Fuel Injector Clinic® GM (06-15) LS3/LS7/LSA/L76/L92/L99 High-Z Fuel Injector Set (8)
Fuel Injector Clinic® GM (06-15) LS3/LS7/LSA/L76/L92/L99 High-Z Fuel Injector Set (8)
Fuel Injector Clinic® GM (06-15) LS3/LS7/LSA/L76/L92/L99 High-Z Fuel Injector Set (8)
Fuel Injector Clinic® GM (06-15) LS3/LS7/LSA/L76/L92/L99 High-Z Fuel Injector Set (8)
Fuel Injector Clinic® GM (06-15) LS3/LS7/LSA/L76/L92/L99 High-Z Fuel Injector Set (8)
Fuel Injector Clinic® GM (06-15) LS3/LS7/LSA/L76/L92/L99 High-Z Fuel Injector Set (8)
Fuel Injector Clinic® GM (06-15) LS3/LS7/LSA/L76/L92/L99 High-Z Fuel Injector Set (8)
Fuel Injector Clinic® GM (06-15) LS3/LS7/LSA/L76/L92/L99 High-Z Fuel Injector Set (8)

IS303-0540H

Fuel Injector Clinic® GM (06-15) LS3/LS7/LSA/L76/L92/L99 High-Z Fuel Injector Set (8)

Regular price$625.00
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    Compatible: (6.2L/7.0L)

    2010 - 2015 Chevy Camaro

    2006 - 2013 Chevy Corvette

    2008 - 2013 Chevy Silverado

    2008 - 2013 GMC Sierra

     








     

    What is Fuel Injector Clinic’s Data Match Technology?

    Fuel Injector Clinic’s Data Match Technology is used to create a very comprehensive information sheet, which customers receive with each injector set*. It provides the most complete flow matching and latency value information available in the industry, featuring dynamic slope flow rates and individual latency deviation values.

    • Data Match Flow Sheet Sample, click image for larger view
    •         Example of DMT Flow sheet

    When Fuel Injector Clinic’s Data Match Technology information is correctly input into your Electronic Control Unit (ECU), the data will allow the ECU to dictate PRECISELY the right amount of fuel to combine with the air in your intake port to consistently achieve the correct Air/Fuel Ratio (AFR), which means you’ll get more complete combustion in your combustion chambers.

    Fuel Injector Clinic has developed a specialized flow bench in collaboration with ECMTuning, Inc., which accurately measures the microscopic volume of fluid dispensed while it is being operated by a car’s ECU. This method provides tuners with the best possible injector data to successfully tune their cars.

    The Data Match Technology information sheet provided with each set of Fuel Injector Clinic injectors matched using this method gives you three sets of very important data:

    1. Dynamic Slope Flow Rate for each individually serial numbered injector,
    2. Individual Injector Offset Values for each serial numbered injector in your set,
    3. Injector Voltage Offset table.


    1. Dynamic Slope Flow Rate for each individually serial numbered injector.

    This slope flow rate, expressed in cc/min at the pressure and temperature listed on the sheet, represents the linear flow rate that the ECU can use when calculating the pulse width (length of time to open) it needs to send to the injector. Since the ECU typically only accepts one value for all injectors, it is clear how important it is that this flow rate is as consistent as possible from one injector to another. The “Dynamic Slope Flow” box of the flow sheet shows how well matched your injectors are. To get the most accurate results, you will typically use the “Average Slope flow value” below the individual data to input into your ECU.

    The individual slope flow data represented in this table is calculated from at least 1,000 pulses per injector, making Data Match Technology the most detailed information provided by any performance injector company at this time.

    NOTE: Testing for these values is done at 3 Bar (43.5psi) using 16B calibration fluid at 90°F (a fluid with similar specific gravity to gasoline, which is widely used in the automotive industry as a “safe” testing fluid closely resembling gasoline.) If you run a different base pressure or a different fuel, you would need to adjust the flow rate in your tuning software accordingly. (More on flow rate can be found in our tech information.)

