KR20100108852A - Rotating bolt with spiral groove - Google Patents

Abstract

PURPOSE: A rotary breechblock having a spiral groove, which reduces recoil and increase a hitting ratio, is provided to reduce weight and volume by simplifying a structure. CONSTITUTION: A rotary breechblock having a spiral groove comprises a breechblock housing(2), a bullet latch(5), a breechblock, a fork(10), a firing pin(13), a breechblock head(7), a rear spring(14), a blind patch and a cam nail. The breechblock housing has a breechblock inlet hole. The bullet latch transfers bullets to a powder chamber. The breechblock is formed in cylindrical shape in order to be inserted into the breechblock housing. The fork is installed at the outer periphery of the front end of the breechblock. The breechblock head prevents the breechblock falling down a breech. The rear spring pressurizes the breechblock to a muzzle of gun.

Description

Rotating bolt with spiral groove

The present invention relates to a rotary glove having a helical groove, which has a less recoil, a higher accuracy, and a stronger bullet than the conventional shot-coil method used in a conventional pistol, and has a simpler and larger structure than a conventional gas operated rotary glove. And a rotary thrust with reduced weight.

When a gun explodes and the gunpowder in the casing explodes, the casing expands and clings to the chamber walls, filling the gap between the chamber and the casing, which prevents the high-pressure gas generated by the gunpowder from leaking around the chamber. Fires stably. Two conditions are necessary to reliably fire such a bullet from an automatic pistol.

     The first is to hold the casing in the chamber for a period of time until the bullet exits the barrel so that the explosion pressure does not leak around the chamber, rather than pushing the bullet away, and the second is the chamber immediately after the bullet is fired. This will open up the casing and reload, two.

     In conventional recoil-type automatic pistols, such as the COLT MODEL 1911, the barrel is engaged with the slide before firing, and when triggered, the barrel and the slide move backwards with the impact. During such a backward movement, the barrel is turned down, and at the same time the barrel and slide are released and only the slide is moved backward.

The barrel of the automatic pistol using this shorttri coil method moves with the slide at the same time as the trigger, and turns off to lower the hit rate of the firearm. Recoil is large when triggered. In addition, such a short-coil pistol has a weakness of being explosive, but can not use a strong bullet, such as Magnum bullets, has a disadvantage in general versatility.

     In order to overcome the shortcomings of the short-coil method, gas-operated rotary gutters are used (for example, the US M16 rifle and the DESERT EAGLE pistol from Israel IWI). As it passes through, the pressure of the gas pushes the piston back through the gas port, and the piston pushes the ball back out again, with the ball stack retracting and the ball starting to turn in place along the cam, allowing the ball to turn completely. When the bolt is in the position of exiting the chamber groove, the bolt is then retracted to discharge the casing.

These gas-operated rotary glyphs can withstand the pressure of strong bullets, but are too large and heavy to apply to pistols, and have a disadvantage in that they are caught inside the chamber due to their operation.

The present invention has been made to solve the above-mentioned problems of the prior art, less recoil, higher hit rate, more powerful than the conventional short-trigger method used in the pistol, can use a more powerful bullet, conventional gas-operated rotary glyph Its purpose is to provide a rotary glyph with a simpler structure and reduced size and weight.

Rotating gland having a spiral groove according to the present invention for solving the above problems is

Make a helical groove (8) about half a wheel long behind the collar (6), and straight down from the helical groove (8) to the bolt surface (11) so that the bolt (6) can retreat after the rotation of the bolt (6) is complete. The straight groove 9 is made out of the groove. The cam nail 17 is installed in the upper part of the rear frame so that the spiral groove 8 of the bolt 6 and the cam nail 17 are engaged so that when the bullet is fired, the spiral groove 8 of the bolt 6 is cam cam 17. ) While rotating in a spiral so that the bullet does not exit the chamber 22 for a period of time, and then the bolt 6 is engaged with the cam nail 17 at the end of the rotation so that it slides along a straight groove (9). Retreat back with 1). At this time, when the cam nail 17 reaches the front end of the straight groove 9 of the bolt 6, the cam nail 17 hits the rear part of the casing and the casing is discharged upwards. In other words, the cam nail 17 serves to discharge the casing to the outside.

     The bolt housing (2) in the slide (1) has a cylindrical bolt opening (3) for insertion of the bolt (6), and the bottom of the bolt housing (2) has a cam nail (17) for the bolt housing (2). Straight from front to back in the center of the bottom of the bolt housing 2 so that the slide 1 can move forward and backward without being obstructed by the cam nail 17 while interfering with the bottom groove of the bolt (8,9) The cam insertion port 4 is cut out.

