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Plans to build Light Combat Helicopters indigenously from 2017-2018 onwards

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Plans to build Light Combat Helicopters indigenously from 2017-2018 onwards - The Economic Times
By PTI | 20 Mar, 2015, 02.20PM IST


NEW DELHI: The production plan for indigenously-built Light Combat Helicopters have been made from 2017-18 onwards, the government said today, adding that they are not a replacement for the ageing fleets of Chetak and Cheetah helicopters.

Minister of State for Defence Rao Inderjit Singh informed the Lok Sabha in a written reply that the light combat helicopters are being developed by HAL to fulfill the requirement of the army and the air force for a combat helicopter.

"The production plan for LCH has been made from 2017-18 onwards subject to firm order from IAF for limited series production," Singh said.

He said the LCH is not a replacement for ageing fleets of Cheetah and Chetak utility helicopters as the combat helicopter is a 5.5 tonne class twin engine armed aircraft. On the other hand, the Cheetah and Chetak come in the sub-three tonne single engine utility helicopter category.


Singh said a LCH prototype has successfully cleared cold weather trials in high altitudes.

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Ministry of Defence
20-March, 2015 16:19 IST

Light Combat Helicopters

The Light Combat Helicopter (LCH) is being developed by HAL to cater to the requirements of the Indian Air Force and the Indian Army for a Combat Helicopter. It is not a replacement for the ageing fleets of Cheetah and Chetak helicopters as LCH is a 5.5 Ton class twin engine armed helicopter whereas Cheetah and Chetak are sub 3 ton single engine unarmed utility helicopters.

As per the requirement, one of the LCH prototypes needs to be subjected to field trials in high altitude and in cold weather. TD-2 prototype has successfully passed the cold weather trials at High altitude. TD-3 and TD-4 prototypes will be utilized for other flight test requirements.

The production plan of LCHs has been made from 2017-18 onwards subject to firm order from IAF for limited series production.

This information was given by Minister of State for Defence Rao Inderjit Singh in a written reply to Shri Senguttuvan B in Lok Sabha today.
 
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Hi
I hope that some systems like fly by wire and a small millimeter radar is fitted to it, at least fly by wire as they are going to be used in Himalayans and it would greatly increase its operations.
Cheers
Thanks
 
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Hi
I hope that some systems like fly by wire and a small millimeter radar is fitted to it, at least fly by wire as they are going to be used in Himalayans and it would greatly increase its operations.
Cheers
Thanks

The idiots in the DRDO didn't think about it earlier & now if we want to mount such a radar on it there must be some serious structural changes
 
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Good news is that won't take much time specially since Reform button has been pushed in Defense Sector but it would have been nice if they would have included one in the start also does Iranian Platforms have such radars on them
 
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Why the Apache is a brute and LCH is elegant


Introduction:

Following up on my previous article about the LCH versus its Chinese opponent (the very sluggish Z-10), the obvious question comes to mind: “How does the LCH compare with what AH-64D Apache that Boeing is offering to India?” Once again, we turn to analysis. The Apache is in the same weight class as the Z-10 and is also two times heavier than the LCH when carrying the same payload in weapons, fuel and crew. The AH-64D is 5,165 kg and the LCH even in its current overweight mode is about 2,800-3,000 kg. But where the Z-10 lost out to an acute lack of power, the Apache reigns supreme. Powered by engines that produce each produce one and half times the LCH’s net power, (an incredible ~2,980 KW for the AH-64D versus ~1,700 KW for the LCH), the Apache makes up for the extra weight by sheer brute power. This allows the Apache to get close to the LCH at both sea-level and high-altitude conditions.

But just how close does it get?

