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An object in flight that spins around an axis that is not aligned with its direction of travel is subject to the Magnus effect.
As an object in motion spins, the part of the object that is spinning into the oncoming air creates a small area of high pressure. Conversely, the part of the object that is spinning away from the oncoming air creates an area of low pressure. The areas of low pressure and high pressure produce a vectored force that can cause an object in flight to alter its direction. This movement is known as the Magnus effect in fluid dynamics. The Magnus effect enables cylindrical or tubular projectiles, when given sufficient linear and rotational velocities, to achieve lift and to move in a generally looping fashion.
In the toy industry, the Magnus effect has been implemented to affect interesting projectile flight patterns. The problem with existing technologies is the complexity of use. For instance, mechanisms that require wrapping a projectile with an elastic cord or string require hand and eye coordination that is beyond the skillset of many children and adults. In addition, elastic cords or strings are not easily aligned in the center of such a projectile. As a consequence, the projectile can easily be launched off-balance, destroying the necessary aerodynamic conditions and ruining the desired looping effect.
Certain illustrative embodiments illustrating organization and method of operation, together with objects and advantages may be best understood by reference detailed description that follows taken in conjunction with the accompanying drawings in which:
While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and will herein be described in detail specific embodiments, with the understanding that the present disclosure of such embodiments is to be considered as an example of the principles and not intended to limit the invention to the specific embodiments shown and described. In the description below, like reference numerals are used to describe the same, similar or corresponding parts in the several views of the drawings.
The terms “a” or “an”, as used herein, are defined as one, or more than one. The term “plurality”, as used herein, is defined as two, or more than two. The term “another”, as used herein, is defined as at least a second or more. The terms “including” and/or “having”, as used herein, are defined as comprising (i.e., open language). The term “coupled”, as used herein, is defined as connected, although not necessarily directly, and not necessarily mechanically.
Reference throughout this document to “one embodiment”, “certain embodiments”, “an exemplary embodiment” or similar terms means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the appearances of such phrases or in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments without limitation.
The present invention is a toy projectile and launcher system. The projectile is cylindrical in shape and lightweight. The projectile has an exterior surface that is symmetrically disposed about an imaginary longitudinal axis. In an embodiment, the launcher has a holding trough that receives and holds the tubular projectile. Within the launcher is a spring loaded element. The spring loaded element selectively moves between a cocked position and a released position. The spring loaded element is biased into its released position by a spring. When manually moved to its cocked position, the spring stores energy. The spring loaded element contacts the projectile in the holding trough as the spring loaded element moves from its cocked position to its released position. Contact with the spring loaded element causes the tubular projectile to launch into flight in a direction perpendicular to its longitudinal axis. Simultaneously, contact with the spring loaded element imparts a spinning rotation to the projectile, wherein the projectile spins about its longitudinal axis in flight. The spinning creates a Magnus effect on the projectile that helps keep it in flight and alters its flight path.
In an alternative embodiment, the innovation described herein is a tubular toy projectile and launcher system, with said projectile having an exterior surface that is symmetrically disposed about an imaginary longitudinal axis. The launcher includes planar leaves, which are rigid or semi-rigid plates of plastic, metal, carbon fiber, or some similar material, designed to hold said projectile between them, and designed variably to flex or remain rigid when struck by a force vector directed perpendicular to the face of the plate. The leaves are positioned opposite each other along said imaginary longitudinal axis, for receiving and holding projectile. The launcher includes a spring loaded element, supported by said launcher, that is selectively moved between a cocked position and a released position, wherein said spring loaded element contacts one or more of said planar leaves as said spring loaded element moves from said cocked position to said released position, and wherein contact between said spring loaded element and said one or more of said planar leaves causes said tubular projectile to launch into flight in a direction perpendicular to said longitudinal axis.
In an alternative embodiment, the innovation described herein is a tubular toy projectile and launcher system, where said projectile has an exterior surface that is symmetrically disposed about an imaginary longitudinal axis and said launcher has holding pins positioned opposite each other along said imaginary longitudinal axis, for receiving said tubular projectile. The launcher further includes a spring loaded element, supported by said launcher, that is selectively moved between a cocked position and a released position, wherein said spring loaded element contacts one or more of said holding pins as said spring loaded element moves from said cocked position to said released position, and wherein contact between said spring loaded element and said one or more of said holding pins causes said tubular projectile to launch into flight in a direction perpendicular to said longitudinal axis.
In an alternative embodiment, the innovation described herein is a cylindrical toy projectile and launcher system, where said projectile has an exterior surface that is symmetrically disposed about an imaginary longitudinal axis and said launcher has a holding cavity composed of at least three rigid sides, two of said rigid sides oriented in parallel and disposed to hold said projectile firmly between them. Said launcher includes a flexible ribbon immovably attached to said holding cavity at the distal end of the first of two rigid parallel sides and slidably attached at the distal end of the second of the two rigid parallel sides, such that said ribbon may translate the length of said holding cavity when acted upon by a force applied outside the holding cavity. The launcher further includes a spring loaded element or pneumatic piston element to provide a motive force. The said spring loaded element or pneumatic piston element is positioned outside the holding cavity and supported by said launcher, and is selectively moved between a cocked position and a released position. Said motive force acts upon said flexible ribbon as said spring loaded element or pneumatic piston element moves from said cocked position to said released position, and wherein contact between said spring loaded element or pneumatic piston element and said ribbon causes said cylindrical projectile to launch into flight in a direction perpendicular to said longitudinal axis.
