#Electro Hydraulic Servo Valve top 10 companies
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trendingreportz · 7 months ago
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Electro Hydraulic Servo Valve Market - Forecast(2024 - 2030)
Electro-Hydraulic Servo Valve Market Overview:
Electro-Hydraulic Servo Valve Market size is forecast to reach $1.42 Billion by 2030, after growing at a CAGR of 3.35% during 2024-2030. This growth is driven by the Electro Hydraulic Servo Valve market is experiencing a trend toward intelligent and interconnected valves. These valves integrate advanced sensors, data analytics, and communication features, enabling real-time monitoring, predictive maintenance, and remote control. This shift towards smart valves enhances operational efficiency and minimizes downtime for industries. With increasing automation and connectivity demands, the demand for intelligent Electro Hydraulic Servo Valves is on the rise, reflecting a significant market trend. 
Additionally, material science advancements and miniaturization are pivotal trends shaping the Electro Hydraulic Servo Valve (EHSV) market. Manufacturers are leveraging innovations to enhance the durability, corrosion resistance, and thermal stability of EHSVs. Moreover, there's a growing emphasis on miniaturization to cater to compact, lightweight systems demanded by portable devices, robotics, and space-constrained environments. This trend towards optimized materials and smaller sizes reflects the evolving landscape of EHSVs, driving market progression. As technology continues to evolve, these developments underscore the industry's commitment to innovation and efficiency.
Electro-Hydraulic Servo Valve Market - Report Coverage:
The “Electro Hydraulic Servo Valve Market Report - Forecast (2024-2030)” by IndustryARC, covers an in-depth analysis of the following segments in the Electro Hydraulic Servo Valve Market.
By Product Stage: Single Stage, Double Stage and Others.
By Type: Nozzle Flapper Valve, Jet Action Valve, Dynamic Valve, Deflector jet valve, and Others.
By End-Use Industry: Industrial, Marine, Aerospace & Defense, Construction Sector, Oil & Gas and Others
By Geography: North America, South America, Europe, APAC, and RoW.
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COVID-19 / Ukraine Crisis - Impact Analysis:  
• The COVID-19 pandemic had a significant impact on the electro-hydraulic servo valve market, affecting both supply and demand. Disruptions in manufacturing and supply chains led to delays in production and delivery of these critical components, causing ripple effects across industries reliant on hydraulic systems. Reduced demand from sectors like aerospace, automotive, and industrial machinery further compounded the challenges faced by servo valve manufacturers. However, the pandemic also spurred innovation, with companies exploring remote monitoring and control solutions to address operational challenges. Additionally, the increased focus on automation and efficiency in response to the pandemic could drive long-term growth in the adoption of electro-hydraulic servo valves, particularly in industries prioritizing safety, reliability, and precision in their hydraulic systems. 
• The Russia-Ukraine crisis has impacted the electro-hydraulic servo valve market due to disruptions in the supply chain and geopolitical tensions affecting trade relations. Ukraine is a significant producer of precision engineering components, including parts used in electro-hydraulic servo valves. Any disturbance in the region can lead to delays or shortages in raw materials and components crucial for manufacturing these valves. Moreover, increased uncertainty and instability can dampen investor confidence, affecting investment decisions in industries that heavily rely on electro-hydraulic servo valves, such as aerospace, defense, and industrial sectors. Furthermore, sanctions or trade restrictions imposed as a result of the crisis may exacerbate supply chain disruptions, leading to price volatility and increased production costs for manufacturers, thereby impacting the overall market dynamics. 
Key Takeaways:
• North America is witnessing remarkable growth in the electro-hydraulic servo valve market due to its flourishing aerospace, defense, and industrial sectors. The region's stringent quality standards and technological advancements drive the demand for precise control systems, where electro-hydraulic servo valves excel. Moreover, the presence of key market players and ongoing research and development initiatives contribute to innovation and product enhancements, further fueling market expansion. Additionally, supportive government policies and investments in defense and infrastructure bolster the region's position as the highest-growing market for electro-hydraulic servo valves. 
• The single-stage electro-hydraulic servo valve segment is witnessing the highest growth in the market due to several factors. Single-stage valves offer simplified design, cost-effectiveness, and ease of integration compared to multi-stage counterparts. Technological advancements have enhanced their precision and reliability, meeting stringent industry requirements. Additionally, the demand for compact, lightweight solutions in industries like aerospace, defense, and industrial automation favors single-stage valves. Moreover, applications requiring rapid response and precise control, such as robotics, further drive the growth of this segment, making it a key driver in the market's expansion. 
• The nozzle flapper valve is emerging as the fastest-growing type in the electro-hydraulic servo valve market due to its exceptional precision and responsiveness. Leveraging a nozzle and flapper mechanism, these valves offer superior fluid flow control, ensuring accurate positioning in critical applications like aerospace, defense, and industrial sectors. Their rapid response times, enhanced accuracy, and compact design make them increasingly favored over traditional valves. With rising demand for precise motion control systems, particularly in automated industries, the market for nozzle flapper valves is poised for significant growth, presenting lucrative opportunities for manufacturers and suppliers.
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Electro-Hydraulic Servo Valve Market Segment Analysis – By Product 
In the electro-hydraulic servo valve market, the single-stage valve is experiencing the highest growth trajectory with a CAGR of 4.5% during the forecast period 2024-2030. This surge can be attributed to several factors. Firstly, single-stage valves offer simplified design and operation compared to multi-stage valves, making them more cost-effective and easier to integrate into various systems. Secondly, advancements in technology have enabled single-stage valves to achieve high levels of precision and reliability, meeting the stringent requirements of industries such as aerospace, defense, and industrial automation. Thirdly, the increasing demand for compact and lightweight solutions across industries has favored the adoption of single-stage valves, which typically have a smaller footprint and lower weight compared to multi-stage counterparts. Additionally, the rise of applications requiring rapid response times and precise control, such as in robotics and autonomous vehicles, has further propelled the growth of single-stage electro-hydraulic servo valves. Overall, the combination of technological advancements, cost-effectiveness, and growing application areas positions single-stage valves as a key driver of growth in the electro-hydraulic servo valve market. 
Electro-Hydraulic Servo Valve Market Segment Analysis – By Type
Nozzle flapper valves are experiencing rapid growth in the electro-hydraulic servo valve market with a CAGR of 4.9% during the forecast period 2024-2030 due to their superior performance and efficiency in various applications. These valves offer precise control over fluid flow by utilizing a nozzle and a flapper mechanism, allowing for highly responsive and accurate operation. Compared to traditional valves, nozzle flapper valves boast faster response times, enhanced accuracy, and improved reliability, making them ideal for applications requiring precise positioning and control, such as aerospace, defense, and industrial sectors. Additionally, advancements in manufacturing technologies have enabled the production of nozzle flapper valves with higher efficiency and reduced maintenance requirements, further driving their adoption. Moreover, increasing demand for automation and robotics across industries has fueled the need for advanced motion control systems, thereby propelling the growth of nozzle flapper valves. Their compact size, lightweight design, and compatibility with digital control systems make them well-suited for integration into modern machinery and equipment. As a result, the market for nozzle flapper valves is expected to continue its upward trajectory, offering lucrative opportunities for manufacturers and suppliers in the electro-hydraulic servo valve industry. 
