1. Technical Field
The present disclosure generally relates to firearms. More specifically, the present disclosure relates to a bolt assembly and bolt carrier assembly with switch mechanism that enables discharging of spent bullet casings from either the left side or the right side of the rifle receiver without the need of disassembling the firearm.
2. Description of Related Art
Presently there are several approaches that enable firearms to discharge spent bullet casings, or cartridges, from either of both sides of the firearm. However, there are one or more shortcomings associated with each of these approaches, including the need to disassemble the firearm for reconfiguration to enable the discharging of spent casings from one side of the firearm to the other.
A first approach, described in Swiss Patent No. CH580269A, relates to a bullpup rifle designed for the purpose of discharging spent casings from either of both sides of the firearm. This approach uses a multi-lug rotating bolt design. Although this approach allows the change of direction out of which spent casings are discharged, disassembling of the firearm is necessary to reconfigure the firearm to enable the discharging of spent casings from one side of the firearm to the other.
A second approach, described in U.S. Pat. No. 7,331,135B2, relates to a bullpup rifle designed for the purpose of discharging spent casings from either of both sides of the firearm. Similarly, this approach uses a multi-lug rotating bolt design. Although this approach allows the change of direction out of which spent casings are discharged, disassembling of the firearm is necessary to reconfigure the firearm to enable the discharging of spent casings from one side of the firearm to the other.
A third approach, described in U.S. Pat. No. 5,675,924, relates to a bullpup rifle designed for the purpose of discharging spent casings to the front of the firearm. Accordingly, this approach does not require any adjustment of the firearm when an operator changes from left-hand firing to right-hand firing of the firearm, and vice versa. This may be preferable to other designs from the perspective of ease for the operator's selection and changing of the firing hand. However, such design tends to retain some spent casings inside the firearm, thereby introducing higher possibility of jamming the firearm. Furthermore, as this design has less open port on the firearm receiver, when jamming does occur it is very difficult for the operator to access the jammed casing and clear the jam.
A fourth approach, described in U.S. Pat. Nos. 7,849,777, 7,819,052 and 7,395,626 and U.S. Patent Application Publication No. 20100300278, relates to a conventional rifle design with a stock. This approach allows spent casings to be discharged from either the left side or the right side of the firearm by the operator pushing a switch mechanism located inside the firearm with a tool. No disassembling of the rifle is necessary. The tool may be a screw driver or a rifle ammo cartridge, for example. However, those tools are not necessarily installed on the firearm. This approach uses a multi-lug rotating bolt design and tends to have quite an amount of material at the bolt head machined away to allow switching of the discharging side to be possible. Therefore, the bolt head strength may be unnecessarily weakened.
A fifth approach, described in U.S. Pat. No. 3,882,625, relates to a bullpup rifle designed for the purpose of discharging spent casings from either of both sides of the firearm. This approach uses a multi-lug rotating design. However, although the direction in which spent casings are discharged can be switched, disassembling of the firearm is necessary.
The standard AR15 design includes a bolt assembly and a bolt carrier assembly with the bolt assembly disposed inside the bolt carrier assembly.
The AR15 bolt assembly 10, looking in the direction from head to tail, is like a gear with eight square teeth. On the extractor slot where the extractor 12 is resided, one tooth is missing from the bolt body. However, the reinforcement lug 15 on the extractor 12 is positioned at the location of the missing locking lug, with somewhat shortened height. Hence, with necessary enhanced design, it is possible to use another gear-shaped piece to turn the bolt assembly according to its axis to change the ejection direction of the spent bullet casing.
However, standard AR15 can only allow spent casings to eject from the right side of the rifle. This is due to the fact that the cam pin hole 11 is restricted by the cam pin (not shown) sliding inside a groove on the upper receiver (not shown) of the rifle. Some custom made AR15 can be made to only allow the spent casing to eject from the left side of the rifle. Interchanging the ejection direction on such rifle, however, is not possible.
