KR101877800B1 - A Balancing Device for Powered Paragliders - Google Patents

Abstract

The present invention relates to a balancing device for a powered paraglider that is capable of adjusting air resistances generated in left and right half planes of a canopy, respectively. According to the present invention, the balancing device for a powered paraglider includes: a pair of vertical members extended along chord directions of a canopy in such a manner as to be spaced apart from each other along the span direction of the canopy and each having one end portion rotatably coupled to a body; and a pair of connection strings each having one end coupled to the other end of the corresponding vertical member and the other end pulled by a rider, wherein one of the vertical members is coupled to suspension lines connected to a left half plane of the canopy, and the other is coupled to suspension lines connected to a right half plane of the canopy, so that if the connection strings are wound or unwound by the rider, the other end of the vertical member is raised or lowered to allow the vertical members to rotate individually.

Description

[0001] A Balancing Device for Powered Paragliders [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an equilibrium holding device for a power paraglider, and more particularly, to an equilibrium holding device for a power paraglider capable of adjusting air resistance generated in a left half and a right half of a canopy, respectively.

Paraglider is one of the gliding means that can glide through the air by generating lift by using wind, and it is mainly used for leisure sports for leisure activities of many people who live in a stiff modern society. Since the paraglider is characterized by the intermediate characteristics between the glide characteristics of the hang glider and the descent characteristics of the parachute, the paraglider has high gliding capability and high safety, and the spread of the paraglider is widespread.

Generally, the paraglider has a canopy that generates a lift force capable of being swung by air inflow and generates a lift force. A row of the ropes is arranged at a lower portion of the canopy, And the other end of the line is joined in a bundle by a riser. A plurality of air chambers are formed by a plurality of diaphragms called rips or separators extending from the front end to the rear end of the canopy. A plurality of air chambers An air inlet port is formed.

On the other hand, a powered paraglider, which adds a propulsion device including an engine and a propeller to the general paraglider described above, is becoming popular for leisure. Such a conventional power paraglider may be constituted by coupling a propulsion device to the rear end of the main body and connecting the canopy to the upper end of the main body.

However, in the conventional power paraglider, the canopy is inevitably relatively large due to an increase in the overall weight, and a torsional moment is applied to the main body due to a strong torque generated by the rotation of the propeller, The bar has a problem that a high level of steering capability is required for stable flight.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an equilibrium holding device for a power paraglider in which the structure is improved so that the air resistance generated in the left half and the right half of the canopy can be respectively adjusted.

In order to achieve the above object, a balance holding device for a power paraglider according to the present invention is a member extending along a protruding direction of the canopy, and is provided with a pair of spaced apart from each other along a span direction of the canopy, A longitudinal member having one end rotatably coupled to the main body; One end of the longitudinal member is coupled to the other end of the longitudinal member and the other end of the longitudinal member is coupled to a line connected to the left half of the canopy, The other one of the longitudinal members is coupled with a line connected to the right half of the canopy. When the occupant pulls or pulls the connecting line, the other end of the longitudinal member ascends or descends to allow the longitudinal members to rotate individually .

It is preferable to include a horizontal member which is a member extending along the span direction of the canopy and which is disposed between the vertical members and maintains a constant distance between the vertical members.

Here, the line may include a plurality of line groups having an upper end connected to a plurality of points arranged along a protruding direction of the canopy from a front end of the canopy to a rear end of the canopy, And the upper ends of the line groups are coupled to the longitudinal members in the order in which the line members are spaced apart from the longitudinal members by a predetermined distance.

Here, one end portion is coupled to the rear end portion of the longitudinal member, and the other end portion includes a pair of control rods to which the occupant can pull, and the control rope is coupled to the rear end portion of the longitudinal member, It is preferable to pass through the first sheave which is a moving sheave.

The fixing member may include a fixing member for fixing the front end of the longitudinal member to the main body, and the connection member may be coupled to the rear end of the longitudinal member.

Here, it is preferable that one end portion is rotatably coupled to the main body, and the middle portion includes a steering bar coupled with the other end portion of the connection string.

Here, it is preferable that the manipulation bar can be fixed in a non-rotatable manner at a specific position unless an external force equal to or greater than a predetermined value is applied.