To answer that question, I present here a comparison study similar to that done previously for the Z-10. We will take the LCH and the Apache and put an identical payload of 1,000 kg on them. Note that we have increased the payload here from 500 kg to 1000 kg for this analysis as opposed to that done for the Z-10. The reasoning is simple: both the LCH and the Apache can haul 500 kg through the high Himalayas. However, to get an idea of different performances, we are getting more realistic and putting a higher payload. In reality, with about 200 kg of crew and around 300 kg of fuel, the effective payload of weapons is only 500 kg. We will run both helicopters through a simulation model where we subject them to altitude variations and see how it affects their rate-of-climb capabilities while in hover, out of Ground Effect conditions. The rate-of-climb (ROC, measured here in meters/second) is a true measure of the maneuvering capability of an attack helicopter. Typically, a ROC of 0.5 m/sec is used to evaluate service ceiling conditions. A ROC of 2.5 m/sec is typically the bare minimum for combat conditions. For a helicopter in high mountains to be truly maneuverable, it may need somewhere in the range of 2.5 to 8 m/sec vertical ROC equivalent in power capacity. Of course, beyond a certain altitude, the helicopter may not be able to fly with the 500 kg payload, let alone providing additional power for high ROC. So we will also see where those limits are for the LCH and the Z-10.

The focus of this analysis is on a preliminary aerodynamic and propulsive standpoint. The analysis is done using simulation tools that integrate payload capacities and typical rate-of-climb requirements with a preliminary rotary aerodynamics model and a simple propulsion module. When coupled with an atmospheric simulator for the Himalayas, the performance of each helicopter type can be predicted and compared. Furthermore, the models allow for the performance analysis in Ground Effect conditions. The Ground Effect conditions are encountered when the helicopters are hovering very close to the ground and serves to work as a performance multiplier with regard to power needed in lifting a certain payload.

The models do not compensate for transmission limitations for the power, which means that the analysis is idealized wherein power generated is power available. This is, of course, not encountered in practice, but works well for high-altitude conditions where power available is almost always less than the transmission limits. At lower altitudes, the performance of the various designs must be assumed to be ideal, rather than restricted from transmission and structural limitations. For example, the maximum rate-of-climb (ROC) values obtained from this simulator for sea-level (SL) conditions will typically be higher than what is allowed by other limitations. However, such removal of limitations is required in order to compare the various contenders at the same performance benchmarks.

Data for this analysis is obtained from the manufacturers via open-sources. No proprietary information is shared here. Unless where cited, the analysis results are to be considered proprietary of the author. See remarks for details.

1zn3ew5.png


LCH versus Apache:

The hover performance is evaluated at altitudes varying from 0 ft (SL) to 25,000 ft. Altitudes in the Himalayan Mountains regularly require flights above 10,000 ft and often up to 22,000 ft. The data is presented for the LCH and the Apache for payload and available maximum ROC capability versus altitude. A threshold ROC line is shown for the reference 8 m/sec combat ROC.

dwa045.png


Notice how the sea-level performance of the LCH and the Apache are similar. The Apache, with a 1,000 kg payload is able to generate a maximum vertical ROC capability of 12.77 m/sec. By comparison, at sea-level, the LCH is able to carry the 1,000 kg and is able to provide a power excess for a theoretical max ROC of 15.16 m/sec. It is instantly apparent how the Apache is able to use its outstanding source of power to lift its much heavier mass and still come close to the LCH performance. This heavier bulk involves greater armor and protection for the Apache pilots.

Now consider how the change in altitude affects both helicopters. The Apache, trying to maintain the 1,000 kg payload, begins to tail-off its ROC capability from 12.77 m/sec at sea-level to 0 m/sec ROC at ~18,000 ft. Beyond 18,000 ft altitude, the Apache also cannot carry its 1,000 kg payload and the tail-off in that capacity is visible, although less dramatic than the Z-10 from the previous articles. The Z-10 cannot operate beyond 10,000 ft under any conditions. The Apache, on the other hand, flies and fights up till ~15,000 ft altitude.

The LCH, on the other hand, once again utilizes its light-weight structure to great effect. It can not only maintain the 1,000 kg payload for another 3,000 ft altitude (i.e. up to ~21,000 ft), the tail-off in the ROC does not drop below 8 m/sec until ~11,000 ft. The tail-off does not drop below the minimum 2.5 m/sec until ~15,000 ft.

Conclusions:

The difference between the LCH and Apache at high altitudes is going to be in maneuverability. The LCH will turn out to be more agile and have higher performance in general because it is custom-designed to fight at higher altitudes. The Apache, on the other hand, is a brute-force machine, matching the LCH up to the Himalayas for payload, but losing out in agility. The Apache will be less agile than the LCH but will take more hits and keep flying. Where the LCH will look to evade and survive, the Apache will turn to its armor.


