Toy gun having a retractable sight

A toy gun having a pneumatic projectile launcher for launching a foam projectile and a retractable sighting mechanism which automatically raises to an operative viewing position when the gun is cocked. The pneumatic launcher having a plunger is concealed by a sliding housing which simulates the action of an automatic weapon, and the sight is pivotally mounted to the housing. When the gun is cocked by sliding the housing rearwardly relative to the body of the gun, the sight contacts an actuator which rotates the sight to an operative viewing position. When the gun is fired, the housing moves forwardly in unison with the plunger, and the sight automatically rotates to its inoperative position.

FIELD OF THE INVENTION 
The present invention relates generally to a toy gun for launching a foam 
projectile. More specifically, the present invention relates to a toy gun 
having a spring-loaded retractable sight assembly which automatically 
raises to an operative viewing position when the toy gun is cocked and 
which automatically retracts when the toy gun is fired. 
BACKGROUND AND SUMMARY OF THE INVENTION 
Toy air guns that launch soft foam projectiles using a blast of compressed 
air are generally well known in the art. Because such guns launch an 
actual projectile they satisfy a child's desire for realism. More 
importantly, because the projectiles are soft, the guns satisfy a parent's 
desire for safety. However, the attention span of a typical child is 
relatively limited, and thus the most popular toy guns are those which 
incorporate a variety of complex, realistic, and futuristic features. 
Accordingly, there is a continuing need for increasingly complex, 
realistic, and futuristic toy guns that will enhance the toy's play value 
and that will stimulate a child's imagination. 
The toy gun according to the present invention incorporates the safety of a 
pneumatic soft foam projectile launcher with a number of complex and 
futuristic features that greatly enhance the play value of the toy. The 
gun includes a retractable sight which automatically shifts to an upright, 
operative position when the gun is cocked in preparation for firing. When 
the sight is in the operative position, a user can easily point the 
projectile towards an intended target. Once the intended target has been 
acquired, the sight automatically retracts upon firing the gun. 
According to one aspect of the invention, the toy gun includes a sliding 
housing which moves rearwardly in unison with the plunger when the gun is 
cocked, thus simulating the action of an actual semi-automatic pistol. The 
sight, which is pivotally mounted to the housing, includes a lever or tab 
which contacts a concealed actuation member when the plunger is retracted, 
thus rotating the sight to its operative position. When the gun is fired, 
a spring returns the sight to its inoperative position as the tab slides 
off the actuation member. When in the inoperative position, the sight is 
protected from breakage and the gun maintains a sleek, futuristic 
appearance. 
Accordingly, it is an object of this invention to provide an improved toy 
gun having a retractable sight. 
Another object of this invention to provide a toy gun having a sight that 
extends and retracts automatically when the gun is operated. 
A further object of this invention is to provide a toy gun having a sight 
pivotally mounted to a sliding housing that simulates the action of an 
actual weapon. 
These and other objects of the invention will become readily apparent to 
those skilled in the art upon a reading of the following description.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
The embodiment described herein is not intended to be exhaustive or to 
limit the invention to the precise form disclosed. The embodiment has been 
chosen and described in order to best explain the principles of the 
invention and its application and practical use so that others skilled in 
the art may follow its teachings. 
Referring now to the drawings, a toy air gun incorporating the features of 
the present invention is generally referred to by the reference numeral 
10. Gun 10 includes a body 12 having a handle 14 and forward and rearward 
ends 16,18, respectively. A trigger assembly 20 is disposed within body 
12, and is used to launch a cylindrical foam projectile or dart 22, shown 
in FIGS. 3 through 5, from a cylindrical launch station 24. Dart 22 fits 
within launch station 24 in a conventional manner. 