Although the present invention projectile and launcher can be embodied in many ways, only a few embodiments of the invention are illustrated and described. These embodiments are selected in order to set forth some of the best modes contemplated for the invention. The illustrated embodiments, however, are merely exemplary and should not be considered limitations when interpreting the scope of the appended claims.
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The hammer 28 contains one or two arms 32 that support the head 30. The arms 32 are pivotally connected to the base 22 at pivot connections 34. The arms 32 are biased into a released position that holds the head 30 immediately adjacent the holding trough 24. The spring bias is provided by one or two torsion springs 36 that connect to both the base 22 and the arms 32. The hammer 28 can be manually moved into a cocked position against the bias of the springs 36. To do this, the hammer 28 is rotated about the pivot connections 34 until the head 30 of the hammer 28 connects to a trigger catch 38. The trigger catch 38 is opened by the pulling of a trigger lever 40 under the base 22.
Once the hammer 28 is rotated to its cocked position, spring energy is stored in the springs 36. When the trigger lever 40 is pulled, the trigger catch 38 disengages the head 30. The stored spring energy then causes the hammer 28 to rotate in the manner of a mousetrap. The head 30 on the hammer 28 accelerates with the rotating hammer 28 until the head 30 strikes the side of the projectile 10. The head 30 of the hammer 28 strikes the projectile 10 with a glancing blow that acts at a tangent to the curvature of the projectile 10. This transfers much of the energy from the hammer 28 to the projectile 10 in the form of spin. However, the contact with the hammer 28 also has the effect of displacing the projectile 10 from the holding trough 24 and launching the projectile 10 into flight. The projectile 10 rotates rapidly around its long axis 14 as it is launched into flight. The forward projection away from the holding trough 24 and the rapid rotation create a Magnus force that helps to keep the projectile 10 in flight. As previously mentioned, the projectile 10 tends to fly up and around in a looping flight path.
Referring to
The projectile 50 is placed in the holding trough 62 so that the gear teeth impressions 52 on the projectile 50 intermesh with the gear rack 64. When the gear rack 64 is released from its cocked position, the gear rack 64 rapidly moves under the projectile 50. This causes the projectile 50 to spin rapidly. As the gear rack 64 moves, the pull tab 70 eventually contacts the projectile 50. The pull tab 70 has an inclined surface 76 that strikes the projectile 50 and launches it into flight while it is spinning. The forward projection away from the holding trough 62 and the rapid rotation creates a Magnus force that helps to keep the projectile 50 in flight. As previously mentioned, the projectile 50 tends to fly up and around in a looping flight path.
Referring to
The projectile 90 is placed between the distal ends of planar leaf 82 and planar leaf 84 such that an imaginary line drawn between the ends of planar leaf 82 and planar leaf 84 bisects the cross-section of projectile 90. When the plunger 94 is released from its cocked position, plunger head 80 moves rapidly toward and strikes planar leaf 82. Projectile 90 is pinched between planar leaf 82 and planar leaf 84, launching projectile 90 into flight while spinning. The forward projection away from the planar leaf 82 and the rapid rotation creates a Magnus force that helps to keep the projectile 90 in flight. The projectile 90 tends to fly up and around in a looping flight path.
Referring to
A plunger is provided. The plunger is spring-loaded with spring. A handle is present at one end of the plunger. When handle is pulled, plunger moves horizontally within an internal track, and spring compresses. Once the spring is fully compressed, the plunger engages an internal trigger catch that holds the plunger and the spring in a cocked position. An internal trigger catch is operated by trigger lever. When the trigger lever is pulled, the plunger is released. The spring releases its stored energy and the plunger is rapidly accelerated horizontally in an internal track, from a cocked position to a released position.
The projectile 90 is placed between the first linear member 102 and second linear member 104, with the ribbon 108 running along the inside of first rigid linear member 102, around the rear-facing side of projectile 90, and along the inside of second rigid linear member 104. In an embodiment, the distance between first linear member 102 and second linear member 104 is only slightly greater than the diameter of projectile 90, and with the addition of ribbon 108, first linear member 102 and second linear member 104 hold projectile 90 firmly between them. When the plunger is released from its cocked position, plunger head moves rapidly toward and strikes ribbon 108, pushing the bottom-most section of ribbon 108 out from the C-shaped compartment 100. Because projectile 90 is held tightly between first linear member 102 and second linear member 104, ribbon 108 imparts a rotational velocity to projectile 90 as ribbon 108 is drawn out from the C-shaped compartment 100. Simultaneously, ribbon 108 imparts a linear velocity to projectile 90. When plunger is fully extended, ribbon 108 is pulled taut, and projectile 90 is launched into flight while spinning. The forward projection away from the C-shaped compartment 100 and the rapid rotation creates a Magnus force that helps to keep the projectile 90 in flight. The projectile 90 tends to fly up and around in a looping flight path.
While certain illustrative embodiments have been described, it is evident that many alternatives, modifications, permutations and variations will become apparent to those skilled in the art in light of the foregoing description.
This application claims under 35 U.S.C. §120, the benefit of the application Ser. No. 14/823,808, filed Aug. 11, 2015, Patent Application Publication Number 17/0045,327, titled “Magnus Effect Cylindrical Projectile and Launcher” which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | 14823808 | Aug 2015 | US |
Child | 15595457 | US |