Electro-Hydraulic Servo Valve Market Segment Analysis – By End-Use Industry
The aerospace and defense industry stands out as one of the highest-growing end-use sectors in the electro-hydraulic servo valve market with a CAGR of 5.3% during the forecast period 2024-2030. Electro-hydraulic servo valves play a critical role in flight control systems, missile guidance systems, and other aerospace and defense applications, where precision, reliability, and rapid response are paramount. With the increasing demand for military aircraft, unmanned aerial vehicles (UAVs), and commercial airliners equipped with advanced flight control systems, the need for high-performance electro-hydraulic servo valves is escalating. Furthermore, the development of next-generation fighter jets, space exploration vehicles, and sophisticated missile defense systems necessitates cutting-edge hydraulic control technologies, thereby driving the demand for electro-hydraulic servo valves. Additionally, ongoing modernization initiatives by defense agencies worldwide, coupled with the growing investments in commercial aviation infrastructure, contribute to the robust growth of this market segment. As aerospace and defense applications continue to evolve, the electro-hydraulic servo valve market is poised to witness sustained growth, with manufacturers focusing on innovation and technological advancements to meet the stringent performance requirements of this industry. 
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Electro-Hydraulic Servo Valve Market Segment Analysis – By Geography
North America stands out as one of the dominant markets in the electro-hydraulic servo valve sector with a market share of 34% in 2023 due to several factors. Firstly, the region's robust aerospace and defense industries, driven by technological advancements and military modernization programs, demand highly precise and reliable control systems, where electro-hydraulic servo valves play a vital role. Secondly, the increasing adoption of automation and robotics in various industrial applications across sectors like automotive, manufacturing, and healthcare further fuels the demand for electro-hydraulic servo valves. Thirdly, the presence of major market players and technological innovators in North America fosters continuous research and development, leading to the introduction of advanced valve solutions catering to diverse industry needs. Additionally, favorable government initiatives supporting infrastructure development and investments in defense and aerospace sectors contribute to the region's growth. With these factors combined, North America emerges as a dynamic and rapidly expanding market for electro-hydraulic servo valves, poised for sustained growth in the foreseeable future. 
Electro-Hydraulic Servo Valve Market Drivers 
Increasing adoption of industrial robots globally 
The increasing adoption of industrial robots globally is driving growth in the electro-hydraulic servo valve market. Industrial robots rely on precise hydraulic control systems to execute tasks with accuracy and efficiency across various industries. With the rise of automation and Industry 4.0 initiatives, industries such as automotive manufacturing, metalworking, and electronics assembly are increasingly integrating robots into their production processes to improve productivity and flexibility. Electro-hydraulic servo valves play a crucial role in controlling the movement and force of these robots, enabling precise and smooth operations. According to the International Federation of Robotics (IFR), global sales of industrial robots reached a record high in recent years, indicating a growing demand for automation solutions. This trend is expected to continue, further fuelling the demand for electro-hydraulic servo valves in the market. 
High acceptance of smart control which uses an electro-hydraulic servo valve 
The growing acceptance of smart control systems is emerging as a significant market driver for electro-hydraulic servo valves. Smart control technologies, integrating advanced sensors, actuators, and feedback mechanisms, enhance the precision, efficiency, and performance of hydraulic systems. Electro-hydraulic servo valves play a pivotal role in these systems, providing precise and dynamic control over fluid flow and pressure. Industries such as aerospace, automotive, and manufacturing are increasingly adopting smart control solutions to optimize operations, reduce energy consumption, and improve productivity. For instance, in aerospace applications, smart control systems utilizing electro-hydraulic servo valves enable aircraft to achieve greater manoeuvrability and fuel efficiency. Moreover, the rise of industry 4.0 initiatives and the Internet of Things (IoT) is driving the demand for intelligent hydraulic systems, further bolstering the growth of the electro-hydraulic servo valve market.
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Electro-Hydraulic Servo Valve Market Challenges
High costs associated with electro-hydraulic servo valves 
High costs associated with electro-hydraulic servo valves present a significant market challenge. These valves incorporate precision engineering, advanced materials, and complex manufacturing processes, leading to inherently high production costs. Additionally, stringent quality standards and regulatory requirements further escalate expenses for manufacturers. The aerospace, defense, and industrial sectors, major consumers of electro-hydraulic servo valves, are often cost-sensitive industries, necessitating competitive pricing. Moreover, customers increasingly demand cost-effective solutions without compromising performance or reliability, adding pressure on manufacturers to optimize production processes and reduce costs. Furthermore, the emergence of alternative technologies, such as electromechanical actuators, poses a threat to the market dominance of electro-hydraulic servo valves. To address this challenge, manufacturers are investing in research and development to innovate cost-effective solutions while maintaining quality standards to remain competitive in the market.
Market Landscape
Product/Service launches, approvals, patents and events, acquisitions, partnerships, and collaborations are key strategies adopted by players in the Electro Hydraulic Servo Valve Market. The top 10 companies in this industry are: Moog, Inc., Eaton Corporation, Honeywell International, Inc, Parker Hannifin Corp, Woodward, Inc, Voith GmbH & Co. KGaA, Bosch Rexroth AG, Schneider Servohydraulics GmbH, HAEW Hydraulik SE, Oligear Co.
Developments:
Moog Inc. in September 2022, launched their new X700 Series servo cartridge valves aimed at the high-end segment of the Electro Hydraulic Servo Valve Market. The key feature of this new series is a robust design that allows for a maximum main-stage operating pressure of 420 bar. This increased pressure capability potentially expands Moog's offerings in the market for high-performance applications.
In February 2022, HAEW Hydraulik introduced its latest innovation, the OSCA load-holding screw-in valve. Designed to resist dirt and debris, this valve boasts a remarkable pressure tolerance of up to 500 bar. HAEW's cutting-edge technology ensures enhanced durability and reliability, catering to demanding industrial applications. This launch underscores HAEW's commitment to delivering high-performance hydraulic solutions, addressing industry needs for robust and efficient components.
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a544197231 · 3 years ago
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somar78 · 6 years ago
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A Brief History of the Nissan Skyline and GT-R – Everything You Need To Know
The Nissan Skyline GT-R – Godzilla
When the name “Nissan Skyline” is mentioned it often brings another name to memory, that of Godzilla, a name given to the seemingly unbeatable 1989 Nissan Skyline GT-R in its 1990 racing guise, the NISMO GT-R, by the Australian motor press after its three consecutive Group A Championship wins from 1990-1992 topped off by two wins in the Bathurst 1000 in 1991-1992.
This had been a car that took not just the motor race, but the technology race squarely up against Porsche and their all wheel drive 959 in a successful effort to beat them at their own game. In order to optimize handling and best distribute the more than 600hp of the RB26DETT 2.6 liter twin turbocharged straight six cylinder DOHC engine Nissan’s engineers developed the ATTESSA E-TS all wheel drive system which used an electro-hydraulic clutch system to distribute that power between the rear and front wheels.
In the case of the racing Nissan Skyline GT-R the power distribution was primarily to the rear wheels until the power was such that they could not grip, at which time the extra horsepower was sent to the front wheels so all wheels maintained traction.
These were sophisticated examples of the best in automotive engineering, but they were actively evolved from a technological legacy that extended back into the 1960’s, and to a company named Prince, which was acquired by Nissan in 1966.
Prince, the Skyline Name, and a Penchant for Racing
Prince Motor Company were motivated towards motor racing both as a means to develop their car technology, and as a means to raise the public profile of their company.
One of the main driving forces in Prince was Shinichiro Sakurai, who had joined Prince as a chassis engineer in 1952 and was closely involved in the development of the original Prince Skyline. That first series of cars called the Prince Skyline were very conventional passenger car powered by a 60hp OHV in-line four cylinder engine and made in four door sedan and five door station wagon variants.
