RU2166172C1 - High-explosive warhead - Google Patents

Abstract

FIELD: ammunition of jet artillery. SUBSTANCE: high-explosive warhead of a jet projectile has a fuze, detonator, fairing, body, explosive charge, with a block of ready-made fragments located between them, and a bottom. The fairing and the bottom are made in the form of truncated cones, whose larger bases are fastened to the body; the angles of inclination of the internal surfaces forming them to the warhead longitudinal axis are selected within

Positioned in the points of attachment of the body with the fairing and bottom are the front and rear ring reflectors with width h_n= (0,035...0,07)L, h₃= (0,01...0,035)L and inside diameters d_n= (0,75...0,85)D and d₃= (0,6...0,7)D respectively, where θ₁ and θ₂ are angles of inclination of the generating internal surfaces of the fairing and bottom to the warhead longitudinal axis; h_n and h₃ is width of the front and rear ring reflectors; L is body length; d_n and d₃ is inside diameter of the front and rear reflectors; D is warhead caliber. EFFECT: reduced loss of energy for end divergence of detonation products, enhanced speed and angle of divergence of fragments, enhanced efficiency of warhead hitting of manpower and non-armored equipment. 1 dwg

Description

 The invention relates to the field of rocket technology, in particular to the designs of warheads of rockets, and can be widely used in the development of rockets of multiple launch rocket systems (MLRS).

 As you know, work is currently underway to improve the warheads of rockets in order to improve their tactical and technical characteristics (the damaging effects of shells, accuracy and firing range).

 Improvement of the tactical and technical characteristics (TTX) of shells is achieved mainly through the use of new materials in their units and parts, taking into account the establishment of optimal ratios of the geometric and physical parameters of individual units and elements that are in functional communication.

 So, known: "High-explosive shell", US Pat. Great Britain N 1364180, F 42 B 13/12 ("Inventions Abroad", issue 24, N 18, 1974, p. 2), "High-explosive shell", US Pat. Great Britain N 1411912, cl. F 42 B 13/12 ("Inventions Abroad", issue 24, No. 18, 1975, p. 3), "Fragmentation projectile" pat. Germany N 1199162, class 72 d 17/12 (R.Zh. "Armament", N 10, 1967), "Shell shell", Pat. Germany N 1453815, class 72 d 18/01 (R.Zh. "Armament", N 24, 1972), "High-explosive fragmentation shell", US Pat. France N 1588755.

 The design of the warheads of these shells consists of a conical-shaped body containing a head fuse, detonator and explosive. When the projectile comes into contact with the ground (near the target), when the fuse detonates, the explosive detonates, its shock wave, as well as fragments of the warhead’s body, affect both the enemy’s manpower and armored equipment outside the shelter.

 Significant disadvantages of these high-explosive fragmentation shells are large energy losses during charge explosion and insufficiently high fragmentation effect.

 Known rocket increased efficiency, US Pat. U.S. N 3742856, CL 102-67, F 42 B 13/48 (R.Zh. "Armament" N 9, 1974), the warhead of which contains ready-made fragments that hit the enemy’s manpower with an explosive explosive.

 The disadvantage of the design of the warhead of the said projectile is a large loss of energy due to the release of detonation products from its ends, which, at small angles of approach of the projectile to the target, the area of the affected zone decreases sharply, and therefore, the projectile's efficiency decreases.

Common signs with the warhead proposed by the authors is the presence of a fuse, detonator, block of ready-made fragments of an explosive charge. (See L. S. Barkan, P. P. Ganichev et al. “Design and operation of artillery shells”, VAA named after Dzerzhinsky, Moscow, 1956, B. A. Prokhorov “Ammunition of artillery”, “Engineering”, Moscow, 1973). Currently, the main criterion for the effectiveness of shells is the area of the reduced fragmentation zone - S _ave .

 The striking effect of the warhead of the projectile depends on the properties and power of its damaging factors (fragments, shock wave, etc.). When evaluating the action of a warhead, the combined effect of all its damaging factors is usually taken into account.

 Suppose, at the point with the coordinates X, Y, the warhead broke. We denote by G (X, Y) the probability of hitting an elementary target located on a horizontal plane at the origin. The considered dependence G (X, Y) of the probability of hitting the target from the coordinates of the discontinuity points of the warhead of the remote action is called the coordinate law of destruction.

