RU2206060C2 - Projectile, device testing electric system arranged in projectile and procedure testing electric system arranged in projectile - Google Patents

Abstract

FIELD: military equipment, electric systems arranged on projectiles. SUBSTANCE: projectile includes interjoined compartments, electric system and electric connector to test electric system placed between compartments of projectile. Projectile can be fitted with additional electric connector. Device testing electric system incorporates testing unit and electric connector for connection to electric system of projectile. Electric connector is put into body with two location points corresponding to location points of projectile between which electric connector to test electric system of projectile is placed. Electric connector of device is mounted in body for joining to electric connector of projectile to test its electric system. Test of electric system is carried out by connection of device testing electric system of projectile when compartments of projectile between which electric connector of projectile testing its electric system is located are detached. EFFECT: simplified design, reduced volume and mass, improved reliability and operational capabilities of projectile. 8 cl, 2 dwg

Description

 The invention relates to military equipment, in particular to shells with an electrical system, methods for assembling them, devices for checking an electrical system located on a projectile and methods for assembling them, methods for checking an electrical system located on a projectile, and methods for testing shells with an electrical system.

 Known anti-aircraft guided missile (projectile) "Indigo" [1], containing stacked compartments, an electronic control system with electrical communications (electrical system) and an electrical connector for checking the electronic system (electrical system) located on the outer surface of the missile (projectile). The assembly of an anti-aircraft guided missile (projectile) consists of assembly operations and the operation of installing an electronic control system (electrical system) and an electrical connector on the missile (projectile) for its verification. The device for checking the electronic control system (electrical system) located on the Indigo anti-aircraft guided missile (projectile) contains an inspection unit and an electrical connector for connecting a missile (projectile) to the electronic system (electrical system). The assembly of this device consists in carrying out the assembly operations of the test block and the operation of connecting to the test block of the electrical connector for connecting to the electronic control system (electrical system) of the rocket (projectile). Checking the electronic control system (electrical system) in the troops is carried out by the repair unit. This check consists in the electrical connection of the device for testing to the electronic control system (electrical system) of the rocket (projectile) and conducting verification operations. Tests of a rocket (projectile) are carried out by conducting test operations and in the electrical connection of the device for verification to its electronic system (electrical system), followed by verification operations.

 The disadvantage of the Indigo anti-aircraft guided missile (projectile) is that the electrical connector for checking its electronic control system (electrical system) is located on the outer surface of the missile (projectile). This requires ensuring reliable sealing of this electrical connector, which increases the volume and weight of the rocket (projectile), and this leads to an increase in the volume and weight of the entire weapons complex as a whole. Increases the likelihood of defeat by the enemy and worsens transportability. All this reduces efficiency. Depressurization of a rocket (shell) with an electronic system (electrical system), given that small voltages and currents are usually used in rockets (shells), due to the possible ingress of moisture and dust into it, can lead to an off-design mode of its operation (failure of the electronic control system - if the projectile is controllable, failure of the warhead — if the warhead is equipped with a missile with an electric blasting system, etc.). If a jet engine is installed on the rocket (projectile), then depressurization of the rocket (projectile) can lead to depressurization of its jet engine with a change (deterioration) in the characteristics of rocket fuel with all the ensuing consequences (failure to start or even rupture of the jet engine, decrease in speed and range and etc.). Efficiency is deteriorating. It is also necessary to protect the electronic control system (electrical system) of the rocket (projectile) for this electrical connector from possible external electromagnetic radiation, which also increases the volume and weight of the rocket (projectile). An additional sealing unit, as well as additional protection against electromagnetic radiation through this electrical connector, worsens the reliability and, accordingly, the effectiveness of combat use. When the electrical connector is located to test the electric system of the rocket (projectile) on the outer surface of the rocket (projectile), this electrical connector is usually closed with a plug made of plastic or metal, which prevents damage to its electrical contacts and the ingress of moisture, dust, etc. Otherwise (in case of damage to the electrical contacts or moisture, dust, etc.), it is possible to short-circuit the electrical contacts of this electrical connector with all the ensuing consequences (abnormal operation of the electrical system - the electronic control system, failure of the electric fuse for the warhead, etc. .). When checking the electrical system of the rocket (projectile), you have to unscrew this plug (usually it is placed on the thread) and after checking, screw it. This may damage the plug, which service personnel may not notice. This is especially true for plugs made of plastic. Consequently, in the future, moisture, dust, etc. can come to the electrical contacts of the electrical connector to check the electrical system of the rocket (projectile) It is almost very difficult to check the tightness of the cavity with electrical contacts under the plug due to its small volume. Reliability is reduced. Efficiency is deteriorating. Also, when plugging a given electrical connector from metal (especially from aluminum alloys) when unscrewing / screwing the plug, it is possible to form metal chips, burrs or metal powder, which in the future, during operation, can lead to the closure of electrical contacts of the electrical connector and abnormal operation of the entire electrical missile (projectile) systems. Efficiency is declining. Therefore, based on the foregoing, this design missile (shell) does not provide increased efficiency. This means that the method of its assembly, the device for checking the electronic system (electrical system) located on it, the method of assembly of this device, the method of checking the electronic control system (electric system) located on it, and the test method do not provide increased efficiency.

