RU207242U1 - Bullet for smoothbore weapons - Google Patents

Abstract

The utility model relates to ammunition, namely to bullets used in smooth-bore weapons. The technical result of the claimed utility model is to increase the accuracy of fire by increasing the reactive torque to impart axial rotation to the bullet during flight, which has a stabilizing effect, while reducing the loss of powder gases through the bullet twist grooves. The essence of the utility model lies in the fact that a bullet for a smooth-bore weapon contains a head part and a tail part, on the outer cylindrical surface of which grooves are made, and the tail part has a rear end surface. According to the utility model, the bullet head is made with a decreasing cross-section in the direction of the bullet's flight with the formation of a streamlined contour. The head part is made with a diameter, the maximum value of which is less than the diameter of the tail part. Each groove is made through, with the exit of one end of the groove on the rear end surface of the tail part and the exit of the other end of the groove towards the head part. Each groove is made curved with a variable angle of inclination of the helical generatrix of the line, and the angle of inclination of the helical generatrix at the point where the groove exits towards the head part is made larger than the angle of inclination of the helical generatrix at the point where the groove exits on the end surface of the tail part. The depth of the groove is made with a value not exceeding the difference between the radius of the tail section and the maximum radius of the head section.

Description

The utility model relates to ammunition, namely to bullets used in smooth-bore weapons.

Known bullet for shooting from smooth-bore weapons, containing a head and a tail, on the outer cylindrical surface of which grooves are made, while the tail has a rear end surface (RF patent No. 2654115 C1, publ., 16.05.2018).

The disadvantages of the known bullet are the low efficiency of the stabilizing effect of the grooves during the axial rotation of the bullet during movement, as well as the loss of effective pressure due to the low resistance to the flow of powder gases.

The technical result of the claimed utility model is to increase the accuracy of fire by increasing the reactive torque to impart axial rotation to the bullet during flight, which has a stabilizing effect, while reducing the loss of powder gases through the bullet twist grooves.

The problem is solved and the technical result is achieved by the fact that a bullet for a smooth-bore weapon contains a head part and a tail part, on the outer cylindrical surface of which grooves are made, and the tail part has a rear end surface, while, according to the utility model, the bullet head is made with a decreasing transverse section in the direction of the bullet's flight with the formation of a streamlined contour, the head part is made with a diameter the maximum value of which is less than the diameter of the tail part, each groove is made through, with the exit of one end of the groove on the rear end surface of the tail part and the exit of the other end of the groove towards the head part, each groove is made curvilinear with a variable angle of inclination of the helical generatrix of the line, and the angle of inclination of the helical generatrix at the point of exit of the groove towards the head part is made larger than the angle of inclination of the helical generatrix at the point of exit of the groove on the end surface of the tail part, and deep the groove bin is made with a value not exceeding the difference between the radius of the tail section and the maximum radius of the head section.

The technical result is also achieved by the fact that the helical generatrix of the groove at the point of its exit towards the head part can be made at an acute angle to the transverse plane of the bullet.

The technical result is also achieved by the fact that the direction of the helical generatrix of the groove in the place of its exit on the rear end surface of the tail part can be made to coincide with the direction of the bullet's flight.

The technical result is also achieved by the fact that the depth of the groove can be equal to the difference between the radius of the tail section and the maximum radius of the head section.

The utility model is illustrated using drawings.

FIG. 1 is a front perspective view;

FIG. 2 - the same, rear view;

FIG. 3 shows an embodiment with the angles of the exit of the grooves according to paragraphs 2 and 3 of the formula.

The described bullet contains a head part 1 and a tail part 2 having a rear end surface 3. On the outer cylindrical surface of the tail part 2 grooves 4 are made. The head part 1 is made with a diameter the maximum value of which is less than the diameter of the tail part 2. Each groove 4 is made through, with the exit of one end 5 of the groove 4 on the rear end surface 3 and the exit of the other end 6 of the groove 4 towards the head part 1. Each groove 4 is made curved with a variable angle of inclination of the helical generatrix of the line, and the angle of inclination of the helical generatrix at the point where the end 6 of the groove 4 emerges towards the head part 1 is made larger than the angle of inclination of the helical generatrix at the point where the end 5 of the groove 4 emerges on the end surface 3. The depth of the groove 4 is made with a value that exceeds the difference between the radius of the tail part 2 and the maximum radius of the head part 1, for example, at the junction of the head part J with the tail part 2. The depth of the groove 4 can be equal to the difference between the radius of the tail part 2 and the maximum radius of the head part 1. that is, the bottom groove 4 at the exit point of its end 6 coincides with the outer surface of the head part 1.

The helical generatrix of the groove 4 at the exit point of its end 6 towards the head part 1 can be made at an acute angle to the transverse plane of the bullet (see Fig. 3). The smaller the specified angle, for example, 10-30 °, the greater the tangential component from the reactive force of the propellant gases and the less the loss of gases. That is, most of the energy flowing through the grooves 4 gases goes to twist the bullet

When the direction of the helical generatrix of the groove at the exit point of its end 5 on the rear end surface 3 coincides with the direction of the bullet's flight (see Fig. 3), the resistance to the passage of gases to the end 6 of the groove 4 decreases. adjacent to its screw part. In this case, the rectilinear outlet section of the groove 4 can be located along the generatrix of the cylinder on the outer surface of the tail part 2.

The described utility model is used as follows. When the combustion products expand, they flow through the grooves 4. In this case, the gases enter the groove 4 from its end 5 on the rear end surface 3 at a slight angle to the longitudinal plane of the bullet, that is, almost along the generatrix of the tail section 2. With further movement of the gases along groove 4, the angle of inclination to the specified longitudinal plane increases and reaches almost a right angle, forming an acute angle with the transverse plane of the bullet at the exit from the end 6 of the groove 4. The reactive force of gases created in this way is directed at the lowest possible (as far as the technology of making grooves 4 allows) angle to the transverse plane of the bullet. That is, most of the energy of gases is directed for its intended purpose: to twist the bullet around its longitudinal geometric axis. This reduces the longitudinal energy component, that is, the lost energy that is not used to spin the bullet. This implementation allows you to optimize the shape and cross-section of the grooves 4 with an increase in the energy used for the flight of the bullet and an increase in the degree of twist of the bullet and, accordingly, the accuracy of fire.

Claims (4)

1. A bullet for smooth-bore weapons, containing a head and a tail, on the outer cylindrical surface of which grooves are made, while the tail has a rear end surface, characterized in that the head is made with a decreasing cross-section in the direction of the bullet flight with the formation of a streamlined contour , the head part is made with a diameter, the maximum value of which is less than the diameter of the tail part, each groove is made through, with the exit of one end of the groove on the rear end surface of the tail part and the exit of the other end of the groove towards the head part, each groove is made curved with a variable angle of inclination of the helical generating line, and the angle of inclination of the helical generatrix at the point where the groove exits towards the head part is made larger than the angle of inclination of the helical generatrix at the point where the groove exits on the end surface of the tail part, and the depth of the groove is made with a value not exceeding the difference in tail radius howling part and the maximum radius of the head part. 2. The bullet according to claim. 1, characterized in that the helical generatrix of the groove in the place of its exit towards the head part is made at an acute angle to the transverse plane of the bullet. 3. A bullet according to claim 1, characterized in that the direction of the helical generatrix of the groove at the point of its exit on the rear end surface of the tail section is made to coincide with the direction of the bullet's flight. 4. A bullet according to claim. 1, characterized in that the depth of the groove is equal to the difference between the radius of the tail section and the maximum radius of the head section.

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