Self-propelled laser systems. From laser tanks of the Soviet empire to the Russian mlk. "Squeeze": laser rainbow
Self-propelled laser complex 1K17 "Compression" designed to counter enemy optoelectronic devices. Not serially produced. The first working sample of the laser was created in 1960, and already in 1963, a group of specialists from the Vympel design bureau began to develop an experimental laser locator LE-1. It was then that the main backbone of scientists of the future NPO Astrophysics was formed. In the early 1970s, the specialized laser design bureau finally took shape as a separate enterprise, received its own production facilities and a bench test base. An interdepartmental research center of the Raduga Design Bureau was created, hiding from prying eyes and ears in the numbered city of Vladimir-30.
SLK 1K17 "Compression" was commissioned in 1992 and was much more advanced than the similar Stiletto complex. The first difference that catches the eye is the use of a multichannel laser. Each of the 12 optical channels (upper and lower row of lenses) had an individual guidance system. The multichannel scheme made it possible to make the laser installation multirange. As a countermeasure to such systems, the enemy could protect his optics with light filters that block radiation of a certain frequency. But against simultaneous damage by rays of different wavelengths, the light filter is powerless.
The lenses in the middle row are sighting systems. The small and large lenses on the right are the probing laser and the receiving channel of the automatic guidance system. The same pair of lenses on the left are optical sights: a small daylight and a large night one. The night sight was equipped with two laser rangefinder illuminators. In the stowed position, the optics of the guidance systems and the emitters were covered with armored shields. In SLK 1K17 "Compression" a solid-state laser with fluorescent pump lamps was used. Such lasers are quite compact and reliable for use in self-propelled units. Foreign experience also testifies to this: in the American ZEUS system, installed on the Humvee all-terrain vehicle and designed to "ignite" enemy mines at a distance, a laser with a solid working body was mainly used.
In amateur circles, there is a tale about a 30-kilogram ruby crystal grown specifically for the "Compression". In fact, ruby lasers became obsolete almost immediately after their birth. Nowadays, they are used only to create holograms and tattoos. The working fluid in 1K17 could well have been yttrium aluminum garnet with neodymium additives. The so-called YAG lasers in pulsed mode are capable of developing impressive power. Generation in YAG occurs at a wavelength of 1064 nm. This is infrared radiation, which in difficult weather conditions is subject to scattering to a lesser extent than visible light. Due to the high power of the YAG laser on a nonlinear crystal, harmonics can be obtained - pulses with a wavelength two, three, four times shorter than the original one. Thus, multiband radiation is formed.
The main problem of any laser is its extremely low efficiency. Even in the most modern and complex gas lasers, the ratio of the radiation energy to the pump energy does not exceed 20%. Pump lamps require a lot of electricity. Powerful generators and an auxiliary power unit occupied most of the enlarged cabin of the 2S19 Msta-S self-propelled artillery mount (already rather big), on the basis of which the Compression SLK was built. The generators charge the bank of capacitors, which, in turn, gives a powerful pulsed discharge to the lamps. It takes time to "refuel" the capacitors. Rate of fire SLK 1K17 "Compression"- this is perhaps one of its most mysterious parameters and, perhaps, one of the main tactical shortcomings.
The most important advantage of laser weapons is direct fire. Independence from the vagaries of the wind and an elementary aiming scheme without ballistic corrections means shooting accuracy that is inaccessible to conventional artillery. According to the official pamphlet of NPO Astrophysics, which claims that the Sanguine could hit targets at a distance of more than 10 km, the range of the 1K17 Compression is at least twice the range of, say, a modern tank. This means that if a hypothetical tank approaches 1K17 in an open area, then it will be disabled before it opens fire. Sounds tempting.
However, direct fire is both the main advantage and the main disadvantage of laser weapons. It requires direct line of sight to work. Even if you fight in the desert, the 10-kilometer mark will disappear over the horizon. To greet guests with a blinding light, a self-propelled laser must be put on the mountain for everyone to see. In real conditions, such tactics are contraindicated. In addition, the vast majority of theaters of war have at least some relief.
