WO2021096455A1 - A new firearm mechanism - Google Patents

Abstract

The invention is an automatically operating weapon mechanism which does not encase the whole of cartridge (10), which has various number of stationary chambers (6), and which allows for the cartridge (10) to be chambered, exploded and ejected quickly – rapidly, by way of at least one second chamber which is overlapped at least one primary wheel (1) operating rotationally and stationary chamber (6) to create a chamber.

Description

A NEW WEAPON MECHANISM Technical Field

The invention is related to a firearm mechanism which allows for the bullet to be fed into the barrel more rapidly and for the empty case to be ejected from the barrel more rapidly after firing so that a firearm fires at a high rate of fire.

The invented mechanism will be able to increase the rate of fire, and also will have a simple structure which have potential to eliminate possible clogging while weapon is in duty.

Prior Art All weapons capable of pushing bullet by the propulsion of powder gas are called firearm. Generally, the term firearm connotes any small caliber weapon carried by a person. However, the firearms include all sorts of weapons of any size from huge cannon to rifle, to hunting rifle and to pistol.

The barrel, a pipe made of steel, is the most important part of a firearm. The open end of a barrel is called muzzle and the remaining part barrel extension. At the starting point of the barrel extension, there is a part called chamber, where the cartridge is placed. Barrel extension is designed in a way that is opened and closed for the cartridge to be chambered and ejected. Many of the firearms have helical indentations called groove inside the barrel which extends from the front part of chamber to the muzzle.

The cartridge used in firearms have three main parts. The tip of the cartridge is bullet. When the weapon is fired, the bullet shoots towards the target. The second is propellant. When the propellant is ignited a pressure is generated which pushes the bullet out from the barrel. The last part is case. The case, whose one side is closed, is a metal cylinder, and it contains the propellant.

At the back end of the case, there is an igniter called primer and it ignites the propellant when the trigger is pulled. The primer, fired by the hit of firing pin or by electric current, ignites the propellant in the case. The hot gas generates pressure when the propellant burns, which pushes forward the bullet, therefore the bullet rushes out of the muzzle at extremely high speed. In a small-caliber weapon, the cartridge is made up of bullet, case and propellant. Because these parts are tightly bound, the cartridge is seen as a single piece. And because the bullet is made of lead, the bullet of small caliber weapon may be called "lead" as well. In cartridge, case and bullet are a single piece and separate only when the propellant is ignited. In the cannon ball, however, bullet and case can be separate and the amount of propellant inside can be quantified with respect to the target distance.

In the current state of art, there exist many different methods to load the cartridge into barrel and then to eject the empty case. The first example of the firearms is revolver (pistol). The revolver has a cylinder with chambers as many as the number of cartridges. The revolver may be named as five-, six-, seven- or eight- chambered with respect to the number of cartridges placed in the cylinder. The cartridges are placed in the cylinder by hand and the empty cases are ejected again by hand and the cylinder is reloaded. Although the user can shoot relatively fast when the cylinder is fully loaded, it takes quite a long time to reload the cylinder.

The patent applications numbered as US2014059912, DE102017123245 and EP3403043 describe differently structured revolver mechanisms. However, rate of fire of these mechanisms remains very limited due to the problems arising from loading cartridge to the barrel and ejecting the empty case.

The patent application numbered as US2015330741 describes a hybrid firearm mechanism. Although this mechanism has a cylinder, the cartridges are loaded to the cylinder through a magazine. And the empty cases are ejected by a mechanism integrated with cylinder.

Likewise, the patent application numbered as GB189922479 describes a similar hybrid firearm mechanism.

Although the patent applications numbered as US2015330741 and GB189922479 describe a mechanism which increases the loading and ejecting speed and the rate of fire as well, it falls short as compared to other firearm mechanisms. The patent application numbered as US5220115 describes a firearm mechanism with two cylinders. Both of the cylinders are run independently from each other and load cartridge to the barrel for firing. Yet, rate of fire and loading and ejecting speed of this mechanism is also limited.

The patent application numbered as US2865126 describes the weapon mechanism known as Dardick revolver (pistol). The mechanism has an open chamber cylinder mechanism and the cartridges in the magazine are transferred to barrel by the open chamber cylinder mechanism. After firing, the case is ejected from the open cylinder.

