This application claims priority to United Kingdom Patent Application No. 0801214.8, filed Jan. 23, 2008, which is incorporated herein by reference in its entirety.
The invention relates to glow plug control unit and method for controlling the temperature in a glow plug.
WO 2007/033825 shows a control of a group of glow plugs for a diesel engine. The glow plugs are periodically connected with supply lines according to pulse-width modulated signals. To provide the glow plugs with the required energy, the voltage drop over the supply lines is calculated by the help of the measured glow plug current. This calculation is done for each glow plug individually to control its temperature. The method is well adapted for ceramic glow plugs of which the resistance strongly varies over the temperature. On the other hand, this method uses a calculation based on a number of measurements and estimations including the risk that the control of the temperature is wrong.
It is accordingly at least one object of the invention to provide an alternative glow plug control unit that provides a more precise control of the temperature of the glow plugs. It is at least another object of the invention to provide a method for controlling a glow plug more precisely. In addition, other objects, desirable features, and characteristics will become apparent from the subsequent summary and detailed description, and the appended claims, taken in conjunction with the accompanying drawings and this background.
Embodiments of the invention provide a glow plug control unit that comprises a first switch for connecting a power supply node to a glow plug. The glow plug control unit further comprises a voltage measurement unit for measuring the voltage at the power supply lines. A current measurement unit is built for measuring the current through the first switch and a control circuit is built for controlling the first switch and, in a current control mode, for regulating the current through the first switch to a predefined value.
The resistance of metallic glow plugs is relatively stable at different temperature conditions compared to the resistance of ceramic glow plugs. The inventive glow plug control unit provides the current control mode in which the current through the glow plugs is regulated directly. The power in the glow plugs and the temperature is accordingly controlled by the help of the current measurement and the current control does not need to compensate the voltage drops. The compensation of the voltage drops needs a series of calculations which may be faulty because they are based on estimations and prior measurements of the resistance. The current control mode is used preferably for metallic glow plugs, as their resistance is relatively stable over temperature.
In an embodiment, the first switch comprises a transistor and the current measurement unit comprises a current mirror mirroring the current through the transistor of the first switch. A current mirror provides a direct measurement of the current through the first switch, which is equal to the current through the glow plug.
Preferably, the glow plug control unit comprises a second switch between the battery and the power supply node. This additional, second switch, may open and close the supply path between the battery and the glow plug. The second switch is a redundant to block the current flow independently of the status of the control circuit.
The current is also measured when the first switch is switched off. This makes it possible to check if no current flows through the first switch in the off-periods.
In an embodiment, the control circuit regulates the voltage at the glow plugs in a voltage control mode. This additional mode may preferably be used for ceramic glow plugs. The resistance of the ceramic glow plug depends strongly on the glow temperature. Accordingly, to calculate the power in the glow plugs, the voltage at the glow plugs needs to be taken into account. Thus, the voltage control mode is needed to support glow plugs having a resistance value varying with the temperature.
In an additional mode, the power control mode, the power in the glow plugs is regulated to a predetermined value. Shifts in the resistance of the glow plugs may be compensated because the measured voltage depends on this resistance.
To regulate the power to a predefined value, the power in the glow plug is estimated based on the current through the first switch and based on the voltage at the first switch.
The invention also relates to a method for controlling a glow plug with a glow plug control unit, and an inventive glow plug control unit is provided and the current through the first switch is measured. Then, in a current control mode, the current through the first switch is regulated to a predetermined value.
Preferably, the first switch of the glow plug control unit being provided comprises a transistor. The current through the first switch is measured by a current mirror mirroring the current through the transistor.
The invention also provides a method for calculating the power in a glow plug. First, a glow plug control unit for a plurality of glow plugs is provided. The glow plug control unit comprises a plurality of switches, each of the switches for connecting a glow plug to a power supply node. The current through the glow plugs is measured and the voltage at the glow plugs is calculated by calculating the voltage drop at power supply node based on the current through the switches being switched on concurrently. The power in the glow plugs is calculated based on the calculated voltage at the glow plugs and the measured current through the glow plugs.