 As studies have shown, the coordinate laws of destruction have a different form depending on the nature of the target, the power of ammunition and other conditions.

 When considering these laws, three different areas are located around the center of the target.

One of these areas (S _d ) is characterized in that the rupture of the warhead at any point always leads to the destruction of the target. This area is called the area of significant lesions. This is followed by the area (S _n ), where the rupture of the warhead does not necessarily lead to the defeat of the target. This area is called the area of unreliable lesions. Then there is a region (S _σ ) in which the gaps do not harm the target; it is called the safe gaps region.

The form of the coordinate law of lesions is simplified by expanding the field of reliable lesions due to the region of unreliable lesions. The resulting expanded area of significant lesions is called the reduced lesion area (S _CR ), and its size is the reduced target size. For all points of the reduced lesion zone in accordance with its definition, G (X, Y) = 1, and outside this zone G (X, Y) = 0. In other words, the area of the reduced lesion zone (S _CR ) is equal to the sum of the products of elementary areas d in the region of the shell rupture on the probability of target G being hit at these sites, i.e.

и зависит от массы боевой части, массы взрывчатого вещества (ВВ), типа ВВ, формы и массы осколков, угла и скорости подхода снаряда к цели, скорости и угла разлета осколков, высоты подрыва боевой части (см. Н.М. Фендриков, В. И. Яковлев "Методы расчетов боевой эффективности вооружения", Военное издательство Министерства Обороны СССР, Москва, 1971 г.).

and depends on the mass of the warhead, the mass of explosives (explosives), the type of explosives, the shape and mass of the fragments, the angle and speed of approach of the projectile to the target, the speed and angle of expansion of the fragments, the height of the detonation of the warhead (see N.M. Fendrikov, V I. Yakovlev, "Methods for calculating the combat effectiveness of weapons," Military Publishing House of the USSR Ministry of Defense, Moscow, 1971).

 The closest in technical essence and the technical result achieved is the high-explosive fragmentation warhead 9H55 of the 9M28 missile, adopted by the authors as a prototype (see 9P138 Combat Vehicle, “Technical Description and Operation Manual”, part III, book 1, M., Military Publishing House, 1986, p. 6).

 The specified warhead contains a fuse, detonator, fairing, body, explosive charge, between which is a block of finished fragments and the bottom.

 For warheads of this design, it is known that the explosive charge mass significantly affects the rate of fragment fragmentation, on which the effectiveness of unarmored technology depends significantly, and the reduced area of destruction for rockets suitable for a small angle to the target depends on the angle of fragmentation of the fragments about twice.

 Thus, the problem of increasing the active mass of the explosive charge, the speed and angle of expansion of the fragments, the proper organization of the detonation process in the warhead is relevant.

 The objective of the known technical solution (prototype) was to create a warhead of increased power by increasing the active mass of the explosive charge and using a block of ready-made fragments, but without presenting requirements for obtaining optimal characteristics of the warhead by optimizing the placement of its structural elements and selecting their parameters.

 The disadvantages of this warhead are significant energy losses at the end expansion of detonation products and a small angle of flight of fragments, which significantly reduces the effectiveness of the warhead as a whole.

 Common signs with the warhead proposed by the authors is the presence of a fuse, detonator, fairing, body, explosive charge, a block of finished fragments and the bottom.

в местах крепления корпуса с обтекателем и дном размещены передний и задний кольцевые отражатели шириной h_п = (0,035...0,07)L, h_з = (0,01... 0,035)L, а их внутренние диаметры соответственно d_п = (0,75...0,85)D, d_з = (0,6...0,7)D, где
Θ₁, Θ₂ - углы наклона образующих внутренних поверхностей обтекателя и дна к продольной оси боевой части;
h_п, h_з - ширина переднего и заднего кольцевого отражателя;
L - длина корпуса;
d_п, d_з - внутренний диаметр переднего и заднего кольцевого отражателя;
D - калибр боевой части.Unlike the prototype, in the warhead proposed by the authors, the fairing and the bottom are made in the form of truncated cones, which are fastened with large bases to the body, while the angles of inclination of their inner surfaces to the longitudinal axis of the warhead are selected within

front and rear annular reflectors with a width of h _p = (0,035 ... 0,07) L, h _h = (0,01 ... 0,035) L, and their inner diameters respectively d _p = (0.75 ... 0.85) D, d _s = (0.6 ... 0.7) D, where
Θ ₁ , Θ ₂ - the angle of inclination of the generatrices of the inner surfaces of the fairing and the bottom to the longitudinal axis of the warhead;
h _p h _h - the width of the front and rear annular reflector;
L is the length of the housing;
d _p, d _s - internal diameter of the front and rear annular reflector;
D - caliber warhead.

