Trigger group for striker-fired firearms

FIELD OF THE INVENTION

The present invention relates to firearms, and more particularly to a trigger group for striker-fired firearms that fires one round upon trigger pull and another round upon trigger release while preventing the firing of a trigger release shot without having first fired a trigger pull shot.

BACKGROUND AND SUMMARY OF THE INVENTION

A trigger group for a semi-automatic firearm includes all parts of the firearm that initiate the firing of the bullet. Parts include the firing pin, which is spring-biased toward a position to strike the primer of the cartridge; a trigger, which is usually a lever that is tripped by one or more fingers of the firing hand; the sear, which holds the firing pin back until the trigger has been pulled; a connector, which acts to move the sear back into a position to retain the firing pin once it has released the firing pin to ignite the primer of a cartridge; and several springs located throughout the trigger group. The sear may be a separate part or can be a surface incorporated into the trigger. As the trigger is pulled, the sear slips, allowing the firing pin to strike the primer of a cartridge to discharge a round.

The National Firearms Act, as interpreted by the Bureau of Alcohol, Tobacco, Firearms and Explosives Technology Branch, defines the pull of a trigger as a function, and the release of the trigger as a second function. As a result, a firearm that fires a shot upon the pull of a trigger and fires a second shot upon the release of the trigger is not a machine gun as defined by the National Firearms Act, 26 U.S.C. 5845 (b), and is not subject to the associated legal restrictions.

An existing approach to a trigger system that fires one round with trigger pull and fires another round with trigger release is disclosed in U.S. Pat. Nos. 8,820,211 and 8,667,881 to Hawbaker. Hawbaker's trigger system provides one mode for normal semi-automatic operation and another mode that fires by pulling the trigger and fires a second round upon trigger release. However, Hawbaker's trigger system suffers from multiple disadvantages. First, Hawbaker requires two selectors with two positions each (a safety selector and a mode selector), with the mode selector being located on the trigger. The selector lever that is attached to the trigger must be manipulated within the trigger guard in order to change the mode of firing from semi-automatic to double fire. This attribute greatly increases the likelihood of an accidental discharge occurring from manipulating the selector lever. Second, once the trigger has been pulled in double fire mode, the user cannot place the firearm in safe mode, and instead must fire a second shot upon trigger release. In addition, Hawbaker's trigger must be pulled fully rearward or released fully forward to operate and utilizes two disconnectors.

Therefore, a need exists for a new and improved trigger group for semi-automatic firearms that prevents the firing of a trigger release shot without having first fired a trigger pull shot. In this regard, the various embodiments of the present invention substantially fulfill at least some of these needs. In this respect, the trigger group for semi-automatic firearms according to the present invention substantially departs from the conventional concepts and designs of the prior art, and in doing so provides an apparatus primarily developed for the purpose of providing a semi-automatic firearm with a trigger system that prevents the firing of a trigger release shot without having first fired a trigger pull shot.

The present invention provides an improved trigger group for striker-fired firearms, and overcomes the above-mentioned disadvantages and drawbacks of the prior art. As such, the general purpose of the present invention, which will be described subsequently in greater detail, is to provide an improved trigger group for striker-fired firearms that has all the advantages of the prior art mentioned above.

To attain this, the preferred embodiment of the present invention essentially comprises a frame defining a medial plane, a slide connected to the frame and operable to reciprocate between a forward battery position and a rearward recoil position, a barrel connected to the slide and having a forward muzzle end, a trigger assembly connected to the frame and movable between a forward trigger position and a rearward trigger position, a firing pin assembly connected to the slide and operable to reciprocate between a rearward retracted position and a forward extended position, the firing pin assembly including a retention surface, the trigger assembly including a sear surface configured to selectively engage the retention surface to releasably restrain the firing pin assembly, the firing pin assembly being responsive to the trigger assembly to release from the retracted position to the extended position in response to movement of the trigger assembly from the forward trigger position to the rearward trigger position and to release from the retracted position to the extended position in response to movement of the trigger assembly from the rearward trigger position to the forward trigger position, the trigger assembly including a retainer movable between a clear position and a blocking position, a selector movable between a first selector position and a second selector position and operably connected to the trigger assembly, a connector operably engaged to the trigger assembly and to the selector, the connector movable between a first connector position and a second connector position, the connector being responsive to the selector position to move to the first connector position when the selector is in the first selector position and to the second connector position when the selector is in the second selector position, the connector having a first trigger assembly guide surface operably engaged to the trigger assembly to move the sear surface out of engagement with the firing pin retention surface in response to a movement of the trigger assembly from the forward trigger position to the rearward trigger position, and the connector having a second trigger assembly guide surface operably engaged to the trigger assembly to move the sear surface out of engagement with the firing pin retention surface in response to a movement of the trigger assembly to the forward trigger position. There are, of course, additional features of the invention that will be described hereinafter and which will form the subject matter of the claims attached.

There has thus been outlined, rather broadly, the more important features of the invention in order that the detailed description thereof that follows may be better understood and in order that the present contribution to the art may be better appreciated.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded view of the current embodiment of a trigger group for striker-fired firearms constructed in accordance with the principles of the present invention along with additional components to form a complete pistol.

FIG. 2 is an isometric enlarged fragmentary view of the trigger connector of FIG. 1.

FIG. 3 is a top view of the trigger group for striker-fired firearms of FIG. 1 with the trigger connector in the first position for pull-fire only.

FIG. 4 is a top view of the trigger group for striker-fired firearms of FIG. 1 with the trigger connector in the second position for pull-and-release-fire.

FIG. 5 is a top view of the trigger group for striker-fired firearms of FIG. 1 with the trigger connector in the third position, which is the “disconnected” position.

FIG. 6 is a top view of the trigger bar, connector, and a cutaway portion of the selector ring of FIG. 1 showing the selector ring in the engaged position.

FIG. 7 is a top view of the trigger bar, connector, and a cutaway portion of the selector ring of FIG. 1 showing the selector ring in the disengaged position.

FIG. 8 is a rear view of the slide and selector ring of FIG. 1 with dashed lines showing the selector ring in the disengaged position.

FIG. 9 is a rear view of the slide, selector ring, trigger connector, and a cutaway portion of the trigger bar of FIG. 1 with the selector ring in the engaged position and the trigger connector in the first position for pull-fire only.

FIG. 10 is a rear view of the slide, selector ring, trigger connector, and a cutaway portion of the trigger bar of FIG. 1 with the selector ring in the engaged position and the trigger connector in the third position, which is the “disconnected” position.