And when the same hypothetical tanks are within range of the SLK, they immediately benefit from the rate of fire. 1K17 "Squeeze" can disable one tank, but while the capacitors are charged again, the second can avenge a blinded comrade. In addition, there are weapons much more long-range than artillery. For example, a Maverick missile with a radar (non-dazzling) guidance system is launched from a distance of 25 km, and the one overlooking the surroundings of the SLK on the mountain is an excellent target for it.
Do not forget that dust, fog, precipitation, smoke screens, if they do not negate the effect of an infrared laser, then at least significantly reduce its range. So the self-propelled laser complex has, to put it mildly, a very narrow area of tactical application.
When creating a complex 1K17 "Compression" the self-propelled howitzer 2S19 "Msta-S" was used as a base. The turret of the machine compared to 2S19 was significantly increased in order to accommodate optoelectronic equipment. In addition, an autonomous auxiliary power unit was located at the rear of the tower to power powerful generators. In front of the turret, instead of a gun, an optical unit was installed, consisting of 15 lenses. On the march, the lenses were closed with armored covers. In the middle part of the tower, there were operator jobs. A commander's turret with a 12.7 mm NSVT anti-aircraft machine gun was installed on the roof.
Why were the SLK 1K17 "Compression" and its predecessors born? There are many opinions on this matter. Perhaps these devices were considered as test benches for testing future military and military space technologies. Perhaps the military leadership of the country was ready to invest in technologies, the effectiveness of which at that moment seemed doubtful, in the hope of empirically finding the superweapon of the future. Or maybe the three mysterious cars with the letter “C” were born because Ustinov was the general designer. More precisely, the son of Ustinov.
There is a version that SLK 1K17 "Compression" It is a weapon of psychological action. The mere possibility of the presence of such a machine on the battlefield makes gunners, observers, snipers be wary of optics for fear of losing their sight. Contrary to popular belief, the 1K17 "Compression" is not subject to the UN Protocol prohibiting the use of blinding weapons, as it is intended to destroy optoelectronic systems, and not personnel. The use of weapons for which blinding people is a possible side effect is not prohibited. This version partly explains the fact that the news about the creation in the USSR of highly classified weapons, including the Stiletto and Compression, quickly appeared in the free American press, in particular in Aviation Week & Space Technology magazine. At the moment, the only surviving copy is in the Military Technical Museum in the village of Ivanovskoye near Moscow.
The performance characteristics of 1K17 "Compression"
Case length, mm 6040
Hull width, mm 3584
Clearance, mm 435
Type of armor homogeneous steel
Armament:
Machine guns 1 x 12.7 mm NSVT
Engine - V-84A supercharged diesel, max. power: 618 kW (840 hp)
Highway speed, km/h 60
Suspension type independent with long torsion bars
Climbability, deg. thirty
Overcoming wall, m 0.85
Crossable ditch, m 2.8
Crossable ford, m 1.2
The 1K11 laser system was mounted on the chassis of the GMZ (caterpillar mine layer) of the Sverdlovsk Uraltransmash plant. Only two machines were manufactured, which differed from each other: during the testing process, the laser part of the complex was finalized and changed.
Formally, the SLK "Stiletto" is still in service with the Russian army and, as the historical brochure of the NPO "Astrophysics" says, meets modern requirements for conducting defense-tactical operations. But sources at Uraltransmash claim that 1K11 copies, except for two experimental ones, were not assembled at the plant. A couple of decades later, both machines were found dismantled, with the laser part removed. One - for disposal in the sump of the 61st BTRZ near St. Petersburg, the second - at the tank repair plant in Kharkov.
"Sanguine": at the zenith
The development of laser weapons at NPO Astrophysics proceeded at a Stakhanovite pace, and already in 1983 the Sangvin SLK was put into service. Its main difference from the "Stiletto" was that the combat laser was aimed at the target without the use of large mirrors. The simplification of the optical design had a positive effect on the lethality of the weapon. But the most important improvement was the increased mobility of the laser in the vertical plane. "Sangvin" was intended to destroy optoelectronic systems of air targets.
The upper and lower rows of lenses of the SLK "Compression" are emitters of a multi-channel combat laser with an individual guidance system. In the middle row are the lenses of the guidance systems.