 Known and anti-aircraft guided missile (projectile) "Rapier" [2], containing stacked compartments, an electronic control system with electrical communications (electrical system) and an electrical connector for checking the electronic system (electrical system) located on the outer surface of the rocket (projectile). The assembly of the Rapira anti-aircraft guided missile (projectile) consists of assembly operations and the operation of installing an electronic control system (electric system) and an electrical connector on the missile (projectile) for its verification. A device for checking the Rapira electronic control system (electric system) located on an anti-aircraft guided missile (projectile) contains a test unit and an electrical connector for connecting a missile (projectile) to the electronic system (electric system). The assembly of this device consists in carrying out the assembly operations of the test block and the operation of connecting to the test block of the electrical connector for connecting to the electronic control system (electrical system) of the rocket (projectile). The electronic control system (electrical system) in the troops is checked by the repair section, which is part of the battery of the Rapira anti-aircraft missile system. It consists in the electrical connection of the device for verification to the electronic control system (electrical system) of the rocket (projectile) and conducting verification operations. Its tests are carried out by conducting test operations and in the electrical connection of the device for verification to its electronic system (electrical system), followed by verification operations.

 The disadvantage of this anti-aircraft guided missile (projectile), like the previous one, is that the electrical connector for checking its electronic control system (electrical system) is located on the outer surface of the missile (projectile). There is a need for an additional sealing unit and providing protection from external electromagnetic radiation through this electrical connector, which reduces reliability, and therefore, efficiency. In addition, as noted above, the volume and weight of the rocket (projectile) increase with all the ensuing consequences. Providing a given volume and weight of a rocket (projectile) is possible while reducing the volume and weight "allocated" to the warhead and jet engine. With a decrease in the volume and weight of the warhead, its power decreases and, accordingly, the damaging effect on the target. If the volume and weight of the jet engine are reduced, then either its power or the operating time is reduced and, therefore, the maximum flight speed of the rocket (projectile) or the possible firing range is reduced. All this reduces efficiency. If the electrical connector for checking the electric system of the rocket (projectile) is combined with the electrical connector for its launch (if for this we use the electrical connector, and not the electrical contacts specially brought to the outer surface of the rocket), then the dimensions of the combined electrical connector and, accordingly, all the problems associated with it will sharply increase with this. Decreases due to the increase in size, the reliability of the seal. With an increase in the number of electrical contacts in this electrical connector, the system of protection against electromagnetic radiation is complicated with all the ensuing consequences. Efficiency is deteriorating. From the above it follows that this design of the rocket (projectile) does not increase efficiency. Therefore, the method of assembling it, the device for checking the electronic system (electric system) located on it, and the method of assembling this device, the method for checking the electronic control system (electric system) located on it, as well as the method of testing the rocket (projectile) do not provide increased efficiency.

 The objective of the proposed technical solution is to increase efficiency by increasing reliability, as well as transportability and invulnerability.

