RU2655574C2 - Mine structure of command post - Google Patents

Abstract

FIELD: weapon.

SUBSTANCE: invention relates to fortification structures. Mine structure of the command post contains a protective device with an upper and lower bases, a compound trunk of the shaft in the form of a straight truncated cone, in which n sections there are technological, testing and starting equipment and technical systems, the upper base being at the level of the ground surface. Upper base of the trunk is connected to the lower base of the protective device. Lower base of the trunk is connected to the base of the shaft.

EFFECT: technical result of the invention is an increase in the volume of all sections and the volume of the mine as a whole, increasing the security of the mine structure.

1 cl, 1 tbl, 1 dwg

Description

The invention relates to the field of underground fortifications and can be used as a mine structure of a command post.

A mine structure of a command post comprising a protective device with upper and lower bases, a composite shaft of a mine in the form of a toroid with upper and lower bases, in which n sections with technological, test and starting equipment and technical systems are located, the upper base of the protective device corresponding to the surface, is known soil, the lower base of the specified device is connected to the upper base of the composite shaft of the shaft, and the lower base of the named shaft is connected to the base of the shaft, all n se tions composite shaft barrel as a toroid have the same height and the same area of its own base [1]. This construction, similar to the construction of mine launchers, has been widely used in fortification [2, 3, 4], but it also has drawbacks, among which the main ones are: significant trunk height with a large number of sections, which affects the security of the object (launcher or command post) [5], the relatively small diameter of the shaft of the mine, which reduces the stability of these objects, and the same volume of sections, which makes it difficult to place equipment and systems that have a significant number of units and devices.

The technical result of the invention is to increase the security of the mine structure by reducing the height of the shaft.

где h_i - высота секции или конуса; R_1i - радиус верхнего основания секции или конуса; R_2i - радиус нижнего основания указанной секции или конуса, при этом отношение объема n-й секции к объему первой секции

где k₂ - коэффициент роста объема усеченного конуса, отношение высоты конуса с нулевым углом наклона боковой поверхности (тороида) к коэффициенту роста его объема

где h₁ - высота конуса, а отношение высоты конуса к высоте тороида

где k₃ - коэффициент уменьшения высоты ствола шахты.The required technical result is achieved by the fact that in the shaft structure of the command post containing a protective device with upper and lower bases, a composite shaft of the shaft with upper and lower bases, containing n sections in which are located: technological equipment, test and start-up equipment and technical systems, moreover, the upper base of the protective device is at the level of the soil surface, the lower base of the protective device is connected to the upper base of the specified trunk, the lower base is called the barrel is connected to the base of the shaft, while the total volume of technological, test and start-up equipment and technical systems corresponds to the volume of the composite shaft of the shaft, the composite shaft of the shaft is made in the form of a straight truncated cone, the diameter of the upper base of which is proportional to the diameter of the shaft, and the diameter of the lower base is proportional to the angle the inclination of the lateral surface of the specified cone to the longitudinal axis of the structure (the lateral surface of the toroid), while the value of the i-th inclination angle is determined by the formula α _i = 10 ° m, where e m - sequence number of the angle measured from the center line of said cone, wherein diameters at the first corner of the lower base sections of all changed by the rule d = d _{1i VC} + 0,25k, _VC where d - diameter of the upper base of the truncated cone; k is the section number; the second angle of the diameters of the lower base sections of all changed by the rule d _2i = d _VC + 0,5k, and at the third carbon of the lower base diameters vary according to the rule d _3i = d _VC + 0,75k, the volume of said cone and the i-th section is determined according to the formula

where h _i is the height of the section or cone; R _1i is the radius of the upper base of the section or cone; R _2i is the radius of the lower base of the indicated section or cone, while the ratio of the volume of the nth section to the volume of the first section

where k ₂ is the growth coefficient of the volume of the truncated cone, the ratio of the height of the cone with a zero angle of inclination of the side surface (toroid) to the growth coefficient of its volume

where h ₁ - the height of the cone, and the ratio of the height of the cone to the height of the toroid

where k ₃ is the coefficient of reduction in the height of the shaft of the mine.

The drawing shows a longitudinal section of a conical shaft of the shaft structure of the command post.

The mine structure contains a protective device (not shown), a composite shaft of a conical shaft 1 with several lateral surfaces 1-1, with sections 2, 3, 4, 5, 6, 7, 8 and 9, the upper base 10 and the lower base 11. The lateral surfaces 1-1 of the conical shaft of the shaft 1 are formed due to the angles Oab, Оас and Oag, located to the left of the center line kk 'and the angles O'a'b', О'а'с ', O'a'g', located to the right of the center line kk '. The upper base 2-1 of section 2 coincides with the upper base of the conical barrel 10, and its lower base 2-2 coincides with the upper base 3-1 of section 3, the lower base 3-2 of section 3 coincides with the upper base 4-1 of section 4, lower the base 4-2 of section 4 coincides with the upper base 5-1 of section 5, the lower base 5-2 of section 5 coincides with the upper base 6-1 of section 6, the lower base 6-2 of section 6 coincides with the upper base 7-1 of section 7, the lower base 7-2 of section 7 coincides with the upper base 8-1 of section 8, the lower base 8-2 of section 8 coincides with the top their base sections 9 9-1, 9-2 lower base section 9 coincides with the upper base 11, a conical tapered shaft barrel 1. The barrel height h ₁ and the height of the sections 2 ... 9 are denoted by h ₂ ... h _9, respectively, wherein the sum of the heights h ₂ ... h ₉ is equal to the total height of the barrel h ₁ , i.e.