The present disclosure is directed to a bolt and bolt carrier assembly with switch mechanism that enables discharging of spent bullet casings from either the left side or the right side of the rifle receiver without the need of disassembling the firearm.
According to one aspect, a bolt assembly for use in a firearm that is capable of selectively ejecting a spent casing in either a first ejection direction or a second ejection direction is provided. The bolt assembly may comprise: a bolt front half piece capable of extracting and ejecting the spent casing; a bolt rear half piece configured to mate with the bolt front half piece; an elastic body received in the bolt rear half piece; and a bolt interlock received in the bolt rear half piece and movable longitudinally with respect to the bolt rear half piece. When the bolt front half piece and the bolt rear half piece are mated together the elastic body may be disposed between the bolt interlock and the bolt rear half piece. When the bolt interlock is in a first bolt interlock position, the bolt front half piece may be interlocked axially with respect to the bolt rear half piece by the bolt interlock to eject the spent casing in the first ejection direction. When the bolt interlock is in a second bolt interlock position, the bolt front half piece may be rotatable axially with respect to the bolt rear half piece to eject the spent casing in the second ejection direction which is different from the first ejection direction.
In some embodiments, when in the second bolt interlock position, the bolt interlock functions as a disposition safety to distance a firing pin of the firearm away from an ammunition primer in an event the bolt assembly is in a battery position with a barrel extension of the firearm.
In some embodiments, the bolt front half piece may further comprise: a bolt head defined at a first end of the bolt front half piece; a plurality of position lugs defined at a second end of the bolt front half piece opposite the first end; and a raised shoulder circling a circumference of the bolt front half piece and defined between the extractor slot and the position lugs.
In some embodiments, the bolt interlock may comprise a body and a plurality of interlocking lugs at the first end of the body with a plurality of grooves defined therebetween. The body may be generally cylindrical in shape and may have a first end and a second end opposite the first end. The first end may be in contact with the bolt front half piece when the bolt interlock is in the first bolt interlock position. The grooves between the interlocking lugs may receive the position lugs of the bolt front half piece to interlock the bolt front half piece axially with respect to the bolt rear half piece when the bolt interlock is in the first bolt interlock position.
In some embodiments, the bolt rear half piece may be generally cylindrical in shape and hollow. A first end of the bolt rear half piece that mates with the bolt front half piece may have an opening that receives the bolt interlock. The bolt rear half piece may have a plurality of longitudinal openings extending from the opening at the first end toward a second end opposite the first end for a portion of a length of the bolt rear half piece so that the interlocking lugs of the bolt interlock slide in the longitudinal openings when the bolt interlock move between the first bolt interlock position and the second bolt interlock position.
In some embodiments, the bolt front half piece may comprise three position lugs, and the bolt interlock may comprise three interlocking lugs.
In some embodiments, the elastic body may comprise a spring.
According to another aspect, a bolt and bolt carrier assembly for use in a firearm that is capable of selectively ejecting a spent casing in either a first ejection direction or a second ejection direction is provided. The bolt and bolt carrier assembly may comprise a bolt assembly and a bolt carrier assembly in which the bolt assembly is received. The bolt assembly may comprise: a bolt front half piece having an extractor slot through which the spent casing is ejected; a bolt rear half piece configured to mate with the bolt front half piece; an elastic body received in the bolt rear half piece; and a bolt interlock received in the bolt rear half piece with the elastic body disposed between the bolt interlock and the bolt rear half piece. The bolt interlock may be movable longitudinally with respect to the bolt rear half piece. The bolt carrier assembly may be configured such that the bolt assembly is movable axially and longitudinally with respect to the bolt carrier assembly between a first bolt assembly position and a second bolt assembly position to allow firing of the firearm when the bolt assembly is in the second bolt assembly position.
In some embodiments, when the bolt interlock is in a first bolt interlock position, the bolt front half piece may be interlocked axially with respect to the bolt rear half piece by the bolt interlock with the extractor slot pointing in the first ejection direction. Further, when the bolt interlock is in a second bolt interlock position, the bolt front half piece may be rotatable axially with respect to the bolt rear half piece so that the extractor slot can point in the second ejection direction which is different from the first ejection direction.