According to the present invention, there is provided a member extending along a protruding direction of the canopy, comprising: a longitudinal member having a pair of members arranged to be spaced apart from each other along a span direction of the canopy and having one end rotatably coupled to the main body; One end of the longitudinal member is coupled to the other end of the longitudinal member and the other end of the longitudinal member is coupled to a line connected to the left half of the canopy, The other one of the longitudinal members is coupled with a line connected to the right side of the canopy. When the occupant pulls or loosens the connecting line, the other end of the longitudinal member is raised or lowered, The air resistance generated in the left half and the right half of the canopy can be controlled.

1 is a perspective view of an equilibrium retaining apparatus according to an embodiment of the present invention.
Fig. 2 is a partial enlarged view of the power paraglider including the balancing device shown in Fig. 1. Fig.
3 is a view showing the balance holding apparatus and the canopy shown in Fig.
Fig. 4 is a view showing a power paraglider including the balancing device shown in Fig. 1. Fig.
5 is a view for explaining the operation principle of the balance holding apparatus shown in Fig.
6 is a plan view of the main body shown in Fig.
7 is a view showing a state in which the first rear wheel is housed in the internal space of the main body.
8 is a view showing a state in which the front wheel and the first rear wheel are housed in the internal space of the main body.
9 is a plan view of the power paraglider shown in Fig.
Fig. 10 is a view showing the shock absorber shown in Fig. 2. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 is a perspective view of an equilibrium maintaining apparatus according to an embodiment of the present invention, and Fig. 2 is a partial enlarged view of a power paraglider including the equilibrium maintaining apparatus shown in Fig. 3 is a view showing the balance holding apparatus and the canopy shown in Fig.

1 to 4, a power paraglider 100 according to a preferred embodiment of the present invention is a powered paraglider to which a propulsion unit including an engine and a propeller is added to a paraglider, 10, a lift generation unit 20, a thrust generation unit 30, a balance holding unit 40, and a shock absorber 60.

The power paraglider 100 is designed to fly with a weight of 130 kg to 477 kg in consideration of the total weight including the occupant and the like.

The main body 10 is a structure of a tricycle or trike structure and has an internal space capable of accommodating a passenger.

The main body 10 includes an upper member 11, a lower member 12, and a rear member 13. The upper member 11, the lower member 12, and the rear member 13 are provided in the form of a plurality of pipe members having a hollow therein.

In the interior of the pipe member such as the upper member 11, the lower member 12 and the rear member 13, there is provided a detachment prevention wire (not shown) for preventing the pipe member from being cut and separated at the time of breakage of the pipe member Not shown).

As shown in FIG. 6, the upper member 11 is a bar-shaped member extending in the forward and backward directions X as shown in FIG. 2, and is provided with a pair of left and right directions Y And is disposed on the upper side of the passenger.

As shown in Fig. 2, the lower member 12 is a bar-shaped member extending in the forward and backward directions X and is disposed on the lower side of the occupant in a state of being spaced apart from each other in the lateral direction Y .

On the upper surface of the front end portion of the lower member 12, a dashboard 51 provided with a display panel and various switches for recognizing the flying state is mounted.

An auxiliary footrest 53 is provided at an intermediate portion of the lower member 12 to allow the feet of the rear occupant to pass through.

The auxiliary footrest 53 protrudes as shown in FIG. 6 when in use, and is folded as shown in FIG. 9 during storage.

The rear member (13) is a structure in which a plurality of pipe members are welded or detachably fastened, and are arranged behind the occupant.

The upper member 11, the lower member 12, and the rear member 13 cooperate with each other to form the inner space capable of accommodating a passenger.

A protective member 14 for protecting the propeller 32, which will be described later, is detachably coupled to the rear member 13.

The protective member 14 is disposed to surround the end of the propeller 32 and has a circular arc shape in which the lower end is cut open in a shape similar to "∩".

A front wheel 15 is rotatably mounted on the front end of the lower member 12.

The front wheel 15 is coupled to the front end of the lower member 12 so as to be laterally reversible about the rotation axis 151. [

One of the front wheels 15 is detachably attached to the front end of the lower member 12.

The front wheel 15 and the rotary shaft 151 have a shape that can be received in the inner space of the main body 10 after being separated from the lower member 12.

At the upper end of the front wheel 15, there are provided a pair of control boards 52 on which the feet of the front passenger can be placed.

When the control footrest (52) is used, the left and right direction of the front wheel (15) can be adjusted.