If the on-times of the switches party overlap, the voltage drop at the power supply node varies over time. As the number of measurement samples is limited, one sample is used to estimate the voltage of a complete period. When the number of switches being switched on concurrently differs during the period, the voltage drop varies and the sample does not provide the correct value for the complete period. Thus, the voltage drop is calculated based on the number of switches being switched on concurrently to compensate this effect.
The present invention will hereinafter be described in conjunction with the following drawing figures, wherein like numerals denote like elements, and:
The following detailed description is merely exemplary in nature and is not intended to limit application and uses. Furthermore, there is no intention to be bound by any theory presented in the preceding background and summary or the following detailed description.
The battery 101, as the system power supply, is connected with its negative pole to the chassis ground 1000 and with its positive pole to the generator and starter block 103. The negative and positive poles of the battery are also connected to the power supply wiring harness block 102. This power supply wiring harness block 102 comprises the wiring harness and the fuses for the supply lines.
The wiring harness block 102 outputs the supply signals pwr and gnd to the control unit 110 that are connected to these signals at its inputs 6a respectively 30. The control unit 110 is also connected at its outputs 16a, 17a, 18a, and 19a to the glow plugs wiring harness 106 providing the connection to the glow plugs A, B, C and D of the glow plugs & cylinders chamber 107.
The glows A, B, C and D are further connected to the node N1 that couples them to the chassis ground 1000 via the resistive path 108. The resistive path 108 is the path in the chassis that connects the negative pole of the battery 101 with the node N1 close to the glow plugs A, B, C and D.
The glow plug control unit 104 is connected to the engine control module 105 via the signals pwm and diag. The signal diag is used for diagnostic purpose to send an error message from the glow control unit 104 to the engine control module 105. By the signal pwm the engine control module 105 requests the glow plug control unit 104 to heat the glow plugs.
The control apparatus is applicable to both glow plugs system showed in
The schematic in
The glow plug control unit 104 comprises a first unidirectional enable switch 5a and a second unidirectional enable switch 5b, the first, second, third, fourth, fifth and sixth high side switches 1a, 2b, 3a, 4a, 1b and 4b. Each of the high side switches 1a, 2b, 3a, 4a, 1b and 4b comprises an n-channel enhancement MOS-field effect transistor 203 and a flyback diode 202. The drain of the transistor 203 is connected to the cathode of the diode 202, whereas the source of the transistor 203 is connected to the anode of the diode 202. The high-side switches 2a and 3b are not shown in
Each of the unidirectional enable switches 5a and 5b comprises a first transistor 206 and a second transistor 207, a first diode 208 and a second diode 209. The source of the first transistor 206 is connected to the anode of the first diode 208. The drain of the first transistor 206 is connected to the cathodes of the first diode 208 and of the second diode 209 and to the drain of the second transistor 207. The source of the second transistor 207 is connected to the anode of the second diode 209. The source of the second transistor 207 of the first unidirectional enable switch 5a is connected to the input 6a, whereas the source of the first transistor 206 of the first unidirectional enable switch 5a is connected to the power supply node 204. The source of the second transistor 207 of the second unidirectional enable switch 5b is connected to the input 6b, whereas the source of the first transistor 206 of the second unidirectional enable switch 5b is connected to the node 205.
The power supply input terminal 6a is connected to the node pwr to establish a low impedance path to the positive pole of the battery 101.
The ground reference terminal 30 is connected to the node gnd. This establishes a low impedance return path to the battery negative pole. The node gnd is the reference node for all the control architecture related voltages.
The first unidirectional enable switch 5a has a redundant switch off capability and the reverse polarity protection necessary for the direct battery connection at the power supply input terminal 6a. By the unidirectional enable switch 5a the current flow into the glow plugs may be blocked independently of the status of the engine control module 105.
The gates of the first transistor 206 and of the second transistor 207 are controlled by the signal first unidirectional enable switch control 20a for the first unidirectional enable switch 5a and by the signal second unidirectional enable switch control 20b for the second unidirectional enable switch 5b. The unidirectional enable switches 5a and 5b are closed to provide the voltage at the nodes 204 and 205.