In some embodiments, the bolt front half piece may further comprise: a bolt head defined at a first end of the bolt front half piece; a plurality of position lugs defined at a second end of the bolt front half piece opposite the first end; and a raised shoulder circling a circumference of the bolt front half piece and defined between the extractor slot and the position lugs.
In some embodiments, the bolt interlock may comprise a body and a plurality of interlocking lugs at the first end of the body with a plurality of grooves defined therebetween. The body may be generally cylindrical in shape and may have a first end and a second end opposite the first end. The first end may be in contact with the bolt front half piece when the bolt interlock is in the first bolt interlock position. The grooves between the interlocking lugs may receive the position lugs of the bolt front half piece to interlock the bolt front half piece axially with respect to the bolt rear half piece when the bolt interlock is in the first bolt interlock position.
In some embodiments, the bolt rear half piece may be generally cylindrical in shape and hollow. A first end of the bolt rear half piece that mates with the bolt front half piece may have an opening that receives the bolt interlock. The bolt rear half piece may have a plurality of longitudinal openings extending from the opening at the first end toward a second end opposite the first end for a portion of a length of the bolt rear half piece so that the interlocking lugs of the bolt interlock slide in the longitudinal openings when the bolt interlock move between the first bolt interlock position and the second bolt interlock position.
In some embodiments, the bolt front half piece may comprise three position lugs, and the bolt interlock may comprise three interlocking lugs.
In some embodiments, the elastic body may comprise a spring.
In some embodiments, the bolt carrier assembly may comprise: a bolt carrier, a cam pin, a bolt interlock push pin, a firing pin, and a firing pin retaining pin. The bolt carrier may have a bolt hole in which the bolt assembly is received. The bolt carrier may further have a cam groove and a clearance groove defined therein such that the cam groove and the clearance groove connect the bolt hole and an outer circumferential surface of the bolt carrier. The cam pin may be movably received in the cam groove of the bolt carrier. The bolt interlock push pin may be movably received in the clearance groove of the bolt carrier. The cam groove and the clearance groove may be shaped such that the cam pin and the bolt interlock push pin can move axially and longitudinally with respect to the bolt carrier when the cam pin and the bolt interlock push pin are received in the cam groove and the clearance groove, respectively.
In some embodiments, the bolt rear half piece may further include a cam pin hole in which the cam pin, received in the cam groove of the bolt carrier, is inserted. The cam pin may include a clearance hole that receives the bolt interlock when the cam pin is inserted in the cam pin hole of the bolt rear half piece through the cam groove of the bolt carrier. The bolt interlock may further include a bolt interlock push pin hole in which the bolt interlock push pin, received in the clearance groove of the bolt carrier, is inserted.
In some embodiments, the bolt carrier assembly may further comprise a firing pin. The bolt interlock push pin may include a clearance hole that receives the firing pin when the bolt interlock push pin is inserted in the bolt interlock push pin hole of the bolt interlock through the clearance groove of the bolt carrier.
According to still another aspect, a firearm capable of selectively ejecting a spent casing in either a first ejection direction or a second ejection direction is provided. The firearm may comprise a bolt assembly, a bolt carrier assembly in which the bolt assembly is received, and a switch mechanism. The bolt assembly may comprise: a bolt front half piece having an extractor slot through which the spent casing is ejected; a bolt rear half piece configured to mate with the bolt front half piece; an elastic body received in the bolt rear half piece; and a bolt interlock received in the bolt rear half piece with the elastic body disposed between the bolt interlock and the bolt rear half piece, the bolt interlock movable longitudinally with respect to the bolt rear half piece. The bolt carrier assembly may be configured such that the bolt assembly is movable axially and longitudinally with respect to the bolt carrier assembly between a first bolt assembly position and a second bolt assembly position to allow firing of the firearm when the bolt assembly is in the second bolt assembly position. The switch mechanism may be coupled to rotate the bolt front half piece axially with respect to the bolt carrier assembly.
