4HP-60HP Mercury Outboard Rectifier / Regulator. Serial Number. Rectifier/Regulator Kit for Mercury Outboards Replaces: CDI # 194-2115K 1; Mercury #s 830179T 1, 830179T 2, 854515T 2, 883072T 1, 883072T 2, 893640-002; Mallory #. SERIAL 0005579 Qty Required For Repair: 2 Minimum Order Qty: 5. Page 1 of 2 - John Deere 110 Charging System - posted in John Deere Tractor Forum: Im new here, thanks to anyone who can help. I have owned my 1971 John Deere 110 serial number 255190M (engine K181S) for 33 years. I am bringing it back to life after several years of no use, and I cant get the charging system working. I am burning out rectifiers. They work for 5 seconds when the tractor starts. Find 3/10 Rectifier & Regulator Assembly - 0585195 here. 2 In Stock - Ships Immediately. Offering discount prices on OEM Johnson/Evinrude, OMC parts for over 50 years.

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The next and the last stage before load, in a power supply system is the Regulator part. Let us now try to understand what a regulator is and what it does.

The part of electronics that deal with the control and conversion of electric power can be termed as Power Electronics. A regulator is an important device when it comes to power electronics as it controls the power output.

Need for a Regulator

For a Power supply to produce a constant output voltage, irrespective of the input voltage variations or the load current variations, there is a need for a voltage regulator.

A voltage regulator is such a device that maintains constant output voltage, instead of any kind of fluctuations in the input voltage being applied or any variations in current, drawn by the load. The following image gives an idea of what a practical regulator looks like.

Types of Regulators

Regulators can be classified into different categories, depending upon their working and type of connection.

Depending upon the type of regulation, the regulators are mainly divided into two types namely, line and load regulators.

  • Line Regulator − The regulator which regulates the output voltage to be constant, in spite of input line variations, it is called as Line regulator.

  • Load Regulator − The regulator which regulates the output voltage to be constant, in spite of the variations in load at the output, it is called as Load regulator.

Depending upon the type of connection, there are two type of voltage regulators. They are

  • Series voltage regulator
  • Shunt voltage regulator

The arrangement of them in a circuit will be just as in the following figures.

Let us have a look at other important regulator types.

Zener Voltage Regulator

A Zener voltage regulator is one which uses Zener diode for regulating the output voltage. We have already discussed the details regarding Zener diode in BASIC ELECTRONICS tutorial.

When the Zener diode is operated in the breakdown or Zener region, the voltage across it is substantially constant for a large change of current through it. This characteristic makes Zener diode a good voltage regulator.

The following figure shows an image of a simple Zener regulator.

The applied input voltage $V_i$ when increased beyond the Zener voltage $V_z$, then the Zener diode operates in the breakdown region and maintains constant voltage across the load. The series limiting resistor $R_s$ limits the input current.

Working of Zener Voltage Regulator

The Zener diode maintains the voltage across it constant in spite of load variations and input voltage fluctuations. Hence we can consider 4 cases to understand the working of a Zener voltage regulator.

Case 1 − If the load current $I_L$ increases, then the current through the Zener diode $I_Z$ decreases in order to maintain the current through the series resistor $R_S$ constant. The output voltage Vo depends upon the input voltage Vi and voltage across the series resistor $R_S$.

This is can be written as

Serial Number Perspective Rectifier RegulatorCar

Serial Number Perspective Rectifier Regulator Diagram

$$V_o=V_{in}-IR_{s}$$

Where $I$ is constant. Therefore, $V_o$ also remains constant.

Case 2 − If the load current $I_L$ decreases, then the current through the Zener diode $I_Z$ increases, as the current $I_S$ through RS series resistor remains constant. Though the current $I_Z$ through Zener diode increases it maintains a constant output voltage $V_Z$, which maintains the load voltage constant.

Case 3 − If the input voltage $V_i$ increases, then the current $I_S$ through the series resistor RS increases. This increases the voltage drop across the resistor, i.e. $V_S$ increases. Though the current through Zener diode $I_Z$ increases with this, the voltage across Zener diode $V_Z$ remains constant, keeping the output load voltage constant.