A shot resolution system specially developed for the complex allowed it to successfully shoot at moving targets. In tests, the Sanguine SLK demonstrated the ability to stably detect and hit the optical systems of a helicopter at ranges of more than 10 km. At short distances (up to 8 km), the device completely disabled the enemy's sights, and at extreme ranges blinded them for tens of minutes.
The Sangvina laser complex was mounted on the chassis of the Shilka self-propelled anti-aircraft gun. In addition to the combat laser, a low-power probing laser and a guidance system receiver were mounted on the tower, which recorded the reflection of the probe beam from a glare object.
Three years after Sanguine, the arsenal of the Soviet army was replenished with the Akvilon shipborne laser system with an operating principle similar to ground-based SLKs. Sea-based has an important advantage over land-based: the power system of a warship can provide much more electricity to pump the laser. So, you can increase the power and rate of fire of the gun. The Akvilon complex was intended to destroy the optoelectronic systems of the enemy coast guard.
"Squeeze": laser rainbow
SLK 1K17 "Compression" was put into service in 1992 and was much more advanced than the "Stiletto". The first difference that catches the eye is the use of a multichannel laser. Each of the 12 optical channels (upper and lower row of lenses) had an individual guidance system. The multichannel scheme made it possible to make the laser installation multirange. As a countermeasure to such systems, the enemy could protect his optics with light filters that block radiation of a certain frequency. But against simultaneous damage by rays of different wavelengths, the light filter is powerless.
The lenses in the middle row are sighting systems. The small and large lenses on the right are the probing laser and the receiving channel of the automatic guidance system. The same pair of lenses on the left are optical sights: a small daylight and a large night one. The night sight was equipped with two laser rangefinder illuminators. In the stowed position, both the optics of the guidance systems and the emitters were covered with armored shields.
SLK "Sangvin" is actually a laser anti-aircraft installation and is used to destroy optical-electronic devices of air targets. The SLK 1K11 Stiletto tower housed a combat laser guidance system based on large-sized mirrors.
In SLC "Compression" a solid-state laser with fluorescent pump lamps was used. Such lasers are quite compact and reliable for use in self-propelled units. Foreign experience also testifies to this: in the American ZEUS system, installed on the Humvee all-terrain vehicle and designed to "ignite" enemy mines at a distance, a laser with a solid working body was mainly used.
In amateur circles, there is a tale about a 30-kilogram ruby crystal grown specifically for the "Compression". In fact, ruby lasers became obsolete almost immediately after their birth. Nowadays, they are used only to create holograms and tattoos. The working fluid in 1K17 could well have been yttrium aluminum garnet with neodymium additives. The so-called YAG lasers in pulsed mode are capable of developing impressive power.
Generation in YAG occurs at a wavelength of 1064 nm. This is infrared radiation, which in difficult weather conditions is subject to scattering to a lesser extent than visible light. Due to the high power of a YAG laser on a nonlinear crystal, harmonics can be obtained - pulses with a wavelength two, three, four times shorter than the original one. Thus, multiband radiation is formed.
The main problem of any laser is its extremely low efficiency. Even in the most modern and complex gas lasers, the ratio of the radiation energy to the pump energy does not exceed 20%. Pump lamps require a lot of electricity. Powerful generators and an auxiliary power unit took b? most of the enlarged cabin of the 2S19 Msta-S self-propelled artillery mount (already rather big), on the basis of which the Compression SLK was built. The generators charge the bank of capacitors, which, in turn, gives a powerful pulsed discharge to the lamps. It takes time to "refuel" the capacitors. The rate of fire of the SLK "Compression" is perhaps one of its most mysterious parameters and, perhaps, one of its main tactical shortcomings.
In secret around the world
The most important advantage of laser weapons is direct fire. Independence from the vagaries of the wind and an elementary aiming scheme without ballistic corrections means shooting accuracy that is inaccessible to conventional artillery. According to the official pamphlet of the NPO Astrophysics, which claims that the Sanguine could hit targets at a distance of more than 10 km, the range of the Compression is at least twice the range of, say, a modern tank. This means that if a hypothetical tank approaches 1K17 in an open area, then it will be disabled before it opens fire. Sounds tempting.
However, direct fire is both the main advantage and the main disadvantage of laser weapons. It requires direct line of sight to work. Even if you fight in the desert, the 10-kilometer mark will disappear over the horizon. To greet guests with a blinding light, a self-propelled laser must be put on the mountain for everyone to see. In real conditions, such tactics are contraindicated. In addition, the vast majority of theaters of war have at least some relief.