    2. Individual Injector Offset Values for each serial numbered injector in your set.

    The offset value (often referred to as the dead time, lag time, or latency value) is used by the ECU to compensate for the loss of flow during the opening and closing period of each pulse, where full (aka constant or linear) flow has not been achieved. While the numerical values needed for data entry in the ECU are listed in the “Injector Voltage Offset” table at the bottom of the Data Match Technology information sheet, the accurate matching of this characteristic for each injector ensures that the ECU, which uses only one correction value for all injectors, is able to instruct the injectors to dispense exactly the right amount of fuel.

    WHY? While offset matching will improve the result with all injectors, it is especially critical for injectors with a large flow rate (for example1000cc and larger) at idle or light throttle. This is because the offset correction length applied by the ECU represents a much higher percentage of total pulse width, so any error is greatly amplified.

    For example, a 2150cc injector may need a 1.1msec total pulse width to dispense the right amount of fuel at idle, of which 0.7msec is the offset correction at 13 volt, resulting in an effective pulse width of 0.4msec. If there is a 0.2msec difference in offset value from one injector in that set to another, the effective pulse width could vary by 0.2msec/0.4msec=0.5 or 50% within the same set, which would easily cause enough variation in AFR to result in a misfire. Using the same variance in a smaller injector, like a 650cc, which requires a 2.3msec pulse width and has a 1.0msec offset value, results in an effective pulse width of 1.3msec. If the 650cc injector set has the same 0.2msec variance from one injector to another as the 2150cc injector in the example above, it is only a 15% fueling error, which is much easier for the motor to forgive.

    Also at play is the fact that in large performance injectors the effective pulse width range you are operating in (0.3 to 0.8msec) is SO short that the injector is only performing an incomplete valve opening, which is an action that is much more challenging to repeat consistently than the fully settled opening at 6 or 7msec. Therefore a well-matched injector set is easy to tune and performs well in idle, cranking and other light throttle conditions.

    3. Injector Voltage Offset table.

    The bottom of the Data Match Technology information sheet lists average offset values for the type of injector you purchased. This data is very time consuming to collect because it requires our injector technicians to perform detailed offset testing at all the voltages and pressures listed (typically five voltages and five pressures.) A test at one voltage and one pressure is derived from test data accumulated from pulsing the injector hundreds of times at 0.5msec intervals from 2msec to 18msec (10% to 90% duty cycle at 6000rpm), representing almost 10,000 data points. (See the four graphs below of this level of testing with even more detail in low pulse width area). You can’t just do this for one injector, it must be representative of the whole spectrum of injectors. So Fuel Injector Clinic tests a minimum of 16 injectors in order to collect a good average. Multiply the 16 injectors by the 25 voltage and pressure combinations in your offset table and you can see why this 4,000,000 point process is not for the faint of heart.

    Bottom line: Fuel Injector Clinic provides more in depth data with each injector set than any other company in the aftermarket performance industry. The method by which we gather and present data as well as characterize injectors is at the forefront of the industry.

    So when you’re studying your Data Match Technology information sheet, keep in mind that what may appear to be a simple excel spreadsheet of injector data, or a simple drop-down selection of base map inputs from an ECU manufacturer (that we may well have supplied), is actually the result of a highly technical and time-consuming process where enormous amounts of data are amassed. And, Fuel Injector Clinic’s investment in our proprietary Data Match Technology works for you every time you run your car.

    Information for ALL graphs shown.

    X-axis:

    • Effective pulse width in milliseconds. Most ECU’s are programmed in either milliseconds (msec = 1/1,000th of a second) or microseconds (µsec = 1/1,000,000th of a second)
    • The four lines (red, black, green and yellow) on the graphs have been corrected for the offset measured on each injector, therefore showing the linear approximations going through the origin (zero). This is done to bring the injector graphs closer together for visual benefit.

    Y-axis:

    • Injector flow in cc/min. This is a calculated value based on flow per injector stroke converted back to cc/min flow assuming a 6000rpm pulse rate. This is done to represent flow values in units most familiar to tuners. We can easily provide the flow per stroke values for interested tuners, since you do not idle your car at 6000rpm.

    The four different Fuel Injector Clinic (FIC) injectors shown are all latest-technology Bosch high impedance injectors driven by a saturated injector driver from a recent model Mitsubishi ECU.