     The bullet latch 5 is formed at the left and right sides of the cap insertion opening 4 at the front of the front bottom of the bolt housing 2.

The diameter of the bolt head (7) at the rear end of the bolt (6) is larger than the diameter of the bolt insert (3) in the bolt housing (2) so that the bolt (6) does not fall into the chamber (22) and behind the bolt head (7). The rear spring 14 is installed so that the bolt 6 can be rotated backwards and then returned to its original position. The rear spring 14 triggers the bullet and restrains recoil while pressing the bolt 6 toward the muzzle 29 when the bolt 6 retreats backward at the explosion pressure, and the bolt 6 returns. When doing so, as shown in Figure 1, the end of the helical groove 8 of the bolt 6 is characterized by pressing the bolt 6 toward the muzzle 29 so that the cam nail 17 is located.

The rotary gland having a spiral groove according to the present invention has a higher accuracy than the short rifle type used in the conventional pistol because the gasket 21 is fixed and retracts only the glove 6 back, and the glove is behind the glove 6. It has a spiral groove (8) that slows the retraction of (6) so that a powerful bullet can be used, and unlike the conventional gas-operated rotary glyph, the glyph (6) is made to operate only by using the recoil when the bullet is exploded. In the chamber 22, the medium is not caught, and also the structure is simple, which has the advantage of reducing the size and weight than the conventional gas-operated rotary gland.

The rotary gland having a spiral groove according to the present invention includes a gasket housing 2 having a cylindrical gasket insert 3 having a size in which the gasket 6 can be inserted into the slide 1, and a bottom of the gasket housing 2. A bullet stopper (5) protruding downward at the front to move the bullet into the chamber, and a bolt (6) having a cylindrical shape and having a spiral groove (8) at its rear end so as to be inserted into the bolt housing (2); , A rake 10 provided on the outer periphery of the front end of the bolt 6, a ball 13 to prevent the ball 12 provided in the bolt 6 from protruding behind the bolt 6, and the bolt ( 6) a bolt head (7) positioned rearward and formed thicker than the hole size of the bolt insertion hole (3) in the bolt housing (2) to prevent the bolt (6) from falling into the chamber (22), and the bolt head (7). Nori by behind A rear spring 14 for pressing the 6 toward the muzzle 29, a blocking plate 15 which prevents the bolt 6 and the rear spring 14 from protruding from the back of the bolt housing 2, and a frame (16) It is fixedly installed on the rear upper part so as to be engaged with the helical groove 8 formed behind the flock 6, and fixed not to move to the intermediate point in the cam nail 17 and the frame 16 which helps the flock 6 rotate. Protrudingly formed under the barrel bundles 21 and 22 and the chamber 22, the barrel barrel 21 and 22 are installed to surround the outer circumferential surface of the barrel barrel support 23 and the barrel 21. As shown in FIG. 1, the revolving spring is configured to press the slide 1 toward the muzzle 29 so that the pistol is in the front closed state.

     The bolt housing (2) is formed inside the slide (1), the inside of the bolt housing (2) has a cylindrical insertion hole (3) of the size that can be inserted into the key 6, the cylindrical horizontally, The bottom of the bolt housing 2 is such that the cam nail 17 engages the grooves 8 and 9 of the bolt 6 inserted in the bolt housing 2 so that the cam nail 17 is engaged with the bolt housing ( 2) A cam insertion hole 4 drilled into the hole is formed at the center of the bottom of the bolt housing 2 and extends in a straight line from the front to the back of the bolt housing 2.

     The left and right sides of the cam insertion hole 4 at the front of the front bottom of the bolt housing 2 are formed to protrude downward.

     The bolt 6 is formed into a cylindrical shape so as to be inserted into the bolt housing 2 so as to move or rotate back and forth, and as shown in FIG. It is arranged in contact with the chamber 22, and the end of the spiral groove 8 is engaged with the cam nail 17.

     The role of the helical groove 8 formed behind the bolt 6 is to engage the cam nail 17 when the bullet is triggered, rotating the bolt 6 in a spiral for a predetermined time until the bullet exits the muzzle 29. Serves to keep the chamber 22 from escaping, and also serves to reduce the recoil when the bullet is triggered. And the spiral groove 8 starting just in front of the bolt head 7 is rotated half a turn spirally towards the bolt surface 11 and then leads to the straight groove 9.

