The diesel engine (also known as a compression-ignition engine) is an inner combustion engine that uses the heat of compression to initiate ignition and burn the fuel that happens to be injected into the combustion chamber. This contrasts with spark-ignition engines such as a petrol engine (gasoline engine) or gas engine (using a gaseous fuel as opposed to gasoline), which use a spark plug to ignite an air-fuel mixture.

The diesel engine gets the greatest thermal efficiency of any standard internal or external burning engine due to its very high compression ratio. Low-speed diesel machines (as used in ships and various other applications exactly where overall engine weight is relatively unimportant) can have a thermal efficiency that surpasses 50%.

Diesel engines are manufactured in two-stroke and four-stroke versions. They were originally used as a much more efficient replacement for stationary steam engines. Because the 1910s they have been used in submarines and ships. Use in locomotives, trucks, hefty gear and electric generating plants followed later on. In the 1930s, they slowly began to be made use of in a couple of automobiles. Since the 1970s, the use of diesel engines in larger on-road and off-road vehicles in the USA increased. According to the British Society of Motor Manufacturing and Traders, the EU average for diesel cars take into account 50% of the total sold, including 70% in France and 38% into the UK.

Diesel engines have the lowest specific fuel consumption of any large internal combustion engine employing a single cycle, 0.26 lb/hp (0.16 kg/kWh) for very large marine engines (combined cycle energy flowers are much more efficient, but employ two engines rather than one). Two-stroke diesels with large pressure forced induction, particularly turbocharging, make up a large percentage of the very largest diesel engines.

In North America, diesel engines are primarily used in large trucks, where the low-stress, high-efficiency period leads to much longer engine life and lower working costs. These advantages also make the diesel engine ideal for use in the heavy-haul railroad environment.

Diesel's original engine injected fuel with the assistance of compressed air, which atomized the fuel and pushed it into the engine through a nozzle (a similar principle to an aerosol spray). The nozzle opening had been closed by a pin valve lifted by the camshaft to initiate the fuel injection before leading dead centre (TDC). This is called an air-blast injection. Driving the three stage compressor used some power but the effectiveness and net power output ended up being even more than any other combustion engine at that time.

Diesel engines in service today raise the fuel to extreme pressures by mechanical pumps and provide it towards the combustion chamber by pressure-activated injectors without compressed air. With direct injected diesels, injectors spray fuel through 4 to 12 small orifices in its nozzle. The early air injection diesels always had a superior burning without the sharp increase in pressure during combustion. Scientific studies are now being performed and patents are being taken out to again use some kind of air injection to reduce the nitrogen oxides and pollution, reverting to Diesel's original implementation with its superior combustion and possibly quieter procedure. In all major aspects, the modern diesel engine keeps true to Rudolf Diesel's original design, that of igniting fuel by compression at an incredibly high pressure within the cylinder. With much higher pressures and high technology injectors, present-day diesel engines make use of the so-called solid injection system used by Herbert Akroyd Stuart for his hot bulb engine. The indirect injection engine could be considered the newest development of these low speed hot bulb ignition engines.

A vital component of all diesel engines is mechanical or digital governor which regulates the idling speed and maximum speed of the engine by controlling the rate of fuel delivery. Unlike Otto-cycle engines, incoming air is not throttled and a diesel engine without a governor cannot have a stable idling speed and can easily overspeed, leading to its destruction. Mechanically governed fuel injection systems are driven by the engine's gear train. These systems use a combination of springs and weights to control gas delivery relative to both load and speed. Modern electronically controlled diesel engines control fuel delivery by use of an electronic control module (ECM) or digital control unit (ECU). The ECM/ECU receives an engine speed signal, since well as various other operating parameters such as intake manifold stress and gasoline temperature, from a sensor and controls the quantity of fuel and start of injection timing through actuators to maximise minimise and power and efficiency emissions. Controlling the timing of the beginning of injection of fuel into the cylinder is a key to minimizing emissions, and maximizing fuel economy (efficiency), of the motor. The timing is measured in degrees of crank angle of the piston before top dead centre. For instance, if the ECM/ECU initiates fuel injection when the piston is before TDC, the start of injection, or timing, is said to be BTDC. Optimal timing will rely on the engine design as well as its load and speed, and is generally BTDC in 1,350-6,000 HP, net, "medium speed" locomotive, marine and stationary diesel engines.

Advancing the start of injection (injecting prior to the piston reaches to its SOI-TDC) results in greater in-cylinder pressure and temperature, and greater efficiency, but also results in increased engine noise due to faster cylinder pressure rise and increased oxides of nitrogen (NOx) formation due to higher burning temperatures. Delaying start of injection causes incomplete combustion, decreased fuel efficiency and an enhance in exhaust smoke, containing a considerable amount of particulate matter and unburned hydrocarbons.

The term Indirect injection, in an internal burning engine, refers to fuel injection where fuel is not directly inserted into the combustion chamber. Gasoline motors are generally equipped with indirect injection systems, wherein a fuel injector delivers the fuel at some time before the intake valve.

An indirect injection diesel engine delivers gasoline into a chamber off the combustion chamber, called a prechamber, where combustion begins and then spreads into the primary combustion chamber. The prechamber is carefully made to ensure sufficient blending of the atomized fuel with the compression-heated air.

