RU192765U1 - SEPARATING BATTLE PART WITH PLANNING BATTLE BLOCKS - Google Patents

Abstract

The utility model relates to the field of military equipment, in particular to missile and artillery weapons, and can be used in the development and creation of combat units of modern operational tactical and tactical missiles (OTP and TP). The technical result is a divided warhead with planning warheads (PBB). The essence of the utility model is that the application of the proposed type of warheads will increase the range of existing OTP and TP without changing the launch vehicle, increase the likelihood of overcoming missile defense (by increasing the number of intercepted targets) the reliability and accuracy of the onboard control system (BSU) of the rocket as a whole (due to the presence of a BSU for each BSP and their integration into one, until the BSP is bred). In addition, the material costs associated with the need to use a large number of missiles (with the existing nomenclature of warheads) will be reduced to defeat diverse and group targets.

Description

The utility model relates to the field of military equipment, in particular to missile and artillery weapons, and can be used in the development and creation of combat units of modern operational-tactical missiles - OTP and tactical missiles - TR.

As an analogue to the proposed utility model, a separable warhead can be adopted - RBC of the famous TP "Point".

The prototype of the claimed utility model is the currently known RBC of the Iskander launch vehicle, which consists of a hull with hatches, a central beam with a cable trunk, a truss holding warheads - BB, an onboard control system - BSU for diluting BB, powder charges for ejection BB through hatches [1].

This RBC have the following disadvantages:

- the dispersion of combat elements is carried out according to the normal law, as a result of which, they are able to effectively hit only area targets with the identical distribution law of elementary objects;

- combat elements have a small explosive charge and light fragments, as a result of which they are suitable only for the destruction of openly located manpower and unarmored vehicles.

The technical result of the utility model is to increase the efficiency of the RBC by increasing the range of the missile with overcoming missile defense due to the properties of the BB.

The necessary technical result of the utility model is achieved by the fact that the separable warhead of an operational-tactical missile consists of a hull with hatches, a central beam with a cable trunk, a truss that holds warheads - BB, onboard control system - BSU for diluting BB, powder charges for pushing BB through hatches, while BB is made with rudders and wings to ensure their planning, each of the planning BB-PBB has its own BSU, integrated into one before breeding PBB and provided with the possibility of scatter and PBB along the flight path of an operational-tactical missile with established time intervals, maneuvering of the PBB and communication with the satellite navigation system, while part of the BSB of the PBB has the ability to reserve from the BSU of a tactical missile, and one of the BSU of the PBB can be used as a launch for operational tactical missiles.

Such a missile defense system can be separated at a considerable distance from the target, which will increase the range of the existing operational tactical missiles by several tens of kilometers and increase the likelihood of missile defense - missile defense. The use of RBF with PBB allows you to:

- to perform effective atmospheric maneuvering of the air safety system along the entire flight path (due to equipping with rudders and wings);

- reduce EPR in all ranges of operation of reconnaissance and detection of enemy missile defense systems (the size of an ASB is smaller than a missile);

- Complicate the enemy’s missile defense by increasing the number of intercepted targets;

- reserve the onboard control system (BSU) of the launch vehicle at the expense of several BSU PBB (including using one BSU PBB as a launch);

- increase the range of application due to planning;

- ensure the defeat of a single missile several single targets or group targets.

The claimed utility model is accompanied by FIG. 1-13.

In FIG. Figure 1 shows the dependence of the probability of destruction of the M270 ATACMS launcher on the power of the warhead of the PBB, which is part of the proposed RFG, and the magnitude of the miss (along the ordinate, the probability; along the abscissa, the miss, m).

In FIG. Figure 2 shows the dependence of the probability of destruction of the M270 ATACMS launcher on the power of the warhead of the PBB, which is part of the proposed RFG, and the magnitude of the miss (the ordinate is the probability; the abscissa is the miss, m).

In FIG. Figure 3 shows the dependence of the probability of suppressing the M270 ATACMS launcher on the power of the warhead of the PBB, which is part of the proposed RFG, and the magnitude of the miss (the ordinate is the probability; the abscissa is the miss, m).

In FIG. Figure 4 shows the dependence of the probability of destruction of the M270 ATACMS launcher on the mass of the warhead of the PBB, which is part of the proposed RFG (along the ordinate axis, probability; along the abscissa axis, mass, kg).

In FIG. Figure 5 shows the dependence of the probability of destruction of the M270 ATACMS launcher on the mass of the warhead of the PBB, which is part of the proposed RFG (along the ordinate axis, probability; along the abscissa axis, weight, kg).

