939003532 - INTRODUCTION - CURRENT GENERATION

ALTERNATOR

COMPOSITION

The alternator is a rotary machine that transforms mechanical energy into electrical energy.
1 - Rotor electromagnetic circuit2 - Fitting rods3 - Rectifier side support4 - Negative heat dissipation plate5 - Positive heat dissipation plate6 - Zener type power press-fit diode7 - Commutator8 - Regulation unit9 - Heat shield cover10 - Rectifier side bearing11 - Rectifier side inner fan12 - Stator electronic circuit13 - Control side support14 - Control side inner fan15 - Control side bearingAs with all electrical machines, it is made up of two basic parts: inductor (rotor) and stator.The rotor for an alternator with internal ventilation is illustrated in the diagram below.

Rotor

The rotor consists of a cylindrical magnetic core, concentric to the drive shaft, with a toroidal coil winding and two opposing magnetic impellers which are magnetized by the winding located in the actual core.The impellers have six talon shaped poles each with reciprocal interpolation producing six alternate North poles and six South poles. There is therefore a single rotor winding which produces the e.m.f. for all the partial magnetic circuits.

Stator

The following diagram shows the stator.
1 - Star connection stator2 - Triangle connection statorThe stator consists of a ring shape pack joined by two or more axial seams electrically welded on the outer part. It is normally equipped with thirty six grooves which contain a three-phase winding made from copper wire insulated with vinyl acetate and connected, as necessary, in a star or triangle formation.

Rectifier bridge

The rectifier bridge is illustrated in the diagram.
1 - Zener type power diode2 - Dissipation plate3 - Alternator B + terminalBridge specifications

The bridge consists of:

  • Zener press-fit diodes.
  • Diodes fitted in the dissipator plates electrically welded to the connection terminals.
  • Sheared dissipator plates.
  • Large dimension dissipators.
  • Phase insulation until the connection with the bridge via a rubber cable duct.
  • Limitation of excess tension in the case of "+ battery" load disconnection guaranteed by zener diodes.
1 - Normal diode2 - Zener diodeZener diodesThe feature of both diodes, if polarized directly, is to pass the current from the anode to the cathode (V+ I+): then a zener diode behaves like a normal silicon diode.If inversely polarized, the current does not initially pass from the cathode to the anode up to value VZBeyond value VZ the normal diode is destroyed, the zener diode, on the other hand, continues to operate normally because its resistance in these conditions decreases sharply. Zener diodes are therefore voltage stabilizer diodes. Voltages of between 4.7 and 24 Volts are used in cars. It is one of the most important components in the regulation unit.It is often used for protection against polarity inversion or as protection against excess voltage.

SPECIFICATIONS OF INTERNAL VENTILATION ALTERNATORS

The main feature of this type of alternator, with a 115 mm stator diameter, is having dual internal ventilation with the vanes at an angle to guarantee the maximum flow of air and limit noise at the same time.For the same power output alternators with internal ventilation are smaller and lighter than types with external ventilation thereby satisfying current application requirements (there is always less space in engine compartments). In addition to this, in terms of quality, reliability and durability, these alternators meet higher standards than the best competition currently on the market.In depth studies and research have made it possible to introduce measures in production to reduce noise limits produced by various components (fluidynamics, magnetics, mechanics).

Typical voltage curve

The graph below illustrates a typical voltage regulator curve.

Wiring diagram

1 - Alternator2 - Interference condenser3 - Regulation unit4 - Energizing rotor5 - Electric field stator6 - Zener diode rectifier bridge7 - Alternator recharging warning light in instrument panel.8 - Body Computer9 - CAN linesOperationWith the alternator still with the ignition key in the ON position, the Body Computer lights up the warning light in the instrument panel and sends a power supply to the voltage regulator built into the alternator via terminal D+.In these conditions the energizing circuit (rotor) is enabled to earth by the regulator electronics.With the alternator rotating through the effect of the variation of the rpm and the magnetic field, a three-phase alternating voltage is produced in the electrical circuit (stator) which rectified by the diode bridge can exit terminal B+.When the upper fixed calibration level (13.7 - 14.2 V) is reached it charges the battery and supplies the system.The Body Computer checks the efficiency of the alternator recharging system by detecting two parameters: the voltage signal coming from terminal D+ of the actual alternator and the engine rpm signal received on the CAN from the engine management control unitAt the key-on as long as the voltage is below around 5.5 V, the Body Computer signals the insufficient recharging state; when the voltage exceeds 5.5 V, the warning light goes out; if, on the other hand, with the engine moving (speed above 700 rpm), the voltage decreases below the level of 4.5 V, then the warning light comes on constantly accompanied by the display of a message.