The purpose of this divided combustion chamber is to speed up the combustion procedure, to be able to increase the power output by increasing engine rate. The addition of a prechamber, nevertheless, boosts heat loss to the cooling system and thereby lowers engine efficiency. The engine requires glow plugs for starting. In an indirect injection system the environment moves fast, mixing the fuel and environment. This simplifies injector design and enables the employment of smaller engines and less tightly toleranced designs which are simpler to manufacture and much more reliable. Direct injection, by contrast, uses slow-moving atmosphere and fast-moving fuel; both the design and manufacture of the injectors is more difficult. The optimisation of the in-cylinder air flow is much more difficult than designing a prechamber. There is a great deal more integration between the design of the injector and also the engine. Information technology is for this reason that car diesel engines were nearly all indirect injection until the ready accessibility of powerful CFD simulation systems made the adoption of direct shot practical.

Information technology consists of a spherical chamber located in the cylinder head and divided from the engine cylinder by a tangential throat. About 50% of the atmosphere enters the swirl chamber during the compression stroke for the engine, producing a swirl. After combustion, the products return through the exact same throat to the main cylinder at much higher velocity. So more heat loss to walls of the passage takes place. This kind of chamber finds application in engines in which fuel control and engine stability are more important than fuel economy. These are Ricardo chambers.

The air cell is a small cylindrical chamber with a hole in a single end. It is mounted more or less coaxially with the injector, said axis being parallel to the piston crown, with the injector firing across a small cavity which is available to the cylinder into the hole within the conclusion of the air cellular. The air cellular is mounted therefore as to minimise thermal contact with the mass associated with the head. A pintle injector with a slim spray pattern is used. At TDC the vast majority of the charge mass is contained in the cavity and air cell.

When the injector fires, the jet of fuel enters the air cell and ignites. This leads to a jet of flame shooting back out of the air cell directly into the jet of fuel still issuing from the injector. The turbulence and heat give excellent gas vaporisation and blending properties. Also since the majority of the combustion requires place outside the environment cell within the cavity, which communicates directly utilizing the cylinder, there is much less temperature loss involved in transferring the burning charge to the cylinder.

Air cell injection can be looked at as a compromise between direct and indirect injection, gaining a few of the efficiency advantages of direct injection while retaining the ease and simplicity of development of indirect injection.

Indirect injection is much less complicated to design and manufacture; less injector development is required and the shot challenges are low (1500 psi/100 bar versus 5000 psi/345 bar and higher for direct injection)

The reduced stresses that indirect injection imposes on internal components imply that it is possible to produce petrol and indirect injection diesel variations of the same basic engine. At best such types differ only in the cylinder head and the demand to fit a distributor and spark plugs in the petrol version whilst fitting a shot pump and injectors to the diesel. Examples are the BMC A-Series and B-Series engines together with Land Rover 2.25/2.5-litre 4-cylinder types. Such styles allow petrol and diesel versions of the same vehicle to be built with minimal design modifications between them.

Higher engine speeds can be reached, since burning continues in the prechamber.

In cold weather condition, high speed diesel engines can be difficult to start because the mass of the cylinder block and cylinder head absorb the heat of compression, preventing ignition as a result of the higher surface-to-volume proportion. Pre-chambered engines make usage of small electric heaters inside the pre-chambers called glowplugs, while the direct-injected engines have these glowplugs in the combustion chamber.

Many engines use resistive heaters within the intake manifold to warm the inlet air for starting, or until the motor reaches running temperature. Engine block heaters (electric resistive heaters in the motor block) connected to the utility grid are used in cold environments whenever an engine is turned off for extended periods (more than an hour), to reduce startup engine and time wear. Block heaters are also used for emergency power standby Diesel-powered generators which must rapidly pick up load on an energy failure. In the past, a wider variety of cold-start methods were used. Some engines, such as Detroit Diesel engines used a system to present small amounts of ether into the inlet manifold to start burning. Others used a mixed system, with a resistive heater burning methanol. An impromptu method, particularly on out-of-tune motors, is to manually spray an aerosol can of ether-based motor starter fluid into the intake air flow (usually through the intake air filter assembly).

Most diesels are now turbocharged and some are both turbo charged and supercharged. Because diesels do not have fuel in the cylinder before combustion is initiated, one or more bar (100 kPa) of air can be loaded in the cylinder without preignition. A turbocharged engine can produce significantly more energy than a naturally aspirated engine of the same configuration, as having more air in the cylinders allows more fuel to be burned and thus more power to be produced. A supercharger is powered mechanically by the engine's crankshaft, while a turbocharger is powered by the engine exhaust, not requiring any mechanical energy. Turbocharging can enhance the fuel economy of diesel engines by recovering waste heat from the exhaust, increasing the excess air factor, and increasing the ratio of engine output to friction losses.

A two-stroke engine does not have a discrete exhaust and intake stroke and thus is incapable of self-aspiration. Therefore all two-stroke engines must be fitted with a blower to charge the cylinders with air and assist in dispersing exhaust gases, a procedure referred to as scavenging. Sometimes, the engine may additionally be fitted with a turbocharger, whose output is directed into the blower inlet.