In FIG. Figure 6 shows the dependence of the probability of suppressing the M270 ATACMS launcher on the mass of the warhead of the PBB, which is part of the proposed RFG (along the ordinate axis, probability; along the abscissa axis, weight, kg).

In FIG. Figure 7 shows the dependence of the probability of passage of at least one PBB (from the proposed RFG) through missile defense against the number of PBB and the probability that the PBB is detected and destroyed by defense (along the ordinate axis, the probability of passing at least one PBB; along the abscissa, the number of PBB, pcs )

In FIG. Figure 8 shows the probability of passage of at least one PBB (from the composition of the proposed RFG) through missile defense for various values of the number of PBB and the probability Kw - the probability that the PBB (from the composition of the proposed RFB) was detected and destroyed by defense.

In FIG. 9 reflects the logic of the functioning of the PBB (from the proposed RGCh) when operating in a chain battle order.

In FIG. 10 reflects the logic of the functioning of the PBB (from the composition of the proposed RFG) when operating in the battle order “all at the same height”.

In FIG. 11 reflects the logic of the functioning of the PBB (from the composition of the proposed RFG) when operating in a battle order of “unconnected chains”.

In FIG. 12 shows the location of the PBB in the hcp top view.

In FIG. 13 shows the location of the PBB in the hcp side view.

Each BSS, from the composition of the RGCh, will hit a specific target, the coordinates of which before launching an operational-tactical missile or before the separation of warheads are entered in the BSB BSS. At the same time, the BSU’s function of the operational-tactical missile as a whole will be performed by the BSB BSB, which will increase the reliability of the BSU. In addition, if a control system integrated with the global satellite navigation system (GPS) is used in the safety control system, the error in determining the current location will decrease, since the consumer on-board equipment of each safety control system that is part of the warhead will be compared and averaged. As a result, the accuracy of hitting the PBB in the target will be quite high and correspond to the class of high-precision weapons (WTO).

In general, the technology of creating an MFR with PBB will make it possible to implement various methods of destroying heterogeneous objects. This allows us to argue that a group target, even with a dispersed battle formation, can be hit by one operational tactical missile equipped with RBM with PBB (several tactical warheads with existing types of warheads will be required). At the same time, the likelihood of overcoming the missile defense system is increased by opponents due to the relatively large number and relatively small size of the PBB.

To justify the required level of power and weight and size characteristics of the WSP included in the proposed RFG, based on the coordinate law of destruction, special tactical calculations were performed to identify the dependence of the probability of damage to ground typical objects on the mass of warheads of the destruction system.

The calculations were performed in the Excel program, using methods for quantifying the effectiveness of the combat use of weapons of destruction of RAV samples, as set out in the governing documents of the RF Ministry of Defense.

Modeling and calculations were performed under the following assumptions:

- PBB are used without taking into account the factor of overcoming the counteraction of enemy air defense systems;

- the dispersion of meeting points on the surface is circular, characterized by the values of probable deviations E _x = E _y ;

- used high-explosive fragmentation warheads PBB concentrated action with a mass of 25-150 kg.

Modeling the combat use of PBB was carried out in rational conditions: a single target is attacked using one PBB, with the given approach conditions in the vertical plane.

The calculation of the values of the probabilities of destruction of objects was carried out for the following recommended degrees of fire damage:

- “destruction” (consists in inflicting the goal of such losses at which it completely loses its combat effectiveness);

- “destruction” (consists in bringing the target into a condition unsuitable for further use);

- “suppression” (consists in inflicting the goal of loss (damage) or in creating by the fire such conditions under which it is temporarily deprived of combat effectiveness, its maneuver is limited or control is disrupted).

The accuracy of pointing the BSS (probable deviation) when modeling the point of impact was taken in a wide range - from 3 m to 19 m, which corresponds to the accuracy of the guidance when using the ANN / SNA complex according to the GLONASS global network.

The results of calculating the values of the probability of defeating an ASB of one of the enemy’s typical targets, such as an M270 ATACMS launcher in an open position, and a warhead of an ASN with different mass m, are presented in graphs in Figures 1-3. The line numbers on these graphs (from top to bottom) correspond to the following masses of the PBB warhead:

- 1 - warhead weighing 150 kg;

- 2 - warhead weighing 100 kg;

- 3 - warhead weighing 50 kg;

- 4 - warhead weighing 25 kg.

Based on the performed calculations, the dependence of the probability of destruction (abscissa axis) of typical objects on the mass of the warhead (ordinate axis) of the BSP is established for various probable deviations E _x = E _in pointing the BSP to the target.