FIG. 11 is a rear view of the slide, selector ring, trigger connector, and a cutaway portion of the trigger bar of FIG. 1 with the selector ring in the disengaged position and the trigger connector in the first position for pull-fire only.

FIG. 12 is a rear view of the slide, selector ring, trigger connector, and a cutaway portion of the trigger bar of FIG. 1 with the selector ring in the disengaged position and the trigger connector in the second position for pull-and-release fire.

FIG. 13 is a rear view of the slide, selector ring, trigger connector, and a cutaway portion of the trigger bar of FIG. 1 with the selector ring in the disengaged position and the trigger connector in the third position, which is the “disconnected” position.

FIG. 14 is an isometric view of the trigger bar, trigger connector, and selector ring of FIG. 1 shown when the slide is in the forward (in battery) position.

FIG. 15A is top view of the trigger group for striker-fired firearms of FIG. 1 in the cocked position, with the trigger at rest. The trigger connector is in the third position.

FIG. 15B is side view of the trigger group for striker-fired firearms of FIG. 1 in the cocked position, with the trigger at rest. The trigger connector is in the third position.

FIG. 16A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger has been pulled to the point that the rounded surface at the rear of the trigger bar is contacting the rear ramp surface of the trigger connector, and the sear of the trigger bar has been guided low enough to be at the “break” point to cause firing.

FIG. 16B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger has been pulled to the point that the rounded surface at the rear of the trigger bar is contacting the rear ramp surface of the trigger connector, and the sear of the trigger bar has been guided low enough to be at the “break” point to cause firing. The dashed circle is intended to demonstrate a cutaway of the trigger connector to enable the striker and sear interaction to be viewed.

FIG. 17A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger remains in the pulled position, while the striker moves forward to the firing position.

FIG. 17B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger remains in the pulled position, while the striker moves forward to the firing position. The dashed circle is intended to demonstrate a cutaway of the trigger connector to enable the striker and scar interaction to be viewed.

FIG. 18A is top view of the trigger group for striker-fired firearms of FIG. 1. Same as FIG. 25, but now a dashed line indicating the guide surface on the slide that interacts with the cam feature on the trigger connector is shown.

FIG. 18B is side view of the trigger group for striker-fired firearms of FIG. 1. Same as FIG. 25, but now a dashed line indicating the guide surface on the slide that interacts with the cam feature on the trigger connector is shown.

FIG. 19A is top view of the trigger group for striker-fired firearms of FIG. 1. The slide is in recoil, and the guide surface of the slide is acting upon the cam feature of the trigger connector to move the trigger connector far enough out of the path of the trigger bar to allow the trigger bar to raise up (under spring bias) to a height that will put it in line to retain the striker when the slide returns home. The trigger connector is moved to the third position.

FIG. 19B is side view of the trigger group for striker-fired firearms of FIG. 1. The slide is in recoil, and the guide surface of the slide is acting upon the cam feature of the trigger connector to move the trigger connector far enough out of the path of the trigger bar to allow the trigger bar to raise up (under spring bias) to a height that will put it in line to retain the striker when the slide returns home. The trigger connector is moved to the third position. The dashed circle is intended to demonstrate a cutaway of the trigger connector to enable the striker and sear interaction to be viewed.

FIG. 20A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger is still being held back, the slide has returned home, the striker is being retained by the sear of the trigger bar, and the trigger connector is in the third position so that it is against the side of the trigger bar, unable to cause a trigger bar dip.

FIG. 20B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger is still being held back, the slide has returned home, the striker is being retained by the sear of the trigger bar, and the trigger connector is in the third position so that it is against the side of the trigger bar, unable to cause a trigger bar dip. The dashed circle is intended to demonstrate a cutaway of the trigger connector to enable the striker and sear interaction to be viewed.

FIG. 21A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger is in the process of being “released” and is driven forward by the spring bias and has reached a position where the trigger connector has a void in its geometry that allows it to move from the third position to the second position. In this view, the trigger connector has yet to move into the second position.

FIG. 21B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger is in the process of being “released” and is driven forward by the spring bias and has reached a position where the trigger connector has a void in its geometry that allows it to move from the third position to the second position. In this view, the trigger connector has yet to move into the second position.

FIG. 22A is top view of the trigger group for striker-fired firearms of FIG. 1. The same as FIG. 30A, but the trigger connector has moved into the second position.

FIG. 22B is side view of the trigger group for striker-fired firearms of FIG. 1. The same as FIG. 30B, but the trigger connector has moved into the second position.

FIG. 23A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger has been released to the point that the trigger bar is engaged with the front ramp surface of the trigger connector, which has guided the sear of the trigger bar down to its “break” point to cause firing.

FIG. 23B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger has been released to the point that the trigger bar is engaged with the front ramp surface of the trigger connector, which has guided the sear of the trigger bar down to its “break” point to cause firing.

FIG. 24A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger remains in the released position, and the striker has been “dropped” to the firing position.

FIG. 24B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger remains in the released position, and the striker has been “dropped” to the firing position.

FIG. 25A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger remains in the released position, and the slide is in recoil to the point that the guide surface of the slide is acting upon the cam feature of the trigger connector to move the trigger connector far enough out of the path of the trigger bar to allow the trigger bar to raise up (under spring bias) to a height that will put it in line to retain the striker when the slide returns home. The trigger connector is moved to the first position.

FIG. 25B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger remains in the released position, and the slide is in recoil to the point that the guide surface of the slide is acting upon the cam feature of the trigger connector to move the trigger connector far enough out of the path of the trigger bar to allow the trigger bar to raise up (under spring bias) to a height that will put it in line to retain the striker when the slide returns home. The trigger connector is moved to the first position.

FIG. 26A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger remains in the released position, the slide has returned home, the striker is being retained by the sear of the trigger bar, and the trigger connector is in the first position.

FIG. 26B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger remains in the released position, the slide has returned home, the striker is being retained by the sear of the trigger bar, and the trigger connector is in the first position.

FIG. 27A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger is in the “pulled” position and is retaining the striker.

FIG. 27B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger is in the “pulled” position and is retaining the striker.

FIG. 28A is top view of the trigger group for striker-fired firearms of FIG. 1. The trigger is in the process of being “released” and is driven forward by the spring bias and has reached a position where the trigger connector has a void in its geometry that allows it to move from the third position to the second position. The dashed line trapezoid is meant to represent the section of the selector ring that interacts with the trigger connector. In this view, they are not engaged with each other, but in the following view set, they will be.

FIG. 28B is side view of the trigger group for striker-fired firearms of FIG. 1. The trigger is in the process of being “released” and is driven forward by the spring bias and has reached a position where the trigger connector has a void in its geometry that allows it to move from the third position to the second position.