Shinichiro Sakurai would go on to be a driving force in the development of the Skyline GT-R up until his passing in 2011.
Dr. Sakurai began his journey in motor racing with the formation of the Prince Motoring Club in 1964, after a factory team of Prince Skyline S54 GT cars had suffered defeat in the Japanese Grand Prix that year. The Prince S54 was fitted with a SOHC G-7 1,998cc inline six cylinder engine, the engine that would form the basis for the later Datsun 510 and 240Z engines.
The Skyline S54 GT cars had been up against a Porsche 904 racing car that had been privately entered and, despite being outclassed by it, obtained second through to sixth places – but for Prince Motors there was to be no second place winner and work began on creation of their own Porsche 904 beating race car.
The Prince Motoring Club team including Dr. Sakurai got to work on a mid-engine racing car, in some respects similar to the Porsche 904 but built on a modified Brabham BT8 chassis. Into this proven racing chassis they installed a new variant of the G-7 engine, the DOHC double-valve 1,996cc GR-8 producing 200hp, and mated to a Hewland 5 speed racing transmission.
1966 was to be the year that four R380 cars were fielded at the Japanese Grand Prix against three Porsche 906. The result was what Nissan and the original Prince Motoring Club had hoped and worked for, first and second place.
It would be the last time the cars would race under the Prince banner however. Nissan acquired Prince that year but went on to further develop the R380, raising the engine power to 220hp, and redesigning the R380’s bodywork for optimal aerodynamics.
The Prince Skyline Sport and the Skyline 2000GT
There had been some sporty Prince cars bearing the Skyline name in the early 1960’s. Prince Motors understood marketing, and thus wanted to not only build cars that would get people’s attention but to actively put these cars into view in the most effective way possible.
To this end they turned to Italian designer Giovanni Michelotti (the man who also designed the Triumph Spitfire) and had him create a new and eye catching body for their otherwise rather ordinary looking S21 Skyline. By 1962 This new Skyline Sport (BLRA-3) was put into limited production both as a coupe and a convertible. These cars were fitted with a GB-4 1,862cc OHV engine producing a modest 94bhp @ 4,800rpm with 113lb/ft torque @ 3,800rpm.
Prince managed to get these Skyline Sport cars in a number of Japanese films by the Toho company thus raising the profile of the company’s cars in much the same way that the James Bond film “Goldfinger” made the Aston Martin DB5 a cultural icon and another Bond movie “You Only Live Twice” would similarly raise the profile of the Toyota 2000GT.
This Prince Skyline Sport is the car that began the journey that would result in the Skyline GT-R series of cars: it didn’t have awe inspiring power, but it did have style.
The S21 based Prince Skyline Sport was followed by the S54 based Prince Skyline GT of May, 1964. It was the racing version of this car that the Prince Motoring Club took to the Japanese Grand Prix of 1964 and finished second, beaten only by a specialist racing Porsche 906.
That second through to sixth place for the Skyline GT led to lots of enthusiastic people with open checkbooks looking eagerly in Prince’s direction and they did not disappoint these customers: they put the car into production.
The road car was called the Prince Skyline 2000GT and was made in two versions. The GT-A version had the designation S54A and was fitted with the 1,988cc G-7 six cylinder engine breathing through a single carburetor and producing 104hp. The high performance version was the GT-B, designated the S54B, with the engine breathing through no less than three dual throat Weber 40DCOE-18 carburetors and producing 123hp @ 5,600rpm, not a race car, but a lively performer by 1960’s standards.
The GT-B also featured a limited slip differential, five speed close ratio gearbox and servo assisted brakes. Both the GT-A and GT-B were fitted with dual piston disc brakes at the front and finned aluminum drums at the rear.
These cars were sold on the Japanese market, and also exported to Australia where there was a Prince dealership in the state of South Australia. In those export cars both the GT-A and GT-B were fitted with the high performance triple Weber carburetor engine, but the GT-A had a four speed manual gearbox while the GT-B was fitted with a German ZF five speed gearbox.
The First Generation Nissan Skyline GT-R “Hakosuka” (1969-1972)
The first of the Nisssan Skyline cars to wear the GT-R name was the C10 series which was developed by Prince at their Okikubo research and development center in Tokyo in 1968. The base model Nissan Skyline was introduced fitted with either the 1.5 liter Prince SOHC G15 inline four cylinder engine or optionally with the 1.8 liter G18.
There was also a sports model, the 2000GT, which was initially powered by a Prince G-7 SOHC 1,988cc inline six cylinder engine and then in September 1971 that was changed in the 2000GT-X model to an L20SU, from the same engine family as used in the Datsun 510 and 240Z.
The Nissan Skyline GT-R (model designation PGC-10) made her debut at the Tokyo Motor Show of February 1969. Costing almost twice as much as her more ordinary Nissan Skyline siblings the PGC-10 was fitted with an S20 inline six cylinder engine derived from the engine that had been used for the Prince R380 racing car.
This 1,989cc DOHC engine was originally fitted with triple Weber 40DCOE dual throat carburetors and tuned to produce 160hp @ 7,000rpm with torque of 87lb/ft. Later in October of that year the fuel system was changed to a British Lucas mechanical fuel injection: all that lovely power was sent to the rear wheels via a five speed manual all synchromesh gearbox.
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Suspension of this first Nissan Skyline GT-R was independent all around with McPherson struts at the front and semi-trailing arms at the rear: a similar suspension to that used on the Nissan/Datsun 510 and later 240Z. Like the Datsun 510 and 240Z this intelligently designed fully independent suspension gave the Skyline GT-R stable handling, even when the going got rough, making it a car that could be driven to its limits with confidence.
From 1969 up until 1971 this Nissan Skyline GT-R was made as a four door sedan and then in March 1971 a two door coupé was also made available (the KGPC-10). The car performed well in competition with the sedan version gaining thirty three wins in less than two years and the coupé another seventeen.
Japanese car enthusiasts nicknamed the car Hakosuka (ハコスカ), which is a condensation of “Skyline Box” in Japanese: hako (ハコ) translates as “box” and suka(スカ)being a contraction of Sukairain (スカイライン) which translates as “Skyline”. So the “Hakosuka” made the name Nissan Skyline GT-R something of a household word.
Second Generation Nissan Skyline GT-R “Kenmeri” (1972-1977)
The 1972 Tokyo Motor Show saw the debut of the successor to the C10 “Hakosuka”: the C110 Nissan Skyline. The 1,989cc S20 inline six cylinder engine with its heritage in the Prince R380 racing car, and five speed gearbox migrated from the GPC-10 into the new and quite different looking bodywork of the C110.
The Nissan Skyline C110 series were made in the same body styles as its predecessor, four door sedan, five door station wagon, and coupé. In export markets the model was sold as the Datsun K series and it appears to have been a very popular model.
The popularity is often attributed to the Nissan advertising campaign which featured “Ken and Mary” and this resulted in the model being dubbed the “Kenmeri”.
The GT-R version made its debut in September 1972 but with the impact of the worldwide oil crisis production of the Skyline GT-R was ended in March 1973. The KPGC110 Nissan Skyline GT-R was fitted with the tried and proven S20 DOHC inline six cylinder engine as used in the first generation cars, with five speed manual gearbox.
Only 197 of these cars were sold in Japan and they were not exported. Nissan withdrew from motor racing and this second generation Skyline GT-R would be the last for a period of years.
The Nissan Skyline R30 “Tekkamen” (1981-1985)
During the years that followed the oil crisis the Skyline GT-R name would be absent, while Nissan continued to make a quite ordinary cars for everyday use, some more stylish than others. The R30 series was introduced in August of 1981 and offered with a variety of four and six cylinder engines, generally shared with other Nissan/Datsun cars.
