Introducing the innovative Constant Velocity Engine. The future we need now.
Massive Continuous Torque
Maximum torque for 90% of the stroke vs momentarily for crankshaft engines
Fuel Efficient
Consumes less than half the fuel to produce the same horsepower
Reduced Emissions
Eliminates 70%+ of exhaust emissions with nearly 100% burn of all fuel
Smaller
Same power in a smaller package permits design & product innovations
Lighter
Same power with far less weight yields additional fuel savings
Fully Scalable
Applications from 2 - 20,000+ horsepower Multi-size, multi-fuel, multi-industry, multi-product
Revolutionizing Defense Mobility Through
Ahiravata's Advanced Engine Technology
Improved Mission Effectiveness & Survivability with an Advanced Combat Engine - Whether a modern combat vehicle is being repowered or is being constructed right from the scratch, the Advanced Combat Engine or ACE showcases the highest level of engineering competence. ACE is painstakingly designed towards the process to increase mission effectiveness, thus guaranteeing exceptional performance as well as dependability under the most trying circumstances. With an emphasis on improving maneuverability, ACE delivers dense vehicles the ability to move quickly and precisely over a variety of difficult terrains. Additionally, it greatly increases survivability by giving one the strength as well as fortitude required to resist & defeat battle dangers. Selecting ACE will revolutionize your combat vehicles by combining state-of-the-art technology with unmatched performance and durability.
Designed with Longevity, Dependability, and Durability in Mind
Ahiravata’s Genuine Parts are painstakingly made to precisely match the requirements of our high-performing products. Every component is created with premium level of materials as well as exacting production techniques in order to guarantee that it matches the dependability as well as longevity of our well-known products. What distinguishes our authentic components right from the imitations is their quality & attention to every single detail. Find your engine’s serial number, browse our extensive parts inventory, & learn why Ahiravata Genuine Parts are the best possible option for preserving your engines’ exceptional performance.
About Ahiravata Motor Corporation Private Limited & CV Global, Inc.
Ahiravata Motor Corporation Private Limited (India) and CV Global, Inc. (USA) are collaborating to bring groundbreaking Constant Velocity (CV) Engine technology to India and other potential markets. This partnership combines cutting-edge innovation with a focus on efficient, high-performance automotive engineering.
Vision for the Future of Internal Combustion Engines:
Ahiravata, a pioneer in advanced engine technologies, aims to revolutionize internal combustion engines for the future. The Constant Velocity (CV) Engine, a product of the strong partnership between Ahiravata Motor Corporation and CV Global, Inc., is set to redefine benchmarks for performance, efficiency, and sustainability across diverse applications.
Sustainable Performance Using Cutting-Edge Engine Technology:
The cutting-edge engines from Ahiravata can deliver unparalleled performance, fuel efficiency, & environmental responsibility. Our engines set the bar for agricultural operations in the future by utilizing state-of-the-art mobility technologies. Longer engine lifespans, lower running costs, as well as increased production are all advantageous to farmers. In addition to increasing farm productivity, these sustainable innovations also assist achieve international environmental goals. Every Ahiravata engine is made with the planet’s as well as agriculture’s future in mind.
Explore Different Types Of Engines
Specifications
Speak with the Defense Engine Professionals at Ahiravata
Ahiravata has a long history of spearheading technologies that support the success of our clients right across the world. Ahiravata is your go-to partner for enabling defense operations because of its extensive global network of professionals & immense experience in the defense engine technology sector. Our seasoned experts are prepared to deliver their priceless perspectives on defense technology's history, present, and future. Allow our professionals to assist you in achieving unmatched dependability as well as performance in your defense-related activities.
Growing Interest in Defense Vehicle Hydrogen Engines
Because zero-emission solutions are much needed in today’s environment, hydrogen engines are becoming more and more popular in the defense industry. A viable non-fossil fuel, hydrogen has major environmental advantages when utilized in military vehicles. The defense sector is now considering hydrogen internal combustion engines for the heavy-duty applications after first concentrating on fuel cell electric vehicles (FCEVs). These engines are simple to integrate as well as maintain because they run on well-known internal combustion technology & use carbon-free hydrogen fuel. Hydrogen engines are positioned as a major contributor to the advancement of sustainable defense mobility due to their unique combination of innovation and dependability.
