CZ307728B6 - Compressed gas gun - Google Patents

Abstract

Regulation of guns that use gas, which is either pre-compressed or compressed just prior to firing, by a spring (2), and by a set of pistons (3) located inside the cylinder (4). The cylinder (4) ends with a head (5) fitted with a nozzle (7) connected to the barrel (8) located in the projectile chamber (6). A seal (9) is fitted between the nozzle (7) and the barrel (8). In guns containing a feeder arm (11) a cut out (13) is made for the regulating element (14) of the feeder arm (11) movement regulator (15) to prevent the nozzle (7) from engaging the seal (9) on the barrel (8) , in the active position of the control element (14). In guns that do not contain a feeder arm (11), the nozzle (7) is prevented from contacting the seal (9) by at least one regulating element (14).

Description

A weapon powered by compressed gas

Field of technology

The invention relates to a weapon powered by a compressed gas comprising a body in which a mechanical box provided with a piston located in a cylinder is located, at the end of which a head is provided with a nozzle connected to a main set in the projectile chamber. The nozzle is connected to a branch provided with a tension spring. Furthermore, the weapon contains a switching mechanism. There is a seal between the nozzle and the main. It is an airsoft weapon, ie a weapon powered by air or other propellant gas, with the energy of projectiles fired up to 16 Joules, measured in the muzzle of the barrel, using standard ammunition weighing 0.20 g. Projectiles for airsoft weapons are plastic bullets with a diameter most often 6 mm, which are fired at a distance of several tens of meters.

Prior art

Currently, airsoft guns work on the principle of accelerating a projectile fired by gas pressure. Gas is used, which is either pre-compressed or compressed before each shot of the weapon. It is mainly air, CO2 or special propellant. The air is compressed during the rapid movement of the piston in the cylinder, filled with air. The energy of the spring, which is compressed before firing, is used for this rapid movement of the piston.

Airsoft weapons are therefore divided into three categories, namely weapons powered by pre-compressed gas, manually operated weapons, where the spring is stretched by the user, or electrically powered, where the spring is stretched by an electric motor with appropriate mechanical transmission.

To accelerate the projectile, an electric motor is used in electric motor-driven weapons to retract a spring which, when released from the compressed state, acts mechanically on a piston moving in a cylinder. The piston is thus accelerated and the air in the cylinder is compressed. The air from the cylinder then acts on the projectile, which is accelerated in the main weapon. At the end of the cylinder there is a cylinder head, which ensures the flow of air from the cylinder to a subsequent nozzle of smaller diameter than the cylinder. The conduction of air from the cylinder through the cylinder head to the barrel is ensured by a movable nozzle, which is mounted on the cylinder head and can move along this cylinder head in a given direction. With its forward and backward movements, the nozzle opens and closes the chamber into which the projectile is inserted. After closing the chamber, the nozzle rests over the seal to the barrel, and then the main spring acting on the piston is released, the piston is accelerated and air pressure is applied through the nozzle to the barrel and to the projectile. The projectile in the barrel is accelerated by air pressure. For the highest possible performance of the airsoft weapon, a good sealing of the nozzle and the barrel is suitable, therefore it is necessary to choose a suitable seal between the nozzle and the barrel, as well as the pressure of the nozzle on the abutting part of the barrel. This is secured by a tension spring. The entire air drive system, as well as most of the functional parts of the weapon, is most often stored in a metal case, called a gearbox, or mechanical box. It is then placed in the body of the weapon and its front part with a moving nozzle rests on the chamber.