 It is this that allows us to conclude that there is a causal relationship between the totality of the essential features of the claimed technical solution and the achieved technical result.

 These signs, distinctive from the prototype, to which the requested amount of legal protection applies, in all cases are sufficient.

 The objective of the invention is to create a warhead of a rocket providing an increase in the speed and angle of expansion of fragments and, therefore, increasing the efficiency of fragmentation in manpower and unarmored vehicles by reducing energy loss on the end emission of detonation products and thereby increasing the efficiency of the combat use of a rocket .

где Θ₁, Θ₂ - углы наклона образующих внутренних поверхностей обтекателя и дна к продольной оси боевой части, в 2...3 раза уменьшить потери энергии на торцевой разлет продуктов детонации, на 10-15% повысить скорость разлета осколков и в 1,8. . .2,0 раза увеличить угол разлета осколков и, следовательно, повысить эффективность осколочного действия боевой части в целом;
- размещения в местах крепления корпуса с обтекателем и дном переднего и заднего кольцевого отражателя шириной h_п= (0,035...0,07)L, h_з = (0,01... 0,035)L, а их внутренних диаметров соответственно d_п = (0,75...0,85)D, d_з = (0,6...0,7)D,
где h_п, h_з - ширина переднего и заднего кольцевого отражателя;
L - длина корпуса;
d_п, d_з - внутренний диаметр переднего и заднего кольцевого отражателя;
D - калибр боевой части,
дополнительно на 25. ..30% уменьшить потери энергии на торцевой разлет продуктов детонации, на 3...5% повысить скорость разлета осколков и на 10... 15% увеличить угол разлета осколков и, следовательно, повысить эффективность осколочного действия боевой части в целом.The new implementation of individual units and parts of the warhead, as well as the optimal ratio of sizes and other parameters allows due to
- perform fairing and the bottom in the form of truncated cones, which are fastened with large bases to the body, and the angles of inclination of the internal surfaces forming them to the longitudinal axis of the warhead selected within

where Θ ₁ , Θ ₂ are the angles of inclination of the generatrix of the inner surfaces of the fairing and the bottom to the longitudinal axis of the warhead, reduce energy losses by the end expansion of detonation products by 2 ... 3 times, and increase the speed of the expansion of fragments by 10-15%, and by 1, 8. . .2.0 times increase the angle of flight of fragments and, therefore, increase the efficiency of fragmentation of the warhead as a whole;
- placement in the places of attachment of the housing with a fairing and the bottom of the front and rear annular reflectors of width h _p = (0,035 ... 0,07) L, h _h = (0,01 ... 0,035) L, and their internal diameters, respectively d _n = (0.75 ... 0.85) D, d _s = (0.6 ... 0.7) D,
where h _p h _h - the width of the front and rear annular reflector;
L is the length of the housing;
d _p, d _s - internal diameter of the front and rear annular reflector;
D - caliber warhead,
additionally 25. ..30% reduce energy loss at the end expansion of detonation products, increase the flight speed of fragments by 3 ... 5% and increase the flight angle of fragments by 10 ... 15% and, therefore, increase the efficiency of fragmentation action of the warhead generally.

 A decrease in energy losses at the end expansion of detonation products and, as a result, an increase in the velocity and angle of expansion of the fragments is achieved by the fact that the angles of inclination of the internal components of the front and rear cones to the longitudinal axis of the warhead are selected from experimentally determined angles of inclination of the cones (φ) during the explosion of an explosive charge substances.

 From experimental work (see Sutterlin R. Les hrojectives. Memorial de 'artilleric francaiso, 1967 t 41 N 159), a relation is known for determining the declination angle φ = Θ / 2, where φ is the angle between the generatrix of the shell and the longitudinal axis of the warhead with a charge explosion.