In some embodiments, when the bolt interlock is in a first bolt interlock position, the bolt front half piece may be interlocked axially with respect to the bolt rear half piece by the bolt interlock with the extractor slot pointing in the first ejection direction. Moreover, when the bolt interlock is in a second bolt interlock position, the bolt front half piece may be rotatable axially with respect to the bolt rear half piece so that the extractor slot can point in the second ejection direction which is different from the first ejection direction.
In some embodiments, the bolt front half piece may further comprise: a bolt head defined at a first end of the bolt front half piece; a plurality of position lugs defined at a second end of the bolt front half piece opposite the first end; and a raised shoulder circling a circumference of the bolt front half piece and defined between the extractor slot and the position lugs.
In some embodiments, the bolt interlock may comprise a body and a plurality of interlocking lugs at the first end of the body with a plurality of grooves defined therebetween. The body may be generally cylindrical in shape and may have a first end and a second end opposite the first end. The first end may be in contact with the bolt front half piece when the bolt interlock is in the first bolt interlock position. The grooves between the interlocking lugs may receive the position lugs of the bolt front half piece to interlock the bolt front half piece axially with respect to the bolt rear half piece when the bolt interlock is in the first bolt interlock position.
In some embodiments, the bolt rear half piece may be generally cylindrical in shape and hollow. A first end of the bolt rear half piece that mates with the bolt front half piece may have an opening that receives the bolt interlock. The bolt rear half piece may have a plurality of longitudinal openings extending from the opening at the first end toward a second end opposite the first end for a portion of a length of the bolt rear half piece so that the interlocking lugs of the bolt interlock slide in the longitudinal openings when the bolt interlock move between the first bolt interlock position and the second bolt interlock position.
In some embodiments, the bolt front half piece may comprise three position lugs, and the bolt interlock may comprise three interlocking lugs.
In some embodiments, the elastic body may comprise a spring.
In some embodiments, the bolt carrier assembly may comprise: a bolt carrier, a cam pin, a bolt interlock push pin, a firing pin, and a firing pin retaining pin. The bolt carrier may have a bolt hole in which the bolt assembly is received. The bolt carrier may further have a cam groove and a clearance groove defined therein such that the cam groove and the clearance groove connect the bolt hole and an outer circumferential surface of the bolt carrier. The cam pin may be movably received in the cam groove of the bolt carrier. The bolt interlock push pin may be movably received in the clearance groove of the bolt carrier. The cam groove and the clearance groove may be shaped such that the cam pin and the bolt interlock push pin can move axially and longitudinally with respect to the bolt carrier when the cam pin and the bolt interlock push pin are received in the cam groove and the clearance groove, respectively.
In some embodiments, the bolt rear half piece may further include a cam pin hole in which the cam pin, received in the cam groove of the bolt carrier, is inserted. The cam pin may include a clearance hole that receives the bolt interlock when the cam pin is inserted in the cam pin hole of the bolt rear half piece through the cam groove of the bolt carrier. The bolt interlock may further include a bolt interlock push pin hole in which the bolt interlock push pin, received in the clearance groove of the bolt carrier, is inserted.
In some embodiments, the bolt carrier assembly may further comprise a firing pin. The bolt interlock push pin may include a clearance hole that receives the firing pin when the bolt interlock push pin is inserted in the bolt interlock push pin hole of the bolt interlock through the clearance groove of the bolt carrier.
In some embodiments, the switch mechanism may comprise: an upper receiver; a bolt gear configured to be engaged to the bolt front half piece to rotate the bolt front half piece axially with respect to the bolt carrier assembly; and a first cheekpiece bracket to which the bolt gear is attached. The first cheekpiece bracket may have two retention holes. The first cheekpiece bracket may be rotatably coupled to the upper receiver such that, when the bolt gear and the bolt front half piece are engaged, by turning the first cheekpiece bracket, the bolt gear turns the bolt front half piece to point the extractor in a direction between the first ejection direction and the second ejection direction.