The output terminal 16a is connected to the glow plug A, the output terminal 18a is connected to the glow plug C, the output terminal 19a is connected to the glow plug D, the output terminal 17b is connected to the glow plug Bb and the output terminal 19b is connected to the glow plug Db.
The gates of the transistors 203 of the high-side switches 1a, 2b, 3a, 4a, 1b and 4b are controlled by the signals high side switches control 22a, 23a, 24a and 25a, such that the transistor gate of the high-side switch 1a and of the high side enable switch 1b are controlled by the high side switch control 22a. The transistor gate of the high-side enable switch 3a is controlled by the high side switch control 24a, that of the high-side enable switch 2b by the high side switches control 23a and those of the high-side enable switches 4a and 4b by the high side switches control 25a.
The high side switches 1a, 2b, 3a, 4a, 1b and 4b provide the capability, via the high side switch control signals 22a, 24a and 25b, to energize the glow plugs A, B, C, D switching the voltage at the power supply node 204 respectively 205 to the output 16a, 18a, 19a, 16b, 17b and 19b. They also provide the capability to adapt the voltage slew-rate for both on/off and off/on transitions to limit the power dissipation. The voltage slew-rate depends on the environmental conditions.
The high side switches control 22a, 23a, 24a and 25a controls the high-side switches 1a, 2b, 3a, 4a, 1b and 4b independently to transfer the voltage to each glow plug A, B, C, D, Ab, Bb, Cb and Db. In this embodiment, the high side switches control 22a, 23a, 24a and 25a are driven by pulse-width modulated signals providing a defined current to the glow plugs and also providing a defined voltage when the high-side switches 1a, 2b, 3a, 4a, 1b and 4b are switched on.
The enable voltage monitor 7a monitors the voltage at the node 204 and the enable voltage monitor 7b monitors the voltage at the node 205. In an embodiment, these voltage monitors 7a and 7b output the maximal and the minimal values of the voltage at the nodes 204 and 205 during the on time of the pulse width modulated command for the glow plugs.
The current monitors 8a, 8b, 9b, 10a, 11a and 11b monitor the current flowing through each high side switches 1a, 1b, 2b, 3a, 4a and 4b during both on and off periods of the pulse width modulated command. The current monitors 8a and 8b are preferably current mirrors mirroring the current through the transistors 202 of the high side switches. In an embodiment, each current monitor 8a and 8b reports the maximal values for both, the on-periods and the off-periods.
The transistor T shows an embodiment of a current mirror used as a current monitor. The transistor T has the same size as the transistor 203 of the high side switch 4b. Its drain is connected to the node 205, whereby its source is connected to node 220. The gate is controlled by the signal high side switch control 25a. A resistor R is provided between the node 220 and the reference ground terminal 30. The resistor R is adjustable such that the voltage at node 220 is regulated to a voltage having the same value as the voltage at the output terminal 19b. As the transistor T has the same size and the same voltage conditions as the output terminal 19b, the current through this transistor is the same as the current through the high side switch 4b. This current may be calculated by diving the voltage at node 220 by the resistance of the resistor R.
The output values of the current monitor 8a, 10a, 11a, 8b, 9b and 10b are captured at the same time at which the respective enable voltage monitors 7a and 7b detect the maximal voltage value for each the pulse width modulated command provided at the high side switch control 22a, 23a, 24a and 25a.
During the off periods, the current measured by the current monitors 8a and 8b should be zero. The current measured by the current monitors 8a and 8b during these periods have no impact on the control function, but are used for diagnosis purposes.
The dashed line 210 shows an optional connection that short-cuts the nodes 204 and 205. In this case, the second unidirectional enable switch 5b will be deleted and the node 205 will also be supplied by the first unidirectional enable switch 5a.
The biasing networks 21a and 21b monitor the voltage supplied to the high side switches 1a, 2b, 3a, 4a, 1b and 4b when the unidirectional enable switch is not active. This has no impact on the control function but is also used for diagnosis purposes.