Case 4 − If the input voltage decreases, the current through the series resistor decreases which makes the current through Zener diode $I_Z$ decreases. But the Zener diode maintains output voltage constant due to its property.

Limitations of Zener Voltage Regulator

There are a few limitations for a Zener voltage regulator. They are −

  • It is less efficient for heavy load currents.
  • The Zener impedance slightly affects the output voltage.

Hence a Zener voltage regulator is considered effective for low voltage applications. Now, let us go through the other types of voltage regulators, which are made using transistors.

Transistor Series Voltage Regulator

This regulator has a transistor in series to the Zener regulator and both in parallel to the load. The transistor works as a variable resistor regulating its collector emitter voltage in order to maintain the output voltage constant. The figure below shows the transistor series voltage regulator.

With the input operating conditions, the current through the base of the transistor changes. This effects the voltage across the base emitter junction of the transistor $V_{BE}$. The output voltage is maintained by the Zener voltage $V_Z$ which is constant. As both of them are maintained equal, any change in the input supply is indicated by the change in emitter base voltage $V_{BE}$.

Hence the output voltage Vo can be understood as

$$V_O=V_Z+V_{BE}$$

Working of Transistor Series Voltage Regulator

The working of a series voltage regulator shall be considered for input and load variations. If the input voltage is increased, the output voltage also increases. But this in turn makes the voltage across the collector base junction $V_{BE}$ to decrease, as the Zener voltage $V_Z$ remains constant. The conduction decreases as the resistance across emitter collector region increases. This further increases the voltage across collector emitter junction VCE thus reducing the output voltage $V_O$. This will be similar when the input voltage decreases.

When the load changes occur, which means if the resistance of the load decreases, increasing the load current $I_L$, the output voltage $V_O$ decreases, increasing the emitter base voltage $V_{BE}$.

With the increase in the emitter base voltage $V_{BE}$ the conduction increases reducing the emitter collector resistance. This in turn increases the input current which compensates the decrease in the load resistance. This will be similar when the load current increases.

Number

Limitations of Transistor Series Voltage Regulator

Transistor Series Voltage Regulators have the following limitations −

  • The voltages $V_{BE}$ and $V_Z$ are affected by the rise in temperature.
  • No good regulation for high currents is possible.
  • Power dissipation is high.
  • Power dissipation is high.
  • Less efficient.

To minimize these limitations, transistor shunt regulator is used.

Transistor Shunt Voltage Regulator

A transistor shunt regulator circuit is formed by connecting a resistor in series with the input and a transistor whose base and collector are connected by a Zener diode that regulates, both in parallel with the load. The figure below shows the circuit diagram of a transistor shunt regulator.

Working of Transistor Shunt Voltage Regulator

If the input voltage increases, the $V_{BE}$ and $V_O$ also gets increased. But this happens initially. Actually when $V_{in}$ increases, the current $I_{in}$ also increases. This current when flows through RS, causes a voltage drop $V_S$ across the series resistor, which also gets increased with $V_{in}$. But this makes $V_o$ to decrease. Now this decrease in $V_o$ compensates the initial increase maintaining it to be constant. Hence $V_o$ is maintained constant. If the output voltage decreases instead, the reverse happens.

If the load resistance decreases, there should be decrease in the output voltage $V_o$. The current through the load increases. This makes the base current and collector current of the transistor to decrease. The voltage across the series resistor becomes low, as the current flows heavily. The input current will be constant.

The output voltage appears will be the difference between the applied voltage $V_i$ and the series voltage drop $V_s$. Hence the output voltage will be increased to compensate the initial decrease and hence maintained constant. The reverse happens if the load resistance increases.

IC Regulators

Voltage Regulators are now-a-days available in the form of Integrated Circuits (ICs). These are in short called as IC Regulators.

Along with the functionality like a normal regulator, an IC regulator has the properties like thermal compensation, short circuit protection and surge protection which are built into the device. Dims software free for pc.

Types of IC regulators

IC regulators can be of the following types −

  • Fixed Positive voltage regulators
  • Fixed Negative voltage regulators
  • Adjustable voltage regulators
  • Dual-tracking voltage regulators

Let us now discuss them in detail.