The interaction between the nozzle and the piston is mechanically ensured in weapons driven by an electric motor. The nozzle is inserted into a component called a feeder arm, which has the function of a pull rod and allows the nozzle to move such that the nozzle opens or closes the chamber for the projectile fired. The feeder arm is fitted at the bottom with a tension spring, which acts on the arm so that the nozzle is pressed into the chamber and the nozzle thus abuts over the seal to the barrel. When moving the nozzle backwards, ie opening the chamber for collecting the hub, mechanical gears are used, serving primarily to tension the spring acting on the piston. By rotating the gears at the appropriate time, a force acts against the tension spring, pushing the feeder arm forward and the feeder arm, and the nozzle connected to it, move backwards from the chamber. In the next phase of rotation of the mechanical transmissions, the arm of the feeder is released and pulled forward by the tension spring, ie to the original position. The nozzle connected to the arm of the feeder also moves forward and thus closes the chamber with the projectile, which

- 1 CZ 307728 B6 is pushed into the barrel by a nozzle. The nozzle rests on the barrel seal and only then is the piston spring released and the air is released only after the chamber is closed and the nozzle rests on the seal. The size of the nozzle as well as the geometry of the chamber depends on the model of the weapon.

At present, the regulation of the muzzle velocity of a weapon, especially a weapon driven by an electric motor, is performed by a replaceable spring acting on the piston. The springs are manufactured with different stiffness and the weapon then reaches different muzzle velocities. Such regulation is also performed in weapons manually drawn by the user. Replacing the spring usually requires disassembly of the weapon, which is a time-consuming process and, for example, in outdoor conditions in which the weapon is operated is almost impossible. However, there are also weapons that allow the spring to be replaced only with partial disassembly. This replacement is significantly faster and can also be done outdoors. However, the user of the weapon must have a spring with a different stiffness, and in addition to this necessity, this method of regulation is accompanied by a number of disadvantages, such as the ingress of dirt into the weapon in the outdoor environment during partial disassembly. A special type of gearbox and weapon body is also required. This variant is therefore quite economically demanding. There is also a time delay in the order of minutes, which is undesirable when actively using the weapon.

WO 2017/121034 describes the regulation of air pressure by means of a regulator with variously sized air leakage openings. This is another element that needs to be inserted into the weapon during its production.

EP 3163247 describes a solution for ensuring that the kinetic energy of the firing ball does not exceed a specified value even when a higher weight ball is used. Leakage of compressed air is created in the nozzle path or the part leading to the nozzle path.

The essence of the invention

The above drawbacks are largely eliminated by a compressed gas-powered weapon comprising a body in which a cylinder is located, at the end of which a head is provided with a nozzle connected to a barrel by a seal adjoining a barrel located in a projectile chamber according to the invention. Its essence is that the weapon is provided with a control element to prevent the nozzle from resting on the seal, mainly in the active position of the control element, to cause a propellant gas leak.

In one preferred embodiment, the weapon is propelled by compressed gas and in its body is a mechanical box provided with a piston located in a cylinder, at the end of which is a head provided with a nozzle connected to the barrel located in the projectile chamber. The nozzle is connected to a feeder arm provided with a tension spring. There is a seal between the nozzle and the barrel, the feeder arm being provided with a cut-out for the regulating element of the feeder arm movement regulator, to prevent the nozzle from resting on the barrel seal, in the active position of the regulating element.

The regulator is preferably located in the space of the switching mechanism. The control element may be formed by an element selected from the group of piston, latch, rod. The regulating element may be formed by a piston provided with a pressure element selected from the group of a compression spring, a tension spring, an electromagnet, a lever. In another embodiment, the control element is part of the switching elements of the weapon selected from the group of microswitch, mos-fet system, microprocessor.

The body of the weapon is preferably provided with an opening for actuating and / or replacing the regulating element. The control element is preferably formed by at least two pistons for control.

In another preferred embodiment, the weapon is driven by compressed gas, the gas being pre-compressed and / or compressed by a mechanically stretched spring, the weapon being provided with an element or set of elements for preventing the nozzle from abutting the seal in the barrel in the active position of the control element.

-2EN 307728 B6

In yet another preferred embodiment, the barrel is driven by compressed gas, wherein in the body there is a set of elements for compressing air before firing by a spring acting on a piston located in the cylinder and is provided with at least one control element to prevent the nozzle from resting on the seal mainly in the active position of the control element.

In yet another embodiment, the weapon is driven by a compressed gas, wherein the gas is pre-compressed and the weapon is provided with at least one control element to prevent the nozzle from resting on the seal, mainly in the active position of the control element.