FIG. 29A is top view of the trigger group for striker-fired firearms of FIG. 1. The same as FIG. 28A, except now the trigger connector has moved into the first position and been stopped there by the selector ring.

FIG. 29B is side view of the trigger group for striker-fired firearms of FIG. 1. The same as FIG. 28B, except now the trigger connector has moved into the first position and been stopped there by the selector ring.

FIG. 30 is a right side view of an alternative embodiment of the trigger group for striker-fired firearms constructed in accordance with the principles of the present invention with dashed lines showing a frame.

FIG. 31 is an exploded view of the trigger group for striker-fired firearms of FIG. 30.

FIG. 32A is a left side view of the trigger group for striker-fired firearms of FIG. 30 with the trigger group in the ready for trigger pull fire condition.

FIG. 32B is a right side view of FIG. 32A.

FIG. 33A is a left side view of the trigger group for striker-fired firearms of FIG. 30 showing the trigger bar having moved the firing pin rearwardly in response to the trigger being pulled. The disconnector rotates counterclockwise. In this stage, the disconnector is no longer in contact with the trigger bar, and the only mechanism preventing it from rotating further clockwise toward its engaged position is interference with the retainer.

FIG. 33B is a right side view of FIG. 32A.

FIG. 34A is a left side view of the trigger group for striker-fired firearms of FIG. 30 showing the trigger bar continuing to move the firing pin rearwardly in response to the trigger being pulled. The retainer rotates clockwise, and the connector moves into a position that aligns its opposed ramp surfaces with the lobe of the trigger bar such that either a continued pull or a reversal of trigger bar travel forward would result in the trigger bar dipping downward and releasing the firing pin, the second of those two conditions being the one that warrants a mechanism to prevent that action.

FIG. 34B is a right side view of FIG. 34A.

FIG. 35A is a left side view of the trigger group for striker-fired firearms of FIG. 30 showing the trigger bar moving forwardly in response to the trigger being released. The retainer rotates clockwise and prevents the trigger bar from continuing to move forwardly to initiate a trigger release shot.

FIG. 35B is a right side view of FIG. 35A.

FIG. 36A is a left side view of the trigger group for striker-fired firearms of FIG. 30 showing the trigger bar continuing to move the firing pin rearwardly in response to the trigger being pulled to disengage the firing pin from the trigger bar to initiate firing. The retainer rotates counterclockwise.

FIG. 36B is a right side view of FIG. 36A.

FIG. 37A is a left side view of the trigger group for striker-fired firearms of FIG. 30 showing the firing pin having released from the trigger bar to fire the host semi-automatic firearm in response to the trigger being pulled. The retainer rotates counterclockwise. The disconnector rotates counterclockwise.

FIG. 37B is a right side view of FIG. 37A.

FIG. 38A is a left side view of the trigger group for striker-fired firearms of FIG. 30 showing the slide having recoiled to reset the firing pin. The trigger bar has moved upwards, and the connector has to a position such its opposing ramp surfaces are out of alignment with the lobe of the trigger bar. The retainer rotates clockwise.

FIG. 38B is a right side view of FIG. 38A.

FIG. 39A is a left side view of the trigger group for striker-fired firearms of FIG. 30 showing the trigger bar and firing pin having moved forwardly in response to the trigger being released. The trigger bar rotates the disconnector clockwise.

FIG. 39B is a right side view of FIG. 39A.

FIG. 40A is a left side view of the trigger group for striker-fired firearms of FIG. 30 showing the trigger continuing to move forwardly in response to the trigger being released. The trigger bar has released the firing pin to fire the host semi-automatic firearm in response to the trigger being released. The trigger bar rotates the disconnector clockwise.

FIG. 40B is a right side view of FIG. 40A.

The same reference numerals refer to the same parts throughout the various figures.

DESCRIPTION OF THE CURRENT EMBODIMENT

An embodiment of the trigger group for striker-fired firearms of the present invention is shown and generally designated by the reference numeral 100.

FIG. 1 illustrates the improved trigger group for striker-fired firearms 100 of the present invention. More particularly, the trigger group for striker-fired firearms is shown forming a complete pistol 200. The complete pistol includes a striker 1, trigger bar 2, trigger 3, trigger connector 4, trigger mechanism housing 5, trigger bar plunger 6, selector ring 7, firing pin sleeve 8, selector paddle 9, frame assembly 10, slide assembly 11, trigger pin 12, trigger mechanism housing pin 13, striker body 101, striker head 102, striker retaining feature 103, sear 201, sear guiding surface 202, sear guiding side surface 203, sear trigger-engagement feature 204, trigger pin hole 301, trigger bar-engagement feature 302, trigger pad 303, trigger safety blade 304, connector cam surface 401, connector pull-shot guide surface 412, connector release-shot guide surface 410, connector step surface A 411, connector step surface B 409, connector anchor tab 406, connector inflection corner 407, trigger mechanism housing receiving slot 501, trigger mechanism housing pin hole 502, trigger mechanism housing safety slot 503, trigger mechanism housing receiving hole 504, selector ring center axis 701, selector ring connector spacer 702, selector ring paddle interface 703, selector paddle main body 901, selector paddle detent geometry 902, selector paddle selector ring interface 903, frame trigger pin hole 1001, frame trigger mechanism housing receiving feature 1002, frame trigger mechanism housing pin hole 1003, slide main body 1101, slide trigger connector guide 1102, and slide connector spacer cavity 1103. The striker, firing pin sleeve, frame assembly, slide assembly, and trigger pin are all conventional original equipment manufacturer parts. The trigger bar, trigger connector, trigger mechanism housing, trigger bar plunger, selector ring, selector paddle, and trigger mechanism housing pin are all novel parts specific to the present invention.

When assembled, the trigger 3, trigger bar 2, trigger mechanism housing 5, and trigger connector form an assembly unit that connects to the frame assembly 10 and is retained within by the trigger pin 12 and trigger mechanism housing pin 13. When assembled, the selector ring 7 and selector paddle 9 form an assembly unit that connects to the slide assembly 11 at the rear. The striker 1 is contained within the slide assembly. The striker has a striker body 101 that is cylindrical in form and runs parallel to the length of the slide assembly. The striker also has a striker head 102 that acts to detonate the cartridge primer when in the firing position. The striker also includes a striker retaining feature 103 that protrudes perpendicular to the striker body. The striker is spring-biased to the forward, striking position.

