Patent Publication Number: US-2005138855-A1

Title: Animated gamebird decoy with movable appendages

Description:
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     BACKGROUND OF THE INVENTION  
      1. Field of the Invention  
      The present invention relates generally to devices for attracting game animals and more particularly to waterfowl decoys especially adapted for attracting game animals.  
      2. Description of the Prior Art  
      When hunting animals, hunters often deploy devices whose function is to attract the animals that are being hunted. Most decoys do not have any movement to them. It would be favorable to have some movement since real live animals move when feeding. Of special interest are decoys which simulate ducks and geese. In the prior art, waterfowl decoys which have moveable wings were mechanically flapped by pulling a string or cord, or have wings that spin or rotate. There are many limitations with pulling a string, and spinning or rotating wings are unnatural movements.  
      Throughout the years, a number of innovations have been developed relating to waterfowl decoys. The following U.S. patents are representative of some of those innovations. U.S. Pat. Nos. 4,172,335; 4,611,421; 4,753,028; 4,485,873; 4,885,861; 4,928,418; 5,172,506; 5,231,780; 5,636,466. Some patents disclose waterfowl decoys that move in the wind, but as we all know, we cannot rely on the wind to give our decoys motion. In this respect it would be desirable for the decoy to move without depending on the wind.  
      It is therefore, an object of the present invention to provide movement electrically causing the two wing-like appendages to flap up and down rather than to rely on the wind.  
      It is a further object of the present invention to produce the up and down motion of the two wing-like appendages using an electric actuator that goes up and down instead of an electric motor that spins the wing-like appendages horizontally which is an unnatural movement.  
      Likewise, it is an object of the present invention to provide an inexpensive, easy to make and operate waterfowl decoy that the average hunter can afford and still have one that has natural movement.  
     SUMMARY OF THE INVENTION  
      One embodiment of the present invention is a plastic shelled gamebird decoy comprising of a frame (the stake that comes with the purchased decoy) with a vertical and a horizontal axis, and a simulated waterfowl body mounted to said frame and defining a chamber, with an electric actuator located within this said chamber being afixed to the vertical stake of the frame being connected to a source of electrical energy that makes the plunger on the actuator move up and down. Down being energized and up when deenergized. The plunger on the actuator is raised back up by the weight of the two wing-like appendages. An intermittent device (such as a flasher relay for an automobiles turn signal or emergency flashers) is situated between the actuator and the power source (battery). This device is attached to the positive wire of the actuator which is afixed to the vertical stake frame inside the chamber formed by the plastic shelled gamebird decoy. When the actuator is energized this causes the plunger on the actuator to be pulled down. The two wing-like appendages are pinned to two mounting brackets that are afixed to the horizontal stake frame. The two wing-like appendages proximal ends protrude through the opposite sides of the plastic shelled gamebird decoy through an elongated hole as to allow the proximal ends to move in an up and down motion simulating a live waterfowl gamebird flapping its wings.  
      The two distal ends of the two wing-like appendages are underneath a bracket which is afixed to the actuators plunger mechanism of the electric actuator. When the actuator is energized the plunger on the actuator is pulled down forcing the distal ends of the two wing-like appendages also. This downward motion will cause the two proximal ends of the two wing-like appendages in an upward motion in relation to the downward motion of the distal ends because the two wing-like appendages are pinned close to the distal ends. When the electric actuator is deenergized the weight of the two wing-like appendages will force the plunger on the actuator back up into the extended position.  
      The two wing-like appendages are made of a cloth or some sort of plastic sheeting that is attached to the proximal ends of the two wing-like appendages as soon as it exits the sides of the plastic shelled gamebird decoy. This sheeting will simulate the wings and feathers of the preferred gamebird and will be afixed to the appendages so they look natural.  
      Yet another embodiment of the present invention is to use an outside power source such as a battery (electrical) energy to achieve the flapping wing motion of real live waterfowl gamebirds for use in the sport of hunting.  
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       FIG. 1  is a quartering side perspective view illustrating the waterfowl decoy apparatus of the present invention in position with the wing-like appendages flapping in a field.  
       FIG. 2  is a quartering frontal view illustrating the waterfowl decoy apparatus shown in  FIG. 1  with the wing-like appendages in the up position.  
       FIG. 3  is a cross-sectional frontal view of the waterfowl decoy apparatus illustrating the components disposed within the interior of the decoy housing.  
       FIG. 4  is a quartering frontal view of the waterfowl decoy apparatus illustrating the components disposed within the interior of the decoy housing with the actuator in the down position.  
       FIG. 5  is a quartering frontal view of the waterfowl decoy apparatus illustrating the components disposed within the interior of the decoy housing with the actuator in the up position.  
       FIG. 6  is an exploded quartering frontal view of the waterfowl decoy apparatus illustrating all of the components disposed within the interior of the decoy housing.  
       FIG. 7  is an exploded view of brackets  23 A &amp;  23 B that are attached to the horizontal frame stake.  
       FIG. 8  is a view of the dowels  34 A &amp;  34 B that makeup the wing-like appendages showing the holes  33 A &amp;  33 B in which the cotter pins  32 A &amp;  32 B pin the dowels to brackets  23 A &amp;  23 B.  
       FIG. 9  is a view of the wing-like appendages that flap up and down when the actuator is activated.  
    