And when the same hypothetical tanks are within range of the SLK, they immediately benefit from the rate of fire. "Squeeze" can disable one tank, but while the capacitors are charged again, the second can avenge a blinded comrade. In addition, there are weapons much more long-range than artillery. For example, a Maverick missile with a radar (non-dazzling) guidance system is launched from a distance of 25 km, and the one overlooking the surroundings of the SLK on the mountain is an excellent target for it.
In the late 70s and early 80s of the 20th century, the entire world “democratic” community dreamed under the euphoria of Hollywood Star Wars. At the same time, behind the Iron Curtain, under the strictest secrecy, the Soviet "Evil Empire" slowly turned Hollywood dreams into reality. Soviet cosmonauts flew into space armed with laser pistols - “blasters”, battle stations and space fighters were designed, and Soviet “laser tanks” crawled across Mother Earth.
One of the organizations involved in the development of combat laser systems was the NPO Astrophysics. The General Director of Astrophysics was Igor Viktorovich Ptitsyn, and the General Designer was Nikolai Dmitrievich Ustinov, the son of that same all-powerful member of the Politburo of the Central Committee of the CPSU and, concurrently, the Minister of Defense - Dmitry Fedorovich Ustinov. Having such a powerful patron, "Astrophysics" practically did not experience any problems with resources: financial, material, personnel. This was not long in affecting - already in 1982, almost four years after the reorganization of the Central Clinical Hospital into an NGO and the appointment of N.D. Ustinov as the general designer (before that, he headed the direction of laser location at the Central Design Bureau) was
SLK 1K11 "Stiletto".
The task of the laser complex was to provide countermeasures to optical-electronic systems for monitoring and controlling the battlefield in harsh climatic and operational conditions imposed on armored vehicles. The co-executor of the topic on the chassis was the Uraltransmash design bureau from Sverdlovsk (now Yekaterinburg), the leading developer of almost all (with rare exceptions) Soviet self-propelled artillery.
This is how the Soviet laser complex was imagined in the West. Drawing from the magazine "Soviet Military Power"Under the guidance of the General Designer of Uraltransmash, Yuri Vasilievich Tomashov (Gennady Andreevich Studenok was then the director of the plant), the laser system was mounted on a well-tested GMZ chassis - product 118, which traces its "pedigree" from the chassis of product 123 (SAM "Krug") and products 105 (SAU SU-100P). At Uraltransmash, two slightly different machines were manufactured. The differences were due to the fact that, in the order of experience and experiments, the laser systems were not the same. The combat characteristics of the complex were outstanding at that time, and they still meet the requirements for conducting defense-tactical operations. For the creation of the complex, the developers were awarded the Lenin and State Prizes.
As mentioned above, the Stiletto complex was put into service, but for a number of reasons it was not mass-produced. Two experimental machines remained in single copies. Nevertheless, their appearance, even in the conditions of terrible, total Soviet secrecy, did not go unnoticed by American intelligence. In a series of drawings depicting the latest models of Soviet Army equipment, presented to Congress for "knocking out" additional funds to the US Department of Defense, there was also a very recognizable "Stiletto".
Formally, this complex is in service to this day. However, nothing was known about the fate of the experimental machines for a long time. Upon completion of the tests, they turned out to be virtually useless to anyone. The whirlwind of the collapse of the USSR scattered them across the post-Soviet space and brought them to the state of scrap metal. So, one of the cars in the late 1990s - early 2000s was identified by BTT amateur historians for disposal in the sump of the 61st BTRZ near St. Petersburg. The second, a decade later, was also found by BTT connoisseurs at a tank repair plant in Kharkov (see http://photofile.ru/users/acselcombat/96472135/). In both cases, the laser systems from the machines were dismantled long ago. The "Petersburg" car retained only the hull, the "Kharkov" "cart" is in the best condition. At present, by the forces of enthusiasts, in agreement with the management of the plant, attempts are being made to preserve it with the aim of subsequent "museification". Unfortunately, the “St. Petersburg” car, apparently, has been disposed of by now: “What we have, we don’t store, but we cry when we lose it ...”.