As shown in FIGS. 3 through 5, gun 10 includes a plunger 26 that is 
reciprocally disposed within a cylinder 28. Plunger 26 and cylinder 28 
cooperate to define a compression chamber 30 at the forward end 32 of 
cylinder 28. Plunger 26 includes a seal 34, and a spring 36 disposed 
within cylinder 28 and abutting seal 34 urges or biases plunger 26 towards 
the forward end 32 of cylinder 28. Compression chamber 30 includes one or 
more ports 37 which communicate gas or air in compression chamber 30 to 
launch station 24. Plunger 26 is shiftable between the uncocked forward 
position shown in FIG. 3 and the cocked rearward position shown in FIG. 5, 
in a manner commonly employed in the art. 
As shown in FIGS. 1, 2 and 6, a cover or housing 38 is slidably mounted to 
body 12 on a pair of rails 39, 41 which serve to guide housing 38 along a 
generally linear path between the uncocked forward position of FIG. 1 and 
the cocked rearward position of FIG. 2. Housing 38 includes a pair of 
sides 42, 44, an interconnecting top 46, and a rearward end 48 having a 
handle 50. Housing 38 thus conceals the plunger 26 and the cylinder 28. A 
return spring 33 biases the housing 38 towards the forward position of 
FIGS. 1 and 3. As shown in FIGS. 3-5, a ratchet or pawl assembly 47 
detachably connects the rearward end 48 of housing 38 to the rearward end 
49 of plunger 26, so that plunger 26 and housing 38 slide back in unison 
as the gun 10 is cocked. As will be explained in greater detail below, 
pawl assembly 47 permits the rearward end 49 of plunger 26 to be released 
or de-coupled from the rearward end 48 of housing 38 when the gun 10 is 
fired, which improves the firing response of the gun 10. 
A sight 52 extends through an opening 53 in the top 46 of housing 38. Sight 
52 is pivotally attached by a pivot 54 to the underside of top 46 of 
housing 38 such as by a bracket (not shown). By virtue of pivot 54, sight 
52 is pivotable between the inoperative position shown in FIGS. 1 and 3 
when the gun 10 is uncocked, and the generally upright operative position 
shown in FIGS. 2, 5 and 6-8 when the gun 10 is cocked. Sight 52 includes 
an actuation arm 58 and a spring tab 60 extending away from pivot 54. A 
tension spring 62 attached to spring tab 60 biases sight 52 towards its 
inoperative position. As can be seen in FIGS. 6 through 8, sight 52 
includes a viewfinder 70 having a central aperture 72, which is visible to 
a user when the sight is in the upright operative position. 
As shown in FIGS. 3 through 5, a protrusion 64 extends upwardly from the 
top edge 65 of body 12. Protrusion 64 includes a pair of actuating or 
camming surfaces 66, 68, each of which engages the actuation arm 58 on 
sight 52 in order to rotate the sight 52 from the folded inoperative 
position to the upright viewing position as the housing 38 is drawn 
rearwardly. It will be noted that spring tab 60 is offset laterally 
relative to protrusion 64 so as not to contact protrusion 64 as the sight 
52 rotates. Protrusion 64 is shown generally adjacent the rearward end 18 
of body 12, but could alternatively be located farther forward or rearward 
from the position shown without substantially altering the operation of 
the retractable sight 52. 
As shown in FIGS. 3 through 5, trigger assembly 20 includes a finger grip 
74 slidably mounted in body 12 on a set of rails 76, 78. Finger grip 74 
includes an arm 80 which engages a camming surface 82 on latch pin 84. 
Latch pin 84 reciprocates vertically within body 12, and is upwardly 
biased within body 12 by a spring 85. Latch pin 84 is positioned to engage 
a notch 86 generally adjacent the seal 34 of plunger 26, in order to 
maintain the plunger in the cocked position shown in FIG. 5. Rearward 
movement of finger grip 74 by a user causes arm 80 to contact camming 
surface 82 on latch pin 84, which draws latch pin 84 out of contact with 
notch 86, thus allowing spring 36 to accelerate the plunger 26 and the 
attached housing 38 in the forward direction. 