A Secret to Emission-Free Living
Among other low-to-zero carbon technologies, Ahiravata's hydrogen engines delivers fleets and automakers a substantial edge. These engines are a familiar technology for manufacturers to integrate into vehicle design as well as manufacturing because they are based on the foundation of today's contemporary and dependable internal combustion engines. Hydrogen engines are also familiar to fleet operators, thus making them easy to use, manage, diagnose, and service. This blend of innovation and familiarity guarantees a smooth transition to a future with lower emissions & more sustainability.
Adaptability in Every Way
The Ahiravata’s engine is the epitome of adaptability and thus may be used in air motors, compressors, generators, direct drive, as well as hybrid systems, among other configurations. It is the perfect option for a wide range of industries as well as applications because of its design, which enables complete scaling based on horsepower needs. Ahiravata delivers maximum level of performance in all industries, whether you require power for industrial machinery, transportation, or energy solutions.
Technology
Massive Continuous Torque
The crankshaft mechanism has served a vital role in internal combustion engine design for more than 130 years. However, despite continuous refinement and incremental improvements over time, the crankshaft has reached the end of its useful life.
Crankshaft geometry has inherent design limitations in the transfer of linear force to rotational power. A crankshaft-based engine achieves its peak torque for only one brief moment at close to mid-stroke.
The CVE design achieves its maximum torque starting at 8%* of the stroke after TDC and maintains maximum torque for over 90%* of the stroke after TDC.
Side-by-side static testing of equal displacement crankshaft based versus CVE Technology based designs show that the CVE design boasts a 58%* improvement in torque over today’s crankshaft engine design.
The patented CV Engine/Technology (CVE) replaces the crankshaft completely with a Powershaft and Rodrack Assembly, which fundamentally alters the geometric relationship of the motion of the piston stroke relative to the movement of the rotating shaft. It continuously converts linear reciprocating piston motion to rotary movement and vice versa in the most efficient manner possible.
Fuel Efficient
When comparing engine designs producing equal power:
The fuel required by the crankshaft-based engine is far greater because:
- The amount of fuel injected into the cylinder must be substantial enough to last until mid-stroke, where a momentary maximum transfer of linear motion to rotational power occurs
- Due to the asynchronous motion of the opposing pistons, an increased amount of energy is required to propel these pistons through their cycle in order to rotate the crankshaft and drive the other pistons not engaged in the power stroke
- The geometry of the crankshaft to connecting rod to piston connection creates drag and friction due to piston side load on the cylinder walls
- The pistons are not traveling at a constant velocity and are operating at continuously varying speeds throughout the stroke, which creates a pulsation within the crankcase
The fuel required by the CV Engine design is far less because:
- The CVE design requires only a small amount of fuel at the top of the stroke to propel the piston down the cylinder to create continuous maximum transfer of linear motion to rotational power occurs
- The piston and rodrack assembly is one integrated component that is in perfect linear alignment, permitting the pistons to move in synchronous motion, requiring minimal energy to propel the full cycle
- Drag and friction due to piston side load on the cylinder walls is non-existent in the CVE engine design due to perfect linear alignment of the piston and rodrack assembly and the linear bearings that support the travel of the rodrack assembly
- The pistons in the CVE are traveling at a constant velocity and are operating at constant speeds throughout more than 80%* of the stroke, virtually eliminating pulsation within the CVE Powercase
Reduced Emissions & Environmental Impact
When comparing engine designs producing equal power:
Crankshaft Engine Design
- In a four-stroke crankshaft-based engine, the fuel required to obtain optimum performance must be sufficient to sustain combustion until the piston reaches mid- stroke and the fuel charge must simultaneously increase in volume as the volume within the cylinder increases as the piston travels to mid-stroke.