The main benefit of the invention is in a method of regulation other than the exchange of a spring accelerating the piston. The regulation of the muzzle velocity takes place at the level of the nozzle and the chamber, when artificially induced leaks between the nozzle and the seal on the barrel are used to limit the power. In order to achieve the highest possible performance of the weapon, a good sealing of the nozzle and the barrel is essential, for which a rubber seal is used, which is located at the beginning of the barrel. In the prior art, the nozzle is pressed against this seal before the shot and thus rests directly on the seal in the normal state. Under ideal conditions, there is no leakage of propellant gas into the chamber area and all the propellant gas pressure is used to accelerate the projectile.

The regulator, the principle of which is the subject of the application, restricts the forward movement of the nozzle so that it does not rest directly on the seal on the barrel. This is a targeted leak, which results in a decrease in the muzzle velocity of the projectile fired from the weapon.

Thus, there is a leakage of propellant gas into the chamber space and only a part of the air from the original volume is used to accelerate the projectile. The muzzle velocity of the projectile is therefore lower during the control intervention.

When the control element is deactivated, the weapon works in the current way. The movement of the nozzle is not limited and it stops in the original position during the forward movement, ie it fully rests on the barrel seal and thus the maximum muzzle velocity of the weapon is achieved.

This creates two-state control, when the weapon fires projectiles at muzzle velocity when the control element is deactivated as before the installation of the control element, and when the control element is activated, the muzzle velocity of projectiles fired from the weapon is lower.

The control device can be operated on all types of airsoft weapons with appropriate modification of existing parts and installation of the necessary parts. For example, when installing in commercially purchased weapons with electric spring tension, it is necessary to replace only a few internal parts of the gearbox and replace them, or adapt them to parts suitable for regulation. With the appropriate modification of the body of the weapon, the controller can then be used on most models of weapons. The regulator can then be designed so as not to interfere with the external design of the weapon, which will look as before the installation of the regulator. Also due to the need to replace several parts, the modification of the weapon is technically undemanding and easy to perform in professional services.

With the current regulation of most used weapons, service intervention is necessary for each required change in power, which is eliminated by one service intervention in the form of installation of this controller.

An alternative to the current regulation by a quick spring change requires the purchase of a special weapon body and gearbox. Therefore, this new method of regulation is also economically undemanding, because the installation of a few parts and modification of the body of the weapon is a more economical option than replacing the body of the weapon and the gearbox with another type. Also during individual regulatory interventions, the internal bowels of the weapon are not contaminated, thus reducing the potential risk of failure.

The main advantage of this method of regulation, however, is the speed of the control intervention. Depending on the design, the user is then able to perform a control intervention in a time interval

-3GB 307728 B6 under one second. It does so by simply releasing the lever, which holds the control element. The current regulation, even on the most perfect types of weapons, was a matter of at least tens of seconds.

This method of regulation should also bring new possibilities of rules of games and competitions to the airsoft environment, as these are currently adapted to complex service operations related to regulation by means of spring replacement. This is now necessary for most types of weapons to be done well in advance, even a few days, as it is necessary to perform a virtually complete disassembly of the weapon. For participants in airsoft games and competitions, as well as other users, greater safety is achieved when using this method of control, as users can use a high muzzle velocity weapon after a quick control intervention in lower muzzle velocity mode to use the weapon for shorter shooting distances.

The biggest advantage of the solution according to this technical solution is the fast possibility of regulation. Depending on the design of the system, this may already concern the shot immediately following, whereby the activation of the system is a matter in a time interval of about a second. Until now, the fastest regulation on weapons modified for this purpose - about 15% of used weapons, was carried out within a time frame of tens of seconds, because it was necessary to perform a partial disassembly of the weapon and replace the propulsion spring. Regulation for most commercial weapons, however, was a matter of hours, as to replace the drive spring, it is necessary to perform a complete disassembly of the weapon.