Just as the Dardick weapon systems can be run in pistol type weapons, it is also described in already existing technique to be used in machine weapon systems, capable of firing more rapidly. There is a video indicating that the Dardick system has been applied to a machine gun. (https://www.voutube.com/watch?v=MThOEMAH99A).

However, the Dardick system can only be used with special cartridges called tround (triangular round). It is not possible to use the standard cartridges in Dardick weapon systems.

Tround is made by placing the standard cartridges in hollow polymer coatings in triangular form. Since this method increases the weight and size of the cartridge, it creates significant technical problems when using, i.e., when loading. On the other hand, the cartridges used in the Dardick system should be prepared in tround form, which brings both additional process and costs.

Another example to be given to firearms is automatically operating weapon mechanisms with magazine. The most common example of which are automatic guns and machine guns.

These weapon mechanisms aim to load the cartridge to the barrel from a magazine.

In the state of current art, fully automatic and semi automatic types are known. In a semiautomatic weapon, only one cartridge is fired when the trigger is pulled, whereas in fully automatic type, it is possible to fire until all cartridges are discharged from the magazine as long as the trigger is pulled and held. The gun fires as many times as the number of the cartridges in the magazine, and then a new magazine should be loaded.

After firing the cartridge, the empty cases are ejected from the weapon by using recoil force resulted from the propulsion of powder gas.

However, it is necessary to pull the empty case back from the chamber for the ejection of the case in such weapon mechanisms. Recoil force is used for backward movement of the mechanism. A new cartridge is loaded to chamber by moving the mechanism forward by means of a spring. For this reason, the maximum rate of fire is limited in this type of weapons. Even though such limit may not be seen important considering other limiting factors such as barrel overheating and barrel life, it is important for high rate of fire and multi-barrel applications.

The patent applications numbered as US3196568, GB1202901, WO2018151912 and US2019226777 describe the automatic weapon systems with different magazines.

In current state of art, another example to firearm mechanisms with high rate of fire is multiple barrel rotary weapons, the most prominent of which is machine gun.

The fact that the machine gun is capable of firing the bullet through multiple barrels both prevents the excessive heating of barrels and increases the rate of fire. The basic form of it is Gatling machine gun which is described in the following website: http://www.victorianshipmodeis .com/antitorpedoboatguns/Gatl ing/gatling1874 .html The patent applications numbered as EP3004785 and

US2016187097 are related to modern machine gun systems. These systems are known as miniguns.

In these mechanisms, the cartridges are loaded to a cylinder (wheel), which can move rotationally, and bullets can be fired through multiple barrels with the rotation of the cylinder.

The cylinder is usually rotated by an electric motor therefore the rate of fire is increased. The standard machine gun systems described above have chambers as many as the number of barrels in the gun. The bullet is loaded to the chambers and fired there. The patent applications numbered as US2012118132, EP3346223, W02011131298, W00106197 and DE4423750 describe the weapon mechanisms operated with more than one cylinder.

These mechanisms can be operated as one-barrel or multiple barrels with a high rate of fire.

In these systems, each cylinder has various number of chambers as well. The chambers are not structured and sized so as to encase the whole of the bullet. In order to explode the cartridge, the chamber is formed by overlapping the bullet chambers of two balls operated interrelatedly.

The cartridges are loaded to the chamber of one of the cylinders and the cylinder moves the cartridge rotationally. The other cylinder operating interrelatedly is moved rotationally in opposite direction to the cylinder loaded with cartridge. The second cylinder also has chambers.

With the motion of both cylinders in opposite direction, the chambers overlap and form chamber, and the cartridge is fired when the two chambers join together.

Due to the fact that the casing has a circular cross- sectional area, the chambers of each cylinder are formed in circular form. When two round pieces overlap, a chamber is created and in this circumstance the cartridge is exploded.

However, it is not possible to completely overlap the chambers by the rotational movement of two cylinders. Overlapping the chamber in the form of two circular pieces do not ensure a proper sealing. Unproper sealing causes the gas generated during explosion to escape from the chamber and loss of pressure and the firing performance to decrease. It may also cause rapture of the case and clogging the weapon.

Moreover, unproper sealing in chamber and gaps in the circular form may cause damage of the case and additional gas leak, which, in turn, endangers safety of the user.