A few styles employ a hybrid turbocharger (a turbo-compressor system) for scavenging and asking the cylinders, which device is mechanically driven at cranking and low speeds to act as a blower, but which will act as a true turbocharger at higher speeds and loads. A hybrid turbocharger can revert to compressor mode during instructions for large increases in engine output power.

As supercharged or turbocharged engines produce more power for a given engine dimensions as compared to naturally aspirated attention, engines must be compensated to the mechanical design of components, lubrication, and cooling to handle the power. Pistons are usually cooled with lubrication oil sprayed on the bottom of the piston. Large engines may use sea, water water, or oil supplied through telescoping pipes attached to the crosshead.

As with petrol engines, there are two classes of diesel engines in current use: two-stroke and four-stroke. The four-stroke kind is the "classic" variation, tracing its lineage back to Rudolf Diesel's prototype. It is additionally the most frequently used form, becoming the preferred power source for many motor vehicles, especially trucks and buses. Much larger engines, such as useful for railway locomotion and marine propulsion, are often two-stroke units, offering an even more favourable power-to-weight ratio, in addition to better fuel economic climate. The most powerful engines in the world are two-stroke diesels of mammoth dimensions.

Two-stroke diesel engine procedure is similar to that of petrol counterparts, except that fuel is not mixed with air before induction, and the crankcase does not take an active role in the period. The traditional two-stroke design relies upon a mechanically driven positive displacement blower to recharge the cylinders with air before compression and ignition. The charging process also assists in expelling (scavenging) combustion fumes continuing to be from the previous power stroke.

The archetype of the modern form of the two-stroke diesel is the (high-speed) Detroit Diesel Series 71 motor, developed by Charles F. "Boss" Kettering and his colleagues at General Motors Corporation in 1938, in which the blower pressurizes a chamber in the engine block that is usually referred to as the "air box". The (extremely much larger medium-speed) Electro-Motive Diesel motor is used as the prime mover in EMD diesel-electric locomotive, marine and stationary applications, and was developed by the same team, and is built to the same principle. However, a significant improvement constructed into most later EMD engines is the mechanically-assisted turbo-compressor, which provides charge air utilizing mechanical assistance during starting (thereby obviating the necessity for Roots-blown scavenging), and provides charge air using an exhaust gas-driven turbine during normal operations—thereby providing true turbocharging and additionally increasing the engine's power output by at least fifty percent.

In a two-stroke diesel engine, as the cylinder's piston approaches the bottom dead centre exhaust ports or valves are opened relieving many of the excess pressure after which a passage between the air box and the cylinder is opened, permitting air flow into the cylinder. The environment movement blows the remaining combustion gases from the cylinder—this is the scavenging process. Because the piston passes through bottom centre and starts up, the passageway is closed and compression commences, culminating in fuel injection and ignition. Refer to two-stroke diesel engines for more detailed coverage of aspiration types and supercharging of two-stroke diesel engines.

Normally, the number of cylinders are used in multiples of two, although any number of cylinders can be used as long as the load on the crankshaft is counterbalanced to prevent excessive vibration. The inline-six-cylinder design may be the many respected in light- to medium-duty engines, though small V8 and larger inline-four displacement engines are also common. Small-capacity engines (generally considered to be those below five litres in capacity) are generally four- or six-cylinder kinds, with the four-cylinder being the most common type found in automotive utilizes. Five-cylinder diesel engines have actually also already been created, becoming a compromise between the sleek running of the six-cylinder and the space-efficient dimensions of the four-cylinder. Diesel engines for smaller sized plant machinery, ships, tractors, generators and pumps may be four, three or two-cylinder types, with the single-cylinder diesel engine remaining for light stationary work. Direct reversible two-stroke marine diesels need at least three cylinders for reliable restarting forwards and reverse, while four-stroke diesels need at least six cylinders.

The need to enhance the diesel engine's power-to-weight ratio produced several novel cylinder arrangements to draw out more power from an offered ability. The uniflow opposed-piston engine uses two pistons in a single cylinder with the combustion cavity in the centre and gas in- and outlets at the ends. This makes a comparatively powerful, light, swiftly running and economic engine suitable for use in aviation. An example is the Junkers Jumo 204/205. The Napier Deltic engine, with three cylinders arranged in a triangular formation, each containing two opposed pistons, the whole engine having three crankshafts, is among the better known.

Hino machines, Ltd. was a Japanese producer of commercial vehicles and diesel motors (like for automobiles, buses and also other engines) based in Hino-shi, Tokyo. The business are a respected producer of modest and heavy-duty diesel vehicles in Asia.

Hino Motors is a constituent from the Nikkei 225 with regards to Tokyo stock market. It really is a subsidiary of Toyota motor organization and another of 16 significant businesses from the Toyota staff.
The organization traces their roots back again to the founding of Tokyo petrol markets staff in 1910. In 1910 Chiyoda petrol Co. was indeed founded and competed fiercely against incumbent Tokyo petrol team eliminate for gasoline lighting effects consumers. Tokyo fuel areas had been a parts supplier for Chiyoda gas nonetheless it ended up being beaten and combined into Tokyo gas in 1912. Losing their particular biggest customer, Tokyo petrol company Co. broadened their products like electronic areas, and rebranded it self as Tokyo gas and electrical energy Industry(), TG&E and it is regularly abbreviated as Gasuden. They created their particular earliest motor vehicle in 1917, the look TGE "A-Type" car. In 1937, TG&E accompanied their particular vehicle division with that of car markets Co., Ltd. and Kyodo Kokusan K.K., to make Tokyo vehicle company Co., Ltd., with TG&E as a shareholder. Four years afterwards, the organization changed their subject to Diesel system markets Co., Ltd., which will eventually being Isuzu machines restricted.

