be stabilized by the balance rod which maintains the horizontality.
  • the toy helicopter balancing device in which the long balance rod having the protuberant portion at each end thereof is supported in an oscillating fashion by the support main body portion having the fixing plate can easily be attached to an upper portion of the fuselage of the toy helicopter by the fixing plate to thereby enhance the stability in flight of the toy helicopter.
  • a toy helicopter is a toy helicopter 100 which has a twin-rotor, oppositely rotating main rotor 150 provided at an upper central portion of a fuselage 110 of the toy helicopter 100.
  • the toy helicopter 100 also includes a rear rotor 116 at a rear end portion of a tail boom 115, and this rear rotor 116 rotates on a horizontal plane.
  • the toy helicopter 100 further includes a balancing device 180 provided at an upper portion of a main body portion 111 which simulates a cabin, and in this balancing device 180, a balance rod 197, which extends from the main body portion 111 laterally to the left and right, is supported so as to oscillate by a support portion 181.
  • a front-rear or up-down direction is referred to in the description of the embodiment, these directions are determined based on an understanding that a nose side of the toy helicopter 100 is referred to as a front and a side of the toy helicopter 100 where the main rotor 150 is provided is referred to as an upper side.
  • the left or right is referred to in relation to the toy helicopter 100 in the description, although the toy helicopter 100 has a laterally symmetrical external appearance, the left and right are referred to based on a state in which the fuselage 110 is seen from a front thereof.
  • the toy helicopter 100 has a landing member 113 which takes the form of a skid below the main body portion 111 which simulates a cabin and includes the fuselage 110 having the main body portion 111 and the pipe-shaped tail boom 115 provided at the rear of the main body portion 111.
  • the toy helicopter 100 has a rear rotor motor 117 at a rear end of the tail boom 115 and the rear rotor 116 which is fixed to a motor shaft of the rear rotor motor 117.
  • the main rotor 150 above the fuselage 110 is made up of an upper rotor 151 and a lower rotor 161 which is disposed below the upper rotor 151, and the upper rotor 151 and the lower rotor 161 rotate in opposite directions.
  • the lower rotor 116 has a lower rotor shaft 163 which projects upwards from the main body portion 111 in a position which lies slightly rearwards of a center of the main body portion 111, and two lower rotor blades 167 are attached to the lower rotor shaft 163 by a lower rotor head 165 which is provided at an upper end of the lower rotor shaft 163.
  • the upper rotor 151 has an upper rotor shaft 153 which is concentric with the lower rotor shaft 163 and which penetrates the lower rotor shaft 163, and two upper rotor blades 157 are attached to the upper rotor shaft 153 by an upper rotor head 155 which is provided near an upper end of the upper rotor shaft 153.
  • the lower rotor head 165 In attaching the two lower rotor blades 167 to the lower rotor shaft 163 by the lower rotor head 165, the lower rotor head 165 is used in which short side portions which constitute longitudinal end portions of a rectangular shape are formed into semi-circular arc-like shapes, and the lower rotor blades 167 are attached rotatably to the lower rotor head 165 in positions lying near longitudinal end portions thereof by blade pins 169. Namely, respective distal end portions of the lower rotor blades 167 are allowed to rotate back and forth relative to the lower rotor head 165 in a horizontal plane about the corresponding blade pins 169.
  • the upper rotor blade 157 or the lower rotor blades 167 which hits the obstacle rotates about the blade pin 169 in such a way that a rotating speed at the distal end of the rotor blade in question becomes slower due to an external force exerted thereon by the obstacle. Because of this, an impact generated by the external force can be prevented from being exerted on the upper rotor head 155 or the lower rotor head 165 and hence to the upper rotor shaft 153 or the lower rotor shaft 163.
  • the rectangular upper rotor head 155 whose longitudinal ends are formed semi-circular is attached to the upper rotor shaft 153 so as to rotate about a longitudinal axis (a major axis) which passes a center of the upper rotor head 155 as a rotating axis. Consequently, a pitch angle or an angle of elevation of the upper rotor blades 157 can be varied by the oscillation of the upper rotor head 155 about the rotating shaft.
  • the two upper rotor blades 157 which are attached to the upper rotor head 155 by the blade pins 169 are given the same pitch angle, so that a front end edge of each rotor blade is positioned higher than a rear end edge thereof.
  • one upper rotor blade 157 rotates so to raise its front end edge to thereby increase the pitch angle.