 The problem is solved in that in a projectile containing interconnected compartments, an electrical system and an electrical connector for checking the electrical system, therein an electrical connector for testing the electrical system of the projectile is located between the projectile compartments, while the projectile can be equipped with an additional electrical connector for testing the electrical system of the projectile moreover, the electrical connectors for checking the electrical system of the projectile are located between the two compartments of the projectile at their adjacent ends and are interconnected, while the electrical circuits of the projectile’s electrical system pass through these electrical connectors. In the device for checking the electrical system located on the projectile, comprising a test unit and an electrical connector for connecting to the electrical system of the projectile, therein, an electrical connector for connecting to the electrical system of the projectile is located in a housing with two seats, reciprocal seats of the projectile compartments, between which there is an electrical connector for check the electrical system of the projectile, while the electrical connector of the device in the housing is located with the possibility of docking with the electrical connector of the projectile its electrical system, while the verification device can be equipped with an additional electrical connector for connecting to the projectile electrical system, made as a response to the additional electrical connector located between the projectile compartments for checking its electrical system and installed in the housing from its opposite side relative to the first electrical connector of the device for connecting it to the electrical system of the projectile, and the additional electrical connector of the device is located in the housing with possible docking with an additional electrical connector of the projectile to test its electrical system, and the electrical connectors of the device for connecting to the electrical system of the projectile are interconnected by electrical circuits, and the electrical connection of these electrical connectors is an insert into the switching circuit of the electrical system of the projectile, and the seats on the housing are reciprocal places of the compartments of the projectile can be located on one axis. In the method of checking the electrical system located on the projectile, which consists in electrically connecting the device for checking the projectile to the electric system and performing test operations, the electric connection of the device for checking the projectile electric system is carried out with the compartments disconnected between each other, between which the projectile’s electrical connector is located electrical system, while the electrical connection of the device for verification to the electrical system of the projectile may led by installing between the compartments of the projectile, between which the projectile’s electrical connector is located, a body with an electrical connector for the test device, while connecting the projectile’s electrical connectors and the device simultaneously with the housing connecting to the compartment at the end of which the electrical connector is located projectile systems. Also, between the projectile compartments, on the adjacent ends of which electrical connectors are located to test the electrical system of the projectile, a housing can be installed with electrical devices located at opposite ends of the device for connecting to the projectile electrical system, while connecting the projectile electrical connectors and the device located at the ends of the projectile compartments and at opposite sides of the shell, produce simultaneously with the connection of the shell with the corresponding compartment of the projectile.

 A positive effect is ensured by simplifying the design and reducing volume and weight.

 The invention is illustrated by drawings (figure 1, 2).

 Figure 1 shows the projectile 1, containing stacked compartments 2, 3, 4, 5, the electrical system 6 and the electrical connector 7 for checking the electrical system of the projectile. An electric control system for a projectile can be its electronic control system (if the projectile is controllable), an electric system for detonating the warhead (if the warhead is equipped with an electric fuse), etc. An electrical connector for testing the electrical system of the projectile is located between the compartments of the projectile in FIG. 1 case between compartments 4 and 5. The projectile may also contain several (two, three, etc.) electrical connectors, for example 7 and 8 additional, for checking its electrical system, which are located, as shown in figure 1, between two compartments 4 and 5, at their adjacent ends 9 and 10. Electrical connectors for checking the electrical system of the projectile, located between two adjacent compartments at their ends, can be connected to each other, while the circuit 11 of the electrical system of the projectile pass through these electrical connectors. In FIG. 2 shows a projectile with a device 12 connected to its electrical system for testing this electrical system. A device for checking the electrical system located on the projectile contains a test unit 13 and an electrical connector 14 for connecting a projectile to the electrical system, which is configured as a response to an electrical connector 7 located between the projectile compartments for testing the electrical system. The electrical connector 14 for connecting a projectile to the electrical system is located in the housing 15 with two seats 16 and 17, reciprocal seats 18 and 19 of the projectile compartments 4 and 5, between which there is an electrical connector 7 for checking the electrical system of the projectile, while the electrical connector 14 of the device the housing is located with the possibility of docking with the electrical connector 7 of the projectile to test its electrical system. A device for checking the electrical system, if the projectile is equipped with an additional electrical connector for checking its electrical system, it can also be equipped with an additional electrical connector 20 for connecting to the electrical system of the projectile, made as a response to the additional electrical connector 8 of the projectile located between the compartments to test its electrical system and located in the housing 15 from its opposite side relative to the first electrical connector 14 of the device for connecting it to an electrical projectile system. An additional electrical connector 20 of the device is located with the possibility of docking with an additional electrical connector 8 of the projectile to check its electrical system, and the electrical connectors 14 and 20 of the device for connecting to the electrical system of the projectile are made interconnected by electrical circuits, and the electrical connection 21 of these electrical connectors is an insert in switching electrical circuits 11 of the projectile electrical system. In figure 2, the housing 15 with electrical connectors for connecting to the electrical system of the projectile is mounted on the projectile between compartments 4 and 5, but it can also be installed between any compartments between which the electrical connectors of the projectile are located to test its electrical system. The seats 16 and 17 of this shell can be located on the same axis 22. The shell, as it were, receives an additional compartment in the form of a shell 15 with electrical connectors for connecting to the projectile's electrical system. In the embodiment of FIG. 2, the test block 13 is made separately and connected by an electric cable 23 to the electrical connectors 14 and 20 for connecting a projectile to the electrical system, which are installed in the housing 15. It is also possible that the test block 13 will be located in the housing 15. This depends from the specific design of the device for checking, in particular from the design of the test block, its dimensions and weight.