An accelerator pedal capable of adjusting the power of the engine 31 to be described later and a brake pedal for braking the front wheel 15 and the first rear wheel 16 .

A pair of first rear wheels 16 are detachably mounted on the rear member 13 at a lower end thereof.

6, the pair of first rear wheels 16 protrude in the lateral direction Y by the first and second support rods 161 and 162 and are spaced apart from each other by a predetermined distance Respectively. In this embodiment, the distance between the pair of first rear wheels 16 is approximately equal to the diameter L1 of the protection member 14.

2, the first support frame 161 is located in front of the first rear wheel 16 and the second support frame 162 is located above the first rear wheel 16 have.

The first rear wheel 16 and the first and second support rods 161 and 162 have a shape that can be received in the inner space of the main body 10 after being separated from the rear member 13 . At this time, the first support member 161 and the second support member 162 are foldable.

At the lower end of the rear member 13, a pair of second rear wheels 17 having a diameter smaller than that of the first rear wheel 16 are mounted.

The pair of second rear wheels 17 are spaced from each other by a predetermined distance L2 in the left-right direction Y as shown in Fig. The distance L2 between the pair of second rear wheels 17 is smaller than the distance between the pair of first rear wheels 16. The distance between the pair of first rear wheels 16, It has a value similar to the separation distance.

7, when the first rear wheel 16 is separated from the first rear wheel 16, the second rear wheel 17 can be rotated in contact with the ground instead of the first rear wheel 16 do.

The lower member 12 is provided with two seats 18 on which a passenger can sit, and is arranged side by side in the forward and backward directions X. [

The seat 18 is provided with a seat belt (not shown) capable of fixing the occupant and a heat ray (not shown) generating heat to warm the occupant. Here, the main body 10 is equipped with a battery (not shown) for supplying electricity to the hot wire.

A pair of cargo rests 19 can be mounted on the rear end of the lower member 12 as shown in Fig.

One end of the cargo mount 19 is rotatably coupled to the lower member 12 and the other end of the cargo mount 19 is detachably coupled to the upper member 11 by a fixing belt 191 have.

The cargo holder 19 is rotatable between a storage position in which the cargo holder 19 is vertically folded to a horizontally extended use position and closely contacted with the main body 10. [

The cargo holder 19 may be completely separated from the main body 10 when not in use and stored separately.

The lift generating unit 20 includes a canopy 21 and a line 22 for generating a lift force to the main body 10. [

4 and 3, the canopy 21 is a part that generates a lift capable of swelling and gliding by the air introduced through the air inlet 211, and provides lifting force to the main body 10 .

The canopy 21 is disposed above the main body 10 and is well known to those skilled in the art, and a detailed description thereof will be omitted.

The line 22 is a plurality of lines for connecting the main body 10 and the canopy 21 to each other.

The upper end of the line 22 is connected to a point distributed all over the lower surface of the canopy 21. [

3, the upper end of the line 22 extends from the front 211 of the canopy 21 having the air inlet 211 to the rearward 212 of the canopy 21, 21 in the protruding direction C thereof.

The upper end of the line 22 is also connected to a plurality of points distributed along the left and right directions Y of the canopy 21.

As shown in Fig. 3, the lower end of the line 22 is detachably coupled to the longitudinal member 41, which will be described later, by a strap 25 and a ring 251. As shown in Fig.

The line 22 may be divided into a plurality of line groups 221, 222, 223, 224, and 225 based on the order of connecting the plurality of points along the protrusion direction C of the canopy 21 have.

In this embodiment, as shown in FIG. 3, the one closest to the front end 211 of the line groups 221, 222, 223, 224, and 225 is referred to as a line A 221, And the line group between the line A 221 and the line E 225 is referred to as a line B 222, a line C 223, and a line D 224, respectively, .

A control rod 23, also referred to as a brake cord, is connected to the lower end of the line E 225 connected to the trailing edge 212 of the canopy 21.

The control rope 23 is also called a control line as a line for controlling the paraglider. The control rope 23 can be rotated in the left-right direction and the speed of the paraglider by changing the shape of the canopy 21 caused by the degree of pulling .

The control rods 23 are connected to the line E 225 connected to the left and right halves of the canopy 21, respectively.