  • the other upper rotor blade 157 rotates so as to lower its front end edge to thereby decrease the pitch angle.
  • a stabilizer 170 is provided at the upper end of the upper rotor shaft 153.
  • the stabilizer 170 is such that a stabilizer rod 173 which is shorter in length than overall lengths of the upper rotor 151 and the lower rotor 161 is attached to the upper end of the upper rotor shaft 153 by a stabilizer head 171.
  • counterweights 177 are provided individually at ends of the stabilizer rod 173, and additionally, rod-like link shafts 179 are provided so as to connect sides of the stabilizer head 171 and sides of the upper rotor head 155 together.
  • the stabilizer head 171 is attached to a boss 176 which is provided at the upper end of the upper rotor shaft 153 by using a stabilizer pin 175, so that an axial direction of the stabilizer rod 173 intersects an axial direction of the stabilizer pin 175 at right angles, whereby the ends of the stabilizer rod 173 can oscillate up and down about the stabilizer pin 175 as an oscillation center.
  • the pitch angle is decreased as a result of a front end edge of the right upper rotor blade 157 shown in Figs. 3A and 3B being pushed downwards, while the pitch angle is increased as a result of a rear end edge of the left upper rotor blade 157 being pushed downwards.
  • the balancing device 180 is attached to an upper portion of the main body portion 111 of the fuselage 110 in a position lying extremely near and ahead of the lower rotor shaft 163.
  • the long rod-like balance rod 197 including a protuberant portion 199 at each end thereof is fixed to the upper portion of the fuselage 110 so as to oscillate by the support portion 180.
  • the balance rod 197 is disposed so as to extend by the same distance to the right and left so as to intersect a longitudinal center axis of the fuselage 110 at right angles and is able to oscillate in such a way that the left and right ends of the balance rod 197 move in the up-down direction, whereby the balance rod 197 can hold a horizontally balanced state in which both the ends of the balance rod 197 are situated in the same horizontal plane by means of the weight balance of the balance rod 197.
  • This balancing device 180 will be described in detail later.
  • a power supply switch 133 is provided on a lower surface of the main body portion 111, and by operating this power supply switch 133, a control signal can be received to thereby activate the constituent components of the toy helicopter 100 based on the control signal so received.
  • a power supply jack socket 131 is provided on the lower surface of the main body portion 111, so that the battery 123 which is incorporated in the main body portion 111 can be charged by inserting a power supply jack plug is inserted into the power supply jack socket 131 for connection.
  • the battery 123 is disposed near a nose of the main body portion so as to hold a weight balance of the toy helicopter 100.
  • An infrared radiation receiving unit as a receiver unit 135 which receives control signals is provided on the lower surface of the main body portion 111 so as to receive control signals sent from a transmitter unit.
  • the first main motor 141, the second main motor 142 and further a control circuit board 121 are accommodated in the interior of the main body portion 111, and this control circuit board 121 includes a control circuit which controls the rotation of the first main motor 141, the second main motor 142 and the rear rotor motor 117 by control signals received by the receiver unit 135.
  • the toy helicopter 100 includes the main rotor 150 having the upper rotor 151 and the lower rotor 161 above the main body portion 111, and the upper rotor 151 and the lower rotor 116 are caused to rotate in the opposite directions, whereby the orientation of the fuselage 110 can be fixed in one direction in the air by matching the rotating speed of the upper rotor 151 with the rotating speed of the lower rotor 161.
  • the fuselage 110 is caused to ascend, whereas when the rotating speeds of the upper rotor 151 and the lower rotor 161 are both made slower, the fuselage 110 is caused to descent.
  • the rotating speed of the upper rotor 151 and the rotating speed of the lower rotor 161 are controlled in association with each other, whereby the ascending speed and the descending speed of the fuselage 110 can be controlled without changing the direction of the fuselage 110, and the fuselage 110 can be caused to hover in the air.
  • the fuselage 110 can be turned so as to direct the nose thereof to the left, for example, while maintaining the height of the fuselage 110 or holding the ascent or descent of the fuselage 110.
  • the fuselage 110 can be turned so as to direct the nose thereof to the right, for example, while maintaining the height of the fuselage 110 or holding the ascent or descent of the fuselage 110.