Listed here period (1942), the modern entity of Hino big business Co., Ltd. spun itself from Diesel system areas Co., Ltd., as well as the Hino name was created. During world War II, Hino manufactured kind 1 Ho-Ha half-track and kind 1 Ho-Ki armored employees services the Imperial Japanese Army. After end of globe War II, the organization must end making huge diesel machines for aquatic systems, along with the signing of pact, the company fallen the "hefty" from the name and officially centered from heavy-duty trailer-trucks, buses and diesel devices areas, as Hino areas Co., Ltd. Business took its name through area of the head office in Hino city within Tokyo prefecture.

To hone its advertising focus to users, in 1948, the company included the name "Diesel" is Hino Diesel markets Co., Ltd. In 1950 the heavy-duty TH10 was indeed launched, equipped with the all-new 7-liter DS10 diesel program. An eight-tonner, this can be significantly larger than current Japanese motors which may have rarely been already designed for more than 6,000 kg (13,230 lb) payload.

In 1953, Hino licensed the exclusive car marketplace, by production Renaults under licence, as well as in 1961 they supposed creating a distinctive Contessa 900 sedan with an 893cc rear-mounted engine, and a pickup truck known as the Hino Briska because of the Contessa system only a little enlarged and setup right in front side with straight back wheel drive. The Italian stylist Giovanni Michelotti redesigned the Contessa number in 1964 with a 1300 cc rear-mounted system. Fed by two SU kind carburettors, this developed 60 hp (44 kW) to the sedan and 70 hp (51 kW) in coup variation. But Hino ceased private vehicle production rapidly in 1967 after joining the Toyota team. In 1963, the Hamura factory started processes, and centered on commercial automobile and coach make.

Hino vehicles are also assembled in Portugal as well as in Canada.

Hino Motors finalized a 10-year system agreement with Kaiser-Illin organizations of Haifa, Israel, in 1963. System of Contessa 900 had been best for sale in 1964. Later on, Briska 900 and 1300 together with Contessa 1300 sedan become assembled in Haifa besides. Through the many years 1964-1965, Israel was indeed Hino's 2nd most crucial market with regards to their Contessas. Israel exports amounted to ~10percent of total Contessa production. After it turned out bought by Toyota, the agreement ended up being concluded plus the acutely final Israeli Contessas rolled off the assembly-line in March 1968. Completely, over 8,000 Hino Contessa and Briska have been put together in Israel.

The Hino Profia are huge obligation cab-over car made by Hino Motors. In lots of export places, it is just referred to as Hino 700. Title Profia are formally used in Japan, and was as soon as referred to as Super Dolphin Profia. The Hino F-Series vehicle's model rules was FN, FP, FR, FS, and FW. The tractor brain design formula were SH and SS.

Super Dolphin (1981--1992)
Hino Super Dolphin

Introduced in 1981, the Super Dolphin was Hino's entry in the heavy-duty automobile marketplace in Japan, and shipped internationally.
Super Dolphin Profia (1992--2003)
Hino Super Dolphin Profia

Diesel motor availabilities is 7,961 cc J08C, 10,520 cc P11C, 13,267 cc K13D, 19,688 cc F20C, and 20,781 cc F21C.
Systems

FQ
Size - 11.99 m (472.0 in)
Circumference - 2.49 m (98.0 in)
Height - 3.64 m (143.3 in)
FR
SH
Length - 6.05 m (238.2 in)
Circumference - 2.49 m (98.0 in)
Height - 2.78 m (109.4 in)

Profia

In 2003 it absolutely was rebranded as Hino Profia whilst nevertheless becoming produced in Japan without Super Dolphin badge. The cabin build resembles the 4th generation Ranger, nevertheless the Profia were bigger. Their in line with the Grand Aerotech build technology ensuing outstanding aerodynamic functionality. The cabin in addition adopts enhanced tragedy shield effects cover (EGIS) to shield occupants. The Hino 700 can be accessible in Taiwan making by Kuozui Motors, which is being put together for other stores.

The design works 10.5-liter P11C, and 12.9-liter E13C diesel motors. Transmission are either 7, 12, or 16 speeds manual. The professional changes 12 automatic transmission emerges the domestic areas.

The 700 can be bought Australian Continent and unique Zealand with Eaton Fuller RoadRanger Super18 transmissions, because this is the most common heavy-duty transmission in use downunder.