When acting on an object, such as an M270 ATACMS launcher in an open position, this dependence is presented in the form of graphs in Figures 4-6. The line numbers in these graphs (from top to bottom) correspond to the following probable deviations E _x = E _at pointing the PBB to the target:

- 5-5 meters;

- 6-10 meters;

- 7-14 meters;

- 8-20 meters.

From the calculations performed, it was found that the probability of destruction (destruction, suppression) of typical enemy targets is more dependent on the probable deviations E _x = E _of pointing the PBB to the target. Given that for PBB related to the WTO class, the values of the probable deviations E _x = E _y should not exceed

3-5 meters, a sufficient mass of explosive will be a mass equal to 80-100 kilograms.

To solve the problem of the required number of PBBs in the RBC, based on the model [2], the following calculations were performed.

OTP (PBB from RGCh) and false targets can take part in a missile strike. False targets can be partially separated from OTP (PBB from the composition of the RFG) depending on the ratio of their characteristics (for example, infrared characteristics, radar cross-section, EPR). In practice, a missile defense system may have limited information on the signs of OTP (PBB from the composition of the RGM) and false targets. To obtain detailed information about some of these features, which are usually calculated on the basis of the general laws of physics, one needs to observe the OTP tests of the enemy. Faced with little information about the likely signs of OTP (PBP from the composition of the RFG) and missile targets, the missile defense system may be forced to set a sufficiently low threshold of discrimination to ensure the effective detection of OTP (PBB from the composition of the RFG), thereby complicating the problem of discrimination of false targets. Basically, there are four probabilities of detecting OTP (PBB from the composition of the RFG) and false targets: probability P1 that OTP (PBB from the composition of the RFG) is really classified as OTP (PBB from the composition of the RFG); the probability of P2 that OTP (PBB from the composition of the RGM) is classified as a false target; the probability P3 that the false target is classified as a false target; and the probability P4 that the false target is classified as OTP (PBB from the RGM).

Probability P2 represents an error of the first type, and P4 represents an error of the second type in the process of isolating a false target. Based on this, the probability P1 is

and the probability of P3 is

If there is W OTP (PBB from the RGM) and D false targets, then the apparent number of W * warheads participating in the attack is given by

that is, this is the number of targets that must be intercepted by the defense.

There are two ways for OTP (PBB from the RGCh) to pass through the defense: (1) OTP (PBB from the RGM) is classified as OTP (PBB from the RGM), but it does not go astray, and (2) OTP (PBB from the RGM) It is classified as a false target and is freely skipped. The discrimination threshold should be set in such a way as to make the probability of Р2 as small as possible, but taking into account that when lowering the threshold, more false targets will look like OTP (PBB from the composition of the RGM) (since the probability of Р4 will increase). The probability Q of the fact that OTP (PBB from the composition of the RGCh) penetrates through the defense is given by the expression

- условная вероятность того, что оборона собьет OTP (ПББ из состава РГЧ)у, которая классифицирована как OTP (ПББ из состава РГЧ). Вводится новое определениеWhere

- the conditional likelihood that the defense will knock down OTP (PBB from the composition of the WGM) from, which is classified as OTP (PBB from the composition of the WGM). New definition introduced

where K _W is the probability that OTP (PBB from the composition of the RGM) is detected and destroyed by the defense.

Interceptor-based missile defense can be modeled as a Bernoulli test problem, where the probability P (x) that x attacking OTPs (PBBs from the RGM) pass through the defense is given by a binomial distribution

- соответствующее число сочетаний.Where

- the corresponding number of combinations.

In this case, K _W is considered the same for all OTP (PBB from the composition of the RGCh), and W is the number of OTP participating in the attack (PBB from the composition of the RGM). In the case when the defense knocks down all OTP (PBB from the composition of the RGCh) (i.e., x = 0), equation (6) reduces to

Given that for guaranteed destruction (destruction, suppression) of the main typical targets of enemy’s defeat, it’s enough to hit one PBB (rocket) with an explosive mass of 80-100 kilograms with probable deviations of E _x = E _at 3-5 meters, it is necessary to find the probability of passage of at least one PBB (missiles) through the missile defense of a potential adversary, which will be equal to

Figure 7 shows the distribution of this probability as a function of the number of BSPs participating in the impact at different values of the probability K _W. The line numbers in Figure 7 (top-down) correspond to the following probability values K _W :

- 9-K _W = 0.3;

- 10-K _W = 0.4;

- 11-K _W = 0.5;

- 12-K _W = 0.6;

- 13-K _W = 0.7;

- 14-K _W = 0.8;

- 15-K _W = 0.9.