  • the fuselage 110 Since the rear rotor 116 is mounted horizontally, when the rear rotor 116 is caused to rotate forwards, for example, the fuselage 110 is allowed to travel forwards while the fuselage 110 is being tilted slightly forwards so as to lift up the tail boom 115. On the other hand, when the rear rotor 116 is caused to rotate backwards, the fuselage 110 can travel backwards while the fuselage 110 is being tilted slightly backwards so as to push down the tail boom 115.
  • the toy helicopter 100 can be controlled freely by control signals so as to ascend, descend, hover at a predetermined height, travel forwards, travel backwards and turn, whereby the toy helicopter 100 is allowed to fly in a stable fashion in a space free from wind or a flow of air as inside a building, and the controlling operation can be performed relatively easily.
  • the balance rod 197 has a rod main body 198 which is made of a thin and long pipe or solid rod-like body of aluminum and is curved into an arc-like shape as a whole in such a way that both ends are situated lower than a central portion.
  • the resin pipes constituting the protuberant portions 199 intersect axial directions of end portions of the rod main body 198 of the balance rod 197 at right angles with center axes thereof directed horizontal in a front-rear direction.
  • the shape of the protuberant portion 199 is not limited to the pipe shape. There may be a situation where the protuberant portion 199 is formed into a spindle shape or a teardrop shape, whose center axis is caused to intersect the axis of the end portion of the curved, thin rod-shaped rod main body 198.
  • the protuberant portion 199 may be formed into a conical shape which can be formed by extending the end portion of the rod main body 198 of the balance rod 197 along the axis thereof into such a shape. Further, although not shown, the protuberant portion 199 can take various forms including a flat triangular or circular plate body which extends in the front-rear direction of the fuselage 110.
  • the support portion 181 by which the balance rod 197 is fixed to the upper portion of the main body portion 111 so as to oscillate has, as shown in Fig. 6 , a support main body portion 183 which is formed into an upwardly open U-like shape by a front support plate 185 and a rear support plate 187 which are provided parallel on a flat fixing plate 189 so as to rise vertically therefrom.
  • the support portion 181 has an oscillating support portion 191 between the front support plate 185 and the rear support plate 187, and the oscillating support portion 191 is made up of a rod support plate 195 and a support pin 193 which penetrates a portion of the rod support plate 195 which lies near an upper end of the rod support plate 195.
  • the oscillating support portion 191 front and rear ends of the support pin 193 are attached rotatably to a portion of the front support plate 185 which lies near an upper end thereof and a portion of the rear support plate 187 which lies near an upper end thereof, so that a lower end of the rod support plate 195 can rotate or oscillate to the left and right about the support pin 193 as an oscillating center.
  • the support pin 193 is fixed to the portion of the front support plate 185 which lies near the upper end thereof and the portion of the rear support plate 187 which lies near the upper end thereof, and the rod support plate 195 is allowed to rotate or oscillate relative to or on the support pin 193, whereby the portion of the rod support plate 195 which lies near the upper end thereof is supported by the support pin 193.
  • the fixing plate 189 of the support main body portion 183 is fixed to an upper surface of a chassis of the main body portion 111 of the fuselage 110 where the first main motor 141, the second main motor 142, the battery 123, the control circuit board 121 and the like which are accommodated in the main body portion 111 are fixed or an upper surface of an external cover of the main body portion 111 of the fuselage 110, whereby the balancing device 180 is attached to the fuselage 110.
  • the balance rod 197 which is fixed to the lower end of the rod support plate 195 of the oscillating support portion 191 can be held horizontal.
  • a groove portion 119 is formed on the external cover at an upper end thereof so as to ensure a vertical oscillating width for the balance rod 197 which projects from the external cover.
  • the balancing device 180 In the event that the balancing device 180 is attached to the upper surface of the chassis or the upper surface of the external cover of the main body portion 111, the balancing device 180 can be fixed to an upper portion of the fuselage 110 extremely simply by applying an adhesive to a lower surface of the fixing plate 189.
  • the toy helicopter 100 includes the balancing device 180 on the fuselage 110 and can freely be controlled to rise, descend, hover at a predetermined height, travel forwards, travel backwards, turn and the like by control signals, whereby the toy helicopter 100 can fly stably in a space free from a flow of air or wind as inside a building, and the controlling operation can be performed relatively easily.
  • this toy helicopter 100 is normally fabricated small in size and light in weight and therefore, there is a risk of the fuselage 110 being caused to vibrate back and force or from side to side by such a slight disturbance as a flow of air generated by convection.