The best share fell to another, no doubt unique apparatus, jointly produced by Astrophysics and Uraltrasmash. As a development of the Stiletto ideas, a new SLK 1K17 "Compression" was designed and built. It was a new generation complex with automatic search and aiming at a glare object of radiation from a multichannel laser (solid-state aluminum oxide laser Al2O3) in which a small part of aluminum atoms is replaced by trivalent chromium ions, or simply - on a ruby crystal. To create an inverse population, optical pumping is used, that is, illumination of a ruby crystal with a powerful flash of light. The ruby is given the shape of a cylindrical rod, the ends of which are carefully polished, silvered, and serve as mirrors for the laser. To illuminate the ruby rod, pulsed xenon gas-discharge flash lamps are used, through which batteries of high-voltage capacitors are discharged. The flash lamp has the shape of a spiral tube wrapped around a ruby rod. Under the action of a powerful light pulse, an inverse population is created in the ruby rod, and due to the presence of mirrors, laser generation is excited, the duration of which is slightly less than the duration of the flash of the pumping lamp. An artificial crystal weighing about 30 kg was grown especially for the "Compression" - the "laser gun" in this sense flew "a pretty penny". The new installation also required a large amount of energy. To power it, powerful generators were used, driven by an autonomous auxiliary power unit (APU).
The chassis of the latest 2S19 Msta-S self-propelled gun (item 316) was used as a base for the heavier complex. To accommodate a large number of power and electro-optical equipment, the Msta felling was significantly increased in length. The APU was located in its aft part. In front, instead of the barrel, an optical unit was placed, including 15 lenses. The system of precise lenses and mirrors in field conditions was closed with protective armor covers. This unit had the ability to point vertically. Operators' workplaces were located in the middle part of the felling. For self-defense, an anti-aircraft machine gun mount with a 12.7-mm NSVT machine gun was installed on the roof.
The body of the machine was assembled at Uraltransmash in December 1990. In 1991, the complex, which received the military index 1K17, was tested and the next year, 1992, was put into service. As before, the work on the creation of the Compression complex was highly appreciated by the Government of the country: a group of Astrophysics employees and co-executors was awarded the State Prize. In the field of lasers, we were then ahead of the whole world by at least 10 years.
However, on this, the "star" of Nikolai Dmitrievich Ustinov rolled up. The collapse of the USSR and the fall of the CPSU overthrew the former authorities. In the context of a collapsed economy, many defense programs have undergone a serious revision. The fate of this and "Compression" did not pass - the exorbitant cost of the complex, despite the advanced, breakthrough technologies and a good result, made the leadership of the Ministry of Defense doubt its effectiveness. The super-secret "laser gun" remained unclaimed. The only copy was hiding behind high fences for a long time, until, unexpectedly for everyone, in 2010 it turned out to be truly miraculous in the exposition of the Military Technical Museum, which is located in the village of Ivanovskoye near Moscow. We must pay tribute and thank the people who managed to pull this most valuable exhibit out of the top secrecy and made this unique machine public - a clear example of advanced Soviet science and engineering, a witness to our forgotten victories.
In the late 70s and early 80s of the 20th century, the entire world “democratic” community dreamed under the euphoria of Hollywood Star Wars. At the same time, behind the Iron Curtain, under the strictest secrecy, the Soviet "Evil Empire" slowly turned Hollywood dreams into reality. Soviet cosmonauts flew into space armed with laser pistols - “blasters”, battle stations and space fighters were designed, and Soviet “laser tanks” crawled across Mother Earth.
One of the organizations involved in the development of combat laser systems was the NPO Astrophysics. The General Director of Astrophysics was Igor Viktorovich Ptitsyn, and the General Designer was Nikolai Dmitrievich Ustinov, the son of that same all-powerful member of the Politburo of the Central Committee of the CPSU and, concurrently, the Minister of Defense - Dmitry Fedorovich Ustinov. Having such a powerful patron, "Astrophysics" practically did not experience any problems with resources: financial, material, personnel. This was not long in affecting - already in 1982, almost four years after the reorganization of the Central Clinical Hospital into an NGO and the appointment of N.D. Ustinov as the general designer (before that, he headed the direction of laser location at the Central Design Bureau) was
SLK 1K11 "Stiletto"
The task of the laser complex was to provide countermeasures to optical-electronic systems for monitoring and controlling weapons of the battlefield in harsh climatic and operational conditions imposed on armored vehicles. The co-executor of the topic on the chassis was the Uraltransmash design bureau from Sverdlovsk (now Yekaterinburg), the leading developer of almost all (with rare exceptions) Soviet self-propelled artillery.