Body styles expanded from four door sedan, station wagon, and two door coupé to include the new three door “hatchback” style which was becoming popular around that time. The R30 could be had in luxury versions, including one powered by an L20ET SOHC turbocharged engine and there was also an FJ20 DOHC double valve four cylinder engine, the first production four valves per cylinder engine from a Japanese maker.
Added to this were simple economy engines and an LD28 inline six cylinder diesel: diesel engines were becoming moderately popular due to their good fuel economy, and in places such as Australia because diesel was the fuel of choice for primary producers.
The most notable model during the R30’s production life was the Nissan Skyline 2000RS which appeared on October 2nd, 1981. This model was designated the DR30 and was powered by a conventionally aspirated FJ20E four cylinder DOHC 1,990cc engine with electronic fuel injection (as identified by the “E” suffix to FJ20E).
The car was a stripped down lightened Skyline which weighed a modest 2,491lb and with the engine developing 148hp @ 6,000rpm and 133lb/ft torque @ 4,800rpm it was a lively performer. This was only to get better in 1983 when the model was upgraded with a turbocharged version of that same engine, the FJ20ET (the “T” suffix denoting Turbocharged). The turbocharged model was badged the Nissan Skyline 2000RS-Turbo and the engine now produced 188hp @ 6,400rpm with 166lb/ft torque @ 4,800rpm.
The Nissan Skyline 2000RS-Turbo was fitted with the most powerful Japanese production car engine of that period and the car was kept lightweight so it could use that power to good advantage.
Once the Skyline 2000RS-Turbo had established its performance street cred it became a desirable car and this curiously resulted in Nissan deciding that it was a “top of the line” model and therefore should have luxury features such as electric windows, air-conditioning and power steering, and a electronic driver’s seat with power lumbar support, all of which added to its weight bringing it up to 2,723 lb and of course causing performance to decline.
This was the Nissan Skyline RS-X model, the “X” denoting “eXtra”: extra luxury, extra weight, and not so fast or clean handling as its nimble predecessor. This car was given a new front end styling treatment which led to it being nicknamed “Iron Man” (Tekkamen (鉄仮面)) after the superhero character whose mask the car’s front end resembled.
For 1984 the car’s engine was fitted with an air-to-air intercooler which enabled the compression ratio of the engine to be increased from 8.0:1 to 8.5:1 boosting its power to 202hp @ 6,400rpm and torque to 181lb/ft @ 4,400rpm. This model was called the Nissan Skyline 2000RS-Turbo C and the extra power helped to restore the performance of the car while keeping the luxury extras.
This car was the basis for the GT-R works Super Silhouette racing car which ran in the All Japan Sports Prototype Championships, the car being sponsored by Japanese toy maker Tomicar. The Nissan Skyline 2000RS-Turbo C was also the basis for the cars that competed in the 1986 Australian Touring Car Championships winning four of the six races, and the Australian Endurance Championship, finishing in second place to a BMW 635 CSi. Nissan won the 1986 Manufacturer’s Championship and drew with BMW for the following year.
The combination of having the 340hp DR30 Nissan Skyline 2000RS racing cars becoming something of a cult car in Japan and their string of competition successes paved the way for Nissan to decide that resurrecting the GT-R model might just be a good idea.
The oil crisis was passed, people had figured out that we were not likely to run out of oil any time soon, and there were people with fat checkbooks wanting a Skyline GT-R. Not only that but there were children playing with their Tomicar model Skyline GT-R’s who would grow up to have a salary, a checkbook of their own, and a desire to own a twelve inches to the foot scale model GT-R that they could jump into and drive and get speeding tickets of their own in.
1984 was the year Nissan decided to merge its existing two motorsport departments into a new entity called “Nismo” which was an abbreviation for Nissan Motorsport International Limited. This new entity would be responsible for creating a range of competition cars, tuning kits, and campaigning in motorsport events.
The R31 2000 GTS-R (1985-1987)
The R31 series of the Nissan Skyline would introduce new technologies, technologies that would greatly enhance the coming generations of the Skyline GT-R models.
The R31 series introduced the new RB engines in both SOHC single valve and DOHC iterations. The RB engines were derived from the Nissan L engines as used in the Datsun 510 and 240Z, which were based on a Mercedes-Benz engine which Prince made under license and then developed into a new design of their own.
A new steering technology made its appearance in the R31 Nissan Skyline cars: High Capacity Actively Controlled Steering (HICAS) which provided rear wheel steering to compliment the conventional front wheel steering. The HICAS system as first used in the R31 Skyline used hydraulics connecting the front to the rear to provide the rear wheel steering.
This was speed sensitive and used the vehicle’s speedometer to determine the nature of the rear wheel steering to provide: at low speeds the rear wheel steering was optimized for close maneuvering, at higher speeds for highway stability and cornering.
The R31 series of Nissan Skyline models included cars at varying levels of performance from utilitarian and economical to more luxurious, and to higher performance. At the top of the performance models were the Nissan Skyline 2000 GTS cars which first appeared in August 1985. From thjis model would come the successor to the Skyline 2000RS racing cars, the Skyline GTS-R coupé.
The Skyline 2000 GTS saw a move from the DOHC turbocharged four cylinder engine of the 2000RS cars to a DOHC six cylinder. This new engine was the RB20DET and it featured twin cams because it had double valves, and an intercooled turbocharger. Power output was 212hp @ 6,400rpm with a solid amount of torque, 195lb/ft @ 3,200rpm, perfect for the road going GTS and luxurious GTS-X.
The Skyline GTS-R coupé was a very limited production car that made its debut in late 1987, with just 823 made. This model was only put into production to provide the homologation necessary to enable the car to compete in Group A Touring Car racing.
This racing car’s engine featured a larger turbocharger on a tubular steel exhaust manifold, and a larger front mounted intercooler. This racing engine produced over 430hp and would prove itself to be a competitive Group A competition car down in Australia where Jim Richards and Mark Skaife campaigned in a Skyline GTS-R coupé that had been race prepared by Gibson Motor Sport in the 1989 Sandown 500, and then went on to win six out of eight races to win the 1990 Australian Touring Car Championships.
Third Generation R32 GT-R (1989-1994)
The Nissan Skyline R32 series moved to be more sporting rather than utilitarian. The body styles were limited to either four door sedan or two door coupé.
The smallest engine option for the R32 Skylines was the 90hp 1,800cc RXi inline four cylinder fitted to the GXi model. The remaining cars were powered by the RB series of inline six cylinder engines fitted with the ECCS (Electronically Concentrated Control System) electronic fuel injection. R32 models were fitted with the HICAS rear steering system, at this stage of development still hydraulically operated.
Other than the four cylinder GXi the other Skylines featured “GT” in their names; the GTE with a 2.0 liter 123hp engine, the GTS Type X, S and J with a 2.0 liter 153hp engine, the GTS-25 Type X, S and SG fitted with a 2.5 liter 178hp engine, the GTS-t, Type-M fitted with a 2.0 liter RB20DET turbocharged 212hp engine as used on the Skyline 2000 GTS, the Autech GTS-4 fitted with a 2.6 liter RB26DE 217hp engine and also equipped with Autech all wheel drive (of which only 188 were made), and the GT-R fitted with the 2.6 liter RB26DETT twin turbocharged engine and also equipped with all wheel drive.