BATTERY

SPECIFICATIONS

The main specifications of the batteries used on new models are the active material support plates produced thanks to the calcium lead production technology that has replaced the older antimony lead one.This involves a mechanical stretching process with a continuous lead band resulting in the final production of the grid spread with lead oxide for the positives and metallic lead only for the negatives, rather than the use of casting machines for producing grids through fusion.The use of materials such as lead-calcium-tin alloy guarantees a considerable reduction of the phenomenon of electrolysis in the operation of the accumulator (dissociation of the water into is hydrogen and oxygen components) and the quality of the gases that can escape thereby causing less evaporation of the actual water with a consequent drastic reduction in the maintenance required for this type of battery.
1 - Cover2 - Plug lip3 - Positive plate4 - Negative plate5 - Separator6 - Bridges7 - Electrolyte8 - Water gauge9 - Negative pole10 - Monobloc11 - Maximum electrolyte level12 - Minimum electrolyte level13 - Plug

Battery electrical specifications

Reduced maintenance type lead accumulator with acidCover: EURODIN, fitted with closing devices on ramp type cover; pressure plugs (one plug per element) with system to prevent penetration of fluids from the outside. Gas evacuation through plugs equipped with gas/liquid separation system.Cover sealing: thermowelding.Attachment to the base: standardized on four sides.Poles: lead bushes produced by cold pressing with seal in the pressing area on the cover.Electrolyte level check: via the openings in the cover plugs, checking the consistency between the indicator (dipstick) and the level of the electrolyte. The dipstick indicates the maximum permitted level, therefore the electrolyte should barely come into contact with the lower end of the dipstick. The minimum level is reached when the electrolyte exceeds the top of the separators and/or the plates by 10 mm.Water gauge for checking minimum electrolyte level and battery charge.No. of plates: 6 positive + 5 negative.Grid alloy: lead-calcium-tin.Separator thickness: 1.15 mm.Plate thickness: positive 1.80 mm; negative 1.60.Electrolyte density: 1280 ± 10 g/dm3 at 25°C with battery 100% charged.

Electrolyte density at 25° Celsius:

  • 1280 g/litre 100 % charged
  • 1240 g/litre 75 % charged
  • 1200 g/litre 50 % charged
  • 1160 g/litre 25 % charged
  • 1120 g/litro run down
  • 1110 g/litre completely run down.

CONTROL SYSTEM

The battery is fitted with an indicator for checking the charge which a water gauge that makes it possible to monitor the quality of the electrolyte level and the state of charge of the battery; this also allows the customer to make an initial check on the efficiency of the battery.This device comprises a transparent plexiglas cylinder: one end contains a gauge fastened to the cover of the battery; at the other end there is a drip tray, made from an acid-resistant material, drilled to allow contact between the battery electrolyte and a green coloured ball, housed in the drip tray, that can slide along a plane tilted towards the centre of the cylinder.The colour of the gauge provides information on the state of the battery charge as summarized in the table below:
CONDITION 3CONDITION 2CONDITION 1
Information visibleLight, bright colourDark colour without green area in the middleDark colour with green area in the middle
Electrolyte levelBelow minimumCorrectCorrect
Charge statusIndefiniteBattery run downbetween 55% and 100%
Action to be takenTop up electrolyte with distilled waterRecharge batteryNo action

This device:

  • does not provide information concerning any possible internal short circuits;
  • the density of the electrolyte varies with the temperature;
  • if the vehicle is stationary for a prolonged period this could have halted the mixing process of the reagents and therefore the measurement might only refer to the surface layers;
  • if the electrolyte level is low, the readings are not reliable.
In conclusion, the measurement is accurate to within 15% (charge status gauge reading = 70% ± 15%).On account of this degree of error in the reading, the battery charge should be checked more accurately at the Service Centre.

Plug

In reduced maintenance type batteries with lead-calcium-tin elements the seal is guaranteed by pressure plugs with an anti-penetration system and a device that evacuates gases through the actual plugs.

The plug allows the escape of gases produced in the battery, preventing however the loss of liquid. The plugsconsists of:

  • The plug body: it acts primarily as an obstacle to the liquids, but allows the escape of gases via special openings.
  • The labyrinth: prevents the particles that are released during the operation of the battery from blocking the special diaphragm.
  • The semi-permeable diaphragm: thanks to a special PTFE layer (polytetrafluoroethylene) it prevents the escape of the liquid allowing, however, the gases that are produced during the normal operation of the battery to pass through.
1 - Plug body2 - Labyrinth3 - Membrane

BATTERY DISCHARGE AT REST

During the design stage, the correct dimensions of the battery for every model/trim level also take into account the absorption from loads when the ignition is switched off.These absorptions should not exceed 0.6 mA for every Ah of battery capacity; this condition is adopted to guarantee that, after the vehicle has been stationary for a month with all the loads that are not ignition-dependent on, the residual capacity of the battery is half of the rated capacity, corresponding to a charge status that can guarantee starting in normal ambient temperature conditions.The table below contains several examples.
BatteryMax. absorption
40 Ah24 mA
50 Ah30 mA
60 Ah36 mA

Battery fluid level check/top up

Undo the plugs on the battery cover, or remove the plug cover (2) and release the plugs which are a press fit in each individual cell.In the max level condition (11) the electrolyte should barely come into contact with the lower end of the dipstick (3) located inside the battery and visible via the openings in the cover for each cell producing the so-called "meniscus effect".In the min level condition (12) the electrolyte should exceed the top end of the separators and/or the plates by about 10 mm.
1 - Cover2 - Plug lip11 - Maximum electrolyte level12 - Minimum electrolyte level13 - Dipstick14 - PlugTo check this condition the clean stick made from a non metallice material (e.g. wood, glass, plastic) should be immersed in the electrolyte until it touches the top of the separators and/or the plates measuring the height of the electrolyte reserve.It is understood that in order to measure the level of the electrolyte, the battery should be on a flat surface and all the cells should be visible from above; if this is not the case because it is not possible, the battery should be removed from the vehicle.The operations of checking the electrolyte level and, if necessary, topping it up through the individual openings for the battery cells, should not be carried out by the Customer, but by
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