Under the guidance of the General Designer of Uraltransmash, Yuri Vasilievich Tomashov (Gennady Andreevich Studenok was then the director of the plant), the laser system was mounted on a well-tested GMZ chassis - product 118, which traces its "pedigree" from the chassis of product 123 (SAM "Krug") and products 105 (SAU SU-100P). At Uraltransmash, two slightly different machines were manufactured. The differences were due to the fact that, in the order of experience and experiments, the laser systems were not the same. The combat characteristics of the complex were outstanding at that time, and they still meet the requirements for conducting defense-tactical operations. For the creation of the complex, the developers were awarded the Lenin and State Prizes.
As mentioned above, the Stiletto complex was put into service, but for a number of reasons it was not mass-produced. Two experimental machines remained in single copies. Nevertheless, their appearance, even in the conditions of terrible, total Soviet secrecy, did not go unnoticed by American intelligence. In a series of drawings depicting the latest models of Soviet Army equipment, presented to Congress for "knocking out" additional funds to the US Department of Defense, there was also a very recognizable "Stiletto".
Formally, this complex is in service to this day. However, nothing was known about the fate of the experimental machines for a long time. Upon completion of the tests, they turned out to be virtually useless to anyone. The whirlwind of the collapse of the USSR scattered them across the post-Soviet space and brought them to the state of scrap metal. So, one of the cars in the late 1990s - early 2000s was identified by BTT amateur historians for disposal in the sump of the 61st BTRZ near St. Petersburg. The second one, a decade later, was also found by connoisseurs of the history of the BTT at a tank repair plant in Kharkov. In both cases, the laser systems from the machines were dismantled long ago. The "Petersburg" car retained only the hull, the "Kharkov" "cart" is in the best condition. At present, by the forces of enthusiasts, in agreement with the management of the plant, attempts are being made to preserve it with the aim of subsequent "museification". Unfortunately, the “St. Petersburg” car, apparently, has been disposed of by now: “What we have, we don’t store, but we cry when we lose it ...”.
This is how the Soviet laser complex was imagined in the West. Drawing from the magazine "Soviet Military Power"
The best share fell to another, no doubt unique apparatus, jointly produced by Astrophysics and Uraltrasmash. As a development of the Stiletto ideas, a new SLK 1K17 "Compression" was designed and built. It was a new generation complex with automatic search and aiming at a glare object of radiation from a multichannel laser (solid-state aluminum oxide laser Al2O3) in which a small part of aluminum atoms is replaced by trivalent chromium ions, or simply - on a ruby crystal. To create an inverse population, optical pumping is used, that is, illumination of a ruby crystal with a powerful flash of light. The ruby is given the shape of a cylindrical rod, the ends of which are carefully polished, silvered, and serve as mirrors for the laser. To illuminate the ruby rod, pulsed xenon gas-discharge flash lamps are used, through which batteries of high-voltage capacitors are discharged. The flash lamp has the shape of a spiral tube wrapped around a ruby rod. Under the action of a powerful light pulse, an inverse population is created in the ruby rod, and due to the presence of mirrors, laser generation is excited, the duration of which is slightly less than the duration of the flash of the pumping lamp. An artificial crystal weighing about 30 kg was grown especially for the "Compression" - the "laser gun" in this sense flew "a pretty penny". The new installation also required a large amount of energy. To power it, powerful generators were used, driven by an autonomous auxiliary power unit (APU).
The chassis of the latest 2S19 Msta-S self-propelled gun (item 316) was used as a base for the heavier complex. To accommodate a large number of power and electro-optical equipment, the Msta felling was significantly increased in length. The APU was located in its aft part. In front, instead of the barrel, an optical unit was placed, including 15 lenses. The system of precise lenses and mirrors in marching
conditions, it was closed with protective armored covers. This unit had the ability to point vertically. Operators' workplaces were located in the middle part of the felling. For self-defense, an anti-aircraft machine gun mount with a 12.7-mm NSVT machine gun was installed on the roof.