In this embodiment, one end of the control rod 23 is coupled to the rear end of the longitudinal member 41, which will be described later, and the other end of the control rod 23 is disposed so that the passenger can be pulled.

3, the control rope 23 is a movable pulley which is coupled to pull the line E 225 connected to the trailing edge 212 of the canopy 21, 1 < / RTI >

The control rods 23 pass through the first sheave 231 and then pass through a second sheave 232 which is a fixed pulley coupled to the upper member 11, The occupant sitting on the front seat 18 is arranged to be easy to grasp.

If the passenger pulls the control rod 23 by 10 cm, the first sheave 231 is lowered by 5 cm and the line E 225 is pulled down by 5 cm. Therefore, the force required for the occupant to pull the control rods 23 is reduced.

A preliminary parachute 24 is mounted between the rear seat 18 and the first rear wheel 16.

The preliminary parachute 24 is provided in such a structure that the parachute stored therein can be instantaneously deployed in an emergency such as an engine stop.

The thrust generating unit 30 includes an engine 31, a propeller 32, and a fuel tank 33. The thrust generating unit 30 is a device for providing thrust to the main body 10.

The engine 31 is detachably coupled to the rear member 13 as an internal combustion engine that is driven by liquid fuel to generate rotational force.

The propeller 32 is a plurality of rotating blades coupled to the engine 31 and generates propulsive force in the forward and backward directions X. [

The fuel tank 33 is a fuel tank disposed between the rear seat 18 disposed behind the seats 18 and the engine 31 as shown in FIG. .

A detachable auxiliary fuel tank 34 is provided at the lower end of the main body 10. In the present embodiment, the auxiliary fuel cylinder 34 is disposed on the lower surface of the rear seat 18.

The balance holding device 40 is an apparatus for canceling a twisting moment received by the main body 10 due to a strong torque generated by the rotation of the propeller 32, A transverse member 42, a fixing line 43, a connecting line 44, and a steering bar 45.

As shown in FIG. 1, the longitudinal member 41 is a member extending along the front-rear direction X of the canopy 21, and is disposed above the upper member 11 with a pair.

The longitudinal members 41 are spaced apart from each other along the span direction Y of the canopy 21.

A first through hole 411 is formed at an upper end of the longitudinal member 41 at a predetermined distance along the forward and backward directions X. As shown in FIG.

A second through hole 412 is formed in the lower portion of the front end of the vertical member 41 and a third through hole 413 is formed in the lower end of the rear end of the vertical member 41.

The second through hole 412 is disposed between the first and second one of the first through holes 411 in consideration of an aerodynamic center of the canopy 21.

A longitudinal member 41 on the left side (-Y direction) of the longitudinal members 41 is coupled to a line 22 connected to the left half of the canopy 21, (+ Y direction) is coupled with a line 22 connected to the right half of the canopy 21. The length of the longitudinal member 41 in the (+ Y direction)

3, the lower ends of the line groups 221, 222, 223, and 224 are aligned with the upper ends of the line members 221, 222, 223, and 224, And is connected to the first through hole 411.

One end of the control rope 23 is connected to a ring 251 coupled to the first through hole 411 located at the rear most of the first through holes 411.

The transverse member 42 is disposed between the longitudinal members 41 as a member extending along the span direction Y of the canopy 21.

The transverse member 42 is a member that keeps the distance between the longitudinal members 41 constant and at the same time allows the other ends of the longitudinal members 41 to rise or fall individually.

In the present embodiment, the transverse member 42 includes a first transverse member 42a and a second transverse member 42b.

The first transverse member 42a is a member extending along the span direction Y, and one end of the first transverse member 42a is non-rotatably coupled to the longitudinal member 41 on the right side.

The second transverse member 42b is a member extending along the span direction Y and has one end rotatably coupled to the longitudinal member 41 on the left side.

The other end of the first transverse member 42a and the other end of the second transverse member 42b are relatively rotatable about the span direction Y. [

One end of the fixing member 43 is coupled to the second through hole 412 and the other end of the fixing member 43 is connected to the other end of the fixing member 43. [ Is fixed to the fixing member 431.

The fixing member 431 is a member provided in a circular ring shape and is provided with a pair and is coupled to the upper member 11, respectively.

One end of the connecting rod 44 is coupled to the third through hole 413 and the other end of the connecting rod 44 is disposed so that the front passenger can be pulled.