In some embodiments, the switch mechanism may further comprise a second cheekpiece bracket, a switch rod, a first switch block, a second switch block, and a switch slide. The second cheekpiece bracket may be rotatably coupled to the upper receiver. The second cheekpiece bracket may have two retention holes. The switch rod may be coupled to move longitudinally with respect to the firearm over the upper receiver. The first switch block may be coupled to the switch rod and may have two locking pins. The second switch block may be coupled to the switch rod and may have two locking pins. The switch slide may be coupled to the switch rod to move longitudinally with respect to the firearm between a first switch slide position and a second switch slide position. When the switch slide is in the first switch slide position, one of the locking pins of the first switch block and one of the locking pins of the second switch block on the same side may be respectively inserted in the respective one of the retention holes of the first cheekpiece bracket and the second cheekpiece bracket, as well as the correspondent retention holes on the upper receiver, to lock the first and second cheekpiece brackets with the upper receiver. When the switch slide is in the second switch slide position, the active locking pin of the first switch block and the active locking pin of the second switch block may be pulled out of the respective one of the retention holes of the first cheekpiece bracket and the second cheekpiece bracket, as well as the respective retention holes on the upper receiver, to allow the first cheekpiece bracket and the second cheekpiece bracket to rotate.
These and other objectives of the present disclosure will be appreciated by those of ordinary skill in the art after reading the following detailed description of the preferred embodiments that are illustrated in the various figures and drawings.
The accompanying drawings are included to provide a further understanding of the disclosure, and are incorporated in and constitute a part of the present disclosure. The drawings illustrate embodiments of the disclosure and, together with the description, serve to explain the principles of the disclosure. It is appreciable that the drawings are not necessarily in scale as some components may be shown to be out of proportion than the size in actual implementation in order to clearly illustrate the concept of the present disclosure.
Various embodiments of the present disclosure relate to a bolt and bolt carrier assembly with switch mechanism that enables discharging of spent bullet casings from either the left side or the right side of the rifle receiver without the need of disassembling the firearm. As the design has one ejection ports on each side of the firearm, it is easier for an operator to access a jammed casing to clear it compared to existing designs.
Examples provided in the present disclosure are based on the standard AR15 barrel extension and bolt head design, which have been used in the U.S. and numerous other countries for more than 40 years and hence battle proven. The AR15 is one of the most popular rifles in the civilian market, and spare parts are relatively easier to find. Nevertheless, those ordinarily skilled in the art would appreciate the applicability of the present disclosure in firearms other than the AR15. In other words, the scope of the present disclosure is not limited to AR15 but, rather, extends to any presently available firearm and any firearm conceived in the future in which the concept of the present disclosure can be implemented.
Reference will now be made in detail to the preferred embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the description to refer to the same or like parts.
The position terms used in the present disclosure, such as “front”, “forward”, “rear”, “back”, “top”, “bottom”, “left”, “right”, “head”, “tail” or the like assume a firearm in the normal firing position, with the firearm being in a position in which the longitudinal axis of the barrel of the firearm runs generally horizontally and the direction of firing points “forward” away from the operator of the firearm. The same convention applies for the direction statements used herein.
According to various embodiments, a bolt assembly for use in a firearm that is capable of selectively ejecting a spent casing in either a first ejection direction or a second ejection direction is provided. The bolt assembly may comprise: a bolt front half piece capable of extracting and ejecting the spent casing; a bolt rear half piece configured to mate with the bolt front half piece; an elastic body received in the bolt rear half piece; and a bolt interlock received in the bolt rear half piece and movable longitudinally with respect to the bolt rear half piece. When the bolt front half piece and the bolt rear half piece are mated together the elastic body may be disposed between the bolt interlock and the bolt rear half piece. When the bolt interlock is in a first bolt interlock position, the bolt front half piece may be interlocked axially with respect to the bolt rear half piece by the bolt interlock to eject the spent casing in the first ejection direction. When the bolt interlock is in a second bolt interlock position, the bolt front half piece may be rotatable axially with respect to the bolt rear half piece to eject the spent casing in the second ejection direction which is different from the first ejection direction.