In April 2017, this facelifted version was revealed with an optional of an 8.9-liter A09C diesel engine. The manual and professional modification automated transmissions remains offered.
Design

The Profia heavy weight vehicles can be obtained because next systems:

FH 4x2
FN 6x2 double front side axle
FQ 6x4 most affordable floors
FR 6x2 double backside axle
Length - 11.98 m (471.7 in)
Circumference - 2.49 m (98.0 in)
Amount - 3.75 m (147.6 in)
FS 6x4
FW 8x4 reduced flooring
Length - 11.99 m (472.0 in)
Circumference - 2.49 m (98.0 in)
Height - 3.48 m (137.0 in)
FY 8x4
SH 4x2 Tractor Mind
Length - 6.19 m (243.7 in)
Circumference - 2.49 m (98.0 in)
Height - 3.75 m (147.6 in)
SS 6x4 Tractor Head
SV 6x4 Tractor Mind
The Hino Dutro (Japanese: ) is a lighter commercial car distributed into the Toyota Dyna, manufactured by Hino Motors. Just as the Dyna and its particular twin Toyoace, the Dutro is made of the U300 program for standard taxi, or U400 program the wide taxi and offered in some various framework means appropriate various purposes. The Dutro took significantly more than through prior Ranger 2 (and Ranger 3), a badge-engineered type of Daihatsu's Delta show. Outside Japan, in addition referred to as '300 tv show'.

For export marketplace, the Dutro will come in Australian Continent, Chile, Colombia, Indonesia, Malaysia, the Philippines, Thailand, Sri Lanka furthermore area in Latin The united states. As of 2008, the Dutro was in fact obtainable in Canada since the 'Hino 155'. Canadian companies are designed in Woodstock, Ontario from CKD kits imported from Japan.

The Andinian and Latin-American companies are produced in Cota (Cundinamarca), Colombia as well as in Chile, from CKD kits introduced from Japan. In certain of these areas, however, the automobiles are brought in from Japan totally assembled.

Japan

Numerous variants is out there in Japan, including the big taxi, twin taxi, crossbreed electric, 4WD, and program Van. Engine alternatives through the 3.7 liter 4B, 4.1 liter 15B-FTE, 4.0 liter N04C, 4.6 liter S05C, 4.7 liter J05D, 4.8 liter S05D, and 5.3 liter J05C.

Indonesia

Introduced in Indonesia in 2002 with five versions: 125ST, 125LT, 125HT, 140GT, and 140HT. Each was Standard Taxi. 125ST test 4-wheel fast wheelbase, others were 6-wheel lengthy wheelbase. Engine for 125 variations were 4.0 liter W04D, the 140 designs is operating on 4.6 liter S05C.
Starting 2007 model year, utilising the authorities needs that vehicles must comply to Euro-2 emission legislation, and Hino launched 4 systems due to the altered W04D system with inter-cooled turbocharger. The newest merchandise was 110SD, 110LD, 130MD, and 130HD.

Thailand

In Thailand: Dutro 300, 301, 340 (Standard taxi), 410 and 420 (wide taxi).

Colombia

A forward thinking brand new installation plant is found in the town of Cota, in Colombia, built and financed by two partners: one location services as well as the Toyota group, almost all owner of this Hino subsidiary plus the brand name. The first items because of this portfolio, put together only at that factory and associated with this short article are generally:

Hino Show 300 Lighter cargo:

Dutro program Trucks.

Second Generation (2011-present)

A lot of these are manufactured in Japanese natural herbs, while some devices are come up with in Canada, Colombia and Indonesia. The greater amount of appreciable improvements will be the engine (triumph aided by the EURO IV/V/Vwe accepted), a unique remodelling created by Toyota, and much more and newest best equipment onboard.
The Hino Ranger test a method to heavy-weight cab-over vehicle produced by the Japanese vehicles producer Hino motors since 1969.

The Ranger is a component of Hino's F-Series car with model signal such as for example FC, FD, FE, FF, FG, FL, and FM. The further the alphabet suggests the larger payload. The 4WD brands become FT and GT. The SG are Tractor check out pull container. In a few nations, the Ranger is simply provided as modest or hefty automobile, even though the little or reduced payload design like FA and FB have been altered by Hino Dutro. In Japan, the tiny Ranger FA ended up being rebadged as Toyota Dyna.

Hino has actually competed in to the Dakar Rally in 1991, with the Ranger FT 4WD truck driven by Yoshimasa Sugawara, a Japanese rally driver. He constantly done to the top in Camion Category. For 17 right many years, Hino constantly gotten the below 10,000 cc course, and grabbed 1st basic in the 1997 special event.

1st Generation (1969-1980)
Hino KL340

The Hino Ranger KL ended up being introduced in Japan in 1969. After the 1979 discontinuation of Toyota Massy Dyna, the Ranger program changed that vehicle. In Australia, it absolutely was supplied as Toyota KL300. The Ranger KL-series was indeed provided as quick wheelbase KL300, means wheelbase KL340 and KL350, along side extended wheelbase KL360 and KL380. The Ranger line-up spawned into KB, KR, KQ, also design. Engines are generally 4.5 liter DQ100 and 5.0 liter EC100.
2nd Generation (1980-1989)
Hino Ranger FF173

Early services and products require circular headlights, while facelift systems include rectangular headlights. The taxi build ended up being prompted by European vehicles and was somewhat more aerodynamic than their forerunner; 35 portion more regarding Hino independently. The taxi was built by robots. the engine quantity has also been up-to-date.