Explanation of drawings

The invention will be further elucidated with the aid of the accompanying drawings. Where Fig. 1 shows a gearbox and a part of the body of a weapon driven by electric tensioning of a spring, including a possible embodiment of a method of regulation in a side section with the nozzle in the forward position, when the regulator is deactivated. Giant. 2 shows a gearbox and a part of the body of a weapon driven by electric tensioning of a spring, including a possible embodiment of a method of regulation in a side section with the nozzle in the rear position, when the regulator is deactivated. Fig. 3 shows a gearbox and a part of the body of a weapon driven by electric tensioning of a spring, including a possible embodiment of the method of regulation in a side section with the nozzle in the front position, the regulator is activated. Fig. 4 shows a gearbox and a part of the body of a weapon driven by electric tensioning of a spring, including a possible embodiment of the method of regulation in a side section with the nozzle in the rear position, the regulator is activated. Fig. 5a shows a top view of the feeder arm, which is placed in a gearbox with the nozzle in the rear position and the regulator deactivated. Fig. 5b shows a top view of the feeder arm, which is placed in a gearbox with the nozzle in the front position and the regulator deactivated. Giant. 6a shows a top view of the feeder arm, which is placed in a gearbox with the nozzle in the rear position and the regulator activated. Fig. 6b shows a top view of the feeder arm, which is placed in a gearbox with the nozzle in the front position and the regulator activated.

Examples of embodiments of the invention

An exemplary embodiment of the invention will be described for weapons operating on the principle of electric spring tension. However, this embodiment of the control can be applied to any embodiment of the weapon drive, including pre-compressed gas and manual spring tension.

It is a weapon powered by compressed gas comprising a body 22 in which a mechanical box 1 provided with a piston 3 located in a cylinder 4 is located. At the end of the cylinder 4, the head 5 is provided with a nozzle 7 connected to a main 8 located in the projectile chamber 6. The nozzle 7 is connected to a feeder arm 11 provided with a tension spring 10. Below the feeder arm 11 there is a switching mechanism 12. Between the nozzle 7 and the main 8 there is a seal 9. The feeder arm 11 is provided

-4EN 307728 B6 a cut-out 13 for the control element 14 of the regulator 15 of movement of the feeder arm 11, to prevent the nozzle 7 from abutting on the seal 9 in the main 8, in the active position of the control element 14.

The technical implementation of this control principle, in the case of weapons operating on the principle of electric spring tension, consists in limiting the movement of the arm 11 of the feeder, into which the nozzle 7 is inserted in a known manner. The return movement of the arm 11 of the feeder in the gearbox 1 ensures the rotation of the mechanical gears 20 in a known manner and the nozzle 7 thus moves backwards. During the forward movement of the nozzle 7 when closing the chamber 6, the restrictor and the arm 11 of the feeder act, and the nozzle 7 connected to it, thus does not reach the original front position. Thus, a leak occurs between the nozzle 7 and the chamber 6, which is the cause of the propellant gas leaks, and thus the muzzle velocity of the projectile fired is reduced.

The space for the original switching mechanism 12 is used to insert the regulator 15 into the gearbox 1. Immediately above the original switch 12, the arm 11 of the feeder moves. The original switching mechanism 12 is replaced by microswitches, for which a much smaller space of the switch 17 is reserved, or by other switches which are considerably less bulky. The microswitches that provide the shot are switched by the existing trigger 18 of the weapon, which is activated by the user. Subsequent use of mos-fet switching or processor-controlled switching is possible. Both principles are already used in practice. However, a combination of the controller 15, which is the subject of the application, with the processor control of the weapon is rather assumed. If the control circuits were to adapt to their shape, which is possible in principle, the controller 15 could be formed by the elements themselves necessary for control, i.e.: control element 14. control element of controller 15, microswitches located in place of switch 17. In the remaining space , electronics can be stored after the original switch 17 for the processor control of the operation of the weapon. The regulator 15 is thus in various embodiments, it being possible to form a single component which is inserted into the space of the original switching mechanism 12 of the weapon. Thus, a regulator 15 in the form of a cylinder or other element is inserted into the space of the original switch 12, which is fixed in the gearbox 1, with a movable regulating element 14 inside. In the case of the desired control, a force is exerted from below on the control element 14 - a piston inserted in the regulator 15. Depending on the type of the gearbox 1, it is necessary to slightly adjust the gearbox 1, for example by grinding a small part. It is also necessary to similarly adjust the body 22 of the weapon so that the piston, or the part connected to it, can be controlled by mechanics. By this modification is meant, for example, drilling a hole 21 in which the piston or the part connected to it would come out of the body 22 of the weapon and the user could manipulate it.