Another technical problem encountered in these types of systems is loading the cartridges to the primary cylinder. For instance, according to the patent application numbered as EP3346223, although the cartridges are connected with a belt, they are loaded to the cylinders by placing in a guide.

Although the structure described in the patent application numbered as EP3346223 allows for the cartridge to be loaded to the cylinders more stably, locating the belt in a guide may introduce complexity. Besides, loading the cartridge with a guide can impede the use of this system in small- caliber weapons.

Object of the Invention

The object of the invention is to eliminate the chamber sealing problems for weapon systems in which the whole cartridge is not encased, in which the chamber is formed by overlapping at least one primary wheel having various number of stationary chambers and sliding chamber. To that end, while the stationary chamber in the primary wheel moves rotationally, the sliding chamber is moved rotationally and vertically, therefore they are overlapped and the chamber is formed.

Thus, the chambers are overlapped much better, and the chamber so formed will have better sealing.

The system to be formed to this end can be operated with two or more wheels as well as with only one wheel equipped with mechanisms overlapping one or more sliding chambers and the primary wheel.

Another object of the invention is to form weapon systems allowing for high rate of fire and ejecting of the cartridge whether or not using one or multiple barrel systems.

Description of the Figures

Figure 1. Front view of primary wheel and secondary wheel

Figure 2. A-A cross section of Figure 1

Figure 3. B-B cross section of Figure 1

Figure 4. Front view of the secondary wheel alone

Figure 5. Front view of the primary wheel alone

Figure 6. Side sectional view of the secondary wheel within the application of the invention which has eccentrical shaft and long and short pins

Figure 7. Front sectional view of the secondary wheel within the application of the invention which has eccentrical shaft and long and short pins Figure 8. Front sectional view of the secondary wheel within the application of the invention which has eccentrical shaft and spring

Figure 9. Side sectional view of the secondary wheel within the application of the invention which has eccentrical shaft and spring

Figure 10. Front view of primary wheel and secondary wheel in an application of without vertical motion unit Definition of the References in the Figures

1. Primary wheel

2. Secondary wheel

3. Vertical motion unit

4. Sliding chamber

5. Flexible unit

6. Stationary chamber

7. Seal

8. Barrel

9. Stationary chamber indentation

10. Cartridge

11. Empty case

12. Belt link

13. Sliding chamber height

14. Stationary chamber groove

15. Central shaft

15.1. Cam

15.2. Shaft eccentric

15.3. Shaft dent

16. Long pin

17. Short pin

18. Connector

19. Bearing connector 20. Bearing

21. Long pin sliding groove

22. Side wall

23. Slide

24. Spring chamber

Detailed Description of the Invention The invention is an automatic firing mechanism which allows for the cartridge (10) to be loaded, fired and ejected serially - rapidly, which is not structured to encase the whole cartridge (10), which has various number of stationary chambers (6), and which has at least one primary wheel (1) moving rotationally and at least one other chamber overlapping a stationary chamber (6) and forming a chamber.

The cartridge is loaded to primary wheel (1) by a belt link (12). Primary wheel (1) has various number of stationary chambers (6) that is preferably in circular form. The stationary chamber (6) is a cavity which encases only a part of the cartridge (10) so as not to form a chamber by itself. That is, the stationary chamber (6) indicates a partial room to form the chamber encased by at least one part from outside.

The chamber is formed by overlapping the sliding chamber (4) and the stationary chamber (6) which is set up on primary wheel (1).

In order to form the chamber, the stationary chamber (6) and at least one of the sliding chambers (4) can be moved towards each other during explosion. Since the stationary chamber (6) is formed on primary wheel (1) and the sliding chamber (4) is formed on secondary wheel (2), moving the secondary wheel (2) towards the primary wheel (1) will allow the stationary chamber (6) to overlap the sliding chamber (4) and therefore a chamber can be formed.

It shall be required to move away secondary wheel (2) and primary wheel (1) from each other to disassembly the chamber after explosion.

Figure 10 illustrates the application of forming the chamber by secondary wheel (2) moving towards the primary wheel (1) and sliding chamber (4) overlapping the stationary chamber (6).

In this application, a vertical motion unit (3) or a similar motion transfer unit is not required to form a chamber. The chamber is formed by primary wheel (1) and secondary wheel (2); both (1,2) rotate and move towards each other and form the chamber.