Japanese build manufacturing ended in 1989, Indonesian design lasted until 2003.

Products in Indonesia are FF172, FF173, FL176, FM226, and SG221. The FF and SG was marketed as Super Ranger, the FL and FM is Jumbo Ranger.

From 1982, Ford motor team and Hino finalized a deal for badge-engineered vehicles to-be referred to as Ford N-series for launch in Australian and unique Zealand areas to restore the Ford D-series automobiles. The offer lasted fifteen many years. As a result of this, many Hino trucks spotted supplier right here disguised as Fords.
3rd Generation (1989-2002)
Hino Ranger FF

In Japan, this generation was promoted as Cruising Ranger, Rising Ranger and Space Ranger.

Light Vehicle : FA, FB
Light Moderate Vehicle : FC, FD, FE, GD
Means Significant Automobile 4x2 : FF, FG
Moderate Car 4x4 : FT, GT, GX
Tractor Notice : SG

Hino joined three Ranger FTs inside 1997 Dakar Rally, and success were 1-2-3 in general inside Camion (vehicle) group.

In united states, Hino would not utilize Ranger title because of its medium vehicle. The united states brands try FA1517, FB1817, FD2320, FE2620, FF3020, SG3320, and SG3325. The initial two digits suggest the Gross automobile fat score (GVWR), additionally the final two digits reference motor energy. Moderate vehicles want 200HP. FA1517 shows the tiniest vehicle with 15,000 pounds GVWR, and around 170 bhp.

The new generation Hino Ranger wasn't offered in Indonesia, considering that the 2nd generation was produced locally until 2003.

In to the Top Gear Burma specialized James May drove a third generation Hino Ranger when you consider the FB110 difference with a crane accessory.

In Southern Korea, this generation rebadged as Kia Rhino.
4th Generation (2001-Current)
Hino Super Ranger SG260J
Hino 500 FG210J Wing in plant in Indonesia
Hino Jumbo Ranger FM320P

Marketed in Japan as Ranger expert, or Hino 500 show for export. Retain the Super Ranger and Jumbo Ranger brands in Indonesia. In Malaysia, it is actually known as Validus. Mega called trucks hino ranger in Thailand.

The Ranger can be acquired with blend of different cabin, standard or wider, standard roofing or maybe more roof, brief taxi or total cab. The FD ordinarily available as dual taxi.

Top quality bundle with chrome bumper, discharge headlights, lumber panel, along with other indoor upgrades might be provided for JDM goods.

Light Medium Truck : FC, FD, GD, FE
Medium Immense Vehicle 4x2 : FF, FG, FJ
Method Vehicle 4x4 : FT, FX, GT, GX
Moderate Important Vehicle 6x2: FL
Moderate Important Automobile 6x4: GK, FM
Moderate Heavy Vehicle 8x4: GY
Tractor Mind 4x2: SG
Tractor Head 6x2: SG
Tractor Brain 6x4: FM

Hino is the markets main for vehicle and bus in Indonesia since 2000. Today's best-selling design are Jumbo Ranger FM260J D. This dump truck is normally used by construction and coal mining.

A diesel hybrid-electric variation ordinarily for sale in Japan.

Some small customizations was introduced in January 15, 2015. The most recent Hino Ranger tv show now have a whole new research with a refreshed upside-down trapezoidal form front part barbeque grill with dark grey colors, amazing headlamp, semi-floating suspension system, and modified framework. Apart from that, there is a improvement regarding axles - all the new Hino Ranger Series today makes use of 10 wheel studs rather than the frequently receive 8 wheel boys in earlier years. This 10-wheel-stud build isn't a new comer to Hino because some heavy-duty series Hino Ranger, usually the concrete mixer vehicle, has at this time placed this build several years ahead of. However, since 2015, the 10-wheel-stud build is an average purpose for several Hino Ranger show.

In April 2017, the refreshed Ranger was launched along with the newly developed 5.1-liter A05C diesel engine. The guide and Pro move automatic transmissions remains supplied.

- **Safety Precautions**
- **Personal Protective Equipment (PPE)**: Wear gloves, safety glasses, and steel-toed boots to protect yourself from sharp objects and heavy components.
- **Work Area**: Ensure your workspace is clean, well-lit, and free of hazards. Use a flat, stable surface to prevent accidents.

- **Tools Required**
- **Socket Set**: Use a metric socket set (e.g., 10mm to 24mm) to remove bolts and nuts. Sockets fit onto a ratchet handle for easier turning.
- **Ratchet Wrench**: A ratchet wrench allows you to quickly tighten or loosen bolts without repositioning the tool. Practice using it by turning it clockwise to tighten and counterclockwise to loosen.
- **Torque Wrench**: Required for accurately tightening bolts to manufacturer specifications. This tool clicks or beeps when the desired torque is reached.
- **Pliers**: Useful for gripping and pulling wires or small components. Needle-nose pliers can help reach tight spaces.
- **Screwdrivers**: Flathead and Phillips screwdrivers are necessary for removing covers and securing smaller components.
- **Breaker Bar**: This long-handled tool provides extra leverage for loosening stubborn bolts.
- **Floor Jack and Jack Stands**: Use a floor jack to lift the vehicle and jack stands to securely hold it in position. Never work under a vehicle supported only by a jack.
- **Oil Drain Pan**: Needed to catch any fluids that might leak from the gearbox during removal.
- **Shop Manual**: A Hino S05C-B workshop manual will provide specific torque specs and diagrams for reference.