Excellent analysis from br
 
.
Why the Apache is a brute and LCH is elegant


Introduction:

Following up on my previous article about the LCH versus its Chinese opponent (the very sluggish Z-10), the obvious question comes to mind: “How does the LCH compare with what AH-64D Apache that Boeing is offering to India?” Once again, we turn to analysis. The Apache is in the same weight class as the Z-10 and is also two times heavier than the LCH when carrying the same payload in weapons, fuel and crew. The AH-64D is 5,165 kg and the LCH even in its current overweight mode is about 2,800-3,000 kg. But where the Z-10 lost out to an acute lack of power, the Apache reigns supreme. Powered by engines that produce each produce one and half times the LCH’s net power, (an incredible ~2,980 KW for the AH-64D versus ~1,700 KW for the LCH), the Apache makes up for the extra weight by sheer brute power. This allows the Apache to get close to the LCH at both sea-level and high-altitude conditions.

But just how close does it get?

To answer that question, I present here a comparison study similar to that done previously for the Z-10. We will take the LCH and the Apache and put an identical payload of 1,000 kg on them. Note that we have increased the payload here from 500 kg to 1000 kg for this analysis as opposed to that done for the Z-10. The reasoning is simple: both the LCH and the Apache can haul 500 kg through the high Himalayas. However, to get an idea of different performances, we are getting more realistic and putting a higher payload. In reality, with about 200 kg of crew and around 300 kg of fuel, the effective payload of weapons is only 500 kg. We will run both helicopters through a simulation model where we subject them to altitude variations and see how it affects their rate-of-climb capabilities while in hover, out of Ground Effect conditions. The rate-of-climb (ROC, measured here in meters/second) is a true measure of the maneuvering capability of an attack helicopter. Typically, a ROC of 0.5 m/sec is used to evaluate service ceiling conditions. A ROC of 2.5 m/sec is typically the bare minimum for combat conditions. For a helicopter in high mountains to be truly maneuverable, it may need somewhere in the range of 2.5 to 8 m/sec vertical ROC equivalent in power capacity. Of course, beyond a certain altitude, the helicopter may not be able to fly with the 500 kg payload, let alone providing additional power for high ROC. So we will also see where those limits are for the LCH and the Z-10.

The focus of this analysis is on a preliminary aerodynamic and propulsive standpoint. The analysis is done using simulation tools that integrate payload capacities and typical rate-of-climb requirements with a preliminary rotary aerodynamics model and a simple propulsion module. When coupled with an atmospheric simulator for the Himalayas, the performance of each helicopter type can be predicted and compared. Furthermore, the models allow for the performance analysis in Ground Effect conditions. The Ground Effect conditions are encountered when the helicopters are hovering very close to the ground and serves to work as a performance multiplier with regard to power needed in lifting a certain payload.

The models do not compensate for transmission limitations for the power, which means that the analysis is idealized wherein power generated is power available. This is, of course, not encountered in practice, but works well for high-altitude conditions where power available is almost always less than the transmission limits. At lower altitudes, the performance of the various designs must be assumed to be ideal, rather than restricted from transmission and structural limitations. For example, the maximum rate-of-climb (ROC) values obtained from this simulator for sea-level (SL) conditions will typically be higher than what is allowed by other limitations. However, such removal of limitations is required in order to compare the various contenders at the same performance benchmarks.

Data for this analysis is obtained from the manufacturers via open-sources. No proprietary information is shared here. Unless where cited, the analysis results are to be considered proprietary of the author. See remarks for details.

1zn3ew5.png


LCH versus Apache:

The hover performance is evaluated at altitudes varying from 0 ft (SL) to 25,000 ft. Altitudes in the Himalayan Mountains regularly require flights above 10,000 ft and often up to 22,000 ft. The data is presented for the LCH and the Apache for payload and available maximum ROC capability versus altitude. A threshold ROC line is shown for the reference 8 m/sec combat ROC.

dwa045.png


Notice how the sea-level performance of the LCH and the Apache are similar. The Apache, with a 1,000 kg payload is able to generate a maximum vertical ROC capability of 12.77 m/sec. By comparison, at sea-level, the LCH is able to carry the 1,000 kg and is able to provide a power excess for a theoretical max ROC of 15.16 m/sec. It is instantly apparent how the Apache is able to use its outstanding source of power to lift its much heavier mass and still come close to the LCH performance. This heavier bulk involves greater armor and protection for the Apache pilots.