The trigger bar 2 has a sear 201 that interacts with the striker retaining feature 103 of the striker 1 to conditionally hold the striker back in the cocked position. The sear also has a sear guiding surface 202, a sear guiding side surface 203, and a sear trigger engagement feature 204. The sear guiding surface is located at the rear of the sear, nearest the striker, and the sear guiding side surface is adjacent and perpendicular to the sear guiding surface. The sear trigger engagement feature is located on the opposite end of the sear, nearest the trigger 3. The trigger bar is spring-biased so the sear is biased to the rear and top of its broadly linear path of travel.

The trigger 3 has a trigger pin hole 301, a trigger bar engagement feature 302, and a trigger pad 303. The trigger pin hole acts as a fulcrum about which the trigger may be rotated by user interaction with the trigger pad. The trigger bar engagement feature acts to operably connect the trigger and sear 201 such that, when the trigger is rotated, the trigger bar engagement feature transfers the motion to move the sear broadly linearly.

The trigger connector 4 has a connector cam surface 401, a connector pull-shot guide surface 412, a connector release-shot guide surface 410, a connector step surface A 411, a connector step surface B 409, a connector anchor tab 406, and a connector inflection corner 407. The connector cam surface governs how far the top end of the connector anchor tab can deflect from its rest position about the connector inflection corner. The connector pull-shot guide surface interacts with the sear guiding surface 203 of the sear 201 to force the sear away from engagement with the striker 1 when the sear is moved rearward upon the pull stroke of the trigger 3. The connector step surface A is adjacent to the connector pull-shot guide surface and acts to conditionally prevent the interaction of the sear guiding surface with the connector pull-shot guide surface. The connector release-shot guide surface interacts with the sear guiding surface to force the sear away from engagement with the striker when the sear is moved forward upon the release stroke of the trigger. The connector step surface B is adjacent to the connector release-shot guide surface and acts to conditionally prevent the interaction of the sear guiding surface with the connector release-shot guide surface.

The trigger mechanism housing 5 has a trigger mechanism housing receiving slot 501 and a trigger mechanism housing pin hole 502. The trigger mechanism housing receiving slot accepts the connector anchor tab 406 to provide a rigid mount for the trigger connector 4 to resist the flexing of the upper portion about the connector inflection corner 407. The trigger mechanism housing pin hole receives the trigger mechanism housing pin 13.

The selector ring 7 is comprised of a generally circular body, having two distinctly protruding features, the radially protruding feature having a connector spacer 702 feature for interaction with the trigger connector cam surface 401 to variably alter the trigger connector between position 1 and position 2. The selector ring has also an axially protruding feature having a selector ring paddle interface 703 joining the rotational position of the selector ring to the perpendicular rotational position of the selector paddle 9.

The selector paddle 9 is housed within the slide 11, protruding to the exterior to the extent that a user may rotate it between at least two positions, the positions being held by detent hole along a detent slot 902. The selector paddle is jointly connected to the selector ring 7 via a semi-spherical protrusion that follows a slot in the selector ring paddle interface 703 to transfer the rotation of the paddle to rotation of the selector ring.

The frame assembly 10 has a frame trigger pin hole 1001, a frame trigger mechanism housing receiving feature 1002, and a frame trigger mechanism housing pin hole 1003. The frame trigger pin hole receives the trigger pin 12, thereby collocating the trigger pin hole 301 of the trigger 3 to the frame trigger pin hole. The frame trigger mechanism housing receiving feature is a pocket within the frame assembly that broadly matches the shape of the negative space formed by the trigger mechanism housing 5 such that all degrees of freedom of the trigger mechanism housing are constrained when the trigger mechanism housing pin is assembled with both the frame trigger mechanism housing pin hole and the trigger mechanism housing pin hole 502.

The slide assembly 11 is constrained to move about the frame assembly 10 in a linear fashion along the length of the frame assembly with a bias toward the front of the pistol 200. The front-most position held by the slide assembly is the condition in which the slide assembly is prepared and able to fire a round, known as the in battery position.

With the selector paddle main body 901 and selector ring 7 in the binary/pull-and-release shot position, and the selector ring connector spacer 702 therefore in the disengaged position, when the user acts upon the trigger 3 in a pulling motion, the trigger transfers motion to the sear 201 via the trigger bar 2, which moves broadly linearly rearward until the trigger bar collides with the trigger connector 4. The interaction between the sear guiding surface 202 and the connector pull-shot guide surface 412 causes the sear to move less broadly linearly and rotates the rear of the sear downward as the sear continues to travel rearward. Simultaneously, the sear forces the striker 1, against the striker's spring bias, further rearward. Once the sear has moved far enough rearward and has had the rear end of sear directed sufficiently downward to clear the striker retaining feature 103, the sear releases the striker to the striker's forward striking position, which ignites the primer of the cartridge and fires a round.

As a round fires, the slide assembly 11 recoils backward and the slide trigger connector guide 1102 moves rearward with the slide assembly, which shifts the top of the trigger connector 4 about the connector inflection corner 407 as the connector cam surface 401 moves from one plane of the slide trigger connector guide to the other plane. The shifting of the trigger connector moves the connector pull-shot guide surface 410 out of the path of travel of the sear guiding surface 202, which allows the rear of the sear to return to the biased upward position. As the slide assembly moves forward on the return portion of the recoiling action, the striker retaining feature is again in line with the sear, and the striker is held rearward in the cocked position while the slide assembly continues to travel forward to the in-battery position. Simultaneously, the slide trigger connector guide returns to the original location relative to the trigger connector, and the second plane of the slide trigger connector guide no longer interacts with the trigger connector. In this condition, the trigger connector would naturally be inclined to return to the original position since the connector cam surface is no longer forcing the trigger connector to disengage from the sear. However, the sear guiding side surface 203 and the connector step surface A 411 interact to prevent this because of the heightened position of the rear portion of the sear.

With the main slide body 1101 in the in-battery position, and the trigger 3 still held back by the user, the initiation of the release shot is accomplished by the user allowing the trigger to return forward to the released position. As the trigger moves from the pulled position to the released position, the sear consequently beings moving broadly linearly forward to the point where the connector step surface A 411 clears the sear guiding side surface 203, and the trigger connector 4 springs back to the trigger connector's most natural position, placing the connector release-shot guide surface 410 in line with the path of travel of the sear guiding surface. Once the sear guiding surface contacts the connector release-shot guide surface, the sear is forced downward similar to the downward motion caused by the connector pull-shot guide surface 412, except with the sear moving forward rather than rearward. At the point that the rear portion of the sear has moved forward and downward enough for the sear to clear the striker retaining feature 103, the striker 1 moves to the forward striking position, igniting the primer of a cartridge and firing an additional round.