Since both wheels (1,2) shall be in motion, stationary chamber (6) and sliding chamber (4) shall move away from each other, thus chamber is disassembled.

According to a preferred application of the invention, sliding chamber (4) is moved by means of at least one vertical motion unit (3) and overlapped the stationary chamber (6), and thus the chamber is formed. The object of the invented mechanism is to fire and eject the cartridges (10) positioned on primary wheel (1) by continuous rotational movement of primary wheel (1).

To this end, the vertical motion unit (3) should be structured in a way to form the chamber by continuously enclosing the stationary chambers (6) which are moving successively on the primary wheel (1).

In accordance with one application of the invention, the vertical motion unit (3) is formed in a structure that operates in relation to a single sliding chamber (4). In this application, the vertical motion unit (3) carries the relatedly formed sliding chamber (4) so as to overlap the stationary chamber (6). Then, the vertical motion unit (3) moves continuously perpendicular to primary wheel (1). Thus, with the rotational movement of primary wheel (1), the stationary chambers (6) on the primary wheel (1) are continuously overlapped by the same sliding chamber (4). The cartridge is fired by exploding in the chamber formed with the stationary chambers (6) and the sliding chamber (4).

The preferable application of the invention is illustrated in Figure 1. According to this application, at least one vertical motion unit (3) is operated in connection with a secondary wheel (2).

Together with the rotational movement of the primary wheel (1), the secondary wheel is moved rotationally as well. In the course of this rotational movement, while the stationary chamber (6) and the sliding chamber (4) overlap, the vertical motion unit (3) also moves perpendicular to primary wheel (1) and moves the sliding chamber (4) forward onto the stationary chamber (6).

Within the application described in Figure 1, six vertical motion units (3) are formed on the secondary wheel (2). Each vertical motion unit (3) is related to a separate sliding chamber (4).

Similarly, primary wheel (1) has six stationary chambers as well (6). The sizes of the two wheels (1, 2) as well as the positions and sizes of the chambers (4, 6) formed on the wheels are designed so as to allow them to operate concurrently.

In another application of the invention, the primary wheel (1) and the secondary wheel (2) can be rotated separately by different motion units. According to one of the preferred applications of the invention, the motion is formed on the primary wheel (1) and the second wheel (2) is activated by it.

One of the preferred applications of the invention, the wheels (1, 2) are driven by an electric motor.

As illustrated in Figure 1, there is a central shaft (15) in the center of the secondary wheel (2). The secondary wheel (2) can move around central shaft (15) rotationally.

In accordance with the preferred applications of the invention, the central shaft (15) is designed so as to move rotationally. As seen in Figure 1, the central shaft (15) can be rotated either in clockwise or counter clockwise direction. There exists at least one cam (15.1) on at least one part of the central shaft (15). It is aimed by the cam (15.1) to move the pins which are formed on the secondary wheel in its particular positions.

As illustrated in Figure 1, there are various number of pins in such a way as to generate motion relatedly on sliding chambers (4) which are placed on the secondary wheel (2). When the pin reaches to the position of the cam (15.1) with the rotational movement of the secondary wheel (2), the cam (15.1) will push the pin and therefore the sliding chamber (4) moving relatedly with it. The effect produced by the cam (15.1) will be made successively on all pins and also on respective sliding chambers (4) with the continuous movement of the secondary wheel.

With this effect produced by cam (15.1) successively, sliding chambers (4) will be pushed so as to overlap the stationary chambers (6).

Taking into account that the primary wheel (1) moves synchronously with the secondary wheel (2), the sliding chambers (4) and the stationary chambers (6) will continuously coincide with each other and when this position occurs, the sliding chamber (4) and the stationary chamber (6) will overlap with the effect of cam (15.1) and form the chamber.

The cartridge (10) will be fired in the chambers that are formed continuously, and empty case (11) left over from the explosion will continue to be carried with the stationary chamber (6). In order for the sliding chamber (4) moving perpendicularly with the effect of cam (15.1) to return its original position after the effect of cam (15.1) is ended, the sliding chamber (4) is equipped with at least one flexible unit (5).

As illustrated in Figure 1, flexible unit (5) is in the form of a spring and operates together with a spring support. The spring is compressed by the effect of cam (15.1) and released when the effect disappears.