- Due to the required duration of combustion and required piston travel within the cylinder, only half of the stroke remains to eliminate the fuel charge, therefore the entire volume of fuel required cannot be burned by the time the power stroke is complete
- The unburned fuel is therefore wasted and creates additional harmful emissions in the exhaust gasses, which must be captured and processed by the catalytic converter. The use of engine exhaust scrubbing devices such as diesel particulate filters and catalytic converters, which require expensive precious metals such as platinum, palladium and rhodium.
- Due to crankshaft geometry, the piston is subject to side-loading. This side load not only creates friction and drag and negatively impacts torque, the unloaded side of the piston creates a gap between the piston and the cylinder wall, allowing exhaust gases to escape into the crankcase, contaminating the engine oil, requiring frequent and environmentally impactful oil and filter changes.
- According to Lafayette University, almost 30% of all US global warming emissions result from America’s transportation sector. 60% of U.S. transportation emissions come from cars and light trucks, which conveys the significant role vehicle exhaust from internal combustion engines in passenger cars has on our environment and community health.
Read the study…
CV Motion Technology Engine Design
- In the CVE four stroke design, optimum performance is achieved at the top of the stroke, where the volume of the cylinder is relatively small, requiring significantly less fuel to generate the maximum transfer of power
- The maximum transfer of power occurs at close to the top of the stroke in the CV Engine design. This short duration combustion phase allows for nearly the entire stroke to be utilized to complete the total combustion of the smaller required fuel charge by the time the exhaust stroke is initiated
- Due to the absence of the majority of unburned fuel and harmful emissions, the need for a catalytic converter in gasoline engine applications is completely eliminated. The cost savings on a per engine basis is significant. Corresponding reductions in emissions are achieved in diesel engine applications which may permit the elimination of exhaust scrubbing devices such as diesel particulate filters
- In the CVE design, the piston and rodrack assembly functions as one integrated component that is in perfect linear alignment and therefore does not allow the piston to come in contact with the cylinder wall. This eliminates piston to side load. This minimizes drag and friction and eliminates the heat produced by the contact of the piston with the cylinder wall.
- The CVE operates with a fully sealed powercase, much like a sealed transmission case. The lack of piston side loading combined with the sealed powercase prevents combustion by-products from entering the powercase, preventing contamination of the engine oil, virtually eliminating environmentally impactful oil and filter changes.
- The forecasted 70% reduction in exhaust emissions from the use of the CV Engine in all modes of fueled transportation would translate to a reduction from 8,887 grams of CO2 per gallon of gasoline burned to 2,667 grams of CO2 and a reduction from 10,180 grams of CO2 per gallon of diesel burned to 3,054 grams of CO2. The potential impact of the CV Engine on reducing global warming emissions from carbon dioxide is enormous.
Read the study…
Smaller
To illustrate the significant reductions in physical size that can be achieved via the CVE design, a direct comparison with a comparable crankshaft-based engine follows.
When comparing engine designs producing equal power:
Specifications | Crankshaft Engine Design Subaru FB25 (4cyl, 4 stroke) | CV Motion Technology Engine Design A02 Version (4cyl, 4 stroke) |
---|---|---|
Horsepower | 170 | 193 |
Displacement | 152.4 cu or 2498 cc | 27 cu or 443 cc |
RPM | 5800 (non direct) | 2450 (direct, not geared) |
Height | 23.63″ | 10″ |
Width | 32.67″ | 14.5″ |
Length | 16.93″ | 11.8″ |
Lighter
The CV Engine design eliminates the crankshaft, the second heaviest component of an internal combustion engine after the engine block.
The CV Engine produces the same power from a much smaller displacement and therefore is lighter overall. The CV Engine also requires fewer total parts in its construction and these parts are generally smaller and lighter as well.
The high compression pressures required in the crankshaft-based design impacts many aspects of the overall engine design, as multiple components must be made robust enough to withstand the very high pressures, which translates to significantly increased engine weight. The CVE design operates at substantially reduced pressures (gas or diesel) which allows for the weight of both the engine and the related subassemblies it would be installed in to be much lighter.
The combined effect of the elimination of the crankshaft, the physically smaller components comprising the engine and the ability to assemble the engine with components of an overall lighter weight construction translates to significant weight savings, on the order of hundreds of pounds even in a modest car size engine.