As the additional round fires, the slide assembly 11 recoils backward, and the slide trigger connector guide 1102 moves rearward with the slide assembly, which shifts the top of the trigger connector about the connector inflection corner 407 as the connector cam surface moves from one plane of the slide trigger connector guide to the other plane. The shifting of the trigger connector moves the connector release-shot guide surface 410 out of the path of travel of the sear guiding surface 202, which allows the rear of the sear to return to the biased upward position. As the slide assembly moves forward on the return portion of the recoiling action, the striker retaining feature 103 is again in line with the sear, and the striker 1 is held rearward in the cocked position while the slide assembly continues to travel forward to the in-battery position. Simultaneously, the slide trigger connector guide returns to the slide trigger connector guide's original location relative to the trigger connector, and the second plane of the slide trigger connector guide no longer interacts with the trigger connector. In this condition, the trigger connector would naturally be inclined to return to the original position since the slide trigger connector guide is no longer forcing the trigger connector to disengage with the sear. However, the sear guiding side surface 203 and the connector step surface B interact to prevent this because of the heightened position of the rear portion of the sear. At this point, the entire assembly has returned to the initial conditions that allowed the first pull shot to be fired, and the sequence of pull, fire, release, fire can begin again.

With the selector paddle main body 901 and selector ring 7 in the pull-shot position, and the selector ring connector spacer 702 therefore in the engaged position, a pull shot is obtained in the same manner as when the selector paddle main body and selector ring are set for two shots. When the user acts upon the trigger 3 in a pulling motion, the trigger transfers motion to the sear 201 via the trigger bar 2, which moves broadly linearly rearward until the trigger bar collides with the trigger connector 4. The interaction between the sear guiding surface 202 and the connector pull-shot guide surface 412 causes the sear to move less broadly linearly and rotates the rear of the sear downward as the sear continues to travel rearward. Simultaneously, the sear forces the striker 1, against the striker's spring bias, further rearward. Once the sear has moved far enough rearward and has had the rear end of sear directed sufficiently downward to clear the striker retaining feature 103, the sear releases the striker to the striker's forward striking position, which ignites the primer of the cartridge and fires a round.

With the main slide body 1101 in the in-battery position, and the trigger 3 still held back by the user, the differentiation of the one shot/pull-shot condition versus two shot/binary/pull-and-release shot condition occurs by the interaction of the selector ring connector spacer 702 with the trigger connector 4. As the user allows the trigger 3 to return forward toward the released position, the sear guiding side surface 203 clears the connector step surface A 411 and allows the trigger connector to spring about the connector inflection corner 407 toward the trigger connector's natural rest position. With the selector ring connector spacer in the engaged position, however, the connector cam surface 401 collides with the selector ring connector spacer, which prevents the trigger connector from springing to the position that would allow the connector release-shot guide surface 410 to be in line with the path of travel of the sear guiding surface. When the trigger and sear 201 are then moved further to their forward-most released position, the sear stays in the upward position, contacting the striker retaining feature 103 and keeping the striker 1 in the cocked position, thereby preventing a release shot from being fired. The condition of the pistol 200 at this stage is such that another pull shot sequence can be initiated all over again.

In the condition that the selector paddle main body 901 and selector ring 7 are in the binary/pull-and-release shot position, and the selector ring connector spacer 702 is therefore in the disengaged position, and the trigger 3 is held back by the user in the pulled position, a release round would be expected to be fired upon release of the trigger by the user. However, the release shot can be cancelled by switching the selector paddle main body and selector ring to the pull-shot engaged position. As the selector paddle main body and selector ring are rotated to the pull-shot engaged position, the selector ring connector spacer is forced forward between the connector cam surface 401 and the slide trigger connector guide 1102, which prevents the trigger connector from aligning the connector release-shot guide surface 410 with the path of travel of the sear guiding surface 202 of the sear 201 upon subsequent release of the trigger by the user.

The frame assembly 10 defines a medial plane 14. The slide assembly 11 is connected to the frame assembly and operable to reciprocate between a forward battery position and a rearward recoil position. A barrel 1104 is connected to the slide assembly and has a forward muzzle end 1105. The trigger group for striker-fired firearms 100 is a trigger assembly connected to the frame assembly and movable between a forward trigger position and a rearward trigger position. The striker 1 is a firing pin assembly connected to the slide assembly and operable to reciprocate between a rearward retracted position and a forward extended position. The striker retaining feature 103 is a forward-facing retention surface. The trigger bar 2 component of the trigger assembly includes a sear 201, which is a sear surface configured to selectively engage the striker retaining feature to releasably restrain the striker. A selector (selector ring 7) is movable between a first selector position and a second selector position. The trigger connector 4 is operably engaged to the trigger group for striker-fired firearms and to the selector ring. The trigger connector is movable between a first connector position and a second connector position. The trigger connector is responsive to the selector ring position to move to the first connector position when the selector ring is in the first selector position and to the second connector position when the selector ring is in the second selector position. The trigger connector has a first trigger assembly guide surface (412) operably engaged to the trigger group for striker-fired firearms to move the sear out of engagement with the striker retaining feature in response to a movement of the trigger group for striker-fired firearms from the forward trigger position to the rearward trigger position. The trigger connector having a second trigger assembly guide surface (410) operably engaged to the trigger group for striker-fired firearms to move the sear out of engagement with the striker retaining feature in response to a movement of the trigger group for striker-fired firearms to the forward trigger position.

The trigger connector 4 includes an engagement portion movable laterally toward and away from the medial plane 14 between a first lateral position closer to the medial plane and a second engagement portion farther from the medial plane. The first trigger assembly guide surface (412) and the second trigger assembly guide surface (410) face in different directions. The first trigger assembly guide surface (412) and the second trigger assembly guide surface (410) are angularly offset from each other. The first trigger assembly guide surface (412) faces forward and downward, and the second trigger assembly guide surface (410 faces rearward and downward. The first trigger assembly guide surface (412) extends laterally a first amount, and the second trigger assembly guide surface (410) extends a second amount, less than the amount of the first surface. The selector ring 7 includes a selector ring connector spacer 702, which is a lateral deviation element that is operably engaged to the trigger connector and operable when the selector ring is the first selector position to move the trigger connector to a first connector position in which only the first trigger assembly guide surface and not the second trigger assembly guide surface interacts with the trigger group for striker-fired firearms 100, and the lateral deviation element is operable when the selector ring is in the second selector position to move the trigger connector to a second connector position in which the second trigger assembly guide surface interacts with the trigger group for striker-fired firearms. The lateral deviation element is operable to move the trigger connector to a third connector position in which neither the first trigger assembly guide surface nor the second trigger assembly guide surface interacts with the trigger group for striker-fired firearms.

