This disclosure generally relates to fuel injectors including a heating element for pre-heating fuel prior to combustion. More particularly, this disclosure relates to a method and device for sensing and regulating a temperature of a heating element for a fuel injector.
Pre-heating fuel prior to being injected into a combustion chamber provides a more complete and efficient combustion that both increases fuel efficiency while reducing the production of undesired emission byproducts. Fuel injectors pre-heat the fuel by exposing fuel flow through the fuel injector to a heating element. The temperature of the fuel is desired to be within a desired range upon exit of the fuel injector and entrance to the combustion chamber. Fuel that is not heated sufficiently does not provide full scale of desired benefits, where fuel that is excessively heated can result in undesirable build up within the fuel system. For these reasons, the temperature of the fuel is sensed and regulated. Typically a temperature sensor is provided within the fuel injector to sense fuel temperature. Such wired sensors required additional circuitry and control at an added cost. Accordingly, it is desirable to design and develop a method and device of sensing temperature that is more efficient.
A disclosed example fuel delivery system for a vehicle includes a fuel injector that dispenses heated fuel flow and controls the temperature of the heated fuel within a desired temperature range.
Fuel flowing through the example fuel injector is inductively heated by a valve element sealed with the fuel flow. The temperature of the heated valve element is monitored without wires or external sensors. The example driver circuit monitors a material parameter that changes the materials inductance in response to changes in temperature. The driver circuit detects the changes in inductance and changes power input into the heated element responsive to the detected temperature. The temperature of fuel provided to an engine is therefore maintained within a desired temperature range to provide a desired performance.
The driver circuit detects changes in temperature by monitoring changes in parameters that vary responsive to temperature in the material of the heated element. Changes in material permeability caused by changes in temperature cause a proportional change in parameters responsive to changes in inductance. In one example, frequency is detected and utilized to correct power input into the heated element to increase, decrease or maintain a desired temperature of the inductively heated valve element and thereby control of fuel temperature.
These and other features disclosed herein can be best understood from the following specification and drawings, the following of which is a brief description.
This disclosure is submitted in furtherance of the constitutional purposes of the U.S. Patent Laws ‘to promote the progress of science and useful arts” (Article 1, Section 8).
Referring to
The example fuel injector 12 provides for pre-heating fuel to aid combustion. A heater coil 30 generates a time varying magnetic field in a heated element 28. In this example the heated element 28 is a valve element that is sealed within the fuel flow 14 through the fuel injector 12. There are no wires attached to the heated element 28. Heating is accomplished by coupling energy through the time varying magnetic field produced by the heater coil 30. Energy produced by the heater coil 30 is converted to heat within the sealed chamber of the fuel injector 12 by hysteretic and eddy current loses in the heated element material. The heated element 28 transfers heat to the fuel flow 14 to produced a heated fuel flow 28 that is injected into the engine 18. The heated fuel flow 28 improves cold starting performance and improves the combustion process to reduce undesired emissions.
The temperature of the heated fuel 28 is controlled within a desired temperature range to provide the desired performance. A temperature that is low will not provide the desired benefits. A temperature that is higher than desired can cause undesired damage and also result in deposit formation within the fuel injector.
The example fuel delivery system 10 includes a method and circuit that provides for the determination and control of the temperature of the heated element 28 without the use of temperature sensors, or any other sensors installed within the sealed fuel flow.
Referring to
B=uH,
where u is permeability and H is magnetomotive force.
Changes in induction may be non-linear, non-monotonic in the case of a Neel temperature and Curie temperature demagnetization, with ferromagnetism between these two temperatures. Further, the change in induction could be linear, as is illustrated in Graph 68, or at least monotonic from strong ferromagnetism at a low temperature and reduced ferromagnetism at higher temperature. The graph 68 illustrates a relationship between permeability 70 and temperature 72. With the known relationship for a specific material the temperature of an induced element such as the example heated element 28 can be determined.
Referring to
Accordingly, the example fuel system 10 measures induction as a parameter that changes responsive to changes in temperature.
Induction is a parameter that causes measurable changes in frequency and phase changes. Frequency is related to inductance according to the equation:
fr=1/(2π√{square root over (LC)})
where L is inductance, the measure of induction, or slope of B plotted against H; and
C is capacitance.
The example fuel delivery system 10 includes a circuit 32 (
Referring to
Frequency or phase is determined from measuring a frequency-dependent variable of the oscillator 36. In this example gate voltage is measured from one side of the push-pull oscillator 36 because gate voltage changes directly with frequency. The frequency or phase is thereby converted to a conveniently measured output such as voltage as schematically indicated at 38.
Current into the oscillator 36 is monitored via a current-sense resistor 40 (R1 in parallel with R2). The measured current from the current-sense resistor 40 is differentially amplified to provide a useful value. That value is then multiplied by the frequency scaled voltage in an analog computational engine 42. The result is a frequency-corrected current that is represented by a voltage. The voltage is then differentially amplified relative to a target current value in a current error amplifier 56 set by a voltage integrator 54.
This conditioning of the frequency senses changes and transforms the detected changes in frequency into signals that control the power sent to the load 26 by the oscillator 36. In this example, if the frequency increases (indicating an increase in temperature), then the current sense voltage is multiplied to a higher value that looks like a higher current to the current error amplifier 56, which causes output of a lower error voltage that in turn commands a lower current.
The error voltage is compared to a generated triangle wave from generator 44 utilized in a PWM (Pulse Width Modulation) circuit portion that includes comparator 46 and PWM gate driver 48 to create a PWM waveform that represents the determined current. The determined current provides the power fed to the power oscillator 36 that is responsive to the detected changes in frequency, and inductance to controls generation of heat in the heated element 28.
Referring to
Accordingly, the example circuit 32 detects changes in temperature by monitoring changes in parameters that vary responsive to temperature in the magnetic material of the heated element. Changes in material permeability caused by changes in temperature cause a proportional change in parameters responsive to changes in inductance. In the example, frequency is detected and utilized to correct power input into the inductive load to reduce, increase or maintain a desired temperature of the inductively heated element 28, and thereby control of fuel temperature.
Although a preferred embodiment of this invention has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.