When comparing engine designs producing equal power:
Specifications | Crankshaft Engine Design Subaru FB25 (4cyl, 4 stroke) | CV Motion Technology Engine Design A02 Version (4cyl, 4 stroke) |
---|---|---|
Horsepower | 170 | 193 |
Displacement | 152.4 cu or 2498 cc | 27 cu or 443 cc |
RPM | 5800 (non direct) | 2450 (direct, not geared) |
Dry Weight | 269 lbs | 71 lbs |
Fully Scalable
The CVE design allows for an extensive range of configurations, several of which are impossible or impractical with a crankshaft-based design. The design of the CVE powershaft allows for unique and highly beneficial designs which creates substantial manufacturing efficiencies, with resultant cost and operational savings.
The tables below highlight some of the applications, configurations and manufacturing benefits.
Configuration | Benefit |
---|---|
Multi-fuel | Gas, diesel, jet fuel, natural gas, hydrogen, compressed air |
Multi-module engine | Combine fueled engine, compressor, air motor (drone) |
Multi-module engine | Combine fueled engine, compressor, air motor (hyper-mileage vehicle) |
Multiple engines | Common, hollow powershaft allows for multiple, redundant engines |
Multiple engines | Coupled engines brought on/off line (more power vs. fuel savings) |
General aviation | Redundant engines; lightweight diesel application, diesel fuel vs. avgas |
Automobile | Compact, mid-engine designs without sacrificing interior space |
Range extender (battery) | Small engine recharges batteries for electric motor without stopping |
Range extender (no battery) | Small engine powers DC generator to directly power electric motors |
Recreational vehicles | Reduced emissions create acceptance in environmentally sensitive areas |
Generators / Heavy equipment | Greatly reduced fuel use creates less downtime & cost savings |
Ocean freight / Cruise Ships | Multiple engines coupled for high speed, “green” ocean crossings |
Ocean freight / Cruise Ships | Uncouple all but one engine for low emission in-harbor operation |
Ocean freight / Cruise Ships | Massive fuel savings from propulsion engines and ship’s electric generators |
Trucking industry | Massive fuel savings for fleet operators |
Trucking industry | Fuel savings mean the difference between profit & loss for owner/operators |
Marine industry | Same power from smaller engine creates more useable space |
Marine industry | Same power with less weight improves performance and saves fuel |
Scalable size | Same horsepower produced with smaller displacement |
Scalable output | Same displacement generating greater horsepower |
Manufacturing | Benefit |
---|---|
Common platform | Many engine variants (4, 6, 8 cylinders) from two CV engine configurations) |
Hollow Powershaft | Engage or disengage multiple engines to save fuel or provide power |
Hollow Powershaft | Reduces number of engine variants required; less parts inventory |
Simplified production | Reduce the number of engine variant production lines; faster production |
Less factory space required | Reduced factory overhead and building maintenance expenses |
Less personnel required | Reduced payroll and benefits expenses |
Reduced number of tools | Production line elimination also eliminates tools required |
Reduced number of parts | Reduced parts manufacturing, storage and inventory tracking expense |
Reduced number of suppliers | Simplified supply chain; less dependency on suppliers; reduced delays |
Smaller engine dimensions | More storage in same space; more engines shipped in same container |
Vehicles | Benefit |
---|---|
Lighter sub-assemblies | A significantly lighter engine allows for substantially lighter sub-assemblies |
Smaller braking components | Less mass due to reduced component weight allows for smaller brakes |
Reduced overall weight | Weight savings from engine & all sub-assemblies adds to fuel savings |
Reduced fuel consumption | Combined effect from engine operation, lighter engine and components |
Smaller, simpler transmissions | Low RPM, high torque engine permits 2 forward, 1 reverse gearing |
Lower center of gravity | Horizontally opposed engine, smaller dimensions, mid-engine applications |
Storage & passenger space | Reduced engine volume opens up space for people and cargo |
Trucking industry | Reduced overall weight permits heavier payloads |
Simpler to maintain | Sealed power case equate to elimination of oil changes; less waste |