As illustrated in Figures 4 and 5, the sliding chamber (4) is equipped with a sliding chamber height (13) and the stationary chamber (6) with a stationary chamber groove (14).

When the sliding chamber (4) overlaps the stationary chamber (6), the sliding chamber height (13) fits into the stationary chamber groove (14).

In accordance with different applications of the invention, the sliding chamber height (13) and the stationary chamber groove (14), which are located at both sides of sliding chamber (4) and the stationary chamber (6), may not be symmetrical. Height and dent profiles may vary from low to high or high to low in accordance with the rotational direction of the wheels (1,2).

More specifically, profiles of the sliding chamber height (13) and the stationary chamber groove (14) may vary from low to high or high to low in accordance with the rotational direction of the wheels (1, 2). The cartridges (10) may be directly fed between two wheels (1, 2) or carried by secondary wheel (2) instead of carrying with primary wheel (1).

Figure 2 illustrates the feed of the cartridges (10), which are connected to each other by the belt links (12), to the primary wheel (1). The cartridges are rotated by placing in the stationary chamber (6) formed on the primary wheel (1).

To that end, the cartridges (10) are positioned on the belt links (12) at certain intervals. These intervals are compatible with intervals of the stationary chamber (6) formed on the primary wheel (1).

The cartridges (10) are carried to the section, which are affected by the vertical motion unit (3), by the primary wheel (1). When the sliding chamber (4), affected by vertical motion unit (3), overlaps the stationary chamber (6) and forms the chamber, the cartridge (10) is fired.

Then the bullet is pushed to the barrel (8) and the empty case (11) remains in the stationary chamber (6) and continues its rotational movement.

The invented mechanism can be operated with only one barrel (8), yet it is also applicable to be operated to more than one barrel (8).

In accordance with a preferred application of the invention, when multiple barrels (8) application is preferred, barrels (8) can be attached to primary wheel (1) and rotated together. It is allowed for the empty case to be ejected with the motion of the primary wheel (1). The stationary chamber (6) empties after the empty case (11) is ejected, then it is reloaded again by rotating and reaching loading position of the cartridge (10) together with link belt (12).

Therefore, the cartridge (10) is loaded into the mechanism and the empty case (11) is ejected without any need for additional effort.

In accordance with one preferable application of the invention, the cartridges (10) are fed with belt link (12) as well as without belt link (12) by using linkless feed system.

As illustrated in Figure 2, there is a seal (7) between the barrel (8) and the chamber formed by overlapping the sliding chamber (4) and the stationary chamber (6).

As illustrated in Figure 3, the stationary chamber (6) has a stationary chamber indentation (9). The stationary chamber indentation (9) prevents the empty case (11) from moving backwards during explosion.

In order to structure the chamber, which is formed by overlapping the sliding chamber (4) and the stationary chamber (6), more suitable to the form of cartridge (10), both the sliding chamber (4) and the stationary chamber can have grooves suitable to the form of the cartridge (10).

In accordance with a preferred application of the invention, vertical motion unit (3) is formed with cam (15.1) and pins moved by the cam (15.1). The invention can be operated by vertical motion units of different structures. The purpose of the vertical motion unit (3) is to allow for vertical motion of the sliding chamber (4), therefore, various systems which can be operated by hydraulic, magnetic or etc. effects can be used to this end.

Figure 6 illustrates a different application of the system. In this application, at least one shaft eccentric (15.2) and at least one shaft dent (15.3) are formed on the central shaft (15). More specifically, in Figure 6, the central shaft (15) is in the form of eccentric shaft.

At least one part of the central shaft (15) has a shaft eccentric (15.2) and a shaft dent (15.3). The continuation of the central shaft (15) is straight.

In this application, the portion of the central shaft (15) with the shaft eccentric (15.2) and a shaft dent (15.3) is equipped with bearing (20).

The bearing (20) is equipped circumferentially with at least one bearing connector (19) on the outer part.

Figure 7 illustrates the bearing (20) equipped circumferentially with 4 bearing connectors (19). The purpose here is to operate four sliding chambers (4), therefore an equal number of bearing connectors (19) is used. In a similar way, in accordance with other preferred applications of the invention, the mechanism can be operated with the same number of sliding chambers (4) as the bearing connectors (19). The bearing connector (19) is linked to at least one connector (18) with at least one short pin (17). The connector (18) is linked to the bearing connector (19) at its one end with a short pin, while it is linked to the sliding chamber (4) at its other end with a long pin (16).