    Information Specific to individual graphs

     

    Zoom 1 of 4
    This graph shows the full range of the injector being pulsed in a motor at 6000rpm or 50Hz, where a 20ms second pulse would represent 100% duty cycle, taking up all the time available for two revolutions of the motor (assumes a 4-stroke motor application for the injector).

    The other graphs below zoom in on the low pulse width area to show why this is the most challenging condition for an injector.

    Injector flow from pulse widths between 0.8msec and 18msec (shaded in gray) is the linear portion of injector operation (Note how the lines - red, black, green and yellow - in this section are basically straight slopes.)

    Zoom 2 of 4
    This graph shows effective pulse widths from 0 to 5 milliseconds.

    The opening “bumps” in the initial operating range of the injector (far left) are clearly identifiable.

    The two black horizontal lines (30 and 60 on the y axis) are approximate fuel consumption at idle and light cruise throttle for a 4 cyclinder engine on gasoline. Note how the two smaller injectors operate in their linear operating range between the idle and cruise lines, whereas the 1100cc/min (black) is a little “bumpy” in that area and the 2150cc/min (red) is clearly in the non-linear area

    Also note how the data points progressively become closer together from right to left as the non-linear operating range is approached. On the right data points are every 0.5 msec, in the center section data points are every 0.1msec and on the left the data points are still too close to define at this zoom level.


    Zoom 3 of 4
    This graph shows effective pulse widths from 0 to 2.5 milliseconds.

    Here there is more detail between the idle and cruise lines . It becomes increasingly obvious why the smaller injectors are much easier to tune based on their very linear operation in this area.
    The 1100cc/min injector still has a reasonably linear operating range in the idle and just above idle pulse width range. While there are some non-linear “bumps,” the variations are likely small enough not to be detectable by the tuner.

    The 2150cc/min injector graph clearly shows how non-linear the operation of an injector of this size is in the area between idle and cruise. While this is obviously not beneficial to tuning a motor, it should be noted that ALL types and brands of large (approximately 1200cc/min and larger) injectors face this issue, since it is related primarily to the flow size of the injector, and the extremely short pulse width required for the minute amounts of fuel required at idle.


    Zoom 4 of 4
    This graph shows effective pulse widths from 0 to 0.8 milliseconds.

    This is an extreme level of detail shown, since we are now able to discern individual data points at close as 0.004msec (or 4 msec = 4/1,000,000th of a second).

    Clearly visible are the “bumps” for all injectors. The “bumps” are made by the valve reaching its maximum opening limit (where the line peaks on the graph) and then bouncing back from hitting the limit (where the line makes a downward slope, creating the valley).

    While these non-linear flow areas of the injector are not very conducive to the matching process, Fuel Injector Clinic includes some of this data to help make the injectors work better for the tuner in this area. Looking at the 1100cc/min injector graph (black) note how the valve bounces a few times until the flow settles into its linear range as the pulse width length is extended. Note that this graph is zoomed to the 0.25 to 0.8millisecond range, or around 4% (very small part) of the 19ms total operating range.

     



    *Data Match Technology information sheet is currently limited to all high impedance injectors 900cc/min and larger due to the the additional cost for little benefit in smaller injector sizes.

     

    The tabled injector data provided in the excel sheet that you can download by following the link on the right are customized to be used by EFI Live software in the OE GM ECU’s. 

    We have spent many hours to convert our standard injector offset and flow data provided with every set into this format for your ease of use, so we hope that it makes our injectors a popular choice for you, and your customers if you are a tuner or performance shop!

    There are a few notes that we would like to highlight when using these tables.

    1.       You need to make sure you choose the correct table for the size of injector that you are using. i.e. 850cc, 1000cc, 2150cc, etc. * See note below on our injector flow sizes

    2.       You need to know exactly which version of ECU and/or software you are using, so that you use the correct table.

    3.       If you are choosing an injector larger than the maximum values allowed in the GM ECU software, you will need to scale not only the injector values, but various others to accommodate the larger injectors. While we have provided the option to scale the injector’s settings in the attached excel sheet, we assume that you fully understand the concept of scaling the injectors if you choose to use this feature. 