The RB26DETT engine was stated by Nissan to produce 276hp but this was an understatement: Japanese car makers had a “gentleman’s agreement” not to quote a power of more than 280PS (i.e. 276hp), the actual power output of the RB26DETT engine was 316hp but as set up for the road cars the ECU and exhaust turbocharger boost restricted the available engine power. In race tune the engine would deliver in the order of 500hp.
Nissan were by this stage very much back into motorsport and the R32 Skyline GTR was designed from the ground up with the rule book for Group A racing in the hands of the design team, led by Chief Engineer Naganori Ito. Thus the car was purpose built and it was built to ensure it would defeat Nissan’s main opponent, the Porsche 959. The car was so perfectly purpose built that it would lead to the demise of Group A racing and its substitution with other touring car events.
The GT-R was made to go quickly from the ground up, wheel arches were flared to accommodate the wider wheels and tires, the intercooler was enlarged to cope with the increased turbocharger temperatures, the brakes were enlarged and the car was strategically lightened with aluminum front guards and hood/bonnet. As the GT-R was a road going high performance car the seats were made more supportive both for comfortable touring and for comfortable support during enthusiastic cornering.
The car was also fitted with a new version of Nissan’s ATTESA all wheel drive system. ATTESA stood for Advanced Total Traction engineering system. The version used for the GT-R was a more advanced E-TS ATTESA design but it added 220lb/100kg to the car’s weight.
The additional weight necessitated Nissan moving the GT-R up into the 4,500cc racing class and so they increased the engine capacity of the GT-R to 2.6 liters so that with the turbocharging of the engine they could obtain a competitive 599hp from the engine. The car’s instrumentation included the usual essentials for monitoring engine state but also included a gauge to indicate the ratio of engine power being delivered to the front and rear wheels by the ATTESA system.
We should remember that the Japanese have a well deserved reputation for being perfectionists as was evident when they took the idea of the two handed saber and perfected it into the Japanese “Nihon To” Japanese sword, perhaps the most refined sword on earth. So we can imagine what would happen if a group of perfectionist Japanese engineers got together with the Group A rule book to build the perfect Group A racing car. The results speak for themselves. A Skyline GT-R was taken to Germany’s Nürburgring for an attempt at the 22.81km (14.173 miles) Nordschleife (North Loop) lap record, which stood at 8’45” and was set by a Porsche 944. The Nissan Skyline GT-R lapped the Nordschleife in 8’20” with Japanese driver Hiroyoshi Katoh putting the pedal to the metal. It was a foreboding of what the Skyline GT-R was going to accomplish in motor racing.
From 1989-1993 the Nissan Skyline GT-R’s won the Japanese Touring Car Championship every year, winning 29 out of the 29 races they started in. For the Group N competition, which limited modifications to the cars so they had to be “Showroom Class” standard cars, the GT-R won 50 races out of 50 they started in the N1 Super Taikyu (i.e. Super Endurance) competition from 1991-1997.
The Nissan Skyline GT-R’s were taken “down under” to Australia’s famous Mount Panorama racing track located in the town of Bathurst, New South Wales, where they proceeded to win the annual Bathurst 1000 race in 1991 and 1992. This led to the pretty little Skyline being dubbed “The monster from Japan”, Godzilla. It was during 1991 and 1992 that the plans were put in place in Australian motor sport to create the “V8 Supercars” competition which would favor the domestically produced GM Holden and Ford cars which had previously carved out a legend for themselves at Bathurst’s Mount Panorama.
This competition has survived up until the present day and the races are quite spectacular. We wonder how a 1993 Nissan Skyline GT-R would fare against one of the current V8 Supercars, it would be an interesting one-on-one contest, best done on Mount Panorama.
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In 1993 the Group A rules were changed to increase the allowed wheel size from 16″ to 17″, which led to the creation of the Skyline GT-R V-Spec cars in February of that year, fitted with 17″ BBS mesh wheels and the larger disc brakes with Brembo calipers the bigger wheels permitted. Wider 245/45 17″ tires were fitted for 1994 in the revised model, the Skyline GT-R V-Spec II. The “V” coincidentally stood for “Victory” as one would expect.
“Godzilla” had monstered the competition and also prompted the ruling bodies to change the competition rules: the Skyline GT-R had certainly made its mark.
Fourth Generation R33 GT-R (1993-1998)
With its image established as a sporting car the R33 Nissan Skylines were kept quite close to the concept of the successful R32 series. The new R33 was about an inch wider and four inches longer than its predecessor, and it gained some mandatory safety equipment, notably airbags, and internal crash bars.
Despite being physically a little larger Nissan’s engineers worked to reduce weight wherever possible to compensate for the additional weight created not only by the size increase but also by the additional safety equipment that had to be installed. The strategies used to decrease weight included using more sophisticated metallurgy with regards to the steel being used in body construction, hollowing out side door beams and the rear anti-roll bar, use of plastics for such items as the fuel tank, and use of lighter sound deadening materials.
Great attention was also put into the aerodynamics of the new model both to make it slip through the air more easily and to improve its stability by giving it more down-thrust as the speed increased. The R32 had suffered from some problems associated with lift at speed and so these problems were addressed in the R33.
Nissan did some reshuffling of its model line-up for the R33 family of Skylines. All bar one of the models were given “GT” in their names. The models were; the HR33 GTS fitted with a 2.0 liter inline six cylinder RB20E SOHC producing 128hp and torque of 127lb/ft, or fitted with the more powerful version of the RB20E engine producing 153hp with torque of 142lb/ft. Next was the ER33 GTS-25 which was fitted with the RB25DE DOHC inline six cylinder engine producing 187hp with 170lb/ft of torque: the ER33 GTS was also made with all wheel drive as the Skyline ENR33 GTS-4.
Moving up in the power stakes the next model was the ECR33 GTS-25t: this was fitted with the turbocharged RB25DET engine producing 247hp and 217lb/ft of torque. The naturally aspirated RB25DE and turbocharged RB25DET engines were fitted with a Nissan Variable Timing Control system, which was called NVCS for this engine.The most powerful of the R33 series curiously was not called a GT but was the ECR33 P.Ride 280 MR with the 2.8 liter turbocharged DOHC RB28DETT producing 296hp.
The GT-R models benefited from the detail engineering that went into making them as light as possible, with the base model Skyline GT-R tipping the scales at 1,540 kg (3,395 lb) while the GT-R V-Spec was 10kg (22lb) heavier. The attention to making the vehicle as light as possible had in part been made necessary because of the Japanese government regulations which limited engine power to 280PS: so in order to make the GT-R faster, the power to weight ratio had to be improved.
With these improvements a R33 GT-R was taken to Germany’s Nürburgring for a new attempt at breaking the record on the Nordschleife (North Loop) lap record. The new R33 GT-R did not disappoint putting down a lap time of 7’59”, while a GT-R V-Spec car managed 7’57”. Nissan was not able to use the R33 GT-R to dominate motorsport in the way they had with the R32 in Group A. They made a showing at the 24 Hours Le Mans in 1995 with two purpose built race cars, with one finishing fifth in class and tenth overall, while the other suffered a gearbox failure.
This quite successful attempt at Le Mans was celebrated the following year, 1996, with a NISMO GT-R LM model fitted with some carbon fiber panels and painted in “Champion Blue”. The LM version was also made in an even higher performance V-Spec version.
Other limited production models were also made including the 40th Anniversary of the GT-R  four door GT-R which was first made by Autech, and then a second by Nismo and Autech working in collaboration. There was also a Nismo 400R with such features as some carbon fiber body parts, a 400hp engine, and twin plate clutch to cope with those four hundred enthusiastic horses.