The other end of the connecting line 44 includes a third pulley 441 which is a fixed pulley provided on the fixing member 431 and a third pulley 442 fixed to the upper member 11, And a three-sheave 441 in this order.

The manipulation bar 45 is a device capable of pulling or pulling the connecting line 44 and has one end rotatably coupled to a hinge 451 coupled to the upper member 11.

At the intermediate portion of the steering bar 45, there is a connecting point 452 which is engaged with the other end of the connecting line 44.

The manipulation bar 45 has an internal structure that can be fixed at a specific position in a non-rotatable manner, unless an external force equal to or greater than a predetermined value is applied.

That is, when the front passenger pulls or pushes the steering bar 45, the steering bar 45 rotates about the hinge 451, and when the front passenger releases his / her hand from the steering bar 45, The manipulation bar 45 is fixed in position.

When the front passenger pulls or pushes the manipulation bar 45, the connecting rod 44 is pulled or loosened so that the rear end of the longitudinal member 41 rises or falls as shown in FIG. 5, Can be individually rotated around the upper end of the fixing line 43.

10, the shock absorber 60 includes a first member 61, a second member 62, and a first engaging member 63, as shown in FIG. 10, A second engaging member 64, and an elastic member 65. As shown in Fig.

The first member 61 is a circular pipe-shaped member and extends by a predetermined length.

The second member 62 is a circular pipe-shaped member extending by a predetermined length, and one end of the second member 62 is slidably coupled to one end of the first member 61.

In this embodiment, one end of the second member 62 is inserted into one end of the first member 61.

The first engaging member 63 is a bobbin type member fixed to one end of the first member 61, and a pair of the first engaging member 63 and the second engaging member 63 are provided.

The first engaging member 63 is coupled to the first engaging member 63 while being disposed at both ends of the first screw 631.

The first engaging member (63) is disposed between the second engaging member (64) and the other end of the second member (62).

The first screw 631 is slidably inserted into the second guide groove 67 formed in the longitudinal direction of the second member 62 and is not separated from the second guide groove 67.

The second engaging member 64 is a bobbin-like member fixed to one end of the second member 62, and is provided with a pair.

The second engaging member 64 is coupled to the second engaging member 64 in a state where the second engaging member 64 is disposed at both ends of the second screw 641.

The second engaging member 64 is disposed between the first engaging member 63 and the other end of the first member 61. Therefore, as shown in FIG. 10, the second latching member 64 is not located below the first latching member 63.

The second screw 641 is slidably inserted into the first guide groove 66 formed in the longitudinal direction of the first member 61 and is not separated from the first guide groove 66.

The elastic member 65 is a wire-shaped member having elasticity, and in this embodiment, a coated rubber band is used.

The elastic member 65 is disposed so that the first engaging member 63 and the second engaging member 64 can be elastically biased in a direction in which they approach each other.

In the present embodiment, the elastic member 65 is wound so as to surround the first engaging member 63 and the second engaging member 64 a plurality of times.

If the second member 62 is moved in the direction of being inserted into the first member 61 by an external force, the first engaging member 63 and the second engaging member 64 are separated from each other And the elastic member 65 is stretched. Therefore, the elastic member 65 can provide a buffering effect similar to that of a spring.

Hereinafter, an example of the principle of operation of the power paraglider 100 having the above-described configuration will be described.

In the ground, the left and right direction of the front wheel 15 can be adjusted by using the above-mentioned control foot 52, and a ground running is performed by using an accelerator pedal and a brake pedal in the control foot 52 .

When the user desires to fly, he or she can control only the control rods 23 and take off with the pair of control rods 45 fixed at appropriate positions.

As shown in FIGS. 1 and 5, the pair of longitudinal members 41 can rotate individually around the upper end of the fixing line 43, so that the left half of the canopy 21 and the right half (X) air resistance generated in the front-rear direction (X).

By using the balance holding device 40 in this way, the torsional moment which the body 10 receives in the direction opposite to the rotating direction of the propeller 32 can be canceled.

For example, when the main body 10 is tilted in such a manner that the left shoulder of the occupant descends due to the rotational force of the propeller 32, the power paraglider 100 tends to rotate to the left. In this case, As shown in Fig. 1, the steering bar 45 gripped by the passenger's right hand is pushed forward, and the rear end of the longitudinal member 41a on the right side is lowered. This increases the air resistance acting on the right half of the canopy 21 and generates a force that allows the power paraglider 100 to rotate to the right. That is, the left rotational force generated by the rotational force of the propeller 32 is canceled by the right rotational force generated by the equilibrium holding device 40, so that the power paraglider 100 can advance forward.