The piston presses on the arm 11 of the feeder from below. The arm 11 of the feeder is provided with a cut-out 13 in contrast to the previously known part, into which the piston-regulating element 14 can slide. The cut-out 13 is designed so that after inserting the piston into the cut-out 13, the feeder arm 11 is restricted in forward movement by the piston and held in a position where the nozzle 7 has not yet fully reached the seal 9 of the barrel. with the open and closed chamber 6. The feeder arm 11 does not return to the position with the maximum forward deflection and the nozzle 7 does not fully abut the seal 9 of the barrel 8. Thus, if the piston is inserted into the recess 13 in the feeder arm 11, the regulator 15 is activated. . The cut-out 13 is further formed so that the feeder arm 11 is not restricted when moving backwards. Thus, the chamber 6 is fully opened even when the control element 14 is activated, just as the opening would take place without control intervention. The regulator 15, even if it is activated, thus does not restrict the movement of the nozzle 7 backwards and the chamber 6 thus fully opens when pulled. The principle of the weapon's retraction, with all its contexts, such as the opening of the chamber 6, is therefore unchanged from the known solution. In Figs. 1 to 4, this force is mediated on the piston by a spring 16, which acts on it from below and pushes the piston upwards. Thus, if the piston is not mechanically held in the lower position, it is pressed against the arm 11 of the feeder. However, the piston will slide into the recess 13 only when the feeder arm 11 is moved, i.e. when the main spring 2 is extended. The first shot after releasing the piston will therefore be subject to regulation and the projectile will be fired at a lower muzzle velocity.

The deactivation of the control element 14 takes place in such a way that its movement, i.e. the control element 14 upwards, is prevented. For example, if the spring 16 acts on the piston from below, as in Figures 1 to 6,

-5 CZ 307728 B6 to deactivate the regulator 15 it is necessary to hold the regulating element 14 - the piston in the lower position.

The arm 11 of the feeder is thus not restricted in its operation and moves freely both when moving backwards and when moving forward. Thus, when deactivated, i.e. preventing the control piston from slipping into the recess 13 of the feeder arm 11, the control element 14 has no effect on the muzzle velocity of the projectiles fired from the weapon and the firing principle works in a known manner.

The magnitude of the restriction of the movement of the nozzle 7, i.e. the magnitude of the leak between the nozzle 7 and the seal 9 of the barrel 8, is proportional to the general mathematical function assumed by the nonlinear, resulting muzzle velocity of the projectile fired. The size of the restriction of the movement of the nozzle 7 can thus be regulated by the above-mentioned principle mainly by two factors.

First, the diameter of the end part of the control element 14 - the piston, which is inserted into the recess 13 of the arm 11 of the feeder when the regulator 15 is activated.

Second, the size and geometry of the cutout 13 in the arm 11 of the feeder.

Since it is easier for the user to replace the piston with a piston with a different end diameter, it is assumed to change the size of the control by changing the diameter of the end part of the control element 14 - the piston. When replacing the piston, it is therefore possible to achieve a different magnitude of the control intervention and the associated muzzle velocity. The control thus remains two-state, but the user is able to change the muzzle velocity of the weapon during the control intervention by replacing the control element 14 of the piston, with a piston with a different end diameter.