The four main versions of the GT-R were; the base GT-R fitted with the RB26DETT twin turbocharged 2.6 liter inline six cylinder engine producing 301hp (although advertised as only 280PS) with 277lb/ft of torque. This model was fitted with the ATTESA-ETS all wheel drive system and the improved electronic Super HICAS all wheel steering system.
The next model was the GT-R LM fitted with the same engine but without the all wheel drive feature: so it was a conventional front engine rear drive car. The next model was the Nismo 400R which was fitted with the 2.8 liter RBX-GT2 DOHC twin turbocharged inline six producing 395hp and 353lb/ft torque, and fitted with the all wheel drive system. Last but by no means least was the rare 4 door GT-R Autech Version four door 40th Anniversary car fitted with the RB26DETT DOHC inline six as used on the GT-R and GT-R LM producing 301hp and 277lb/ft of torque, but again advertised as producing 280PS.
Only 400 of these four door 40th Anniversary models were made but they were, of course, the perfect car for a family man with a bit of a Jekyll and Hyde personality.
Fifth Generation R34 GT-R (1998-2002)
When we look back to 1998 we see that personal computers and the Internet were making their way into people’s lives, this sort of technology was becoming fashionable. Microsoft introduced their new operating system “Windows 98” to replace Windows 95, while the world’s number one Internet search engine was AltaVista: Google was not yet a dominant force.
This digital technology was finding its way into many areas of our lives and it found its way into the cars from the Land of the Rising Sun quickly. Japan, Korea and Hong Kong were among the places where this sort of technology achieved rapid market penetration.
The Nissan Skyline was one of the early cars to implement digital technology with a pop-up digital display on turbocharged models. The turn of the millennium, as people worried of a global collapse caused by the “millennium bug” the Skyline was given the option of state of the art Xenon headlights. The R34 engines were built with Nissan’s new NEO technology, which was Nissan’s Ecology Oriented valve lift and timing, a system intended to optimize engine performance and minimize pollution by maximizing efficient fuel use.
The R34 models were the base model GT fitted with an RB20DE NEO whose inline six cylinder produced 153hp with 137lb/ft torque, the 25GT, 25GT-X, 25GT-V, 25GT-FOUR, and the 25GT-X FOUR, all fitted with the RB25DE NEO engine producing 197hp and 188lb/ft torque.
Going up the power scale came the 25GT Turbo and 25GT-X Turbo fitted with the RB25DET NEO six cylinder turbocharged engine producing 280hp and 253lb/ft torque. These models came with various optional extras including more aerodynamic body kits, improved brake, suspension and performance parts. All GT-R models were fitted with the all wheel drive ATTESA E-TS Pro AWD system.
The new R34 Skyline GT-R versions made their debut in 1999 and sported a display unit at the top of the dashboard called the “MFD” (Multi Function Display). This display replaced gauges and provided information such as turbocharger boost pressure, oil and water temperature, and the G-force acceleration the car was under at any given time. The system also incorporated a “lap timer” with control located just by the gear lever.
  The R34 Skyline GT-R models were; the base GT-R fitted with the RB26DETT 2.6 liter twin turbo inline six cylinder producing 327hp and 289lb/ft of torque: the engine power being advertised as being just 280PS/276hp.
There was a veritable plethora of derivative models, albeit almost all fitted with the same engine, these being; GT-R V-Spec with different aerodynamic body kit parts, different brake ventilation ducting, a diffuser, and an active limited slip differential (ALSD).
Next came the GT-R V-Spec N1 which came with a blueprinted N1 engine: this car was a stripped down speed machine for the adrenaline enthusiast and had no air-conditioning, no stereo sound system (because the sound of the engine was music enough), no rear screen wiper, and a spartan interior trim. The next model was the GT-R V-Spec II which was the same as the V-Spec N1 but with a carbon fiber hood/bonnet fitted with a NACA duct: this model was also made as the GT-R V-Spec II N1, again with the same Spartan fittings.
Following on from the purist performance oriented cars Nissan understood that there were customers who liked their adrenaline served up in stylish comfort and so the GT-R M-Spec featured leather seats, less sporty more comfort oriented suspension with “Ripple Control” shock absorbers, and heated seats so the driver could be warm and cozy while enjoying their enthusiastic driving.
The GT-R V-Spec Nür and GT-R M-Spec Nür continued with the “enter the comfort zone” luxury speed and both were fitted with 300 km/hr speedometers. The other two models were the GT-R NISMO S-Tune and R-Tune which were the derived from the M-Spec but with some style differences.
Last of the comfort GT-R’s was the GT-R NISMO Z-tune which was fitted with a bored and stroked 2.8 liter RB28DETT twin turbocharged version of the inline six cylinder engine pushing out no less than 493hp and 398lb/ft of torque for drivers with a significant dose of Mr. Hyde in their personality and having strong neck muscles to cope with the rather brisk acceleration. the Z-tune’s standing to 100km/hr time was just 3.8 seconds and its top speed was in excess of 327km/hr.
Only nineteen of the Z-tune cars were made so they have the potential to attract some significant collector value. These cars were made from second hand R34 GT-R V·Spec cars which were completely stripped down and rebuilt using functional components from Nissan’s racing cars, and the engine revised so it was able to get up to 8.000rpm.
Not only was the engine redesigned but the suspension also. The body was strategically reinforced with seam welding in key areas such as around the door frames and use of carbon fiber reinforcing. These were the ultimate R34 Nissan Skyline GT-R cars ever made.
Sixth Generation R35 GT-R (2002-Present)
For the sixth generation of the GT-R Nissan decided to separate the GT-R from the Skyline range of vehicles. This Nissan GT-R was the first to be exported to the United States and marked a distinct separation from the legacy of the previous cars which traced their lineage back to Prince Motors and the R380 racing car.
This new generation GT-R was given a new 3.8 liter V6 engine, the VR38DETT, and while the HICAS all wheel steering was not carried forward into the new model the ATTESA (Advanced Total Traction Engineering System) in a new improved form was very much a part of the new look, and new performance GT-R.
The 3.8 liter V6 engine now churns out an elegantly sufficient 565hp in the standard model and that increases to 600hp for the specialist Nismo model. The R35 GT-R boats a top speed of 310km/hr (193mph) and standing to 60mph time of just 3.2seconds, so it accelerates slightly faster, and has a top speed almost as fast as the very limited production R34 GT-R NISMO Z-tune cars: it is the fastest standard production GT-R ever produced.
The R35 GT-R is every inch a twenty-first century automobile with extensive use of digital technology in the car’s engine and transmission systems, including an active limited slip rear differential controlled by the ATTESA system. The digital display inside the car was created by the programmers who created the “Gran Turismo” video game, bringing video game graphics to the car’s dashboard.
Conclusion
The Nissan Skyline series of cars came from humble beginnings in the post-war era, as the economical Prince Skyline with a 60hp OHV four cylinder engine, and it developed into the current Nissan GT-R with a twin turbocharged engine that develops fully ten times that power level in the Nismo version.
The story of the Skyline’s journey from small car to a digital technology enriched super-car is complex, and it is a tribute to the nation that created it: a nation that prides itself on attending to every fine detail to produce the most refined result possible. Back when I was training the Japanese sword I was visiting Tokyo and one of the sword club members at one stage said to me “for a Japanese what is not seen is just as important, perhaps even more important, than what is seen”.
This was the sort of thinking that led to the technological advances that the Nissan Skyline GT-R cars epitomized, as evidenced by the GT-R being dubbed “Godzilla” by the Australian motoring press: it was at that time the “unbeatable monster from Japan’. Although it was a rather pretty “monster”, don’t you agree?