In some embodiments, when in the second bolt interlock position, the bolt interlock functions as a disposition safety to distance a firing pin of the firearm away from an ammunition primer in an event the bolt assembly is in a battery position with a barrel extension of the firearm.
In some embodiments, the bolt front half piece further comprises a bolt head, a plurality of position lugs, and a raised shoulder. The bolt head is defined at a first end of the bolt front half piece. The position lugs are defined at a second end of the bolt front half piece opposite the first end. The raised shoulder circles a circumference of the bolt front half piece and is defined between the extractor slot and the position lugs.
In some embodiments, the bolt interlock comprises a body and a plurality of interlocking lugs at the first end of the body with a plurality of grooves defined therebetween. The body is generally cylindrical in shape and has a first end and a second end opposite the first end. The first end of the body is in contact with the bolt front half piece when the bolt interlock is in the first bolt interlock position. The grooves between the interlocking lugs receive the position lugs of the bolt front half piece to interlock the bolt front half piece axially with respect to the bolt rear half piece when the bolt interlock is in the first bolt interlock position.
In some embodiments, the bolt rear half piece is generally cylindrical in shape and hollow. A first end of the bolt rear half piece that mates with the bolt front half piece has an opening that receives the bolt interlock. The bolt rear half piece has a plurality of longitudinal openings extending from the opening at the first end toward a second end opposite the first end for a portion of a length of the bolt rear half piece so that the interlocking lugs of the bolt interlock slide in the longitudinal openings when the bolt interlock move between the first bolt interlock position and the second bolt interlock position.
In some embodiments, the bolt front half piece comprises three position lugs, and the bolt interlock may comprise three interlocking lugs.
In some embodiments, the elastic body comprises a spring.
In the embodiment illustrated in
A first end of the bolt rear half piece 108 that mates with the bolt front half piece 104 has an opening that receives the bolt interlock 106. The bolt rear half piece 108 three longitudinal openings 112 extending from the opening at the first end toward a second end opposite the first end for a portion of a length of the bolt rear half piece 108 so that the interlocking lugs 111 of the bolt interlock 106 slide in the longitudinal openings 112 when the bolt interlock 106 move between a first bolt interlock position and a second bolt interlock position. The circumferential grooves 153 on the bolt rear half piece 108 receive the position lugs 110 on the bolt front half piece 104, so that the bolt front half piece 104 will not move relative to the bolt rear half piece longitudinally.
In the example illustrated in
The bolt interlock 106 is designed to have a generally cylindrical shape. It has the same number of locking lugs 111 and associated grooves 151 as the position lugs 110 and the associated grooves 157 on the bolt front half piece 104. When the bolt front half piece 104 is in the position shown in
The bolt rear half piece 108 is designed to have a generally cylindrical shape. On one of the bolt rear half piece 108, longitudinal openings 112 in the bolt rear half piece 108 allow the locking lugs 111 to slide therein, and thereby allowing the bolt interlock 106 to slide longitudinally inside the bolt rear half piece 108. The bolt rear half piece 108 also has circumferential grooves 153 that receive the position lugs 110 of the bolt front half piece 104 such that the bolt front half piece 104 can turn co-axially with the bolt rear half piece 108 but cannot move longitudinally with the bolt rear half piece 108 if the bolt front half piece 104 is not in the assemble/disassemble position as shown in
As shown in
In
According to another aspect, a bolt and bolt carrier assembly for use in a firearm that is capable of selectively ejecting a spent casing in either a first ejection direction or a second ejection direction comprises a bolt assembly and a bolt carrier assembly in which the bolt assembly is received. The bolt assembly comprises: a bolt front half piece having an extractor slot through which the spent casing is ejected; a bolt rear half piece configured to mate with the bolt front half piece; an elastic body received in the bolt rear half piece; and a bolt interlock received in the bolt rear half piece with the elastic body disposed between the bolt interlock and the bolt rear half piece. The bolt interlock is movable longitudinally with respect to the bolt rear half piece. The bolt carrier assembly is configured such that the bolt assembly is movable axially and longitudinally with respect to the bolt carrier assembly between a first bolt assembly position and a second bolt assembly position to allow firing of the firearm when the bolt assembly is in the second bolt assembly position.