If the overall speed of the power paraglider 100 is to be increased after securing the straightness of the power paraglider 100 in this way, the passenger must move the pair of manipulation bars 45 to both sides You can pull it. As a result, the rear end portions of the pair of longitudinal members 41a and 41b are lifted to decrease the air resistance acting on the entire canopy 21, thereby increasing the speed of the power paraglider 100. Conversely, if it is intended to reduce the overall speed of the power paraglider 100, the occupant may push both of the pair of steering bars 45 forward with both hands.

After securing the straightness and speed of the power paraglider 100, the fine control of the power paraglider 100 uses the control rod 23 like a conventional paraglider. When the passenger pulls the control rope 23b gripped by the left hand, the air resistance acting on the left half of the canopy 21 increases to cause the power paraglider 100 to rotate to the left, The air resistance acting on the right half of the canopy 21 increases and the power paraglider 100 rotates to the right side.

The power paraglider 100 of the above-described configuration includes a main body 10 capable of receiving an occupant; A canopy 21 disposed above the main body 10 for providing lifting force to the main body 10; A line (22) connecting the main body (10) and the canopy (21) to each other; A thrust generating unit (30) coupled to the main body (10) and providing thrust to the main body (10); And a balance holding device (40) for canceling a torsional moment received by the main body (10) by a torque generated by the thrust generating unit (30), wherein the main body (40) Shaped member extending in a left-right direction (Y), and an upper member (11) disposed on the upper side of the occupant in a state of being spaced apart from each other in the left-right direction (Y) Since the other end is coupled to the line 22, the flying stability of the main body 10 is improved by eliminating the deflection of the main body 10.

The power paraglider (100) is characterized in that the main body (10) includes a plurality of pipe members having a hollow inside thereof, and at the time of breakage of the pipe member, Since the shape of the main body 10 can be maintained to a certain extent even if the main body 10 is damaged by the impact, the safety of the occupant can be maintained There is an advantage that can be guaranteed.

The power paraglider 100 may further include an engine 31 mounted on the rear end of the main body 10 and operated by liquid fuel; A propeller 32 coupled to the engine 31; And a protection member 14 disposed so as to surround the end of the propeller 32. The protection member 14 has an arc shape with its lower end cut open to reduce its overall weight, There is an advantage that the lower end of the protective member 14 does not contact the ground even if the angle of attack of the main body 10 increases.

The power paraglider 100 is provided with a detachable auxiliary fuel tank 34 at the lower end of the main body 10, so that it is possible to easily increase the flying distance according to the flight mission.

The power paraglider 100 also includes a seat 18 on which an occupant can sit; A heat line that heats to warm the passenger (not shown); And a battery (not shown) for supplying electricity to the hot wire. Therefore, it is advantageous that high altitude long distance flight can be performed even in a cold weather.

The power paraglider 100 includes a front wheel 15 mounted on a front end of the main body 10; A pair of first rear wheels (16) detachably mounted on the rear end of the body (10); And a pair of second rear wheels 17 mounted on the rear end of the body 10 and having a smaller diameter than the first rear wheels 16. The first rear wheels 16, Since the first rear wheel 16 is detached from the main body 10 and can be received in the internal space of the main body 10, even when the first rear wheel 16 is detached as shown in FIG. 7, (17) can roll in contact with the ground, and the size and volume of storage can be reduced during storage or transportation.

The power paraglider 100 is provided with a pair of members that extend along the protruding direction X of the canopy 21 so that the balance holding device 40 can be moved in the span direction Y of the canopy 21 A vertical member 41 having one end rotatably coupled to the main body 10; One end of the longitudinal member 41 is coupled to the other end of the longitudinal member 41 and the other end of the longitudinal member 41 includes a pair of connecting lines 44 to which a passenger can be pulled, The other one of the longitudinal members 41 is coupled to the line 22 connected to the right side of the canopy 21 and the other end 41a of the longitudinal member 41 is connected to the line 22 connected to the left half of the canopy 21, The other end portion of the longitudinal member 41 is raised or lowered when the connecting member 44 is pulled or loosened so that the longitudinal member 41 can rotate individually. (X) air resistance generated in the canopy (21) by adjusting the air resistance of the main body (10), thereby increasing or decreasing the angle of attack of the left half and / or right side of the canopy There are advantages.

