Electronic Engine Performance Controller

TPS-Based WCB Controller With Peak Supression


This circuit is one of several designs based on the Electronic Engine Performance Controller concept.  It is important to read the Basic Design page first, or you will probably have trouble understanding some of the terms I am using.  Be sure to read the entire contents of these pages.
 

Description

This circuit is a four-stage wastegate control bleed (WCB) controller with boost peak supression, although not all four bleed controllers have to be implemented.  Four solenoids are required if all four stages are to be implemented (3 for the boost stages and 1 for the peak supressor).  The peak supression greatly reduces the boost peak problem at high boost, but is not as effective as using wastegate control valves (WCVs).

This design uses all four comparators in the LM339.  All four of them are configured as positive response circuits, 3 of which are used as the TPS stages.  The forth is used for boost peak supression.  Here is what the schematic looks like:


(click here for the full image)

Theory Of Operation

The way the comparators work has already been discussed, but here I will explain why the various compnents are there:

R1 - R4: These are the reference voltage adjustments.
R5, D1: These provide the 5.1V reference voltage.  A 270 ohm R5 provides about 11mA of current, which is more than enough for 4 comparator references.  If your circuit has many more comparators or uses different pots (R1-R4), you may need to drop the value of R5 to increase the supply current, but each comparator and reference (if 47k pots are used) only requires about 0.4mA of current.
R7 - R10: These are in place to limit the input current to the comparator so that some feedback can be provided for hysteresis
R11 - R14: These are the feedback resistors that provide hysteresis to each comparator to prevent oscillation when the input voltage is very close to the reference voltage.  With R7-R10 set to 10k and R11-R14 set to 1M, the total hysteresis is about 81.2mV (0.0812V), which is small enough to still provide very good response.  If your input signal is noisey and the comparator oscillates, you can decrease value of the feedback resistor to increase the hysteresis voltage.
R15 - R16: These are used in conjunction with D2-D5 as input signal protection.
R17 - R20: These are used to limit the base current of the driver transistors.  If you are using a different transistor other than TIP120, then you may need to adjust the values of these.
C1:  This is a filter capacitor that is used to keep the LM339 chip from oscillating due to noise on the power supply.  Each LM339 chip has to have its own filter capacitor and it should be put very close to the Vcc pin (pin 3).
C2, C3: These are used to assist the 7808 regulator is maintaining a very stable output voltage.  C2 suppresses high frequency noise while C3 acts as a reserve current source for improved regulator transient response.
D2 - D5: These are used in conjunction with R15-R16 to prevent the input signal voltage from going below ground or above Vcc.
D6 - D9: These are used to suppress the lash-back current from the solenoids.
Q1 - Q4: These are the driver transistors for the solenoids.  They are NPN-type and are setup in an open-collector configuration.  When a comparator turns a solenoid on, the output (collector) of the transistor provides ground to the solenoid.
U1a - U1d: These are the comparators within the LM339 chip.  I recommend using a DIP-14 socket when building the circuit
U2: This is the 8V regulator, a 7808 is recommended.  For power supply alternatives, see the EEPC: Basic Design page.
 

Parts

You will need to decide what kind of project cases, wire, and connectors to use, depending on which setup you choose.  I have designed these circuits so that the part can be purchased at your local Radio Shack, but I recommend purchasing them through another dealer, such as Mouser or Digikey for better prices.  Use the industry part numbers or descriptions when ordering from one of these other suppliers.  The Radio Shack catalog part numbers have also been provided, if you choose to go that route.  Keep in mind the Radio Shack tends to package their parts in fixed quantities, so you will end up with extra parts.  The number of packages you need depends on the quanity inside, so keep track of this.  Also, if you modified the design at all, this list will not be correct (obviously).
 
 
Ref # Industry Part # or Desc. Radio Shack
R1-R4 47k ohm trim pot 271-283
R5 270 ohm, 1/4 watt, 5% resistor 271-1314
R7-R10 10k ohm, 1/4 watt, 5% resistor 271-1335
R11-R14 1M ohm, 1/4 watt, 5% resistor 271-1356
R15-R16 1k ohm, 1/4 watt, 5% resistor 271-1321
R17-R20 470 ohm, 1.4 watt, 5% resistor 271-1317
C1 0.1uF, 50V, monolithic capacitor 272-1069
C2 0.22uF, 50V, monolithic capacitor 272-1070
C3 1uF, 35V, tantalum capacitor 272-1434
D1 1N4733 - 5.1V, 1 watt zener diode 276-565
D2-D5 1N4148 - 75PIV, switching diode 276-1122
D6-D9 1N4001 - 50PIV, 1A (30A surge) diode 276-1101
Q1-Q4 TIP120 - med-power NPN transistor 276-2068
U1 LM339 - quad comparator 276-1712
for U1 DIP-14 IC socket, dual wipe, 0.300 spacing 276-1999
U2 7808 - +8VDC fixed voltage regulator RSU 11468972

Testing

Before calibrating the circuit, you should test out the power supplies, inputs, and outputs.  This is only possible if you installed a socket for the LM339 chip (U1).
  1. With the LM339 chip removed from the socket, connect the circuit 12V and ground connections to a 12VDC power source.
  2. Using a voltmeter, test the output of your 8V regulator.  If you used a 7808, it should be very close to 8.0V.  If you used the zener method, it should be close to 8.2V.
  3. Test the output of your 5V reference voltage.  It should be close to 5.1V.
  4. Put the positive lead of your voltmeter to pin 3 of the socket and the negative lead to pin 12 of the socket.  You should measure 8V.
  5. Test the reference outputs by measuring the voltage at pins 4, 6, 8, and 10 of the U1 socket.  You should be able to vary them between about 0V to about 5V by turning their respective trim pots.
  6. Test the inputs by putting a 0 - 8 test voltage on each input connection.  When the test voltage is on the TPS input, you should be able to detect it at pins 5, 7, and 9 of the U1 socket.  When it is on the MAP sensor input, you should be able to detect it at pin 11 of the U1 socket.
  7. Connect a 12V test device on one of the circuit outputs.  A relay, solenoid, or low-current 12V lamp will work.  Connect 12V to one side of the device and the output of the circuit to the other side.
  8. Test the output transistor by applying 8VDC to the respective output pin (2, 1, 14, or 15).  The test device should activate.
If your circuit has passed all of these tests, then it is probably functioning properly.  Disconnect the power to the circuit and install the LM339 chip in the socket (if you have one).  Follow this procedure to test out the entire circuit:
  1. Connect the circuit 12V and ground connections to a 12VDC power source.
  2. Apply about a 2.5V test voltage to the TPS signal input connection.
  3. Connect your output test device (a relay, solenoid, or low-current 12V lamp will work) to output 1 of the circuit.
  4. Adjust the corresponding trim pot (R1, in this case) to change the reference voltage for that comparator.  When the reference voltage id above the input test voltage, the output should be off.  When it is below the test voltage, the output should be on.
  5. Repeat steps 3 and 4 for each of the four outputs, remembering that you have to put the test voltage on the MAP sensor input for the 4th one.
If your circuit passed this test, then it is ready to calibrate!
 

Calibration

You now need to set the reference voltages to the desired values.  See the Multi-Stage Wastegate Control Bleed Using The EEPC page for details on how to do this.
 
 
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This page is maintained by Russell W. Knize and was last updated 04/20/99. Comments? Questions? Email minimopar@myrealbox.com.

Copyright © 1996-2003 Russ W. Knize