The control logic 26 provides the control methods to drive the unidirectional enable switch controls 20a and 20b and the high side switches controls 22a, 23a, 24a and 25a based on the engine operating conditions, on the environmental conditions, on the glow plug type respectively depending on the information received from the voltage monitors 7a and 7b and the current monitors 8a, 10a, 11a, 8b, 9b and 11b.
The secondary voltage monitors 12′, 14′, 15′, 12b, 13b and 15b provide an alternative method to monitor the output voltages at the output terminal 16a, 18a, 19a, 16b, 17b and 19b during both on and off periods of the respective pulse width modulated command. The information generated at the off periods permits to compensate the voltage ground shift between engine block and chassis ground 1000 if necessary.
The functional targets of the control can be summarized by the following aspects: The target temperature should be reached quickly. However, dangerous temperature overshoot should be avoided. Further, the temperature should be kept within a defined range depending on the engine operating conditions.
The control apparatus permits via the pulse width modulated output commands that are provided as high side switches control signals 22a, 23a, 24a and 25a to control the temperature of each individual glow plug. Depending on the engine operating condition and on the glow plug technology, the control logic shall select the most efficient method to control and to drive the glow plugs.
The four control methods being supported by this control architecture are 1) the inrush energy control, 2) the effective voltage closed loop, 3) the effective glow plug current closed loop and 4) the output power closed loop.
The voltage set-point calibration 501 receives the engine operation conditions, in this case the information that the engine is in the inrush phase. The voltage set point calibration 501 outputs the value voltage set point that represents the requested voltage for the given engine operation condition.
The voltage estimation 502 receives from the voltage monitor 7a the voltage that is measured at the power supply node 204. From this value, the voltage estimation 502 outputs a value representing the estimation of the voltage at the glow plug A. The estimated voltage is received by the integrator 506 which first squares the estimated voltage and then integrates the result of the square operation. By this operation, the energy being provided to the glow plug since the start of the engine is summed up.
The thermal status estimation 503 receives the engine operation conditions and the environmental operating conditions, especially the external temperature and the speed of the wind. If the engine operating conditions indicate that the engine was just started, the glow plug temperature is estimated to be the same as the external ambient temperature.
The estimated temperature of the glow plug is used as a start value for the integration in the integrator 506. The integrated energy is compared with a predetermined target value for the energy in the comparator 508. If the energy is below the target energy, the comparator 508 sends an output signal to the PWM generator 507 to open the high-side switch 1a.
The high-side switch 1a will be closed if the voltage at the glow plugs exceeds a threshold voltage defined by the voltage set point. To detect this condition, the divider 504 divides this estimated voltage by the voltage set point and outputs its result to the multiplier 505 which sets the PWM generator 507 that generates a parameters PWM duty cycle, PWM frequency and PWM offset. These parameters are used to generate the signal high side switch control 22a.
The inrush energy control is used when a fast energizing of the glow plugs is requested, mainly in the inrush phase. The control circuit will provide an amount of energy depending on environmental and engine operating conditions, on the estimated initial thermal status of the glow plug and on the glow plug characteristics. The real-time energy transferred to the glow plug, called normalized energy, is calculated by integrating the square of the estimated effective voltages applied to the glow plugs. The control also limits the effective voltage applied to the glow plugs to avoid excessive thermal gradients during this phase.
The voltage control 600 provides to each glow plug a predetermined effective voltage depending on the engine operating conditions and on the temperature target. The voltage estimation 502 receives the voltage measured by the voltage monitor 7a. From this feedback signal, the voltage at the glow plug A is calculated.
The estimated voltage is divided by the output value of the voltage set point 501, the result of this operation is squared and then output as a duty cycle to the PWM generator 507. The PWM generator 507 defines the parameters frequency, offset and duty cycle for the generation of a pulse width modulated signal first high-side switch control 22a. The glow plug A is opened and closed according to this signal providing a defined voltage at the glow plug A.
The blocks 601, 602 and 603 feedback the parameters PWM offset, PWM frequency and PWM duty cycle. The feedback is used to ensure that these parameters do not exceed an upper limit.
To calculate the voltage being applied to the glow plug, the voltage drop over the glow plug wiring harness 106 is compensated. Accordingly, the output of current monitor 8a and a value for the resistance of the glow plug wiring harness 106 is input to the voltage estimation 502.