The calculation results are presented in the form of a table in figure 8.

Based on the characteristics of the probable enemy’s air defense system and the calculations made, it was revealed that to overcome the enemy’s missile defense with at least one PBB, with a probability of P (x ≥1) = 0.95, 6-8 PBB in one launch, two OTP of 3-4 PBB, OTP are enough with existing nomenclature warheads will require much more. The proposed type of RGH with PBB is shown in Figures 12-13, with the name of the main structural elements. The proposed type of warhead is made with the central location of the PBB according to the pushing scheme of separation of the PBB. After breeding PBB, depending on their number in warheads and characteristics of the target being hit, they can act in the following battle formations (PSUs) [3]:

- BP “chain” is used in the case when several PBBs are sent to one small or point target and arrive at the target point sequentially with specified time intervals. The minimum distance between adjacent PBBs in the chain is determined by the requirements of their mutual non-destruction when the combat charge of one PBB is undermined and the simultaneous destruction of two or more PBBs by one missile defense is impossible;

- BP "all at the same height" is used when several PBBs are intended to hit an area target or several targets located at a relatively small distance from each other;

- BP “unconnected chains” is characteristic for such an option of using a divided warhead, when BBs are sent to targets located at the greatest distance from each other within the range of their reach. In this case, the requirement to synchronize the moments of arrival of the BB to various targets is not mandatory.

The logic of the functioning of the RGH with PBB during operations in various battle formations is shown in Figures 9-11. In Figures 9-11 are shown: 16 - OTP before separation of the PBB; 17 - planning warheads; 18 - goals.

The Figure 12 shows: 19 - the housing of the RGCH; 20 - the central beam with a cable trunk; 21 - farm holding BSP; 22 - PBB; 23 - guides.

The Figure 13 shows: 19 - the housing of the RGCH; 21 - farm holding BSP; 24 - pusher PBB; 25 - a control system for breeding PBB and rocket movement after breeding PBB; 22 - PBB; 26 - retaining rings of wings and rudders PBB; 27 - powder charge pusher PBB; 28 - squib; 29 - access door for PBB; 30 - wings and rudders PBB.

The proposed RBC with PBB works as follows. Upon reaching the required section of the trajectory, the signal from the on-board control system of one of the BSP is fed to the BSP breeding control system (25). The PBB dilution control system (25) sends a signal to open the hatch for the output of the first PBB (29). After opening the door to exit the PBB

(29) the PBB dilution control system (25) sends a signal to activate the squib (28), which ignites the powder charge of the PBB pusher (27). Under the action of powder gases, the powder charge of the PBB pusher (27), the PBB pusher (24) is activated. Under the action of the pusher PBB (24), PBB (22) begins to move along the guides (23 of Fig. 12) and leaves the farm (21 of Fig. 12) holding the PBB (22). After exiting the truss (21 of Fig. 12) holding the PBB (22) and the housing of the RGC (19), the retaining rings (26) remain in the guides (23 of Fig. 12) of the truss (21 of Fig. 12) holding the PBB (22) , wings and rudders of PBB

(30) are revealed and PBB (22) begins to move toward the target by commands of its own onboard control system.

The procedure is then repeated for the next BSP. After breeding all the BSPs, the rocket continues to move toward the target according to the commands of the control system (25) in the form of a false target.

Bibliography

1. Guided operational-tactical missile 9M723 (Iskander) [on-line], the date of the upload to the site 01/16/2016 in accordance with the site https://archive.org found from the Internet https://vpk.name/library/f/ 9m723.html.

2. A. Wilkening. A Simple Model for Calculating Ballistic Missile Defense Effectiveness. - Science and Global Security. - 1999. - Volume 8: 2, pp. 183-215.

3. Lysenko L.N. Guidance and navigation of ballistic missiles: a training manual / Lysenko L.N. - M .: Publishing house of MGTU im. N.E. Bauman, 2007 .-- 672 p.

Claims (1)

The separable warhead of an operational-tactical missile, consisting of a hull with hatches, a central beam with a cable trunk, a farm holding the warheads, an onboard control system - BSU dilution of warheads, powder charges for pushing warheads through the hatches, characterized in that the warheads made with rudders and wings to ensure their planning, each of the planning warheads - PBB has its own BSU, integrated into one before breeding PBB and provided with the ability to spread the PBB along the tram flight paths of an operational-tactical missile with established time intervals, maneuvering the ASB and communication with the satellite navigation system, while some of the BSU-PBBs can be backed up with the BSUs of an operational-tactical missile, and one of the BSU-PBBs can be used as a launch for operational-tactical rockets.

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