 The projectile works as follows. Before the shot, it is installed on the launcher (if the projectile has a jet engine) or in the barrel of an artillery gun (if the shell is artillery) and its electric system is activated (electronic control equipment — if the projectile is controllable, an electric system for detonating the warhead — if the projectile is mounted warhead with an electric blasting system, etc.). Then, the projectile is fired towards the target or in the right direction (if the projectile is intended for meteorological research, etc.). Actuation of the projectile’s electrical system usually involves connecting a power source to the projectile’s electrical components (electronic or power, such as electric steering gears or some kind of solenoid valve, electrical warhead demolition system, etc.). Given that shells typically use "ampoule" type electric batteries, activating the electrical system basically involves "starting" these electric batteries. The operation of the electrical system of the projectile can also be carried out directly during the shot, for example automatically, under the influence of starting overloads acting on a special starting element of electric batteries. If there is an electric generator on the projectile, the activation of the projectile electrical system consists in starting up the electric generator with a system for electrically connecting it to the projectile electrical system. If necessary, the troops, during storage and operation of the projectile can be checked its electrical system. To do this, the projectile is undocked at the junction between the compartments between which the electrical connector is located to check its electrical system, and the verification device is connected to it by docking the electrical connector of the projectile to test its electrical system and the device’s electrical connector designed to connect to the electrical system of the projectile. Next, check the electrical system of the projectile. In the case when the projectile has several electrical connectors for checking its electrical system (two, three, etc.), then, accordingly, the same number of electrical connectors of the device for testing are connected to them. If the electrical connectors for checking the projectile’s electrical system are located on two opposite sides of two adjacent compartments, and the electrical circuits of the projectile’s electrical system pass through them in the assembled projectile, then, therefore, the electrical connectors in the testing device for connecting to the projectile’s electrical system must be connected electrical circuits. Checking the electrical system of the projectile is carried out not only in the troops, during operation and storage, but during their manufacture. In this case, the projectile for inspection can arrive in an unassembled form, separately in compartments. Immediately before the test, the projectile is “docked” with the electrical connectors (electrical connector, if there is one) of the device for testing. If the electrical connector (sockets) of the verification device is installed (installed) in the housing with two seats corresponding to adjacent adjacent seats of the projectile compartments, between which the electrical connector (electrical connectors) is located (for electrical inspection) to verify its electrical system, then this housing is installed between these projectile compartments . After an electrical connection of the verification device to the projectile's electrical system, the system is checked. If necessary, they can carry out various tests of the projectile (mechanical, climatic, etc.) with installation between its compartments, at the end of one of which is an electrical connector (electrical connectors) for checking the electrical system, a housing with an electrical connector (electrical connectors) for connecting the device for testing to the electrical system of the projectile. This makes it possible to control the “behavior” of the projectile’s electrical system with an electrical connector (sockets) for testing it, located (located) between the ends of the compartments, directly during the test or immediately after it. For this, a housing with an electrical connector (electrical connectors) is installed between the projectile compartments to connect the verification device and a test is carried out, controlling, as necessary, the parameters of the electrical system.