To illustrate the principle, a control simulation was performed in the described embodiment. In this simulation, such a control intervention was set that the nozzle 7 was stopped at a distance of 0.8 mm before the position with its maximum deflection. Compared to the state with the assumed maximum tightness, the state was simulated in which the nozzle 7 is stopped by the control element 14 at a distance of 0.8 mm shorter. In the state with the maximum deflection of the nozzle 7, i.e. the simulation of the state when the regulator 15 is deactivated, a certain muzzle velocity was monitored, which is considered to be the maximum of the given weapon under the given conditions. Thus, 100% muzzle velocity was relatively achieved. In the state with the deflection of the nozzle 7 shortened by 0.8 mm, i.e. the simulation of the state when the regulator 15 is activated, the muzzle velocity was observed to be 22% lower. In a possible specific embodiment, however, the decrease of the muzzle velocity depends on many factors, such as the stiffness of the spring 2, the tightness of the driving piston 3, the nozzle end 7, or the shape of the seal 9 on the barrel 8. However, the effect of control intervention is noticeable in all variants. it is not possible to predict a specific magnitude of muzzle velocity decrease. The size of the control intervention, however, can be influenced by the above-mentioned factors - the size and geometry of the cut-out 13 of the arm 11 of the feeder, and by changing the diameter of the end part of the piston.

However, it is also possible to use another way of acting on the piston to move it upwards. For example, an electromagnet can be used, which exerts a force on an appropriately oriented second electromagnet, or a permanent magnet, which will exert a force on the modified piston in the desired direction. If the pressure on the piston is exerted by electromagnetic forces, it is possible to use processor control, which could be common with the processor control of the operation of the weapon. The user could thus switch the control states using an electrical switch or microswitch.

However, the control element 14 can be inserted and secured in another way. The piston can be inserted, for example, by the force of the user, or it can be screwed on. Or specific latches may be used. Alternatively, the force element may not be directly part of the movable piston. The piston can, for example, be connected to such an element by a mechanical rod. Another variant of the embodiment can be such that another spring, not shown here, acting on the piston is outside the regulator 15. This further spring pushes the pistons out by its force and pushes another spring into the recess 13 in the feeder arm 11. In the modified regulator 15, it is possible to secure the piston, for example, with a latch, or again to ensure a suitable action of another mechanical element by means of a rod. This can be, for example, the use of a bow 23 or other element of the body 22 of the weapon. In this embodiment, the controller 15 operates in reverse than it is

-6GB 307728 B6 the design described in this chapter is described. Also in this embodiment, tension springs can be used.

In principle, the controller 15 will behave like the controller 15 described in the exemplary embodiment, only its elements will be arranged differently.

In principle, all the described design options will work. The choice of a given design is, however, a matter of design complexity or user requirements.

When applying pressure to the piston in another way, for example if the piston is pushed by the user or the regulator 15 operates in reverse, it may happen that the piston is not constantly pushed on the arm 11 of the feeder. Thus, the piston may slip into the recess 13 of the feeder arm 11 only during one of the following cycles of the weapon. Therefore, a series of shots that are not subject to regulation is not excluded. However, this situation can be prevented by appropriate processor control of the weapon. For example, it is possible to control the operation of the weapon so that the weapon ends the cycle in such a position that the cut-out 13 in the arm 11 of the feeder would be above the space for inserting the piston. For example, weapon control in preload mode, which is already known in the processor control of airsoft weapons. If the user inserts the control element 14 - the piston into the weapon manually, it is necessary to hit the correct place in this mutual position of the piston and the arm 11 of the feeder. This would mean a control intervention for the shot immediately following, as well as in the case of mediating the pressure on the piston as described in the main embodiment in this chapter.

To achieve multi-state control, it is possible, for example, to use a hollow piston in which a larger number of other hollow pistons with a smaller diameter would be inserted concentrically. By activating always one of the pistons of different diameters, the multi-state regulation would then take place. However, this variant is structurally very difficult to implement, but in principle possible.

The specific decrease in muzzle velocity, and associated energy, cannot be generally predicted, as it depends on many factors, as described above. Also, it is not possible to exactly predict a decrease in range. However, it can be stated that all quantities related to the energy of the projectile fired from the weapon will decrease during the regulatory intervention.