    4.       We would also like to point out that there are various sections of these injector data tables that will never be used by the ECU, or areas where the injector will no longer operate, so we have chosen either generic values or 0 values in these areas that may display in an odd way when you input them and/or see them displayed on 3D graphs, as is common in the HP tuners software. Please do not be alarmed when you see these values, and if you are concerned with what you see, please feel free to call or email us, and we will explain how we arrived at the values entered.

    5.       Please realize that the values in the tables are carefully chosen from data for a median set. What that means is that we will have tested a large group of injectors (usually 50 or more) and then picked a set in the middle of that group, then tested that complete set through the range of pressures and voltages listed in the OE GM tables and then populated the attached tables based on the average values of that median set of injectors.
    Important for you to note is that the values in the attached tables are averages, and that the set you receive may need small adjustments to correct the values for your particular set.

     

    *Please note that all our listed injector flow sizes are rated at 43.5psi (3 bar) so that you always know which injector flows more than another, across all brands of cars, some of which run 43.5psi OE fuel pressure, others, like many of the GM cars run 58psi (4 bar) fuel pressures – e.g. Our 1100cc/min or 105lb/hr is rated at 43.5psi, which would equate to 1270cc/min or 121 lb/hr at 58psi.
    All values listed in the tables attached assume you are running the OE GM 58psi system when applicable. You are NOT required to adjust any of the provided data because of our policy to list flow sizes at 43.5psi when advertising our injectors for sale.

     

    EFI Live Data for our 365cc/min Injector

    EFI Live for FIC 365cc Injectors

    HP Rating

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 354.57
    WHP on Gas at 58psi 90%DC Turbo 409.53
    WHP on E85 at 43.5psi 90%DC Turbo 272.75
    WHP on E85 at 58psi 90%DC Turbo 315.02
    WHP on Gas at 43.5psi 90%DC NA 425.49
    WHP on Gas at 58psi 90%DC NA 491.44
    WHP on E85 at 43.5psi 90%DC NA 327.30
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated

     

    EFI Live for our 445cc/min Injector

    EFI Live for FIC 445cc Injectors

    HP Rating

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 432.29
    WHP on Gas at 58psi 90%DC Turbo 499.29
    WHP on E85 at 43.5psi 90%DC Turbo 332.53
    WHP on E85 at 58psi 90%DC Turbo 384.07
    WHP on Gas at 43.5psi 90%DC NA 518.74
    WHP on Gas at 58psi 90%DC NA 599.15
    WHP on E85 at 43.5psi 90%DC NA 399.03
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated

     

    EFI Live for our 525cc/min Injector

    EFI Live for FIC 525cc Injectors

    HP Rating

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 510.00
    WHP on Gas at 58psi 90%DC Turbo 589.05
    WHP on E85 at 43.5psi 90%DC Turbo 392.31
    WHP on E85 at 58psi 90%DC Turbo 453.12
    WHP on Gas at 43.5psi 90%DC NA 612.00
    WHP on Gas at 58psi 90%DC NA 706.86
    WHP on E85 at 43.5psi 90%DC NA 470.77
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated

     

     


    EFI Live for our 650cc/min Injector

    EFI Live for FIC 650cc Injectors

    HP Rating

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 631.43
    WHP on Gas at 58psi 90%DC Turbo 729.30
    WHP on E85 at 43.5psi 90%DC Turbo 485.71
    WHP on E85 at 58psi 90%DC Turbo 561.00
    WHP on Gas at 43.5psi 90%DC NA 757.71
    WHP on Gas at 58psi 90%DC NA 875.16
    WHP on E85 at 43.5psi 90%DC NA 582.86
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated

     

     

    EFI Live for our 525cc/min Injector

    EFI Live for FIC 775cc Injectors

    HP Rating

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 752.86
    WHP on Gas at 58psi 90%DC Turbo 869.55
    WHP on E85 at 43.5psi 90%DC Turbo 579.12
    WHP on E85 at 58psi 90%DC Turbo 668.88
    WHP on Gas at 43.5psi 90%DC NA 903.43
    WHP on Gas at 58psi 90%DC NA 1043.46
    WHP on E85 at 43.5psi 90%DC NA 694.95
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated

     

     