 The assembly of the projectile is as follows. Assemble the nodes and compartments of the projectile and install on the projectile an electrical system and an electrical connector to test its electrical system. As the electrical system of the projectile, as noted above, there can be an electronic control system (if the projectile is controllable), an electric system for detonating the warhead (if the warhead is equipped with an electric fuse), etc. An electrical connector for checking the electrical system of the projectile is installed between two compartments, at the end of one of them. If the electrical system of the projectile is located only on one side of the junction of the compartments between which an electrical connector is installed to test it, then this electrical connector is installed on the end of the compartment from which it is located. When the electrical system of the projectile is located on both sides of the junction of the compartments, between which an electrical connector is installed to test it, this electrical connector can be installed on any of the adjacent ends of these compartments. Moreover, these components of the electrical system of the projectile, located on opposite sides of this junction of the compartments, must be connected by an electric cable. This power cable can also be "detachable", i.e. have electrical connectors that allow electrical connection of the components of the electrical system located in opposite parts of the projectile relative to the junction with the electrical connector to test the electrical system. The electrical connectors for this cable can be located either at one of the ends of the compartments, or somewhere in the middle of the cable. The cable length should allow the cable to be connected to dockable compartments. Electrical connectors for checking the electrical system of the projectile, if there are several, can be located between two compartments at their adjacent ends. During assembly, these electrical connectors can also be connected to each other, and the electrical circuits of the projectile’s electrical system can be passed through them. This is achieved by the fact that the projectile switching circuits are connected to the electrical connectors for checking the electrical system, and the electrical connectors themselves are, as it were, an insert into the projectile switching electrical circuits. At the same time, the switching electrical circuits of the projectile brought to these electrical connectors can also serve to check the electrical system. If through the electrical connectors of the projectile to test its electrical system pass the electrical circuits of the electrical system of the projectile, then an additional connection with a special electrical cable to the components of the electrical system located on opposite sides of the junction of the edema of the projectile with these electrical connectors may not be made. In this case, all the electrical circuits of the projectile’s electrical system that “pass” through the junction of the compartments with electrical connectors for checking the electrical system must be carried out through these electrical connectors. It should be noted that the installation of an electric system and an electrical connector (electrical connectors) on the projectile to check the electrical system can be done element-wise (in parts) in the appropriate compartments when they are assembled and finally connected into a single whole when docking all the compartments of the projectile.

 The assembly of the device for checking the electrical system of the projectile consists in carrying out assembly operations and the operation of connecting with the test unit of the electrical connector to connect to the electrical system of the projectile, which is executed as a response to the electrical connector located between the compartments of the projectile to test its electrical system. If there are several electrical sockets on the projectile for which the device to be assembled is used to test its electrical system, then, consequently, an appropriate number of electrical sockets are connected to the test unit to connect it to the projectile electrical system. When the electrical connectors on the projectile to test its electrical system are connected to each other and the electrical circuits of the electrical system of the projectile pass through them, the electrical connectors of the device for connecting to the electrical system of the projectile can be interconnected via electrical circuits, while the electrical connection of these electrical connectors is performed as an insert into the switching electrical circuit electric projectile system. The electrical connectors of the device for connecting to the electrical system of the projectile can be installed in a housing with two seats, reciprocal seats of the projectile compartments with electrical connectors for checking its electrical system from these electrical connectors, while the electrical connectors of the device in the housing are opposite the electrical connectors of the projectile to test its electrical system with the possibility of docking. This installation of electrical connectors is necessary if the verification device is used to control the parameters of the electrical system of the projectile during their tests or immediately before or after them. For a more complete correspondence of the projectile with a housing with electrical connectors for connecting a projectile without a housing to its electrical system, the housing seats corresponding to the seats of the projectile compartments with electrical connectors for testing its electrical system can be arranged along one axis. A body with electrical connectors becomes, as it were, an integral part of the projectile, increasing the correspondence of the loads and test effects acting on the projectile with the body (with electrical connectors for connecting to the electric system of the projectile), loads and test effects acting on the projectile in real conditions of operation and use. The test unit of the device for checking the electrical system of the projectile can be performed both separately from the housing with electrical connectors for connection to the electrical system of the projectile, so directly in this housing. As noted above, this is determined by the specific design of the test block, its size and weight. If the test block is performed separately from the case with electrical connectors for connecting to the projectile's electrical system, then they are connected by an electric cable.