Now consider how the change in altitude affects both helicopters. The Apache, trying to maintain the 1,000 kg payload, begins to tail-off its ROC capability from 12.77 m/sec at sea-level to 0 m/sec ROC at ~18,000 ft. Beyond 18,000 ft altitude, the Apache also cannot carry its 1,000 kg payload and the tail-off in that capacity is visible, although less dramatic than the Z-10 from the previous articles. The Z-10 cannot operate beyond 10,000 ft under any conditions. The Apache, on the other hand, flies and fights up till ~15,000 ft altitude.

The LCH, on the other hand, once again utilizes its light-weight structure to great effect. It can not only maintain the 1,000 kg payload for another 3,000 ft altitude (i.e. up to ~21,000 ft), the tail-off in the ROC does not drop below 8 m/sec until ~11,000 ft. The tail-off does not drop below the minimum 2.5 m/sec until ~15,000 ft.

Conclusions:

The difference between the LCH and Apache at high altitudes is going to be in maneuverability. The LCH will turn out to be more agile and have higher performance in general because it is custom-designed to fight at higher altitudes. The Apache, on the other hand, is a brute-force machine, matching the LCH up to the Himalayas for payload, but losing out in agility. The Apache will be less agile than the LCH but will take more hits and keep flying. Where the LCH will look to evade and survive, the Apache will turn to its armor.


Excellent analysis from br
Good comparison... I always wondered how LCH would perform against the Apache in the Himalayas.
Can you please forward me the link to the comparison b/w LCH and Z-10
 
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Good comparison... I always wondered how LCH would perform against the Apache in the Himalayas.
Can you please forward me the link to the comparison b/w LCH and Z-10
Why the LCH is a sports car compared to the lumbering Z-10


Introduction:

I often get asked the question: “Is the Indian LCH better than the Chinese Z-10?” An attempt to answer such a question verbally is difficult. It is preferable that one sees the numbers themselves. The Z-10 is two times heavier than the LCH when carrying the same payload in weapons, fuel and crew. The Z-10’s empty weight is 5,540 kg and the LCH even in its current overweight mode is about 2,800-3,000 kg. And yet the Z-10 is powered by the same net total power as the LCH (~2,000 KW for the Z-10 versus ~1,700 KW for the LCH). That’s a nasty combination in terms of performance, both at sea-level and at high altitudes. The effect of additional weight versus power required is non-linear for rotary flying machines.

But just how bad is it really for the Z-10?

To answer that question, I present here a comparison study. We will take the LCH and the Z-10 and put an identical payload of 500 kg on them. We will run both helicopters through a simulation model where we subject them to altitude variations and see how it affects their rate-of-climb capabilities while in hover, out of Ground Effect conditions. The rate-of-climb (ROC, measured here in meters/second) is a true measure of the maneuvering capability of an attack helicopter. Typically, a ROC of 0.5 m/sec is used to evaluate service ceiling conditions. A ROC of 2.5 m/sec is typically the bare minimum for combat conditions. For a helicopter in high mountains to be truly maneuverable, it may need somewhere in the range of 2.5 to 8 m/sec vertical ROC equivalent in power capacity. Of course, beyond a certain altitude, the helicopter may not be able to fly with the 500 kg payload, let alone providing additional power for high ROC. So we will also see where those limits are for the LCH and the Z-10.

The focus of this analysis is on a preliminary aerodynamic and propulsive standpoint. The analysis is done using simulation tools that integrate payload capacities and typical rate-of-climb requirements with a preliminary rotary aerodynamics model and a simple propulsion module. When coupled with an atmospheric simulator for the Himalayas, the performance of each helicopter type can be predicted and compared. Furthermore, the models allow for the performance analysis in Ground Effect conditions. The Ground Effect conditions are encountered when the helicopters are hovering very close to the ground and serves to work as a performance multiplier with regard to power needed in lifting a certain payload.