FIG. 2 illustrates an enlarged portion of the improved trigger connector 4 of the present invention. More particularly, the trigger connector 4 has three duty positions (the first connector position, second connector position, and third connector position). In the first connector position, the trigger connector is aligned with the trigger bar 2 to cause the sear 201 to dip down upon a trigger 3 pull, causing a “pull shot” when the trigger is pulled far enough to release the striker 1. In the second connector position, the trigger connector is aligned with the trigger bar to cause the sear to dip down upon trigger release, causing a “release shot” when the trigger is released far enough to release the striker. In the third connector position, the trigger connector is “disconnected,” where the trigger connector is positioned such that the trigger connector causes no dipping effect on the trigger, regardless of which direction the trigger is moved, thereby preventing the pistol 200 from firing another shot until the trigger has been moved sufficiently opposite the direction the trigger had been moved to induce the previous shot.

The trigger connector 4 has a cam surface 408 that engages the slide trigger connector guide 1102 on the slide assembly 11 and selectively engages the selector ring connector spacer 702. The trigger connector has a surface 409 that maintains the trigger connector in the first connector position by colliding with the side of the trigger bar 2 when the trigger bar can contact surface 409. The trigger connector has a front “ramp” 410 that engages the trigger bar and directs the trigger bar downward in response to release of the trigger 3 when the trigger connector is in the second connector position. The trigger connector has a surface 411 that maintains the trigger connector in the third connector position by colliding with the side of the trigger bar when the trigger bar cam contact surface 411. The trigger connector also has a rear “ramp” 412 that engages the trigger bar and directs the trigger bar downward in response to trigger pull when the trigger connector is in the first connector position or second connector position.

FIGS. 3-5 illustrate the three connector positions of the improved trigger connector 4 relative to the trigger bar 2. FIG. 3 illustrates the improved trigger group for striker-fired firearms 100 with the trigger connector in the first connector position. The trigger connector is positioned so that a “pull” of the trigger 3 will cause the trigger bar to be guided downward and release the striker 1 for a “pull shot.” FIG. 4 illustrates the improved trigger group for striker-fired firearms 100 with the trigger connector in the second connector position. The trigger connector is positioned so that a “release” of the trigger will cause the trigger bar to be guided downward and release the striker for a “release shot.” In this position, the user could also pull rearward, too, which would still dip the trigger bar down and have another “pull shot.” This capability does not adversely affect the legality of the firearm because multiple “functions” of the trigger are required for any shot achieved. This is because the trigger must have been released by a material amount for the trigger connector to move from the first connector position to the second connector position. FIG. 5 illustrates the improved trigger group for striker-fired firearms 100 with the trigger connector in the third connector position, which is the “disconnected” position. In this position, the trigger bar is in the upward position, either retaining the striker or being in a position to retain the striker upon making contact with the striker.

FIGS. 6 and 7 illustrate the improved trigger bar 2, trigger connector 4, and a cutaway of the selector ring 7, showing the geometry of the selector ring connector spacer 702. FIG. 6 shows the selector ring in the “engaged” position, which acts to limit the total range of motion of the trigger connector. The connector cam surface 401 of the trigger connector touches the selector ring connector spacer, which prevents the trigger connector from springing into the second connector position, thereby preventing “release fire.” FIG. 7 shows the selector ring in the “disengaged” position and the trigger connector in the second connector position. The trigger connector is allowed to move between all three of the connector positions when not otherwise prevented by colliding with the trigger bar 2.

FIG. 8 shows the slide assembly 11 and the selector ring 7, with phantom lines outlining the selector ring's “disengaged” position. FIGS. 9-10 show the slide assembly with the selector ring in the “engaged” position and the trigger connector 4 in the two connector positions that are permitted when the selector ring is in the “engaged” position (the first and third connector positions). FIG. 9 shows the trigger connector in the first connector position, limited by the selector ring, for pull-fire only and a cutaway of the trigger bar 2 for positional reference. FIG. 10 shows the trigger connector in the third connector position, limited by the slide trigger connector guide 1102, in the “disconnected” position and a cutaway of the trigger bar for positional reference.

FIGS. 11-13 are the same views as FIGS. 9-10, except that the selector ring 7 is in the “disengaged” position. So, the trigger connector 4 is shown in all three connector positions because all are allowable with the selector ring in the “disengaged” position. FIG. 11 shows the trigger connector in the first connector position for pull-fire only. FIG. 12 shows the trigger connector in the second connector position for pull-and-release fire. FIG. 13 shows the trigger connector in the third connector position, which is the “disconnected” position.

FIG. 14 shows the interactions and spacing between the trigger bar 2, trigger connector 4, and selector ring 7 when the slide assembly 11 is in the forward (in battery) position.

FIGS. 15A-26A and 15B-26B show a top view and a side view simultaneously of a full binary firing/pull-and-release firing sequence. FIGS. 15A-B show the trigger group for striker-fired firearms 100 in the “cocked” position, with the trigger 3 at rest. The trigger connector 4 is in the third connector position. FIGS. 16A-B show the trigger having been pulled to the point that the rounded surface at the rear of the trigger bar 2 (the sear guiding surface 202) contacts the rear ramp 412 of the trigger connector. The sear 201 of the trigger bar has been guided low enough to be at the “break” point to cause firing. The circular phantom line denotes a cutaway of the trigger connector to show the engagement of the striker 1 and the sear of the trigger bar. FIGS. 17A-B show the trigger remaining in the pulled position while the striker moves forward to the firing position. FIGS. 18A-B are the same as FIGS. 17A-B, except for a dashed line indicating the slide trigger connector guide 1102 on the slide assembly 11 that interacts with the cam surface 408 on the trigger connector. FIGS. 19A-B show the slide assembly in recoil. The slide trigger connector guide acts upon the cam surface on the trigger connector to move the trigger connector to the third connector position. The third connector position is located far enough out of the path of the trigger bar to allow the trigger bar to raise up (under spring bias) to a height that will put the trigger bar in line to retain the striker when the slide assembly returns home. FIGS. 20A-B show the trigger being held back, the slide assembly has returned home, the striker is being retained by the sear of the trigger bar, and the trigger connector is in the third connector position. In the third connector position, the trigger connector is positioned against the side of the trigger bar, unable to cause a trigger bar dip.