The area of all the bases of all sections 2 ... 9 and the bases 10 and 11 of the conical trunk 1 are determined by the standard formula

where S _i is the area of the i-th base; D _i - the diameter of the i-th section (lower or upper base of the barrel).

The angles of inclination of the side surface to the left and to the right of the center line kk 'are determined by the formula

where m is the serial number of the angle, counted from the centerline of the composite barrel 1 to the right or left.

At the first angle α ₁ = 10 °, the diameters of the lower bases: 2-2, 3-2, 4-2, 5-2, 6-2, 7-2, 8-2 and 9-2 of sections 2 ... 9 change according to the rule

where d _VK - the diameter of the upper base 10 of the truncated cone; k is the section number.

At the second angle α ₂ = 20 °, the diameters of the lower bases 2-2 ... 9-2 of sections 2 ... 9 are changed according to the rule

and at the third angle α ₃ = 30 °, the diameters of the lower bases 2-2 ... 9-2 of sections 2 ... 9 change according to the rule

The volume of the specified cone and i-th section are determined by the formula

where h _i is the height of the section or cone; R _1i is the radius of the upper base of the section or cone; R _2i is the radius of the lower base of the specified section or cone.

The volume of sections 2 ... 9 and conical trunk 1 are summarized in table 1 (in relative units).

To determine the growth rate of the trunk volume 1 at the first angle, we find the volume ratios of section 9 and section 2

and to find the volume growth coefficient at the second angle, we take the ratio

whence it follows that at an angle α ₁ = 10 ° the volume of sections increased by one and a half times, and at an angle α ₂ = 20 ° it doubled, i.e. the coefficients k ₂₁ and k ₂₂ are growth factors for the volume of the truncated cone.

If we take the scale of the drawing, where the height of the shaft of the shaft is 21 cm, then you can get the heights of the conical shaft of the shaft with the corresponding growth factors for the volume of the truncated cone, i.e.

wherein

where k ₃₁ , k ₃₂ are the coefficients for reducing the shaft height at different angles of inclination of the lateral surface of the truncated cone (k ₃₁ for α ₁ ; k ₃₂ for α ₂ ). The mine structure of the command post is used as follows.

In accordance with the plan for the deployment of command posts, the geographical coordinates of the point at which the mine is equipped, in which the shaft of the shaft 1 of the conical shape is installed, are selected, while its lower base 11 is attached to the base of the shaft (not shown). After the installation of the conical trunk in its section 2 ... 9, technological, test and start-up equipment and technical systems are installed. After completing the barrel, a protective device (not shown) is installed on it so that the lower base (not shown) of the protective device is fixed on the upper base 10 of the conical barrel 1. Next, a series of tests of units and devices, as well as technical systems, are performed and with positive results Test conical shaft of the mine is put into operation according to the established program.

Thus, an increase in the angle of inclination of the lateral surface of a straight truncated cone makes it possible to significantly reduce the height of the composite shaft and shaft as a whole with the same value of the given volume, which achieves the desired result.

Information sources

1. Leontenkov A.A., Vasiliev G.Yu., Borisenko B.C. Unparalleled. M., Inter-scales, 2001, 192 p.

2. Chikalov N.V., Deryushev V.V. Launchers and command posts of missile systems. M., Ministry of Defense of the Russian Federation, 2005, 350 p.

3. Malikov V.G. Mine launchers. M., Military Publishing, 1975, 128 pp.

4. Mine launchers. Ed. Yu.P. Perfilieva. M., MSTU them. N.E. Bauman, 2006, 352 pp.

5. Technical fundamentals of the effectiveness of rocket systems. Ed. E.B. Volkova. M., Mechanical Engineering, 1990, pp. 215 ... 216.

Claims (1)

The mine structure of the command post, containing a protective device with upper and lower bases, a composite shaft of the shaft with upper and lower bases, containing n sections in which are located: technological equipment, test and start-up equipment and technical systems, and the upper base of the protective device is at the level the surface of the soil, the lower base of the protective device is connected to the upper base of the specified trunk, the lower base of the named trunk is connected to the base of the shaft, while the total the volume of technological, test and start-up equipment and technical systems corresponds to the volume of the composite shaft of the shaft, characterized in that the composite shaft of the shaft is made in the form of a straight truncated cone, the diameter of the upper base of which is proportional to the diameter of the shaft, and the diameter of the lower base is proportional to the angle of inclination of the side surface of the specified cone to the longitudinal axis of the structure, while the value of the i-th angle of inclination is determined by the formula α _i = 10 ° m, where m is the serial number of the angle measured from the center line Foot of the cone, wherein at the first corner of the lower base diameter of all the sections vary according to the rule d = d _{1i VC} + 0,25k, _VC where d - diameter of the upper base of the truncated cone; k is the section number; the second angle of the diameters of the lower base sections of all changed by the rule d _2i = d _VC + 0,5k, and at the third carbon of the lower base diameter of all the sections vary according to the rule d _3i = d _VC + 0,75k, the volume of said cone and the i-th section is determined by the formula

where h _i is the height of the section or cone; R _1i is the radius of the upper base of the section or cone; R _2i is the radius of the lower base of the indicated section or cone, the ratio of the volume of the nth section to the volume of the first section V _n / V ₁ = k ₂ , where k ₂ is the growth coefficient of the volume of the truncated cone, the ratio of the height of the cone with a zero angle of inclination of the lateral surface to the growth coefficient of its volume h _k0 / k ₂ = h ₁ , where h ₁ is the height of the cone, and the ratio of the height of the cone to the height of the cone with a zero angle of inclination of the side surface h ₁ / h _k0 = k ₃ , where k ₃ is the reduction coefficient shaft height.

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