  • the vibration of the fuselage 110 occurring back and forth can be eliminated so that the toy helicopter 100 can restore its proper flight by controlling the toy helicopter 100 to travel forwards or backwards.
  • the vibration of the fuselage 110 occurring from side to side cannot be eliminated, and hence, it is difficult to control the toy helicopter 100 so as to prevent a fall or a crash thereof.
  • the toy helicopter 100 includes the stabilizer 170 and the balancing device 180.
  • the support point of the balance rod 197 which is situated in a position lying above on a vertical line of a center of gravity of the fuselage 110 deviates from the vertical line. Consequently, for the fuselage 110 to tilt, a force is necessary which moves laterally the balance rod 197 having the protuberant portion 199 at each end from the position lying above the position of the center of gravity of the fuselage 110.
  • the weight of the balance rod 197 constitutes resistance to an external force which attempts to tilt the fuselage 110, whereby the tilt of the fuselage 110 can be reduced.
  • the fuselage 110 can be returned to the normal state shown in Fig. 8A quickly by the balancing device 180.
  • the upper rotor 155 which is connected to the stabilizer head 171 with the link shafts 179 tilts, and the upper rotor head 155 tilts alternately in opposite directions every time the upper rotor shaft 153 rotates 180 degrees.
  • the pitch angle of the upper rotor blade 157 which is the angle of elevation thereof, becomes great on a tilting side (a right side in Fig. 8B ), whereas the pitch angle becomes small on an opposite side (a left side in Fig. 8B ), whereby a lift F1 by the upper rotor 151 is generated much on the tilting side, and as shown in Fig. 8B , an obliquely upward lift F1' is generated so as to restore the normal state from the tilting state.
  • the lift F1 by the upper rotor 151, a lift F2 by the lower rotor 161 and the gravity G of the whole of the fuselage 110 including the balancing device 180 are aligned with one another on the vertical line, whereby the fuselage 110 can be returned quickly to the stable state where an isosceles triangle is formed by the ends of the balance rod 197 and the center of the upper rotor head 155.
  • the balance rod 197 of the balancing device 180 is allowed to oscillate so that the balance rod 197 is held horizontal.
  • the material of the protuberant portions 199 which are formed at both the ends of the balance rod 197 is not limited to resin, and there may be a case where the protuberant portions 199 are formed of a light metal such as aluminum so as to reduce the weight of the balancing device 180, whereby the increase in weight of the toy helicopter 100 is suppressed.
  • the balance rod 197 is curved so that the central portion is situated higher than the ends thereof, in the case of the balance rod 197 being suspended from the support pin 193 which constitutes the oscillation center as shown in Fig. 6 or the like, there may also be a case where the balance rod 197 is formed into a straight-line shape.
  • the balance rod 197 is fixed to the main body portion 111 in such a way that the balance rod 197 is suspended by the support main body portion 183 such as the fixing plate 189 and the oscillating support portion 191 such as the rod support plate 195.
  • the balance shaft 197 may be attached to the upper portion of the main body portion 111 so as to oscillate in such a way that the balance rod 197 is suspended from the chassis incorporated in the main body portion 111 of the fuselage 110.
  • the balance rod 197 having the protuberant portion 199 at each end thereof is curved, so that the center of gravity of the balance rod 197 is situated below the central portion of the balance rod 197
  • the support point of the balance rod 197 which acts as the oscillating center is situated below the balance rod 197 so as to lift up the balance rod 197 from therebelow.
  • the balance rod 197 of the balancing device 180 should at least be held horizontal with the center of gravity of the balance rod 197 lying below the support point which acts as the oscillating center while the central position of the balance rod 197 is raised higher and both the ends of the balance rod 197 kept at the same height.
  • the long balance shaft 197 which is provided so as to extend laterally to the left and right across the fuselage 110 is provided on the fuselage 110 so as to oscillate, even when the fuselage 110 is caused to oscillate sideways, the balance rod 197 having the protuberant portion 199 at each end thereof is held horizontal, so that the tilt of the fuselage 110 is suppressed to a small level by this balance rod 197 and the tilt of the fuselage 110 is corrected quickly to restore the stable state, thereby enabling the toy helicopter 100 to fly in a stable fashion.
  • the balance rod 197 which can oscillate up and down at the left and right ends thereof on the upper portion of the main body portion 111, even though the fuselage 110 is caused to tilt, the balance rod 197 which is held horizontal is kept at the height of the fuselage 110. Thus, even when the toy helicopter flies low near the ground or a floor, the balance rod 197 is prevented from hitting an obstacle. In addition, even though the balance rod 197 is curved in such a way that the ends are situated lower than the center thereof, the balance rod 197 can be attached to the fuselage 110 in a stable fashion.