FIGS. 21A-B show the trigger 3 in the process of being “released.” The trigger is driven forward by spring bias and has reached a position where the trigger connector 4 has a void in its geometry directly between the two cam surfaces, 410 and 412 that allows the trigger connector to move from the third connector position to the second connector position. However, in FIGS. 21A-B, the trigger connector has yet to move into the second connector position. FIGS. 22A-B are the same as FIGS. 21A-B, except the trigger connector has moved into the second connector position. FIGS. 23A-B show the trigger has been released to the point that the trigger bar is engaged with the front ramp 410 of the trigger connector, which has guided the sear 201 of the trigger bar down to its “break” point to cause firing. FIG. 24A-B show the trigger remaining in the released position. The striker 1 has been “dropped” to the firing position. FIGS. 25A-B show the trigger remaining in the released position. The slide assembly 11 has recoiled to the point that the slide trigger connector guide 1102 is acting upon the cam surface 408 of the trigger connector to move the trigger connector to the first connector position. In the first connector position, the trigger connector is far enough out of the path of the trigger bar to allow the trigger bar to raise up (under spring bias) to a height that will put the trigger bar in line to retain the striker when the slide assembly returns home. FIGS. 26A-B show the trigger remaining in the released position. The slide assembly has returned home, the striker is being retained by the sear of the trigger bar, and the trigger connector is in the first connector position.

FIGS. 15A-20B are the same for semi-automatic/pull-only firing as they are for binary/pull-and-release firing. The remaining sequences of events for semi-automatic/pull-only firing are illustrated in FIGS. 27A-29B. FIGS. 27A-B show the trigger 3 in the “pulled” position where the trigger is retaining the striker 1. FIGS. 28A-B show the trigger in the process of being “released.” The trigger is driven forward by spring bias and has reached a position where the trigger connector 4 has a void in its geometry directly between the two cam surfaces, 410 and 412 that allows the trigger connector to move from the third connector position to the second connector position. Unlike FIG. 21A, FIG. 28A includes a trapezoidal dashed outline of the selector ring 7. The selector ring is positioned to prevent the trigger connector from moving to the second connector position. Instead, the trigger connector can only move to the first connector position. In FIGS. 28A-B, the trigger connector has not yet moved to contact the selector ring and stop in the first connector position. FIGS. 29A-B are the same as FIGS. 28A-B, except the trigger connector has moved into the first connector position and has been stopped there by the selector ring.

It should be appreciated that the selector ring 7 transfers user input received from the selector paddle main body 901 from the more desirable left-hand side to the right-hand side of the firearm where the trigger componentry of the pistol 200 is found, by utilizing the existing firing pin sleeve 8 as an axle, about which the selector ring rotates. Limited space in the slide main body 1101 at that location, primarily because of the size and shape of the striker retaining feature 103 and firing pin sleeve 8, makes it extremely challenging to place the selector paddle main body on the left side while getting the selection action to occur on the right side.

FIGS. 30 & 31 illustrate an alternative embodiment of the improved trigger group for striker-fired firearms 1200 of the present invention. More particularly, the alternative embodiment of the trigger group for striker-fired firearms has a frame 10 defining a medial plane 14 (shown in FIG. 1). A slide 11 is connected to the frame and operable to reciprocate between a forward battery position and a rearward recoil position. A barrel 1104 is connected to the slide and has a forward muzzle end 1105. The trigger group for striker-fired firearms 1200 is a trigger assembly including a trigger lever 3 connected to the frame and movable between a forward trigger position and a rearward trigger position. A striker 1 is a firing pin assembly connected to the slide and operable to reciprocate between a rearward retracted position and a forward extended position. The striker retaining feature 103 is a forward-facing retention surface. A trigger bar 1202 component of the trigger assembly includes a sear 1204, which is a scar surface configured to selectively engage the striker retaining feature to releasably restrain the striker. The striker is responsive to the trigger group for striker-fired firearms 1200 to release from the retracted position to the extended position in response to movement of the trigger group for striker-fired firearms 1200 from the forward trigger position to the rearward trigger position and to release from the retracted position to the extended position in response to movement of the trigger group for striker-fired firearms 1200 from the rearward trigger position to the forward trigger position. The trigger group for striker-fired firearms 1200 includes a retainer 1206 movable between a clear position enabling forward trigger assembly motion toward the forward trigger position and a blocking position preventing forward trigger assembly motion toward the forward trigger position. A disconnector 1208 has a disconnector shaft 1210 operably connected to the trigger assembly and to the retainer whereby, after discharge by moving the trigger assembly to the trigger rearward position, to prevent the retainer from blocking trigger assembly motion toward the forward trigger position. The disconnector is also operably engaged with a forward-facing portion 1212 of the trigger bar.

The retainer 1206 is operable in response to the trigger assembly to move to the blocking position in response to motion of the trigger assembly from a forward trigger position to an intermediate position between the forward trigger position and the rearward trigger position. The retainer is operable when in the blocking position to prevent movement of the trigger assembly from the intermediate position to the forward trigger position, to disable discharge of the firearm. The retainer is operable when in the blocking position to enable further movement of the trigger assembly from the intermediate position to the rearward trigger position, to enable discharge of the firearm.

A selector (selector ring 7 shown in FIG. 1) is movable between a first selector position and a second selector position. A trigger connector 1220 is operably engaged to the trigger group for striker-fired firearms 1200 and to the selector ring. The trigger connector is movable between a first connector position and a second connector position. The trigger connector is responsive to the selector ring position to move to the first connector position when the selector ring is in the first selector position and to the second connector position when the selector ring is in the second selector position. The trigger connector has a first trigger assembly guide surface 1222 operably engaged to the trigger group for striker-fired firearms to move the sear out of engagement with the striker retaining feature in response to a movement of the trigger group for striker-fired firearms from the forward trigger position to the rearward trigger position. The trigger connector has a second trigger assembly guide surface 1224 operably engaged to the trigger group for striker-fired firearms to move the sear out of engagement with the striker retaining feature in response to a movement of the trigger group for striker-fired firearms to the forward trigger position.

A spring-loaded trigger bar plunger 6 is received in an aperture 1216 defined by a trigger mechanism housing 1214. The disconnector 1208, retainer 1206, and trigger connector 1220 are all pivotally connected to the trigger mechanism housing. The trigger connector is secured to the trigger mechanism housing by a screw 1216 that passes through an aperture 1218 defined by the trigger connector 1220 and is threadedly received by an aperture 1222 defined by the trigger mechanism housing. The disconnector is mounted in a slot 1228 defined by the trigger mechanism housing. The disconnector is secured within the slot by the disconnector shaft 1210, which passes thorough apertures 1224 and 1226 defined by the trigger mechanism housing and aperture 1230 defined by the disconnector. The retainer has a protrusion 1232 received by an aperture 1234 defined by the trigger mechanism housing and a protrusion 1236 received by a groove 1238 defined by the trigger mechanism housing. A retainer spring 1240 is also received by the groove and biases the retainer in a clockwise direction. The retainer has a greater range of motion when the disconnector is disengaged and the crescent geometry 1242 defined by one end of the disconnector shaft switches from a position of interference to a position of clearance. A spring 1244 biases the disconnector counterclockwise. The forward-facing portion 1212 of the trigger bar 1202 pushes the disconnector all the way down during the “pull” shot, giving the disconnector clearance to rotate into its “engaged” position.