As illustrated in Figure 6, the bearing connector (19) is linked to two connectors (18) placed at its both sides with a short pin (17).

Again, as illustrated in Figure 6, the two connectors (18) are linked to the bearing connector (19) at its one end with a short pin, and to the sliding chamber (4) at its other end with a long pin (16).

The long pin (16), linking the connector (18) to the sliding chamber (4) is operated within the long pin sliding groove (21) formed on the side wall (22).

The motion formed on the sliding chamber (4) by the central shaft (15) is upwards - downwards due to the fact that the motions of the long pin are limited within the long pin sliding groove (21).

The structure illustrated in Figures 6 and 7 and described above in detail can be given as an example of a different type of vertical motion unit (3). With the rotational motion of the central shaft (15) structured in eccentrical shaft, long pin (16)/short pin (17) as well as the bearing connector (19) / connector (18) operated relating to them are moved and thus the chamber (4) can be moved forward and backward. That forward and backward motion assembles or disassembles the chamber which is formed by overlapping the sliding chamber (4) and the stationary chamber (6).

Figures 8 and 9 illustrate the structure of a different vertical motion unit (3) described in the invention. Just like the application described in Figure 6 and 7, at least one shaft eccentric (15.2) and at least one shaft dent (15.3) are formed on the central shaft (15). More specifically, the central shaft (15) is in the eccentrical shaft form.

At least one part of the central shaft (15) has a shaft eccentric (15.2) and a shaft dent (15.3). The continuation of the central shaft (15) is straight.

In this application, the portion of the central shaft (15) with the shaft eccentric (15.2) and a shaft dent (15.3) is equipped with bearing (20).

In this application (Figure 8), the sliding chamber (4) is lengthened. Therefore, the sliding chamber (4) is in connection with the central shaft. As illustrated in Figure 8, the sliding chamber (4) is in direct contact with the bearing (20) around the central shaft (15).

Thus, the sliding chamber (4) is equipped with at least one slide (23) and at least one spring chamber (24). With the rotational motion of the central shaft (15), which is in eccentric form, the sliding chamber (4) can be moved forward and backward. This forward and backward movement is arranged by slide (23) and spring chamber (24). As illustrated in Figure 9, the sliding chamber (4) has a slide (23) in the middle part and two spring chambers (24) on both sides.

According to the preferred application of the invention, the spring chamber (24) has a spring in it. The spring allows for the sliding chamber (4) to return back after the effect produced for forward motion of the sliding chamber (4) ends up.

In accordance with different applications of the invention, it can be operated, instead of spring, by a compensation unit having different flexible structure which serves the purpose described above.

Figure 8 illustrates the application of the invention which is operated with 4 sliding chambers (4). Different applications of the invention can be operated with different numbers of sliding chambers (4). In this case, each of the sliding chambers (4) should be equipped with a slide (23) and a spring chamber (24). Thus, the chamber formed by overlapping the sliding chamber (4) and stationary chamber (6) by the forward and backward motion of the sliding chamber (4) is assembled or disassembled.

Claims

1. It is an automatically operating weapon mechanism, having at least one primary wheel (1), which has various number of stationary chambers (6), which does not encase a cartridge (10) completely, and which moves rotationally; and by having at least one other chamber that is overlapped a stationary chamber (6) to form an explosion chamber allowing for cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising a chamber which can be formed by assembling and/or disassembling stationary chamber (6) and at least one of sliding chambers (4) approaching and/or moving away to/from each other during explosion.

2. According to Claim 1, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a vertical motion unit (3) allowing to form a chamber by overlapping the sliding chamber (4) and the stationary chamber (6) composed on the primary wheel (1) moving vertically to the primary wheel (1).

3. According to Claim 2, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a vertical motion unit (3) operating relatedly with a single sliding chamber (4) and together with the rotational motion of the primary wheel (1), successively and continuously closing the stationary chambers (6) formed on the primary wheel (1) by moving vertically to the primary wheel (1).

4. According to Claim 2, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of at least one secondary wheel (2) equipped with at least one vertical motion unit (3) and moving rotationally in coordination with the rotational motion of the primary wheel (1), in order to allow for at least one sliding chamber (4) to move.