 The implementation of the electrical connector to test the electrical system of the projectile located between the compartments of the projectile allows you to simplify the projectile with the electrical system. This is achieved by eliminating the need for sealing and special protection from external electromagnetic radiation for this electrical connector. There is also no need to plug the electrical connector to check the electrical system of the projectile, which would be required if the electrical connector was located on the outer surface of the projectile. Reliability increases, dimensions and weight decrease. Increases transportability and reduces the likelihood of damage from enemy fire. Efficiency is increasing. The location of the electrical connectors for checking the electrical system between two projectile compartments at their adjacent ends simplifies the projectile with the electrical system if the electrical system is located on both sides of the given compartment junction. This makes it possible not to "pull" electrical circuits from elements of the electrical system that require verification and located in opposite parts of the projectile (relative to the junction of the compartments with electrical connectors for testing), to the compartment of the projectile on the end of which there is an electrical connector for testing (if the electrical connector for testing is one or if there are several of them and they are located at the end of one compartment). It also improves efficiency. When passing electrical circuits connecting parts of the electrical system located in opposite parts of the projectile through these electrical connectors, the design is even more simplified, because there is no need for an electric cable connecting these parts of the electrical system. Efficiency increases even more. When assembling the projectile, installing an electrical connector to test the electrical system of the projectile between two compartments at the end of one of them allows you to collect the proposed projectile with an electrical connector to test the electrical system located between the compartments of the projectile. This simplifies the assembly process itself, since there is no need to seal the electrical connector to check the electrical system of the projectile, as well as a special system of protection against electromagnetic radiation through this electrical connector. Accordingly, increased reliability. Efficiency is increasing. When assembling electrical connectors for checking the electrical system of the projectile between two compartments at their adjacent ends, docking them together, as well as wiring through them the electrical circuits of the electrical system of the projectile, the assembly of the projectile with the electrical system is provided if it has several electrical connectors for checking the electrical system of the projectile and they are located between two compartments at their adjacent ends, as well as if these electrical connectors are connected to each other and electrical circuits of the electrical system pass through them we are a shell. The assembly process is even more simplified since there is no need to lay a special electric cable connecting the parts of the projectile electrical system located on both sides of the junction of the compartments, between which electrical connectors are installed to check the projectile electrical system. Reliability is rising, which means efficiency.

 The implementation in the device for checking the electrical system of the projectile of the electrical connector for connecting to the electrical system of the projectile as a response to the electrical connector located between the compartments of the projectile to test its electrical system allows you to check the electrical system of this projectile, which increases its reliability. Efficiency is increasing. At the same time, during the test, there is no need to unscrew-screw the outer plug of the electrical connector to check the electrical system, because This electrical connector is located inside the projectile and no additional plug is required for it. Accordingly, it is impossible, when checking the electrical system of the projectile, damage to this plug, the formation of metal shavings, burrs or metal powder, improper installation of the plug after checking, etc., with all the consequences that follow (shorting the electrical contacts of the electrical connector for checking the electrical system of the projectile - due to moisture, dust, metal chips, burrs, etc.) getting into the cavity with these electrical contacts. Reliability is increased, and hence, efficiency. Before checking the electrical system of the projectile, its undocking at the junction between the compartments between which the electrical connector of the projectile is located to test its electrical system allows you to test the projectile if it is finally assembled, for example, in the army, during operation, etc. This makes it possible to increase reliability, and therefore, efficiency. Providing a device for testing with several electrical connectors for connecting a projectile to the electrical system, made as a response to electrical connectors located on adjacent ends of the projectile compartments for checking its electrical system, allows you to check the projectile if it contains several electrical connectors for checking the electrical system. The reliability of this projectile is increasing. Efficiency is increasing. In the device for testing, the connection between each other through electrical circuits of electrical connectors for connecting a projectile to an electrical system makes it possible to exclude in a projectile in which electrical connectors for testing are located between two compartments at their adjacent ends, are interconnected and electrical circuits of the electrical system of the projectile pass through them, allows to exclude in this projectile the need for a special electric cable connecting the parts of the projectile electrical system located on both sides of the junction of the projectile compartments with electrical connectors for checking the electrical system. The design of the projectile is simplified, and when checking the electrical system, the possibility of damage to this electrical cable is excluded (if it were on the projectile). Accordingly, increased reliability. Efficiency is increasing. Installation of electrical connectors (electrical connector) for connecting a projectile to the electrical system in a housing with two seats, reciprocal seats of projectile compartments with electrical connectors (electrical connector) for checking its electrical system from these electrical connectors, as well as the location of the device’s electrical connectors in the housing opposite the electrical connectors of the projectile its electrical system with the ability to dock them allows using this device to conduct not only a simple check of the electrical system the volume of the projectile, but also monitor the "behavior" of the electrical system during various tests of the projectile, in particular climatic ones. Reliability rises. Accordingly, efficiency is growing. The location on one axis of the seats of the device’s body, reciprocal of the seats of the junction of the projectile compartments with electrical connectors (electrical connector) to test its electrical system, further expands the device’s test capabilities, since the housing with electrical connectors (electrical connector) mounted on the shell for connecting to an electrical the projectile system becomes, as it were, an integral part of the projectile, which differs little from the projectile without such a shell. This makes it possible to carry out not only climatic tests, but also mechanical tests, such as shock and vibration strength, etc., with this case of the device for testing (with electrical connectors for connecting a projectile to the electrical system). All this increases reliability. Efficiency is increasing.