A front wheel 15 is mounted on a front end portion of the main body 10 so as to be able to be turned in the left and right direction about a rotation axis 151. The front wheel 15 is provided with a passenger- And a pair of steering pedals 52 for placing the foot of the front wheels 15 on the front wheels 15. The steering pedal 52 is provided with an accelerator pedal for adjusting the power of the thrust generating unit 30, The left and right direction of the front wheel 15 can be adjusted with both feet by using the control pedal 52. At the same time, the power of the engine 31 can be adjusted and braked There is an advantage.

The power paraglider 100 includes: a first member 61 extending by a predetermined length; A second member (62) extending one end of the predetermined length, one end of which is slidably engaged with one end of the first member (61); A first latching member (63) fixed to one end of the first member (61); A second engaging member (64) fixed to one end of the second member (62) and disposed between the first engaging member (63) and the other end of the first member (61); The first engaging member 63 and the second engaging member 64 are wound around each other so that the first engaging member 63 and the second engaging member 64 can be elastically biased in the direction in which they approach each other Shaped elastic member 65 that connects the elastic member 65 to the elastic member 65. This makes it possible to realize a simple and lightweight shock absorber without using a complicated structure including a coil-shaped spring.

The equilibrium holding device 40 is a device that can be used for a paraglider including the main body 10, the canopy 21, and the line 22, and has a protrusion direction X of the canopy 21 A pair of longitudinal members 41 arranged along the span direction Y of the canopy 21 and spaced apart from each other and having one end rotatably coupled to the main body 10, ; One end of the longitudinal member 41 is coupled to the other end of the longitudinal member 41 and the other end of the longitudinal member 41 includes a pair of connecting lines 44 to which a passenger can be pulled, The other one of the longitudinal members 41 is coupled to the line 22 connected to the right side of the canopy 21 and the other end 41a of the longitudinal member 41 is connected to the line 22 connected to the left half of the canopy 21, The other end portion of the longitudinal member 41 is raised or lowered when the connecting member 44 is pulled or loosened so that the longitudinal member 41 can rotate individually. There is an advantage that the air resistance in the forward and backward direction (X) generated in the air conditioner can be adjusted.

The balance holding device 40 is a member extending along the span direction Y of the canopy 21 and is disposed between the longitudinal members 41. The distance between the longitudinal members 41 Since the horizontal member 42 that keeps the canopy 21 constant is provided, the left half of the canopy 21 and the line 22 connected to the right half are not tangled with each other.

The balance holding device 40 is configured such that the line 22 extends from a front end portion of the canopy 21 to a rear end portion of the canopy 21 at a plurality of points arranged along a protrusion direction C of the canopy And a lower end of the line groups 221, 222, 223, 224, and 225 includes a plurality of line groups 221, 222, 223, 224, Since the upper ends of the line groups 221, 222, 223, 224 and 225 are connected to the longitudinal members 41 in the order of being arranged in a state of being spaced apart from each other by a predetermined distance, 43, it is possible to increase or decrease the angle of attack of the entire left half or right half of the canopy 21.

One end of the balancing device 40 is coupled to the rear end of the longitudinal member 41 and the other end of the balancing device 40 includes a pair of control rods 23 to which the rider can pull. Passes through the first sheave 231 coupled to draw the line E (225), which is a line group connected to the rear end of the canopy 21, so that the occupant pulls the control line 23 by the pulley principle There is an advantage that the required force is reduced by half. This advantage is more necessary as the canopy 21 is larger.

The balance holding device 40 includes a fixing line 43 for connecting the front end of the longitudinal member 41 to the main body 10 and the connecting line 44 is connected to the rear end of the longitudinal member 41 As compared with the case where the connecting member 44 is coupled to the front end of the longitudinal member 41 and the fixing member 43 is coupled to the rear end of the longitudinal member 41, The force required to pull the connecting line 44 is reduced and the overall flight stability is also increased when the aerodynamic center of the canopy 21 is considered.

Since the balance holding device 40 includes the steering bar 45 having one end rotatably coupled to the main body 10 and the middle portion coupled to the other end of the connecting rod 44, The force required to pull the connecting line 44 is reduced.