- **Preparation Steps**
- **Disconnect Battery**: Always disconnect the negative terminal of the battery to prevent electrical shocks or short circuits.
- **Drain Fluids**: Use the oil drain pan to collect any transmission fluid from the gearbox. This prevents spills and keeps your workspace clean.
- **Remove Driveshaft**: Unbolt the driveshaft from the gearbox and secure it out of the way. You might need a universal joint tool or a screwdriver to help with this.
- **Label Wiring**: If there are any electrical connections, label them for easier reconnection later.

- **Removing the Gearbox**
- **Locate Mounting Bolts**: Identify all bolts securing the gearbox to the engine and frame. Refer to your shop manual for the exact locations.
- **Loosen Bolts**: Use the socket set and ratchet to loosen and remove the bolts. Keep them organized to ensure you have all necessary hardware for reinstallation.
- **Support the Gearbox**: Use a floor jack to support the gearbox as you remove the last bolts to prevent it from falling.
- **Disconnect Linkages**: If present, remove any linkages or cables attached to the gearbox, using pliers or screwdrivers as necessary.
- **Carefully Extract Gearbox**: With everything disconnected, gently slide the gearbox away from the engine. You may need to wiggle it slightly to free it from any tight spots.

- **Inspect and Replace Parts**
- **Inspect Gearbox Components**: Check for worn or damaged components like seals, gaskets, or bearings.
- **Replacement Parts**: Common parts that may need replacing include:
- **Input/Output Seals**: Prevent fluid leaks; if damaged, replace them to avoid future leaks.
- **Clutch Kit**: If the vehicle has a manual transmission, inspect the clutch for wear and replace it if necessary.
- **Gaskets**: Replace any gaskets that show signs of wear to ensure a proper seal.

- **Installing the New Gearbox**
- **Position the New Gearbox**: Use the floor jack to lift the replacement gearbox into position. Align it carefully with the engine.
- **Reattach Linkages and Wiring**: Reconnect any cables or linkages you removed earlier, referring to your labels.
- **Secure with Bolts**: Reinstall the mounting bolts using the socket set. Use a torque wrench to tighten them to the manufacturer's specifications found in the shop manual.
- **Reconnect Driveshaft**: Reattach the driveshaft, ensuring all bolts are securely fastened.

- **Final Steps**
- **Refill Fluids**: Refill the gearbox with the appropriate transmission fluid as specified in the manual.
- **Reconnect Battery**: Reattach the negative battery terminal.
- **Test Drive**: Take the vehicle for a short drive to ensure everything is functioning properly. Check for any leaks or unusual noises.

- **Clean Up**
- Dispose of any used fluids and old parts properly according to local regulations. Clean your workspace and put away all tools.
rteeqp73

Ordered diagnostic workflow (theory + how each repair fixes the fault). Follow this sequence on a Hino S05C‑B.

Preparations (tools & safety)
- Tools: Hino‑compatible code reader or J1939/OBD scanner, multimeter, oscilloscope (ideal for crank/cam), fuel pressure gauge, boost gauge/smoke tester, basic hand tools, wiring probe, service manual pinouts/specs.
- Safety: battery disconnect for wiring work, relieve fuel/boost pressures before testing, engine warm for some tests.

1) Visual / basic electrical check
- Theory: The ECU and all sensors need correct battery voltage, fuses, and solid grounds. Damaged wiring/connectors cause open/shorts and intermittent signals that set CELs.
- What to do: Inspect battery, battery ground and chassis grounds, main fuses, ECU connector for corrosion, harness chafing, water intrusion.
- How repair fixes it: Restoring power/ground and reliable connectors removes false or intermittent sensor readings so the ECU no longer sees faults.

2) Read and record DTCs + freeze frame / live data
- Theory: DTCs are symptom pointers (which circuit/parameter failed and under what conditions). Freeze frame tells engine rpm, load, temp when the fault occurred.
- What to do: Read codes with proper Hino/J1939 scanner. Record all DTCs and freeze frame. Note pending vs active vs history codes.
- How repair fixes it: Identifying the correct DTC focuses testing on the failed circuit/component rather than random replacement.

3) Clear codes and reproduce
- Theory: Some codes are one‑offs. Reproducing ensures failure is current and gives real‑time data.
- What to do: Clear codes, attempt to reproduce under same conditions from freeze frame (idle, cruise, cold start).
- How repair fixes it: Confirms the repair target is the root cause rather than a transient condition.

4) Verify ECU power, grounds and communications
- Theory: Loss of ECU supply, ground or CAN/J1939 comms creates multiple spurious codes or loss of sensors/actuators.
- What to do: Measure ECU supply voltage, check ground continuity, check CAN/J1939 lines for activity with a scanner.
- How repair fixes it: Repaired wiring or replaced ECU restores reliable signal exchange so sensors/actuators are correctly read and controlled.