Pawl assembly 47 includes a latch member 51 which is mounted to housing 38 
by a pivot 55. A rotary spring 57 biases the latch member 51 towards the 
latched position shown in FIG. 3 (in the counterclockwise direction when 
viewing the drawings), enabling the end 59 of latch member 51 to engage a 
cutout 61 in the rearward end 49 of plunger 26. Accordingly, when the 
housing 38 is retracted in order to cock the gun 10, the end 59 of latch 
member 51 engages the cutout 61 so that the housing 38 and the plunger 26 
are drawn rearwardly in unison. When the gun 10 is fully cocked as shown 
in FIG. 5, the return spring 33 causes the housing 38 to be biased 
forwardly relative to the plunger 26. In the process, the tip 63 of 
plunger 26 cams against the underside of latch member 51, thus rotating 
the latch member in a clockwise direction against the force of the rotary 
spring 57. The end 59 of latch member 51 is thus disengaged from the 
cutout 61, and the end 49 of plunger 26 abuts a stop 65. When the gun 10 
is fired, the plunger 26 accelerates forwardly. Because of the relative 
strength of spring 36, the end 49 of plunger 26 passes the latch member 51 
before the rotary spring 57 can cause the latch member 51 to re-engage the 
cutout 61. The housing 38 is returned to the forward position by virtue of 
return spring 33. Accordingly, performance of the gun 10 is greatly 
improved because the spring 36 does not need to accelerate the mass of the 
housing 38 when the gun 10 is fired. 
In operation, when it is desired to use the gun 10 to launch a dart 22, 
user draws the housing 38 in a rearward direction relative to the body 12 
by grasping handle 50. The housing 38 is thus shifted between the uncocked 
position of FIGS. 1 and 3 towards the cocked position of FIGS. 2, 5 and 8. 
As the housing 38 is drawn rearwardly, the plunger 26 also moves 
rearwardly by virtue of pawl assembly 47. In the process, air is drawn 
drawing air into the compression chamber 30 of cylinder 28. The dart 22 is 
inserted into the launch station 24 in a conventional manner. 
As the housing 38 and plunger 26 are being drawn rearwardly, the actuation 
arm 58 of sight 52 contacts camming surface 66 of protrusion 64, thus 
beginning the rotation of sight 52 away from its inoperative position as 
shown in FIG. 5. As the rearward motion of housing 38 continues, the 
actuation arm progresses over camming surface 66 and contacts camming 
surface 68, thus completing the rotation of sight 52. The sight 52 is now 
in the upright, operative position shown in FIGS. 6-8. When the housing 38 
reaches the fully rearward or cocked position of FIG. 5, the latch pin 84 
of trigger assembly 20 engages the notch 86 in plunger 26. When the gun is 
fully cocked, the pawl assembly 47 shifts to the de-coupled position shown 
in FIG. 5. The gun 10 thus remains in the cocked position until the 
trigger assembly 20 is actuated. 
When the user desires to fire the gun, the finger grip 74 is urged 
rearwardly so that the arm 80 cams against surface 82 on latch pin 84, 
drawing latch pin 84 downwardly against the force of spring 85 until the 
latch pin 84 disengages the notch 86 in plunger 26, which thus releases 
the plunger 26. The force of spring 28 against plunger 26 accelerates the 
plunger 26 forwardly, so that air or gas within chamber 30 is compressed 
and forced through the ports 37 into launch station 24, thus ejecting the 
dart 22 from the gun 10. As shown in FIG. 9, by virtue of pawl assembly 47 
the plunger 26 is de-coupled from the housing 38. 
Shortly after the gun 10 is fired, the actuation arm 58 slides off the 
camming surfaces 68, 66 in progression as shown in FIG. 9. Accordingly, 
the sight 52 rotates back to its inoperative position aided by the force 
of spring 62. While in the inoperative position, the sight 52 is protected 
from breakage. As outlined above, the return spring 33 returns the housing 
38 to its original forward position. 
It will be appreciated that the foregoing is presented by way of 
illustration only and not by way of any limitation. It is contemplated 
that various alternatives and modifications may be made to the described 
embodiment without departing from the spirit and scope of the invention.