    
     DETAILED DESCRIPTION OF THE INVENTION  
      Referring now to the drawings, the waterfowl decoy apparatus is constructed in accordance with the present invention includes a decoy housing  2  having the configuration of a waterfowl&#39;s body and defining an inside chamber. The waterfowl decoy housing may be constructed of any suitable material such as plastic or fiberglass. A shell decoy of this type is described in U.S. Pat. No. 4,885,861 issued to R. S. Gazalski, the description of which is incorporated herein in its entirety by reference. The head and neck assembly  1  shown comes with the decoy body. The actuator  3  is a purchased 12 volt automobile door lock actuator.  
      Referring to  FIG. 3  the vertical stake  11  and the horizontal stake  12  are also parts of the purchased decoy. The bracket  4  on top of the actuator is held in place by a bolt  5 . As seen in  FIG. 6  the said bracket has two elongated holes  6 A&amp;B in which the two wing-like appendages  35 A&amp;B as seen in  FIG. 2  pass through. These two wing-like appendages move up and down when the electrical power is supplied as shown in  FIG. 2  by a battery  10  as the current passes through an intermittant device  9  which is a flasher relay for an automobiles turn signal assembly. These wing-like appendages pass through the decoy shell through two elongated holes  36 A&amp;B as shown in  FIG. 3 . When the power is supplied to the actuator the plunger on the actuator is pulled down forcing the distal ends of the two dowels  34 A&amp;B down also since the said dowels are cotter pinned see  FIG. 7  by two cotter pins  32 A&amp;B through holes  31 A&amp;B that are through the two dowels. These two dowels are attached to two brackets  23 A&amp;B which in turn are attached to the horizontal stake  12  by two bolts  29 A&amp;B that are threaded through two holes  26 A&amp;B in the two brackets and two holes  25 A&amp;B that are through the horizontal stake  12  attached by two wing nuts  30 A&amp;B see  FIG. 6 . Also through these two brackets are two holes  27 A&amp;B in which two rivets  28 A&amp;B pass through two other holes  24 A&amp;B through the horizontal stake see  FIG. 6  and are pop riveted through the two said holes in the horizontal stake only. These two rivets just rest inside the two holes  27 A&amp;B in the bracket so as to just stabilize the bracket onto the horizontal stake. Since the proximal ends of the two wing-like appendages are much heavier than the distal ends, the weight of the proximal ends force the plunger on the actuator back up into the extended position.  
      Referring to  FIG. 6  the said actuator is attached to two brackets  16 A&amp;B by two bolts  21 A&amp;B that go through four holes  20 A&amp;B&amp;C&amp;D and are secured by two nuts  22 A&amp;B. The said brackets are riveted to the vertical stake frame by two rivets  18 A&amp;B. These two rivets go through two holes  19 A&amp;B in said brackets and through two holes  17 A&amp;B in the vertical stake frame. The vertical and horizontal stake frames are riveted together with a pop rivet  15  that passes through a hole  13  in the vertical stake frame and a hole  14  in the horizontal stake frame.  
      Referring to  FIG. 9  the two wing-like appendages are made from two dowels  34 A&amp;B and two pieces of plastic sheeting  35 A&amp;B that are attached to the two dowels as to look like the real wings of a waterfowl gamebird.  
      Referring to  FIG. 3  is the two wires that go to the battery from the actuator. Wire  8  is the positive wire and wire  7  is the negative wire.