в зависимости от показателя политропы k. Отсюда угол наклона внутренней образующей переднего конуса к продольной оси боевой части определяется соотношением:

Для реальных составов, применяемых в осколочно-фугасных боевых частях снарядов РСЗО, показатель политропы k меняется в пределах 2,65...3,2. Исходя из этого, для осколочно-фугасной боевой части РСЗО, угол наклона внутренней образующей переднего конуса к продольной оси боевой части установлен в пределах:

что позволяет исключить из заряда взрывчатое вещество за пределами Θ₁, так как для зарядов в реальной осколочной части оно не участвует в метании осколков.From the work (see Abarbanel S. The deflection of Journal of Techology, 1966, Vol. 4, N 1, p. 77-81), a relationship is confirmed experimentally confirmed by choosing the optimal angle Θ:

depending on the polytropic index k. Hence, the angle of inclination of the inner generatrix of the front cone to the longitudinal axis of the warhead is determined by the ratio:

For real compositions used in high-explosive fragmentation warheads of MLRS shells, the polytropic index k varies between 2.65 ... 3.2. Based on this, for high-explosive fragmentation warhead MLRS, the angle of inclination of the inner generatrix of the front cone to the longitudinal axis of the warhead is set within:

which allows us to exclude explosives from the charge beyond Θ ₁ , since for charges in the real fragmentation part it does not participate in throwing fragments.

Experiments show that this technical solution makes it possible to exclude from the region close to the ends of the charge an explosive that is not involved in throwing fragments, which means a 2 ... 3 times reduction in energy loss at the end expansion, increase by 10 ... 15% fragment scatter speed. The design of the claimed warhead allows 1.8 .... 2 times to increase the angle of flight of fragments (for known high-explosive fragmentation warheads, the angle of flight of fragments does not exceed 15 - 20 ^o ).

в местах крепления корпуса с обтекателем и дном размещены передний и задний кольцевые отражатели шириной h_п = (0,035...0,07)L, h_з = (0,01... 0,035)L, а их внутренние диаметры соответственно d_п = (0,75...0,85)D, d_з = (0,6...0,7)D,
где Θ₁, Θ₂ - углы наклона образующих внутренних поверхностей обтекателя и дна к продольной оси боевой части;
h_п, h_з - ширина переднего и заднего кольцевого отражателя;
L - длина корпуса;
d_п, d_з - внутренний диаметр переднего и заднего кольцевого отражателя;
D - калибр боевой части.The essence of the invention lies in the fact that the warhead containing a fuse, detonator, fairing, body, explosive charge, between which is a block of finished fragments and the bottom, in contrast to the prototype, according to the invention has a fairing and bottom, made in the form of truncated cones, which are fastened with large bases to the body, while the angles of inclination of the inner surfaces forming them to the longitudinal axis of the warhead are selected within:

front and rear annular reflectors with a width of h _p = (0,035 ... 0,07) L, h _h = (0,01 ... 0,035) L, and their inner diameters respectively d _p = (0.75 ... 0.85) D, d _s = (0.6 ... 0.7) D,
where Θ ₁ , Θ ₂ are the angles of inclination of the generatrices of the inner surfaces of the fairing and the bottom to the longitudinal axis of the warhead;
h _p h _h - the width of the front and rear annular reflector;
L is the length of the housing;
d _p, d _s - internal diameter of the front and rear annular reflector;
D - caliber warhead.

 The invention is illustrated in the drawing, where in FIG. 1 shows a General view of the warhead.

 The proposed warhead contains a fuse 1, a detonator 2, an explosive charge 3, a fairing 4, a front annular reflector 5, a housing 6, a block of finished fragments 7, a rear annular reflector 8 and the bottom 9.

 The front 5 and rear 8 ring reflectors are located in the places of attachment of the housing 6 with a fairing 4 and a bottom 9.

 The fairing 4 and the bottom 9 are fastened with large bases to the body 6, the warhead is filled with a charge of explosive 3, and between the body 6 and the charge of explosive 3 there is a block of finished fragments 7, between the fairing 4 and the body 6 there is a front annular reflector 5, and between the bottom 9 and the housing 6 is placed rear annular reflector 8.

 The work of the proposed high-explosive fragmentation warhead is as follows: when meeting with an obstacle fuse 1 with a detonator 2, which initiates a charge of explosive 3.

 The detonation wave propagating along the explosive charge 3 is reflected from the fairing 4 and the front annular reflector 5 to the side and along the axis of the explosive charge 3.