In some embodiments, the bolt carrier assembly comprises a bolt carrier, a cam pin, a firing pin, a firing pin retaining pin and a bolt interlock push pin. The bolt carrier includes a bolt hole in which the bolt assembly is received. The bolt carrier further includes a cam groove and a clearance groove defined therein such that the cam groove and the clearance groove connect the bolt hole and an outer circumferential surface of the bolt carrier. The cam pin is movably received in the cam groove of the bolt carrier. The bolt interlock push pin is movably received in the clearance groove of the bolt carrier. The cam groove and the clearance groove are shaped such that the cam pin and the bolt interlock push pin can move axially and longitudinally with respect to the bolt carrier when the cam pin and the bolt interlock push pin are received in the cam groove and the clearance groove, respectively.
In some embodiments, the bolt rear half piece further includes a cam pin hole in which the cam pin, received in the cam groove of the bolt carrier, is inserted. The cam pin includes a clearance hole that receives the bolt interlock when the cam pin is inserted in the cam pin hole of the bolt rear half piece through the cam groove of the bolt carrier. The bolt interlock further includes a bolt interlock push pin hole in which the bolt interlock push pin, received in the clearance groove of the bolt carrier, is inserted.
In some embodiments, the bolt carrier assembly further comprises a firing pin. The bolt interlock push pin includes a clearance hole that receives the firing pin when the bolt interlock push pin is inserted in the bolt interlock push pin hole of the bolt interlock through the clearance groove of the bolt carrier.
The bolt assembly 100 is received inside the bolt hole 122 of the bolt carrier 150 and secured by the cam pin 116. On the front end of the bolt carrier 150, there is a clearance cut 161 to accept the bolt gear 130 in the switch mechanism 300, when the bolt assembly 100 is in the locking position with the barrel extension 20. When the bolt head 103 of the bolt assembly 100 rams into the breech surface (not shown) of the barrel extension 20, under the force of the main spring 142, the force of the main spring 142 and the momentum of the bolt carrier assembly 200 will keep the bolt carrier assembly 200 move forward. The cam pin 116 will be forced to rotate, or turn, clockwise as shown in
According to various embodiments, a firearm capable of selectively ejecting a spent casing in either a first ejection direction or a second ejection direction comprises a bolt assembly, a bolt carrier assembly in which the bolt assembly is received, and a switch mechanism. The bolt assembly comprises: a bolt front half piece having an extractor slot through which the spent casing is ejected; a bolt rear half piece configured to mate with the bolt front half piece; an elastic body received in the bolt rear half piece; and a bolt interlock received in the bolt rear half piece with the elastic body disposed between the bolt interlock and the bolt rear half piece, the bolt interlock movable longitudinally with respect to the bolt rear half piece. The bolt carrier assembly is configured such that the bolt assembly is movable axially and longitudinally with respect to the bolt carrier assembly between a first bolt assembly position and a second bolt assembly position to allow firing of the firearm when the bolt assembly is in the second bolt assembly position. The switch mechanism is coupled to rotate the bolt front half piece axially with respect to the bolt carrier assembly.
In some embodiments, the switch mechanism comprises: an upper receiver; a bolt gear configured to be engaged to the bolt front half piece to rotate the bolt front half piece axially with respect to the bolt carrier assembly; and a first cheekpiece bracket to which the bolt gear is attached. The first cheekpiece bracket has two retention holes. The first cheekpiece bracket is rotatably coupled to the upper receiver such that, when the bolt gear and the bolt front half piece are engaged, by turning the first cheekpiece bracket, the bolt gear turns the bolt front half piece to point the extractor slot in a direction between the first ejection direction and the second ejection direction.