5. According to Claim 4, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of at least one vertical motion unit (3) to allow for the each sliding chamber (4) to move.

6. According to Claim 5, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a primary wheel (1) on which motion is formed and a secondary wheel (2) which is moved by and operated in coordination with the primary wheel (1).

7. According to any of the claims above, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a central shaft (15) fixed in the center, and a secondary wheel (2) moving rotationally around it.

8. According to Claim 7, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a central shaft (15) in the center which can move rotationally.

9. According to Claim 7, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a central shaft (15) with a cam (15.1), at least on one part of it, to move the pins which are formed on the secondary wheel (2) in its particular positions.

10. According to any of the claims above, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a sliding chamber (4) equipped with at least one flexible unit (5) in order for the sliding chamber (4) moving vertically with the effect of cam (15.1) to return its original position after the effect of cam (15.1) disappears.

11. According to Claim 10, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a flexible unit (5) in the form of spring.

12. According to Claim 11, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a spring compressed by the effect of cam (15.1) and released when the effect disappears.

13. According to any of the claims above, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of,

• a design so as to fit with each other,

• a sliding chamber (4) equipped with a sliding chamber height (13), and

• a stationary chamber (6) equipped with a stationary chamber groove (14).

14. According to any of the claims above, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of,

• a design so as to fit each other,

• a stationary chamber (6) equipped with a sliding chamber height (13), and

• a sliding chamber (4) equipped with a stationary chamber groove (14).

15. According to any of the claims above, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of cartridges (10) are carried by a belt link (12) on which the cartridges (10) are positioned at certain intervals that are compatible with intervals of the stationary chamber (6) formed on the primary wheel (1).

16. According to any of the claims above, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a single barrel (8) or more than one barrel (8).

17. According to any of the claims above, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of grooves on both the sliding chamber (4) and the stationary chamber (6) that is suitable to the form of cartridge (10) in order to form a chamber in convenient form.

18. According to Claim 8, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a central shaft (15) with at least one shaft eccentric (15.2) and at least one shaft dent (15.3).

19. According to Claim 18, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a central shaft (15) in the form of eccentric shaft.

20. According to Claim 18, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a central shaft (15) that a portion of it, shaft eccentric (15.2) and a shaft dent (15.3), is equipped with bearing.

21. According to Claim 20, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of

• a bearing (20) circumferentially equipped with at least one bearing connector (19),

• a bearing connector (19) which is linked to at least one connector (18) at its one end with at least one short pin (17), and

• a sliding chamber (4) which is linked to the connector (18) at its other end with at least one long pin (16).

22. According to Claims 21, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a bearing connector (19) that is linked to two connectors (18) from its both sides with a short pin (17).

23. According to Claims 21, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a long pin (16) operated within long pin sliding groove (21) formed on side wall (22).

24. According to Claim 20, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a sliding chamber (4) equipped with at least one slide (23) and at least one spring chamber (24) and in direct contact with the bearing (20) on the central shaft (15).

25. According to Claim 24, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a sliding chamber (4) equipped with at least one slide (23) and at least one spring chamber (24).

26. According to Claim 24, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a spring chamber (24) equipped with spring.

27. According to Claim 24, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a spring chamber (24) equipped with a flexible absorption unit.

28. According to Claim 1, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of an explosion chamber which is assembled and/or dissembled by secondary wheel (2) moving forward to and/or moving away from the primary wheel (1) and sliding chamber (4) overlapping the stationary chamber (6) and/or moving away.

29. According to Claim 28, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of an explosion chamber assembled by secondary wheel (2) moving forward to primary wheel (1) and sliding chamber (4) overlapping the stationary chamber (6).

30. According to any of the claims above, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a sliding chamber height (13) and/or a stationary chamber groove (14) which may not be symmetrical.

31. According to Claim 30, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of a sliding chamber height (13) and a stationary chamber groove (14), forms of which may vary in accordance with the direction of movement.

32. According to Claim 31, it is an automatically operating weapon mechanism, allowing for the cartridge (10) to be chambered, exploded and ejected quickly - rapidly, characterized by comprising of sliding chamber height (13) and a stationary chamber groove (14) forms of which may vary from low to high or high to low in accordance with the rotational direction of the wheels (1, n2).