  • the fuselage 110 can be caused to tilt forwards or backwards by rotating the rear rotor 116 forwards or backwards, whereby the fuselage 110 can easily be controlled to travel forwards and rearwards by the simple mechanism with the nose directed in a desired direction in a stable fashion by the main rotor 150.
  • the balancing device 180 such as the balance rod 197 is light in weight
  • the length L2 of the balance rod 197 which is held horizontal is made equal to or longer than the overall length L1 of the fuselage 110, whereby it is possible to restrict effectively the occurrence of lateral vibration of the fuselage 110 which is attributed to the narrow transverse width thereof.
  • the balancing device 180 supports the balance rod 197 by using the support main body portion 183 having the flat fixing plate 189 so as to oscillate, the balancing device 180 can easily be attached and fixed to the upper portion or the like of the fuselage 110 of the toy helicopter 100 by the fixing plate 189.
  • the support portion 181 of the balancing device 180 is made up of the support main body 183 and the oscillating support portion 191, and the balance rod 197 is supported at the central portion thereof by the oscillating support portion 191, whereby the balance rod 197 can be laterally symmetrical with respect to the support point and hence can be supported horizontally while being allowed to oscillate easily.
  • the balance rod 197 having the protuberant portion 199 at each end of the rod main body 198 is curved so that both the ends are situated lower than the central portion thereof.
  • the position of the center of gravity of the balance rod 197 can be caused to lie lower than the central portion of the balance rod 197 which constitutes the support portion, whereby the balance rod 197 which can oscillate can be held horizontal in a more ensured fashion.
  • the toy helicopter 100 has the upper rotor 151 and the lower rotor 161 which make up the twin-rotor, oppositely rotating main rotor to thereby be allowed to rise, descend, hover and the like.
  • the toy helicopter 100 also has the stabilizer 170 which controls the pitch angle of the upper rotor blades 175 to thereby be allowed to fly in a stable fashion.
  • the toy helicopter 100 has further the balancing device 180 so as to enhance further the lateral stability, whereby the toy helicopter 100 is allowed to fly in a stable fashion more easily.
EP17157098.9A 2016-10-19 2017-02-21 Hélicoptère jouet et son dispositif d'équilibrage Withdrawn EP3311898A1 (fr)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP2016205065A JP2018064749A (ja) 2016-10-19 2016-10-19 ヘリコプタ玩具及びヘリコプタ玩具用平衡装置

Publications (1)

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EP3311898A1 true EP3311898A1 (fr) 2018-04-25

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EP17157098.9A Withdrawn EP3311898A1 (fr) 2016-10-19 2017-02-21 Hélicoptère jouet et son dispositif d'équilibrage

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US (1) US20180104610A1 (fr)
EP (1) EP3311898A1 (fr)
JP (1) JP2018064749A (fr)
CN (1) CN107961551A (fr)
CA (1) CA2958632A1 (fr)

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JP6542421B1 (ja) 2018-03-29 2019-07-10 住友化学株式会社 リチウム金属複合酸化物粉末、リチウム二次電池用正極活物質、リチウム二次電池用正極、及びリチウム二次電池
CN109455295B (zh) * 2018-11-07 2023-09-12 杭州翼能科技有限公司 旋翼控制装置及旋翼飞行器
CN111976989B (zh) * 2020-08-31 2022-05-24 中国农业大学 一种植保无人机药箱自平衡装置及方法

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JP2007191144A (ja) 2006-01-19 2007-08-02 Ccp:Kk ヘリコプタ
US20090215355A1 (en) * 2008-02-25 2009-08-27 Spin Master Ltd. Acrobatic rotary-wing toy helicopter
JP2010075568A (ja) 2008-09-26 2010-04-08 Nikko:Kk ヘリコプタ玩具
CN203916080U (zh) * 2014-06-27 2014-11-05 吉林工程技术师范学院 三栖直升机模型
US20160023759A1 (en) * 2014-07-25 2016-01-28 Ronald M. Barrett Movable member bearing aerial vehicles and methods of use

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JP2018064749A (ja) 2018-04-26
US20180104610A1 (en) 2018-04-19
CA2958632A1 (fr) 2018-04-19

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