The control solution relates in particular to airsoft weapons operating on the principle of electric spring tension, but the use of the principle of the function of the invention in other types of airsoft or air weapons in general is not excluded. The method of regulation can in principle be used for all types of airsoft weapons, by inserting existing modified parts, or by inserting new parts.

In the case of weapons driven by manual tensioning of a spring, there is usually no part in the weapon, such as the arm 11 of the feeder, and so it is necessary to solve the regulation by another technical design. The existing technical design of the cylinder head, which passes smoothly into the nozzle, can be used here. However, the front part of the cylinder head has a large area, which fits close to the surface of the chamber before firing. It is therefore possible to insert a mechanical insert into this space, which prevents the cylinder head from fitting tightly on the chamber. The nozzle connected to the cylinder head is thus stopped again at a shorter distance than in the original position and thus does not rest on the barrel seal and an artificial leak occurs, which causes a control intervention. However, with this method of control solution, there will be no control intervention for the shot immediately following.

In the case of weapons powered by pre-compressed gas, the same fact would be used in the case of the design, since the cylinder, which is usually connected to the nozzle, again has a considerable front surface. However, it does not have to rest directly on the chamber, but the cylinder can be stopped in a suitable position, for example by means of a protrusion in the body of the weapon. Therefore, the technical design of the controller in this case could consist in a variable size of this protrusion.

The intervention of the regulation, made by means of any of the mentioned embodiments, for all types of airsoft weapons is affected by the energy of the projectile fired, and the muzzle velocity of the projectile is explicitly connected with it.

-7 CZ 307728 B6

Industrial applicability

The invention finds use in the field of airsoft weapons. Especially where the user is emphasized about the limited energy of the projectile fired, and the associated muzzle velocity. This can be, for example, short-range shooting. However, it is possible to use a weapon with an activated control system for a longer period of time, for example if there is a flat limit of the muzzle velocity of the weapon within the competition, or other activities in which airsoft weapons are used. The solution can also be used where the target distance is variable, as the controller can be activated immediately before firing. Therefore, if the user fires at a shorter distance, or expects to shoot at a shorter distance, he can set a lower power on the weapon almost immediately. Such a possibility does not yet exist on current airsoft weapons.

Claims (8)

PATENT CLAIMS A pressurized gas gun comprising a body (22) in which a cylinder (4) is disposed at the end of which a head (5) is provided with a nozzle (7) connected to the main (8) by a seal (9) adjacent to the barrel (8) ) located in the projectile chamber (6), characterized in that it comprises at least one regulating element (14) for preventing the nozzle (7) from abutting the seal (9) of the barrel (8) in the active position of the regulating element (14), fuel gas leakage. Compressed gas gun according to claim 1, characterized in that a mechanical box (1) is provided in the body (22) provided with a piston (3) disposed in a cylinder (4) at the end of which is a head (5) provided with a nozzle (7) ) connected to the main (8) located in the projectile chamber (6) and the nozzle (7) connected to the feeder arm (11) provided with a tension spring (10) and a seal (9) between the nozzle (7) and the main (8) ), wherein the feeder arm (11) is provided with a cutout (13) for the control element (14) of the regulator (15) of the feeder arm (11). Compressed gas gun according to claim 2, characterized in that the regulator (15) is located in the space of the switching mechanism (12). Compressed gas gun according to claim 2 or 3, characterized in that the control element (14) is formed by an element selected from the group of a piston, a latch, a drawbar. Compressed gas gun according to claim 2 or 3, characterized in that the control element (14) is formed by a piston provided with a pressure element selected from the group of a compression spring (16), a spring, an electromagnet, a lever. A pressurized gas gun according to any one of the preceding claims, characterized in that the weapon body (22) is provided with an opening (21) for controlling and / or replacing the control element (14). Compressed gas gun according to any one of the preceding claims, characterized in that the control element (14) comprises at least two control pistons. A compressed gas gun according to claim 1, characterized in that the body (22) is a set of elements for compressing air prior to firing by means of a spring (2) acting on the piston (3) located in the cylinder (4).