    GM Data for our Short 1000cc/min Injector

    EFI Live for FIC Short 1000cc Injectors

    HP Rating

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 903.43
    WHP on Gas at 58psi 90%DC Turbo 1043.46
    WHP on E85 at 43.5psi 90%DC Turbo 694.95
    WHP on E85 at 58psi 90%DC Turbo 802.66
    WHP on Gas at 43.5psi 90%DC NA 1084.11
    WHP on Gas at 58psi 90%DC NA 1252.15
    WHP on E85 at 43.5psi 90%DC NA 833.93
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated

     

    GM Data for our 1000cc/min Injector

    EFI Live for FIC 1000cc Injectors

    HP Rating

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 903.43
    WHP on Gas at 58psi 90%DC Turbo 1043.46
    WHP on E85 at 43.5psi 90%DC Turbo 694.95
    WHP on E85 at 58psi 90%DC Turbo 802.66
    WHP on Gas at 43.5psi 90%DC NA 1084.11
    WHP on Gas at 58psi 90%DC NA 1252.15
    WHP on E85 at 43.5psi 90%DC NA 833.93
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated

     

    GM Data for our 1200cc/min Injector

    EFI Live for FIC 1200cc Injectors

    HP Rating

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 1117.14
    WHP on Gas at 58psi 90%DC Turbo 1290.30
    WHP on E85 at 43.5psi 90%DC Turbo 859.34
    WHP on E85 at 58psi 90%DC Turbo 992.54
    WHP on Gas at 43.5psi 90%DC NA 1340.57
    WHP on Gas at 58psi 90%DC NA 1548.36
    WHP on E85 at 43.5psi 90%DC NA 1031.21
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated

     

    GM Data for our 1650cc/min Injector

    EFI Live for FIC 1650cc Injectors

    HP Rating

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 1505.71
    WHP on Gas at 58psi 90%DC Turbo 1739.10
    WHP on E85 at 43.5psi 90%DC Turbo 1158.24
    WHP on E85 at 58psi 90%DC Turbo 1337.77
    WHP on Gas at 43.5psi 90%DC NA 1806.86
    WHP on Gas at 58psi 90%DC NA 2086.92
    WHP on E85 at 43.5psi 90%DC NA 1389.89
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated

     

    GM Data for our 2150cc/min Injector

    EFI Live for FIC 2150cc Injectors

    Cylinder Quantity 8
    Impedance High-Z
    WHP on Gas at 43.5psi 90%DC Turbo 2088.57
    WHP on Gas at 58psi 90%DC Turbo 2412.30
    WHP on E85 at 43.5psi 90%DC Turbo 1606.59
    WHP on E85 at 58psi 90%DC Turbo 1855.62
    WHP on Gas at 43.5psi 90%DC NA 2506.29
    WHP on Gas at 58psi 90%DC NA 2894.76
    WHP on E85 at 43.5psi 90%DC NA 1927.91
    Fuel Pressure (psi) 58
    Engine aspiration naturally aspirated



    Fuel Injector Clinic injectors are flow tested and rated at 43.5psi (3Bar) at 90ºF fuel temperature using CF-16B calibration fluid.


    Fuel Injector Clinic injectors are set up to and include all o-rings needed to fit the factory application for the listed vehicle. For aftermarket or other unusual setups please contact us prior to placing your order to make sure you receive injectors that fit properly.

    This injector set contains high impedance injectors matched to the saturated injector signal generated by this vehicle’s OEM ECU, OR is suitable for use with an aftermarket ECU made or set up for high impedance injectors.

    This set of injectors requires you to change the injector plug on the wiring harness in your car. This can be done by soldering in the pigtails (included with purchase) to replace the plugs currently on your harness, or you can choose to purchase the optional plug-n-play adaptors which will convert from the type of plugs on these injectors to the plugs on your harness without any need for cutting or soldering.

    This plug conversion is made necessary because FIC always chooses to provide brand new, unused injectors for its performance applications. We do not believe that increasing the chance of a failure due to using remanufactured or core program based injectors is ever warranted.



    Every injector is covered against failure caused by defects in original manufacture by our 12 month warranty.



     

     

     

    Warranty:

     

     

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