Also, the balancing device 40 can be fixed at a specific position in a non-rotatable manner, so long as the steering bar 45 is not subjected to an external force equal to or greater than a predetermined magnitude, ) Can be fixed in position.

The horizontal member 42 includes the first horizontal member 42a and the second horizontal member 42b which are relatively rotatable about the span direction Y and are relatively rotatable, It goes without saying that the member 42 may have any structure capable of maintaining the interval between the pair of longitudinal members 41 and rotating the longitudinal members 41 individually.

The fixing member 43 is coupled to the front end of the longitudinal member 41 and the connecting member 44 is coupled to the rear end of the longitudinal member 41. However, 41 may be coupled to the front end of the longitudinal member 41 and the fixing member 43 may be coupled to the rear end of the longitudinal member 41.

The technical scope of the present invention is not limited to the contents described in the above embodiments, and the equivalent structure modified or changed by those skilled in the art can be applied to the technical It is clear that the present invention does not depart from the scope of thought.

[Description of Reference Numerals]
100: Powered paraglider
10: Body
11: upper member
12: Lower member
13: rear member
14:
15: front wheel
16: first rear wheel
17: second rear wheel
18: Rear seat
19: Cargo hold
20: lift generation unit
21: Canopy
22: Line
23: Steering column
24: Preliminary parachute
25: Strap
30: Thrust generating unit
31: engine
32: Propeller
33: Fuel tank
34: auxiliary fuel tank
40: Balancing device
41: longitudinal members
42: transverse member
42a: first lateral member
42b: second lateral member
43: Fixed line
44: Connections
45: Steering bar
51: Instrument cluster
52: Steering footrest
53: Auxiliary footrest
60: shock absorber
61: first member
62: second member
63: first engaging member
64: second engaging member
65: elastic member
66: first guide groove
67: second guide groove
151:
161: first support
162: second support
191: Fixing belt
211: Air inlet
212:
221: Mountain line A
222: Line B
223: Line C
224: line D
225: Line E
231: 1st pulley
232: 2nd pulley
251: Ring
411: First through hole
412: second through hole
413: Third through hole
431: Fixing member
441: Third pulley
451: Hinge
452: Connection point

Claims (7)

A body capable of accommodating an occupant; A canopy disposed above the body for providing lifting force to the body; And an arbor connecting the main body and the canopy to each other, the apparatus comprising:
A longitudinal member having a pair of protrusions extending along a protrusion direction of the canopy, the pair of longitudinal members being spaced apart from each other along a span of the canopy and having one end rotatably coupled to the main body;
And a pair of connecting rods, one end of which is coupled to the other end of the longitudinal member, and the other end of which can be pulled by a passenger,
Wherein one of the longitudinal members is coupled to a line connected to the left half of the canopy and the other one of the longitudinal members is connected to a line connected to the right half of the canopy,
When the occupant pulls or loosens the connecting line, the other end of the longitudinal member is moved up or down so that the longitudinal member can rotate individually,
Wherein a front end portion of the longitudinal member is rotatably coupled to the main body and the connection string is coupled to a rear end portion of the longitudinal member, The method according to claim 1,
And a transverse member disposed between the longitudinal members and extending in the span direction of the canopy to maintain a constant distance between the longitudinal members. The method according to claim 1,
Wherein the line includes a plurality of line groups each having an upper end coupled to a plurality of points arranged along a protrusion direction of the canopy from a front end of the canopy to a rear end of the canopy,
Wherein the lower ends of the line groups are connected to the longitudinal members in the order in which the upper ends of the line groups are arranged in a state of being spaced by a predetermined distance from the longitudinal members. The method according to claim 1,
Wherein one end portion is coupled to the rear end portion of the longitudinal member and the other end portion includes a pair of control rods to which the occupant can pull,
Characterized in that the control rods pass through a first sheave which is a moving sheave coupled to pull a group of ropes connected to the rear end of the canopy. delete The method according to claim 1,
Wherein the one end portion is rotatably coupled to the main body and the middle portion includes a steering bar coupled to the other end portion of the connecting line. The method according to claim 6,
Characterized in that the control bar can be fixed at a specific position in a non-rotatable manner unless an external force equal to or greater than a predetermined magnitude is applied,

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