Fixed Positive Voltage Regulator

The output of these regulators is fixed to a specific value and the values are positive, which means the output voltage provided is positive voltage.

The most used series is 7800 series and the ICs will be like IC 7806, IC 7812 and IC 7815 etc. which provide +6v, +12v and +15v respectively as output voltages. The figure below shows the IC 7810 connected to provide a fixed 10v positive regulated output voltage.

In the above figure, the input capacitor $C_1$ is used to prevent unwanted oscillations and the output capacitor $C_2$ acts as a line filter to improve transient response.

Fixed Negative Voltage Regulator

The output of these regulators is fixed to a specific value and the values are negative, which means the output voltage provided is negative voltage.

The most used series is 7900 series and the ICs will be like IC 7906, IC 7912 and IC 7915 etc. which provide -6v, -12v and -15v respectively as output voltages. The figure below shows the IC 7910 connected to provide a fixed 10v negative regulated output voltage.

In the above figure, the input capacitor $C_1$ is used to prevent unwanted oscillations and the output capacitor $C_2$ acts as a line filter to improve transient response.

Adjustable Voltage Regulators

An adjustable voltage regulator has three terminals IN, OUT and ADJ. The input and output terminals are common whereas the adjustable terminal is provided with a variable resistor which lets the output to vary between a wide range.

The above figure shows an unregulated power supply driving a LM 317 adjustable IC regulator which is commonly used. The LM 317 is a three terminal positive adjustable voltage regulator and can supply 1.5A of load current over an adjustable output range of 1.25v to 37v.

Dual-Tracking Voltage Regulators

A dual-tracking regulator is used when split-supply voltages are needed. These provide equal positive and negative output voltages. For example, the RC4195 IC provides D.C. outputs of +15v and -15v. This needs two unregulated input voltages such as the positive input may vary from +18v to +30v and negative input may vary from -18v to -30v.

The above image shows a dual-tracking RC4195 IC regulator. The adjustable dual-tacking regulators are also available whose outputs vary between two rated limits.

About Rick's Honda Regulator Rectifier

Serial Number Perspective Rectifier Regulator System

Why the Honda Regulator Rectifier is Important

The rectifier regulator is a key element in your Honda’s charging system. Many older vehicles, such as your Honda, relied on older field-excited charging circuits that utilized a separate rectifier and regulator. Rick’s Motorsport Electrics has developed a part that merges the two outdated components into a single solid-state device with modern technology.

Additional Tips for installing Rick’s Part# 10-100

Connecting the regulator - the 3 single wires with spade terminals are meant to be plugged in at the same location as the color coded wires going to the OE regulator.

Connecting the rectifier - Disconnect the 6-position, 5 wire connector from the OE rectifier & plug the identical connector on the 10-100 in its place.

Kohler Rectifier Regulator

Excerpted from a CB750/550 Wiring Diagram

The 10-100 regulator is connected to the harncss via the 3 single wires with spade terminals (these plug into the wires that originally were going to the tabs on the OE regulator). The color code remains the same. The 10-100 rectifier plugs into the harness at the same location as the OE rectifier.

Your charging system should end up matching this diagram

Rick’s Motorsport makes a variety of parts for your vintage bikes - check them out here!

Voltage Regulator Rectifier Test

Fits Honda Year + Models

Rick's Honda Regulator Rectifier Model #10-100 will replace all of these Honda Motorcycle Models

Serial Number Perspective Rectifier Regulator Replacement

1972 CB350F Supersport
1973 CB350F Supersport
1974 CB350F Supersport
1975 CB400F
1976 CB400F
1977 CB400F
1971 CB500K
1972 CB500K
1973 CB500K
1975 CB550F
1976 CB550F
1977 CB550F
1974 CB550K
1975 CB550K
1976 CB550K
1977 CB550K
1978 CB550K
1975 CB750F Supersport
1976 CB750F Supersport
1977 CB750F Supersport
1978 CB750F Supersport
1969 CB750K SOHC
1970 CB750K SOHC
1971 CB750K SOHC
1972 CB750K SOHC
1973 CB750K SOHC
1974 CB750K SOHC
1975 CB750K SOHC
1976 CB750K SOHC
1977 CB750K SOHC
1978 CB750K SOHC