Photo Credits: Nissan, Prince, RM Sotheby’s.
The post A Brief History of the Nissan Skyline and GT-R – Everything You Need To Know appeared first on Silodrome.
source https://silodrome.com/nissan-skyline-gt-r-history/
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venkateshiarc-blog · 6 years ago
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Electro Hydraulic Servo Valve Market : share, market forecast, analysis and growth research report
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According to the new market research report by IndustryARC titled “Electro-Hydraulic Servo Valve Market: By Product (Single Stage, Double Stage, etc.); By Type (Nozzle Flapper, Jet Pipe, Deflector Jet); By Application (Aerospace, Industrial, Mobile/Marine); By Phase Lag; By Geography – (2018-2023)”, the market is driven by the utilization of industrial robots across the vertical along with the rising demand for valves from the aerospace and defence industry for braking, steering, and flight control. The market is expected to grow at a CAGR of 3.85% and reach $1.63 billion by 2023.
Europe dominates the Electro Hydraulic Servo Valve Market
Europe has a major share of 42% in the Electro Hydraulic Servo Market. North America and the Asia Pacific region follow the suit. The region will grow at a CAGR of 3.13% and reach $660.5 million by 2023. The market is more prominent in countries such as Germany, US, UK, Canada, and China. This is due to their cost-effectiveness in industrial applications. The key players such as Boeing and Lockheed Martin Aeronautics of aerospace and defense sectors in North America escalate the growth of hydraulic valves in the region.
In Canada, electro hydraulic servo valves are used in turbines to control the steam, fuel, water discharge, and other applications. They are also used in machine tools for controlling the workpiece. The growing demand for machine tools in the construction and automotive industries will enhance the growth of the electro-hydraulic servo valves in the region.
The iron and steel industry in Mexico employs servo valve and metal processing and machine tools. The growing demand from the iron and steel industry due to the demand from construction industries will drive the growth of the market in Mexico.
Selected Regulatory Analysis done in the Electro Hydraulic Servo Valve Market report
The hydraulic servo valve is employed in robotic applications to control the actuators. Growing use of industrial robots for welding, painting, assembling, and material handling in different industries is bolstering the growth of the Electro Hydraulic Servo Valve Market. Metal processing machines such as mechanical presses, machine tools, and rolling mills have evolved from conventional mechanical control to CNC to improve speed, efficiency, and accuracy.
Computer numeric electro flow control valve can control various actuation functions in machines such as roller height adjustment in rolling machines, hammer drop in presses, and spindle/tool holder movement in machine tools. In earthquake simulation, seismic simulators incorporate electro hydraulic servo valves which actuate the machine’s movable platform to create vibrations like earthquakes.
To Access/Purchase the Electro Hydraulic Servo Valve Market report please browse the link below:
https://industryarc.com/Report/18042/electro-hydraulic-servo-valve-market.html
Excerpts on Electro Hydraulic Servo Valve Market Growth Factors
• The miniature electric hydraulic valve is employed in industrial robots for motion control such as control of leg motion, joint motion, and arm motion. It is used in the robots which are used for material handling, painting, welding, and other automated industrial processes. The increasing demand for industrial robots in automation enhances the growth of the market.
• In the aerospace industry, the directional control valve is used in the engine control system of the aircraft. It is also used for flight control, thrust vector control, and missile control application. Flight simulators also employ these valves for actuation of motion and control loading simulation.
• The hydraulic proportional valve is even used in material test machines, active suspension systems, mining machinery, and mill equipment.
Key Players of the Electro Hydraulic Servo Valve Market
Moog provides proportioning valves that are used in industrial and marine applications. The main application includes basic metal processing, fatigue, material testing, rubber processing, robotics, etc. Rexroth Bosch Group produces two-directional electro hydraulic servo valves suited for closed-loop controlling of force, velocity, and pressure. Parker Hanfinn Corporation offers diverse electro hydraulic servo valves that are used in industrial and mobile machinery performance.
Aviation Industry Corporation of China (AVIC)
Honeywell International Inc
Schneider Kreuznach
Eaton Corporation Plc Oilgear Company Voith GmbH
Electro Hydraulic Servo Valve Market is segmented as below
The low-cost solution for industrial and other low-level applications in recent times has bolstered the growth of the Electro Hydraulic Servo Valve during the forecast period.
• Electro Hydraulic Servo Valve Market by product 1.Single stage 2.Double stage 3. Others
• Electro Hydraulic Servo Valve Market by type 1. Nozzle Flapper Valve 2. Jet Action Valve 3. Others (Dynamic Valve)
• Electro Hydraulic Servo Valve Market by application 1. Industrial 2. Mobile/Marine 3. Aerospace & Defense 4. Others
• Electro Hydraulic Servo Valve Market by geography(covers 13+ countries) • Electro Hydraulic Servo Valve Market by entropy • Company Profiles • Appendix: Abbreviations, Sources, Research Methodology, Bibliography, Compilation of Experts, Disclaimer.
What can you expect from the report?
The Electro Hydraulic Servo Valve Market Report is Prepared with the Main Agenda to Cover the following 20 points:
1. Market Size by Product Categories 2. Market trends 3. Manufacturer Landscape 4. Distributor Landscape 5. Pricing Analysis 6. Top 10 End-user Analysis 7. Product Benchmarking 8. Product Developments 9. Mergers & Acquisition Analysis 10. Patent Analysis 11. Demand Analysis (By Revenue & Volume) 12. Country-level Analysis (15+) 13. Competitor Analysis 14. Market Shares Analysis 15. Value Chain Analysis 16. Supply Chain Analysis 17. Strategic Analysis 18. Current & Future Market Landscape Analysis 19. Opportunity Analysis 20. Revenue and Volume Analysis
Any other custom requirements can be discussed with our team; we can provide a separate quote based on your requirement. You can drop in an e-mail to [email protected] to discuss more about our consulting services.
Media Contact: Mr. Venkat Reddy Sales Manager Email 1: [email protected] Or Email 2: [email protected] Contact Sales: +1-614-588-8538 (Ext-101)
About IndustryARC:
IndustryARC is a Research and Consulting Firm that publishes more than 500 reports annually, in various industries such as Agriculture, Automotive, Automation & Instrumentation, Chemicals and Materials, Energy and Power, Electronics, Food & Beverages, Information Technology, Life sciences &Healthcare.
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rohitkoluguri-blog · 6 years ago
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A Quick Look At The Latest Happenings In The Electro Hydraulic Servo Valve Market
Europe dominates the Electro Hydraulic Servo Market:
Europe has a major share of 42% in the Electro Hydraulic Servo Market. North America and the Asia Pacific region follow the suit. The region will grow at a CAGR of 3.13% and reach $660.5 million by 2023. The market is more prominent in countries such as Germany, US, UK, Canada, and China. This is due to their cost effectiveness in industrial applications. The key players such as Boeing and Lockheed Martin Aeronautics of aerospace and defence sectors in North America escalate the growth of hydraulic valves in the region.
In Canada, electro hydraulic servo valves are used in turbines to control the steam, fuel, water discharge, and other applications. They are also used in machine tools for controlling the work piece. The growing demand of machine tools in construction and automotive industries will enhance the growth of the electro hydraulic servo valves in the region.
The iron and steel industry in Mexico employs servo valve and metal processing and machine tools. The growing demand fromthe iron and steel industry due to the demand from construction industries will drive the growth of the market in Mexico.