FIGS. 32A & B illustrate the alternative embodiment of the improved trigger group for semi-automatic firearms 1200 of the present invention. More particularly, the trigger group is shown in the ready for trigger pull fire condition.

FIGS. 33A & B illustrate the alternative embodiment of the improved trigger group for semi-automatic firearms 1200 of the present invention. More particularly, the trigger bar 1202 has moved the striker 1 rearwardly in response to the trigger 3 being pulled. The disconnector 1208 has rotated counterclockwise. In this stage, the disconnector is no longer in contact with the trigger bar, and the only mechanism preventing the disconnector from rotating further clockwise toward its engaged position is interference with the retainer 1206.

FIGS. 34A & B illustrate the alternative embodiment of the improved trigger group for semi-automatic firearms 1200 of the present invention. More particularly, the trigger bar 1202 has continued to move the striker 1 rearwardly in response to the trigger 3 being pulled. The retainer 1206 rotates clockwise, and the trigger connector 1220 has moved into a position that aligns its opposed ramp surfaces 1222, 1224 with the lobe 1246 of the trigger bar such that either a continued pull or a reversal of trigger bar travel forward would result in the trigger bar dipping downward and releasing the striker, the second of those two conditions being the one that warrants a mechanism to prevent that action.

FIGS. 35A & B illustrate the alternative embodiment of the improved trigger group for semi-automatic firearms 1200 of the present invention. More particularly, the trigger bar 1202 has moved forwardly in response to the trigger 3 being released. The retainer 1206 has rotated clockwise and prevented the trigger bar from continuing to move forwardly to initiate a trigger release shot.

FIGS. 36A & B illustrate the alternative embodiment of the improved trigger group for semi-automatic firearms 1200 of the present invention. More particularly, the trigger bar 1202 has continued to move the striker 1 rearwardly in response to the trigger 3 being pulled to disengage the striker from the sear 1204 on the trigger bar to initiate firing. The retainer 1206 has rotated counterclockwise.

FIGS. 37A & B illustrate the alternative embodiment of the improved trigger group for semi-automatic firearms 1200 of the present invention. More particularly, the striker 1 has been released from the trigger bar 1202 to fire the host semi-automatic firearm in response to the trigger 3 being pulled. The retainer 1206 has rotated counterclockwise. The disconnector 1208 has rotated counterclockwise.

FIGS. 38A & B illustrate the alternative embodiment of the improved trigger group for semi-automatic firearms 1200 of the present invention. More particularly, the slide 11 has recoiled to reset the striker 1. The trigger bar 1202 has moved upwards, and the trigger connector 1220 has moved to a position such its opposing ramp surfaces 1222, 1224 are out of alignment with the lobe 1246 of the trigger bar. The retainer 1206 has rotated clockwise.

FIGS. 39A & B illustrate the alternative embodiment of the improved trigger group for semi-automatic firearms 1200 of the present invention. More particularly, the trigger bar 1202 and striker 1 have continued to move forwardly in response to the trigger 3 being released. The trigger bar has rotated the disconnector 1208 clockwise.

FIGS. 40A & B illustrate the alternative embodiment of the improved trigger group for semi-automatic firearms 1200 of the present invention. More particularly, the trigger 3 has continued to move forwardly in response to the trigger being released. The trigger bar 1202 has released the striker 1 to fire the host semi-automatic firearm in response to the trigger being released. The trigger bar has rotated the disconnector 1208 clockwise. The retainer 1206 has rotated counterclockwise. Subsequently, the slide 11 recoils to reset the firing pin, the trigger bar moves upwards and forwards, the trigger bar rotates the disconnector clockwise, and the retainer rotates clockwise to return the trigger group to the condition shown in FIGS. 32A & B.

It should be appreciated that the purpose the trigger group for semi-automatic firearms 1200 serves is to prevent the user from being able to fire a trigger release shot without first having fired a trigger pull shot. It is the nature of a trigger system that has opposing ramp surfaces 1222, 1224 that, when the sear 1204 has moved far enough rearward to be positioned between both ramps, nothing will prevent the user from forcing the sear down the rear ramp versus the front ramp, even if the user may not expect the sear to go down the front ramp when the direction of trigger travel is switched. The retainer 1206 pops up because of spring 1240 to serve as a blocker to stop the sear from moving back forward once the sear hits the middle point between the opposing ramp surfaces unless the sear is pulled so far back that the retainer is held down and out of the way to enable the sear's return trip forward. The disconnector 1208 accomplishes the holding down of the retainer.

In the context of the specification, the terms “rear” and “rearward,” and “front” and “forward” have the following definitions: “rear” or “rearward” means in the direction away from the muzzle of the firearm while “front” or “forward” means it is in the direction towards the muzzle of the firearm. In the context of the specification, the terms “clockwise” and “counterclockwise” have the following definitions: “clockwise” means in the direction in which the hands of a clock rotate as viewed from in front or as if standing on a clock face when the trigger group for semi-automatic firearms is viewed from the right side while “counterclockwise” means in a direction opposite to that in which the hands of a clock rotate as viewed from in front when the trigger group for semi-automatic firearms is viewed from the right side.

While a current embodiment of a trigger group for striker-fired firearms has been described in detail, it should be apparent that modifications and variations thereto are possible, all of which fall within the true spirit and scope of the invention. With respect to the above description then, it is to be realized that the optimum dimensional relationships for the parts of the invention, to include variations in size, materials, shape, form, function and manner of operation, assembly and use, are deemed readily apparent and obvious to one skilled in the art, and all equivalent relationships to those illustrated in the drawings and described in the specification are intended to be encompassed by the present invention.

Therefore, the foregoing is considered as illustrative only of the principles of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation shown and described, and accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the invention.

Number	Name	Date	Kind
8667881	Hawbaker	Mar 2014	B1
8820211	Hawbaker	Sep 2014	B1
11644261	Fellows	May 2023	B2
11828552	Stojaković	Nov 2023	B1
20240200895	Geissele	Jun 2024	A1

	Number	Date	Country
	63413345	Oct 2022	US
	63188820	May 2021	US

	Number	Date	Country
Parent	17577096	Jan 2022	US
Child	18127493		US

Trigger group for striker-fired firearms

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