The models do not compensate for transmission limitations for the power, which means that the analysis is idealized wherein power generated is power available. This is, of course, not encountered in practice, but works well for high-altitude conditions where power available is almost always less than the transmission limits. At lower altitudes, the performance of the various designs must be assumed to be ideal, rather than restricted from transmission and structural limitations. For example, the maximum rate-of-climb (ROC) values obtained from this simulator for sea-level (SL) conditions will typically be higher than what is allowed by other limitations. However, such removal of limitations is required in order to compare the various contenders at the same performance benchmarks.

Data for this analysis is obtained from the manufacturers via open-sources. No proprietary information is shared here. Unless where cited, the analysis results are to be considered proprietary of the author. See remarks for details.

2n13pc.png


LCH versus the Z-10:

The hover performance is evaluated at altitudes varying from 0 ft (SL) to 25,000 ft. Altitudes in the Himalayan Mountains regularly require flights above 10,000 ft and often up to 22,000 ft. The data is presented for the LCH and the Z-10 for payload and available maximum ROC capability versus altitude. A threshold ROC line is shown for the reference 8 m/sec combat ROC.

11ui61w.png


Notice how the sea-level performance of the LCH and the Z-10 are significantly different. The Z-10, with a 500 kg payload (not counting weapons and fuel) is able to generate a maximum vertical ROC capability of 3.6 m/sec. By comparison, at sea-level, the LCH is able to carry the 500 kg and is able to provide a power excess for a theoretical max ROC of 21 m/sec! Of course, this will not be allowed in reality. The LCH powertrain transmission limitations will bring that max ROC to about ~10 m/sec for structural safety reasons. Both helicopters are able to lift the 500 kg requirement at sea-level.

Now consider how the change in altitude affects both helicopters. The Z-10, trying to maintain the 500 kg payload, begins to tail-off its ROC capability from 3.6 m/sec at sea-level to 0 m/sec ROC at ~8,000 ft. Beyond 8,000 ft altitude, the Z-10 also cannot carry its 500 kg payload and the tail-off in that capacity is dramatic. The Z-10 cannot operate beyond 10,000 ft under any conditions.

The LCH, on the other hand, utilizes its light-weight structure to great effect. It can not only maintain the 500 kg payload for all altitudes from sea-level to the Himalayan mountain tops, the tail-off in the ROC does not drop below 8 m/sec until ~12,000 ft. The tail-off does not drop below the minimum 2.5 m/sec until ~19,000 ft. The LCH can fly, and fight, at all altitudes in the Himalayas.

Z-10 versus the Mi-35: The Pakistani Insight

You will notice that I put the Mi-35 performance numbers in the plot above for identical conditions. The reason for doing so is to illustrate why the Pakistanis went for the Mi-35 option when the spanking-new Z-10s were on the table. The Mi-35 performance for high-altitude conditions is dismal. This is a fact known in Indian Air Force circles for many years and has led to the genesis of the LCH. But as bad as the performance for the Mi-35 is in the mountains, it is still better than the Z-10. At sea-level, the Mi-35 can completely outperform the Z-10 for ROC capability. Its ROC tail-off at high altitude is at ~9,500 ft. Its payload tail-off is at ~12,500 ft. Both these numbers are better than that of the Z-10. Coupled with lower operating costs and generally rugged reliability, the Pakistani decision to pursue the Mi-35 becomes clearer. Additional geo-political and economic constraints may also apply, but are not discussed here.
 
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The idiots in the DRDO didn't think about it earlier & now if we want to mount such a radar on it there must be some serious structural changes

Hi
Yes, mounting a radar will be difficult , so it can be added in later blocks. But I seriously think that using a fly by wire now before it attains FOC can be possible as it will also help in overall weight reduction. Also i am not that knowledgeable but they have developed one for Tejas so incorporating one in LCH shouldn't be difficult.
Cheers
Thanks

Hi
Sir,I didn't get you. I meant it will form our frontline attack line against Chinese light armoured Tanks which they are building for use in Tibet. I am sorry if I didn't get you.
Cheers
Thanks
 
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