In some embodiments, the switch mechanism further comprises a second cheekpiece bracket, a switch rod, a first switch block, a second switch block, and a switch slide. The second cheekpiece bracket is rotatably coupled to the upper receiver. The second cheekpiece bracket has two retention holes. The switch rod is coupled to move longitudinally with respect to the firearm over the upper receiver. The first switch block is coupled to the switch rod and may have two locking pins. The second switch block is coupled to the switch rod and may have two locking pins. The switch slide is coupled to the switch rod to move longitudinally with respect to the firearm between a first switch slide position and a second switch slide position. When the switch slide is in the first switch slide position, one of the two locking pins of the first switch block and one of the two locking pins of the second switch block are respectively inserted into the respective one of the retention holes of the first cheekpiece bracket and the second cheekpiece bracket, as well as the corresponding retention holes on the upper receiver, to lock the first and second cheekpiece brackets with the upper receiver. When the switch slide is in the second switch slide position, the locking pin of the first switch block and the locking pin of the second switch block are pulled out of the respective one of the retention holes of the first cheekpiece bracket and the second cheekpiece bracket, as well as the respective retention holes on the upper receiver, to allow both the first cheekpiece bracket and the second cheekpiece bracket to rotate.
In some embodiments, the switch mechanism 300 further comprises a rear cheekpiece bracket 125, a switch rod 135, a front switch block 128, a rear switch block 123, and a switch slide 133. The rear cheekpiece bracket 125 is rotatably coupled to the upper receiver 137. The rear cheekpiece bracket 125 has at least one retention hole 141. The switch rod 135 is coupled to move longitudinally with respect to the firearm over the upper receiver 137. The front switch block 128 is coupled to the switch rod 135 and has at least one locking pin 129. The rear switch block 123 is coupled to the switch rod 135 and has at least one locking pin 124. The switch slide 133 is coupled to the switch rod 135 to move longitudinally with respect to the firearm between a first switch slide position and a second switch slide position.
As shown in
As shown in
Due to the distance between the pivoting point on the interlock push lever 127 and the contact point of it with the interlock push pin 115 being greater than the distance between the pivoting point on the interlock push lever 127 and the contact point of it with the front switch block 128, and that the front switch block 128 is moving at the same displacement as that of the bolt carrier assembly 200, starting from the time that the interlock push lever 127 is in contact with the bolt interlock push pin 115, as the interlock push lever 127 turns more, the bolt interlock push pin 115 will be pushed backward in relation to the bolt carrier assembly 200. At certain position, the bolt interlock 106 will be pushed all the way back to clear its lock lugs 111 out of the circumferential grooves 153 (as shown in
After the change of direction is completed, the operator can release the switch slide levers 136. Before the bolt assembly 100 is pushed back into battery, the interlock push lever 127 will be pushed forward and upward both by the movement of the bolt carrier assembly 200 and the interlock push lever return spring (not shown, a torsion spring installed on the interlock push lever base 126) hence allowing the bolt interlock return spring 107 to push the bolt interlock 106 back into the locking position to lock the bolt front half piece 104 and the bolt rear half piece 108 together. The slide rod return spring 138 will push the slide rod 135 into the first slide position. Resultantly, the locking pins 124 and 129 on the front and rear switch blocks 123 and 128 will lock the front and rear cheekpiece brackets 125 and 131 with the upper receiver 137. Meanwhile, the main spring 142 of the firearm will push the bolt carrier assembly 200 back into battery. At this time the firearm can be fired again.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present disclosure without departing from the scope or spirit of the present disclosure. In view of the foregoing, it is intended that the present disclosure cover modifications and variations of the present disclosure provided they fall within the scope of the following claims and their equivalents.
The present application claims the priority benefit to U.S. Provisional Patent Application No. 61/561,208, filed on Nov. 17, 2011, which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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61561208 | Nov 2011 | US |