Selected Regulatory Analysis done in the Electro Hydraulic Servo Market report:
The hydraulic servo valve is employed in robotic applications to control the actuators. Growing use of industrial robots for welding, painting, assembling, and material handling in different industries,is bolsteringthe growth of the Electro Hydraulic Servo Valve Market. Metal processing machines such as mechanical presses, machine tools, and rolling mills have evolved from conventional mechanical control to CNC to improve speed, efficiency, and accuracy.
Computer numeric electro flow control valve can control various actuation functions in machines such as roller height adjustment in rolling machines, hammer drop in presses, and spindle/tool holder movement in machine tools. In earthquake simulation, seismic simulators incorporate electro hydraulic servo valves which actuate the machine’s movable platform to create vibrations like earthquakes.
Excerpts on Electro Hydraulic Servo Market Growth Factors:
• The miniature electric hydraulic valve is employed in industrial robots for motion control such as control of leg motion, joint motion, and arm motion. It is used in the robots which are used for material handling, painting, welding, and other automated industrial processes. The increasing demand for the industrial robots in automation enhances the growth of the market.
• In the aerospace industry, the directional control valve is used in the engine control system of the aircraft. It is also used for flight control, thrust vector control, and missile control application. Flight simulators also employ these valves for actuation of motion and control loading simulation.
• The hydraulic proportional valve is even used in material test machines, active suspension systems, mining machinery, and mill equipment.
To access / purchase the full report browse the link below:
https://industryarc.com/Report/18042/electro-hydraulic-servo-valve-market.html
Key Players of the Electro Hydraulic Servo Valve Market:
Moog provides proportioning valves that is used in industrial and marine applications. The main application includes basic metal processing, fatigue, material testing, rubber processing, robotics, etc. Rexroth Bosch Group produces twodirectional electro hydraulic servo valves suited for closed loop controlling of force, velocity, and pressure. Parker Hanfinn Corporation offers diverse electro hydraulic servo valves that are used in industrial and mobile machinery performance.
Aviation Industry Corporation of China (AVIC) Honeywell International Inc Schneider Kreuznach
Eaton Corporation Plc Oilgear Company Voith GmbH
Electro Hydraulic Servo Valve Market is segmented as below:
The low cost solution for industrial and other low level applications in recent times has bolstered the growth of the Electro Hydraulic Servo Valve during the forecast period.
Electro Hydraulic Servo Valve Market by product 1.Single stage 2.Double stage 3. Others
Electro Hydraulic Servo Valve Market by type 1. Nozzle Flapper Valve 2. Jet Action Valve 3. Others (Dynamic Valve)
Electro Hydraulic Servo Valve Market by application 1. Industrial 2. Mobile/Marine 3. Aerospace & Defense 4. Others
• Electro Hydraulic Servo Valve Market by geography(covers 13+ countries) • Electro Hydraulic Servo Valve Market by entropy • Company Profiles • Appendix: Abbreviations, Sources, Research Methodology, Bibliography, Compilation of Experts, Disclaimer.
What can you expect from the report?
The Electro Hydraulic Servo Valve Market Report is Prepared with the Main Agenda to Cover the following 20 points:
1. Market Size by Product Categories 2. Market trends 3. Manufacturer Landscape 4. Distributor Landscape 5. Pricing Analysis 6. Top 10 End user Analysis 7. Product Benchmarking 8. Product Developments 9. Mergers & Acquisition Analysis 10. Patent Analysis 11. Demand Analysis (By Revenue & Volume) 12. Country level Analysis (15+) 13. Competitor Analysis 14. Market Shares Analysis 15. Value Chain Analysis 16. Supply Chain Analysis 17. Strategic Analysis 18. Current & Future Market Landscape Analysis 19. Opportunity Analysis 20. Revenue and Volume Analysis
Does IndustryARC publish country, geography or application based reports in Electro Hydraulic Servo Valve Market ? Yes, we do have separate reports as mentioned below:
1. North America Electro Hydraulic Servo Valve Market Report (2018-2023) 2. Europe Electro Hydraulic Servo Valve Market Size(2018-2023) 3. Asia Pacific Hydraulic Servo Valve Market Forecast(2018-2023) 4. Industrial Hydraulic Servo Valve Market growth(2018-2023) 5. Aerospace & Defence Hydraulic Servo Valve Market Share(2018-2023) 6. Mobile/ Marine Hydraulic Servo Valve Market Insights(2018-2023)
Does IndustryARC provide customized reports and charge additionally for limited customization?
Yes, we can customize the report by extracting data from our database of reports and annual subscription databases. We can provide the following free customization: 1. Increase the level of data in application or end user industry. 2. Increase the number of countries in geography chapter. 3. Find out market shares for other smaller companies or companies which are of interest to you. 4. Company profiles can be requested based on your interest. 5. Patent analysis, pricing, product analysis, product benchmarking, value and supply chain analysis can be requested for a country or end use segment.
Any other custom requirements can be discussed with our team; we can provide a separate quote based on your requirement. You can drop in an e-mail to [email protected] to discuss more about our consulting services.
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larryarora-blog · 8 years ago
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Worldwide Electro Hydraulic Servo Valve Market Analysis and Forecasts 2017
The Report added on Electro Hydraulic Servo Valve Market added by DecisionDatabases.com to its huge database. This research study is segmented on the bases of applications, technology, geography and types. The Report provides a detailed Electro Hydraulic Servo Valve Industry overview along with the analysis of industry’s gross margin, cost structure, consumption value and sale price. The leading companies of the Electro Hydraulic Servo Valve Market, manufacturers and distributors are profiled in the report along with the latest Industry development current and future trends.
Access the Report and full TOC @ http://www.decisiondatabases.com/ip/500-electro-hydraulic-servo-valve-industry-market-report
This report studies Electro Hydraulic Servo Valve in Global market, especially in North America, Europe, China, Japan, Southeast Asia and India, focuses on top manufacturers in global market, with capacity, production, price, revenue and market share for each manufacturer, covering *Moog *Bosch Rexroth *Parker *Eaton Vickers *Team *Honeywell *Woodward *YUKEN *E+H *EMG *Voith *Schneider *Star Hydraulics *Duplomatic *Oilgear *Nireco *Nanjing Electro-mechanical *Qinfeng *FACRI *Servo Technology *CSIC *Bmtri Precision *Hangyu Mechanical
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Market Segment by Regions, this report splits Global into several key Regions, with production, consumption, revenue, market share and growth rate of Electro Hydraulic Servo Valve in these regions, from 2011 to 2021 (forecast), like *North America *Europe *China *Japan *Southeast Asia *India
Split by product type, with production, revenue, price, market share and growth rate of each type, can be divided into *Permanent magnet type *Dynamic type
Split by application, this report focuses on consumption, market share and growth rate of Electro Hydraulic Servo Valve in each application, can be divided into *Military *Civil
Table of Contents - Snapshot 1 Market Overview 2 Global Market Competition by Manufacturers 3 Global Capacity, Production, Revenue (Value) by Region (2011-2016) 4 Global Supply (Production), Consumption, Export, Import by Regions (2011-2016) 5 Global Production, Revenue (Value), Price Trend by Type 6 Global Market Analysis by Application 7 Global Manufacturers Profiles/Analysis 8 Manufacturing Cost Analysis 9 Industrial Chain, Sourcing Strategy and Downstream Buyers 10 Marketing Strategy Analysis, Distributors/Traders 11 Market Effect Factors Analysis 12 Global Market Forecast (2016-2021) 13 Research Findings and Conclusion 14 Appendix
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View Related Reports @ Global Glass Cleaner Industry 2015 Market Research Report
http://www.decisiondatabases.com/ip/500-electro-hydraulic-servo-valve-industry-market-report
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