 The proposed technical solutions can increase efficiency by increasing reliability, as well as portability and invulnerability, which are achieved by simplifying the design and reducing volume and weight.

Sources of information
1. S. A. Peresada. Anti-aircraft missile systems. M .: Military Publishing House, 1973, p. 181-185.

 2. A.N. Latukhin. Combat guided missiles. M .: Military Publishing House, 1978, pp. 103-104.

Claims (8)

 1. A projectile containing stacked compartments, an electrical system and an electrical connector for checking the electrical system, characterized in that the electrical connector for testing the electrical system of the projectile is located between the compartments of the projectile.  2. The projectile according to claim 1, characterized in that it is equipped with an additional electrical connector for checking the electrical system of the projectile, moreover, the electrical connectors for checking the electrical system of the projectile are located between two compartments of the projectile at their adjacent ends and are connected to each other, while electrical circuits pass through these electrical connectors electric projectile system.  3. A device for checking the electrical system located on the projectile, comprising a test unit and an electrical connector for connecting to the projectile's electrical system, characterized in that the electrical connector for connecting to the projectile's electrical system is located in a housing with two seats, reciprocal seats of the projectile compartments, between which an electrical connector is located to check the electrical system of the projectile, while the electrical connector of the device in the housing is located with the possibility of docking with the electrical connector of the projectile Yes to verify its electrical system.  4. The device according to claim 3, characterized in that it is provided with an additional electrical connector for connecting to the projectile electric system, made as a response to the additional projectile electrical connector located between the projectile compartments to test its electrical system and located in the housing from its opposite side relative to the first electrical connector devices for connecting it to the electrical system of the projectile, and an additional electrical connector of the device is located in the housing with the ability to dock with additional an additional electrical connector for the projectile to test its electrical system, and the electrical connectors of the device for connecting to the electrical system of the projectile are interconnected by electrical circuits and the electrical connection of these electrical connectors is an insert into the switching electrical circuits of the electrical system of the projectile, moreover, the seats on the shell, corresponding to the seats on the shell compartments, are located on one axis.  5. The device according to any one of claims 3 and 4, characterized in that the housing seats corresponding to the seats of the projectile compartments are located on one axis.  6. A method of checking the electrical system located on the projectile, which consists in electrically connecting the device for checking to the projectile's electrical system and performing test operations, characterized in that the electrical connection of the device for testing to the projectile's electrical system is made when the compartments are disconnected, between which there is an electrical connector a projectile to test its electrical system.  7. The method according to p. 6, characterized in that the electrical connection of the device for testing to the electrical system of the projectile is made by installing between the compartments of the projectile, between which is located the electrical connector of the projectile to test its electrical system, a housing with an electrical connector of the device for checking the electrical system of the projectile this connection between the electrical connectors of the projectile and the device is carried out simultaneously with the connection of the housing with the compartment, at the end of which is located an electrical connector for checking the electrical second projectile system.  8. The method according to p. 6, characterized in that between the compartments of the projectile, on the adjacent ends of which are electrical connectors for checking the electrical system of the projectile, a housing is installed with electrical devices located at opposite ends of the device for connecting to the electrical system of the projectile, while connecting the electrical connectors of the projectile and devices located at the ends of the projectile compartments and on opposite sides of the shell are produced at the same time as the shell is connected to the corresponding shell compartment.

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