 The centered rarefaction wave moves in the region of the housing 6 and the block of finished fragments 7. The process is then carried out due to the relative position of the forward and backward (reflected) shock waves, while the rear annular reflector 8 and the bottom 9 additionally disturb the detonation process by reflection and refraction of shock waves moving to the rear end of the charge. At the points of intersection of the shock waves, a region of increased pressure arises, under the influence of which a more complete and faster chemical transformation of the explosive 3 occurs. Due to this, the efficiency of the charge of the explosive 3 increases significantly, which ultimately increases the speed and angle of expansion of the fragments and, therefore , fragmentation effect.

где Θ₁ и Θ₂ - углы наклона образующих внутренних поверхностей обтекателя 4 и дна 9 к продольной оси боевой части позволяет в 2...3 раза уменьшить потери энергии на торцевой разлет продуктов детонации, на 10...15% повысить скорость разлета и в 1,8...2 раза увеличить угол разлета осколков и, следовательно, повысить эффективность осколочного действия боевой части в целом.The use of the fairing 4 and the bottom 9, made in the form of truncated cones, which are fastened with large bases to the body 6 with the implementation of the angle of inclination of their internal surfaces to the axis of the warhead within:

where Θ ₁ and Θ ₂ are the angles of inclination of the generatrices of the inner fairing 4 and the bottom 9 to the longitudinal axis of the warhead to reduce energy losses by the end expansion of detonation products by 2 ... 3 times, increase the expansion speed by 10 ... 15% and by 1.8 ... 2 times increase the angle of flight of fragments and, therefore, increase the efficiency of fragmentation action of the warhead as a whole.

 When the angle of inclination of the generatrices of the inner surfaces of the fairing 4 and the bottom 9 is less than 0.3 π / 4 mm or more than 0.5 π / 4, the energy losses at the end expansion of detonation products are significantly increased, the velocity and angle of expansion of the fragments decrease, and the efficiency decreases sharply warhead.

When placed in the attachment points of the housing 6 with the fairing 4 and the bottom 9 of the front 5 and rear 8 ring reflectors with a width of h _p = (0.035 ... 0.07) L, h _z = (0.01 ... 0.035) L, and their inner diameters, respectively, d _p = (0.75 ... 0.85) D, d _s = (0.6 ... 0.7) D,
where h _p h _h - the width of the front and rear annular reflector;
L is the length of the housing;
d _p, d _s - internal diameter of the front and rear annular reflector;
D is the caliber of the warhead,
allows to additionally reduce by 25 ... 30% the energy loss at the end expansion of detonation products, by 3 ... 5% increase the rate of expansion of fragments and by 10 ... 15% increase the angle of expansion of fragments and, as a result, increase the efficiency of fragmentation warhead for manpower and unarmored vehicles.

 If these ratios of the internal diameters of the annular reflectors deviate in one direction or another, this leads to a sharp decrease in the effect obtained.

 The proposed warhead allows due to the implementation of the fairing 4 and the bottom 9 in the form of truncated cones fastened with large bases to the body 6, while performing the angles of inclination of the inner surfaces forming them to the longitudinal axis of the warhead within the specified limits, and in the places of attachment of the body 6 to the fairing 4 and bottom 9 of the placement of the front 5 and rear 8 ring reflectors with optimal ratios of the geometric dimensions of the nodes and parts significantly increase the efficiency of its use in manpower and unarmored bathroom appliances.

 Tests have confirmed that the effectiveness of the proposed warhead exceeds the known (prototype) in fragmentation action of 1.25 ... 1.35 in the defeat of manpower and unarmored vehicles.

 At present, technical documentation has been developed, state tests have been carried out, and mass production is scheduled.

Claims (1)

A high-explosive fragmentation warhead containing a fuse, detonator, fairing, body, explosive charge, between which a block of finished fragments is located, and a bottom, characterized in that the fairing and bottom are made in the form of truncated cones, which are fastened with large bases to the body, the angles of inclination of the inner surfaces forming them to the longitudinal axis of the warhead are selected within

front and rear annular reflectors with a width of h _p = (0,035 ... 0,07) L, h _h = (0,01 ... 0,035) L, and their internal diameters are respectively d _n = (0.75 ... 0.85) D and d _z = (0.6 ... 0.7) D, where Θ ₁ and Θ ₂ are the angles of inclination of the generatrices of the inner surfaces of the fairing and the bottom to the longitudinal axis of the combat parts; h _p and h _z - the width of the front and rear annular reflectors; L is the length of the housing; d _p and d _z - the inner diameter of the front and rear annular reflectors; D - caliber warhead.