     The length of the spiral groove 8 may be adjusted by the rotational length of the spiral groove 8 according to the explosion pressure or the amount of gunpowder filled in the bullet. That is, bullets with high explosion pressure extend the length of the spiral groove 8 to withstand the explosion pressure, whereas bullets with low explosion pressure reduce the explosion pressure of the bullet by shortening the length of the spiral groove 8. It is enough to adjust the rotation length of the spiral groove 8 so that it can withstand and discharge the casing quickly.

     The rake 10 is installed on the outer periphery of the front end of the bolt 6 to draw the casing out of the chamber 22 upon retraction of the bolt 6.

     The ball pin 13 is inserted and installed into the key 6 on the outer circumferential portion of the key 6, so that the ball 12 is engaged with the ball 12 so that the ball 12 does not bounce behind the key 6.

     The bolt head 7 is formed at the rear end of the bolt 6, has a circular shape, and is larger in diameter than the diameter of the bolt insert 3 in the bolt housing 2, so that the bolt 6 is chamber 22. Do not fall to the) side.

     The rear spring 14 abuts directly behind the bolt head 7, and the blocking plate 15 abuts behind the rear spring 14.

     A blocking plate groove 30 is formed in the left and right sides of the rearmost end of the knock housing 2 so that the blocking plate 15 can be inserted from below. Inserting the shaped blocking plate 15 prevents the bolt 6 and the rear spring 14 from falling behind the bolt housing 2.

     The cam nail 17 is formed in a 'b' shape so as to be engaged with the grooves 8 and 9 of the bolt 6 through a cam insertion hole 4 formed in the bottom of the bolt housing 2. The upper portion of the cam nail 17 directly contacting the grooves 8 and 9 of the bolt is formed in a rectangular shape so as to withstand the shock during the retraction of (6). In addition, the cam fixing pin 20 is continuously inserted into the cam fixing hole a 18 formed on the side of the lower part of the cam nail 17 and the cam fixing hole b 19 formed on the rear side of the frame 16. ) To the frame 16.

     In addition, the cam nail 17 in the front closed state as shown in Figure 1 is fixed to the upper portion of the rear of the frame 16 to engage with the end of the spiral groove 8 located in the rear of the bolt 6, the rear as shown in FIG. In the open state, a portion of the cam nail 17 sticks out of the straight groove 9, which serves to discharge the casing outward.

     The barrel bundles 21 and 22 are fixedly installed at an intermediate point in the frame 16, and the barrel fixing holes a 24 and the frame 16 formed on the side of the barrel support 23 protruding below the chamber 22. The barrel fixing pins 26 are continuously inserted into the barrel fixing holes b 25 formed at the intermediate points to fix the barrel bundles 21 and 22 to the frame 16.

     The closing spring 27 is installed to surround the outer circumferential surface of the barrel 21, the front is installed on the bottom surface of the outlet 28, the rear is in contact with the chamber 22 front. Normally, the closing spring 27 presses the slide 1 toward the muzzle 29 so that the pistol is in the front closed state as shown in FIG.

     Looking at the operation of the rotary gland having a spiral groove according to the present invention configured as described above are as follows.

     First, the magazine containing the bullet is inserted into the magazine insertion unit, and then the slide 1 is retracted and released. The bullet catches the rear portion of the bullet at the latch 5, and the bullet moves into the chamber 22 and is loaded.

     Subsequently, when triggering, the explosion pressure at the time of triggering pushes the bolt 6 backward, and at this time, the bolt 6 does not retreat straight back, but the spiral groove 8 formed at the end of the bolt 6 is cam nail 17 ), The nail nails (17) rotate half a turn and then the cam nails (17) help the bolts (6) rotate along the helical groove (8) so that the casing exits the chamber (22) for a period of time. If the cam nail 17 leaves the helical groove 8, then a straight straight groove 9 emerges, at which time the slide 1 and the bolt 6 move backwards without interference of the cam nail 17. Retreat

    On the other hand, when the clasp 6 retreats backward, the rear spring 14 serves to suppress the recoil while pressing the clasp 6 toward the muzzle 29 to prevent the casing from escaping from the chamber 22, FIG. 1. In the front closed state as described above, the end of the helical groove 8 of the press 6 is pressed against the muzzle 29 such that the end of the helical groove 8 is positioned at the cam nail 17.