The body of the machine was assembled at Uraltransmash in December 1990. In 1991, the complex, which received the military index 1K17, was tested and the next year, 1992, was put into service. As before, the work on the creation of the Compression complex was highly appreciated by the Government of the country: a group of Astrophysics employees and co-executors was awarded the State Prize. In the field of lasers, we were then ahead of the whole world by at least 10 years.
However, on this, the "star" of Nikolai Dmitrievich Ustinov rolled up. The collapse of the USSR and the fall of the CPSU overthrew the former authorities. In the context of a collapsed economy, many defense programs have undergone a serious revision. The fate of this and "Compression" did not pass - the exorbitant cost of the complex, despite the advanced, breakthrough technologies and a good result, made the leadership of the Ministry of Defense doubt its effectiveness. The super-secret "laser gun" remained unclaimed. The only copy was hiding behind high fences for a long time, until, unexpectedly for everyone, in 2010 it turned out to be truly miraculous in the exposition of the Military Technical Museum, which is located in the village of Ivanovskoye near Moscow. We must pay tribute and thank the people who managed to pull this most valuable exhibit out of the top secrecy and made this unique machine public - a clear example of advanced Soviet science and engineering, a witness to our forgotten victories.
The last Cyclops of the Empire or lasers in service with Russia.
Posted by Hrolv Ganger
Dec 24 2010In the late 70s and early 80s of the 20th century, the entire world “democratic” community dreamed under the euphoria of Hollywood Star Wars. At the same time, behind the Iron Curtain, under the strictest secrecy, the Soviet "Evil Empire" slowly turned Hollywood dreams into reality. Soviet cosmonauts flew into space armed with laser pistols - “blasters”, battle stations and space fighters were designed, and Soviet “laser tanks” crawled across Mother Earth.
One of the organizations involved in the development of combat laser systems was the NPO Astrophysics. The General Director of Astrophysics was Igor Viktorovich Ptitsyn, and the General Designer was Nikolai Dmitrievich Ustinov, the son of that same all-powerful member of the Politburo of the Central Committee of the CPSU and, concurrently, the Minister of Defense - Dmitry Fedorovich Ustinov. Having such a powerful patron, "Astrophysics" practically did not experience any problems with resources: financial, material, personnel. This was not long in affecting - already in 1982, almost four years after the reorganization of the Central Clinical Hospital into an NGO and the appointment of N.D. Ustinov, the general designer (before that he led the Central Design Bureau for laser location), the first self-propelled laser complex (SLK) 1K11 "Stiletto" was put into service.
The task of the laser complex was to provide countermeasures to optical-electronic systems for monitoring and controlling weapons of the battlefield in harsh climatic and operational conditions imposed on armored vehicles. The co-executor of the topic on the chassis was the Uraltransmash design bureau from Sverdlovsk (now Yekaterinburg), the leading developer of almost all (with rare exceptions) Soviet self-propelled artillery.
Under the guidance of the General Designer of Uraltransmash, Yuri Vasilievich Tomashov (Gennady Andreevich Studenok was then the director of the plant), the laser system was mounted on a well-tested GMZ chassis - product 118, which traces its "pedigree" from the chassis of product 123 (SAM "Krug") and products 105 (SAU SU-100P). At Uraltransmash, two slightly different machines were manufactured. The differences were due to the fact that, in the order of experience and experiments, the laser systems were not the same. The combat characteristics of the complex were outstanding at that time, and they still meet the requirements for conducting defense-tactical operations. For the creation of the complex, the developers were awarded the Lenin and State Prizes.
As mentioned above, the Stiletto complex was put into service, but for a number of reasons it was not mass-produced. Two experimental machines remained in single copies. Nevertheless, their appearance, even in the conditions of terrible, total Soviet secrecy, did not go unnoticed by American intelligence. In a series of drawings depicting the latest models of Soviet Army equipment, presented to Congress for "knocking out" additional funds to the US Department of Defense, there was also a very recognizable "Stiletto".