5) Sensor circuit diagnosis (MAP/MAF, coolant temp, oil pressure, ambient/temp, etc.)
- Theory: Sensors provide the ECU the inputs needed for fuel quantity and timing. Open/shorted or inaccurate sensors cause incorrect fueling, timing, EGR behavior and emission faults.
- What to do: For a reported sensor DTC, check sensor 5V ref (if used), ground, and signal voltage/resistance. Wiggle harness, compare to spec. Swap or bench‑test sensors if uncertain.
- How repair fixes it: Replacing a failed sensor or repairing its wiring returns accurate input to the ECU → correct fuel/air control → removes CEL and fixes drivability.

6) Crankshaft / camshaft position faults
- Theory: Injection timing and engine sequencing come from crank/cam sensors. Missing or noisy tooth signals cause no‑start, misfire, or timing error DTCs.
- What to do: Probe crank/cam signals with an oscilloscope or high‑speed dwell meter. Verify tooth wheel integrity and sensor air gap. Check for metal debris or timing gear damage.
- How repair fixes it: Replacing a failed sensor or repairing the trigger wheel/relocating timing restores a clean timing reference so the ECU can schedule injection pulses correctly.

7) Fuel delivery / pressure problems
- Theory: Diesel combustion needs correct fuel pressure and delivery. Low fuel pressure, air in feed, clogged filters, or failing lift pump/injection pump generate CELs and poor power.
- What to do: Check fuel filter condition, water separator, bleed for air, measure fuel rail/lift pressure per service specs, inspect lines for collapse.
- How repair fixes it: Replacing filters, repairing lift pump or bleeding air restores pressure and supply so injectors get correct fuel quantity — ECU commands then produce expected engine output and emissions.

8) Air/boost and intake faults (leaks, MAP sensor, turbo actuator)
- Theory: ECU uses intake pressure/air mass to meter fuel. Boost leaks, failed MAP/MAF or turbo actuator lead to incorrect fuelling and boost control DTCs.
- What to do: Smoke test intake and intercooler for leaks, check MAP/MAF signals, verify turbo actuator movement and vacuum/pressure supply.
- How repair fixes it: Fixing leaks or replacing a faulty sensor/actuator restores correct air measurement/control so ECU can match fuel to air — improving power and stopping related CELs.

9) EGR / exhaust aftertreatment faults (EGR valve, DPF sensors)
- Theory: EGR position and DPF status affect backpressure and emissions. Clogged EGR or DPF and failed differential pressure sensors generate CELs and limp modes.
- What to do: Check EGR for carbon build‑up and position feedback, measure DPF differential pressure and soot load (if equipped), run forced regen where applicable.
- How repair fixes it: Cleaning/replacing EGR or performing DPF treatment returns expected exhaust flow and sensor readings; replacing failed sensors restores accurate monitoring, so ECU can manage regen/EGR properly.

10) Injector and actuator checks
- Theory: Injectors and other actuators must respond to ECU commands. Shorted coils, stuck nozzles or broken actuator wiring cause misfires, smoke and CELs.
- What to do: Use active test from scanner to command actuators; measure injector coil resistance, perform balance/compression tests, inspect nozzle spray pattern if possible.
- How repair fixes it: Replacing faulty injectors or repairing actuator wiring returns commanded response so combustion is correct and ECU no longer flags fault.

11) Mechanical checks (compression/timing)
- Theory: Severe mechanical issues (low compression, slipped timing) can set fault codes or produce symptoms that look like sensor faults.
- What to do: If electrical/fuel/air tests good, perform compression/leak‑down test and verify injection pump or cam timing.
- How repair fixes it: Correcting timing or repairing mechanical defects ensures proper combustion and removes related DTCs.

12) Final verification and ECU reset / relearn
- Theory: After repair ECU may need to clear learned trims or perform adaptations.
- What to do: Clear codes, use scanner to perform any required relearn/idle or injector adapt procedures, road test under original freeze frame conditions and monitor live data.
- How repair fixes it: Relearning ensures ECU calibrations match the repaired components so the engine performs as designed and the CEL stays off.

General troubleshooting principles (short)
- Always interpret DTCs as clues, not the final diagnosis.
- Start at power and ground, then the sensor/actuator wiring, then the component.
- Prefer live data and freeze frame to blind part replacement.
- Use an oscilloscope for crank/cam and rapid signal diagnosis.
- Document test values and comparisons to spec in the service manual.

Common examples (theory → repair effect)
- Crank position intermittent: theory — ECU loses timing reference → misfire/no‑start. Repair — replace/gap sensor or fix reluctor wheel → restores timing signal so injections fire correctly.
- MAP sensor out of range: theory — ECU miscalculates air mass → wrong fuel quantity and high soot/black smoke. Repair — replace MAP or fix wiring → restores correct air measurement → proper fueling.
- Fuel pressure low: theory — under‑fueling or erratic injection → poor power, limp. Repair — replace clogged filter or lift pump, bleed air → restores fuel pressure → stable combustion.
- EGR stuck open: theory — excessive recirculated exhaust lowers combustion temp → rough idle and NOx/soot DTCs. Repair — clean/replace EGR valve and restore correct position feedback → correct combustion and emissions control.

If you want, give me the exact DTC(s) from the Hino scanner and the freeze‑frame values and I’ll walk through the specific test sequence and the most likely repairs.
rteeqp73