     In addition, when the bolt 6 retreats, the rake 10 pulls the casing out of the chamber 22, and then continues to retract so that the cam nail 17 reaches the end of the straight groove 9 of the bolt 6 (17) hits the back of the shell and the shell is discharged to the outside.

     After the retraction of the slide 1 is completed, the closing spring 27 presses the slide 1 toward the muzzle 29 so that the pistol is in the front closed state as shown in FIG. 1, and thus the slide 1 is returned forward. At this time, the rear part of the bullet is caught by the bullet latch 5 protruding in front of the front bottom of the bolt housing 2, and the bullet moves into the chamber 22 and is loaded again.

1 is a cross-sectional view of the front closure and firing ready state of the rotary gland having a spiral groove according to the present invention.

2 is a cross-sectional view of a shell extraction process of a rotary gland having a spiral groove according to the present invention.

3 is a cross-sectional view of the rear open and chamber open state of the rotary gland having a spiral groove according to the present invention.

Figure 4 is a perspective view of a part of a rotary gland having a helical groove, the glyph housing and the frame, according to the present invention.

<Explanation of symbols on main parts of the drawings>

2: bolt housing 3: bolt insert 4: cam insert

5: bullet brace 6: bolt 7: bolt head

8: spiral groove 9: straight groove 14: rear spring

17: cam nail 23: barrel support 27: closing spring

Claims (5)

A lock housing (2) formed in a cylindrical shape with a lock insert (3) into which the lock (6) can be inserted into the slide (1); A bullet stopper (5) protruding from the front of the bottom of the bolt housing (2) to move the bullet into the chamber; A bolt 6 formed in a cylindrical shape so as to be inserted into the bolt housing 2 and having a spiral groove 8 at a rear portion thereof;  A rake (10) provided on an outer circumferential portion of the front end of the bolt (6);  A ball pin (13) for preventing the ball (12) installed in the gull (6) from jumping out of the glove (6);  A bolt head (7) formed at the rear of the bolt (6) to prevent the bolt (6) from falling into the chamber (22);  A rear spring (14) positioned behind the bolt head (7) to press the bolt (6) toward the muzzle (29);  A blocking plate (15) which prevents the bolt (6) and the rear spring (14) from protruding behind the bolt housing (2);  Rotating bolt with a spiral groove, characterized in that it consists of a cam nail (17) fixedly installed in the upper rear of the frame (16) and engaged with the spiral groove (8) formed behind the bolt (6) to help the bolt (6) to rotate. . The method according to claim 1, The cam housing 17 is engaged with the cam nail 17 in the bottom thereof so that the cam nail 17 engages with the grooves 8 and 9 of the bolt inserted in the bolt housing 2 at the bottom thereof. A cam insertion hole (4) drilled to enter is located at the bottom center of the bolt housing (2) and is formed extending in a straight line from the front of the bolt housing (2) to the front of the front bottom of the bolt housing (2). On the left and right of the cam insertion port 4 of the rotary latch having a spiral groove, characterized in that the bullet latch 5 is formed to protrude downward. The method according to claim 1, The bolt 6 is formed larger than the hole size of the bolt insertion hole 3 at the rear, and has a circular bolt head 7 which prevents the bolt 6 from falling into the chamber 22 and the bolt head ( 7) with a helical groove 8 formed in front of the helical groove 11 and a straight groove 9 in a straight line from the helical groove 11, followed by the helical surface 11, located in front of the helical surface 11; Rotary grommet with a spiral groove, characterized in that it is composed. The method according to claim 1, The blocking plate 15 is formed in a rectangular shape, and the blocking plate 15 is inserted into the blocking plate groove 30 formed in the left and right sides of the rear end of the bolt housing 2 from below. Rotating helical groove having a spiral groove, characterized in that it serves to prevent the bolt (6) and the rear spring (14) from falling behind the bolt housing (2). The method according to claim 1, The cam nail 17 passes through the cam insertion hole 4 formed in the bottom of the bolt housing 2, and the helical groove 8 of the bolt 6 inserted into the bolt housing 2. It is formed in a 'b' shape to be engaged with the straight groove (9), the upper portion of the cam nail 17 has a long rectangular shape, and a cam fixing hole formed in the side of the lower cam nail (17) The cam fixing pin 20 is continuously inserted into the cam fixing hole b 19 formed at the rear side of the a 18 and the frame 16 so that the cam nail 17 is fixedly installed at the upper rear side of the frame. Tumblers with helical grooves.

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