This is how the Soviet laser complex was imagined in the West. Drawing from the magazine "Soviet Military Power"
Formally, this complex is in service to this day. However, nothing was known about the fate of the experimental machines for a long time. Upon completion of the tests, they turned out to be virtually useless to anyone. The whirlwind of the collapse of the USSR scattered them across the post-Soviet space and brought them to the state of scrap metal. So, one of the cars in the late 1990s - early 2000s was identified by BTT amateur historians for disposal in the sump of the 61st BTRZ near St. Petersburg. The second one, a decade later, was also found by BTT connoisseurs at a tank repair plant in Kharkov (see http://photofile.ru/users/acselcombat/96472135/). In both cases, the laser systems from the machines were dismantled long ago. The "Petersburg" car retained only the hull, the "Kharkov" "cart" is in the best condition. At present, by the forces of enthusiasts, in agreement with the management of the plant, attempts are being made to preserve it with the aim of subsequent "museification". Unfortunately, the “St. Petersburg” car, apparently, has been disposed of by now: “What we have, we don’t store, but we cry when we lose it ...”.
The remains of SLK 1K11 "Stiletto" on 61 BTRZ MO RF
The best share fell to another, no doubt unique apparatus, jointly produced by Astrophysics and Uraltrasmash. As a development of the Stiletto ideas, a new SLK 1K17 "Compression" was designed and built. It was a new generation complex with automatic search and aiming at a glare object of radiation from a multichannel laser (solid-state aluminum oxide laser Al2O3) in which a small part of aluminum atoms is replaced by trivalent chromium ions, or simply - on a ruby crystal. To create an inverse population, optical pumping is used, that is, illumination of a ruby crystal with a powerful flash of light. The ruby is given the shape of a cylindrical rod, the ends of which are carefully polished, silvered, and serve as mirrors for the laser. To illuminate the ruby rod, pulsed xenon gas-discharge flash lamps are used, through which batteries of high-voltage capacitors are discharged. The flash lamp has the shape of a spiral tube wrapped around a ruby rod. Under the action of a powerful light pulse, an inverse population is created in the ruby rod, and due to the presence of mirrors, laser generation is excited, the duration of which is slightly less than the duration of the flash of the pumping lamp. An artificial crystal weighing about 30 kg was grown especially for the "Compression" - the "laser gun" in this sense flew "a pretty penny". The new installation also required a large amount of energy. To power it, powerful generators were used, driven by an autonomous auxiliary power unit (APU).
SLK 1K17 "Compression" on trials
The chassis of the latest 2S19 Msta-S self-propelled gun (item 316) was used as a base for the heavier complex. To accommodate a large number of power and electro-optical equipment, the Msta felling was significantly increased in length. The APU was located in its aft part. In front, instead of the barrel, an optical unit was placed, including 15 lenses. The system of precise lenses and mirrors in field conditions was closed with protective armor covers. This unit had the ability to point vertically. Operators' workplaces were located in the middle part of the felling. For self-defense, an anti-aircraft machine gun mount with a 12.7-mm NSVT machine gun was installed on the roof.
The body of the machine was assembled at Uraltransmash in December 1990. In 1991, the complex, which received the military index 1K17, was tested and the next year, 1992, was put into service. As before, the work on the creation of the Compression complex was highly appreciated by the Government of the country: a group of Astrophysics employees and co-executors was awarded the State Prize. In the field of lasers, we were then ahead of the whole world by at least 10 years.
However, on this, the "star" of Nikolai Dmitrievich Ustinov rolled up. The collapse of the USSR and the fall of the CPSU overthrew the former authorities. In the context of a collapsed economy, many defense programs have undergone a serious revision. The fate of this and "Compression" did not pass - the exorbitant cost of the complex, despite the advanced, breakthrough technologies and a good result, made the leadership of the Ministry of Defense doubt its effectiveness. The super-secret "laser gun" remained unclaimed. The only copy was hiding behind high fences for a long time, until, unexpectedly for everyone, in 2010 it turned out to be truly miraculous in the exposition of the Military Technical Museum, which is located in the village of Ivanovskoye near Moscow. We must pay tribute and thank the people who managed to pull this most valuable exhibit out of the top secrecy and made this unique machine public - a clear example of advanced Soviet science and engineering, a witness to our forgotten victories.