As an option, the voltage drop across the high side switch 1a is also compensated. The voltage drop may be calculated by the difference between the voltage monitor 7a and the voltage monitor 12′ when the high-side switch 5a is on. The voltage drop varies over the temperature, accordingly the estimated temperature of the high-side switch may also be considered. It also should be considered that the voltage drop highly depends on the current through the high-side switch 1a. Therefore, the voltage drops should be measured at different currents.
In addition, the voltage drop across the resistive path 108 may be compensated using the current monitor 8a feedback during the on periods of the pulse width modulated commands. Optionally, the duty cycles of the pulse width modulated commands may be limited by an upper limit to avoid excessive currents.
The current estimation 702 receives the current measured by the current monitor 8a. From this feedback signal, the current through the glow plug A is calculated. The estimated current is divided by the output value of the current set point calibration 701, the result of this operation is squared in the multiplier 705 and then output as a duty cycle to the PWM generator that outputs the parameters PWM frequency, PWM offset and PWM duty cycle for the generation of a pulse width modulated signal first high side switch control 22a. The glow plug A is opened and closed according to these signals providing a defined current at the glow plugs.
The current control circuit 700 provides an effective current to the glow plug, using the current monitor 8a feedback during the on periods of the pulse width modulated commands. This method is typically applied if the equivalent electrical resistance does not dependent too much on the electrical power supplied to the hot glow plug A.
In contrast to the voltage closed loop control, the compensation of voltages drop across the resistive path between the monitoring point and the glow plug is not necessary.
The fourth method, the output power closed loop, is provided by the power control circuit 800 shown in
The result of this division is used to generate the parameters PWM offset, PWM frequency and PWM duty cycle in the PWM generator 507. In contrast to the first method, the inrush energy control, only the power being actually supplied is regulated. In the inrush energy control, the energy was integrated since the beginning of the inrush phase.
The control circuit 800 provides a defined power to each glow plug, using the current monitor 8a feedback during the on periods of the pulse width modulated commands and the voltage monitor 7a feedback.
As an option, the voltage drop across internal High Side Switches is compensated, in a further option the voltage drop across external wiring harness is compensated using the current monitor 8a feedback, optionally limiting the duty cycles of the pulse width modulated commands to avoid excessive currents.
The following electrical effects may be compensated by the above-described control methods: supply voltage variation, ground shift, high side switch Rdson voltage drop, wiring harness losses and voltage variations during command overlaps and during PWM frequency modulation.
The thermal/fluid dynamic effects air flow cooling effect, combustion heat release and the initial thermal variations may also be compensated.
The control methods 2) and 4) compensate supply voltage variations at the power supply input terminal by the help of the voltage monitor 7a feedback.
The ground shift between the node gnd and the negative pole of the battery may be compensated by help of the output voltage monitor 12′, 14′, 15′, 12b, 13b, 15b feedbacks measured during the off periods of the pulse width modulated commands.
With the control methods 2), 3) and 4) voltage drops on the internal high side switches are also compensated. The voltage drops over the high side switches is measured by the voltage monitors 12′, 14′, 15′, 12b, 13b and 15b when the high side switches are on.
All control methods 1), 2) and 4) compensate the voltage drops over the external wiring harness of the power supply wiring harness block 102 because the current monitor 8a feedbacks the actual current during the on periods of the PWM commands. The voltage drop over the external wiring harness in the power supply wiring harness block 102 may be calculated by multiplying the sum of currents through the high-side switches by a resistance that is based on parameters identifying the values of the wiring harness path resistance.
Voltage drops across the power supply wiring harness 106 due the commands overlaps affect the voltage being measured by the voltage monitor 7a. As a consequence, voltage steps on the monitored voltage affect the RMS value calculation but are not measured. The voltage at power supply node 204 is affected by the voltage drops across the wiring harness due the commands for the high-side switches. These commands partly overlap, meaning that at least two high side switches are switched on at the same time. During this time, the voltage at power supply node 204 drops by ΔV2. As a consequence, voltage steps on the monitored voltage affect the estimation of the RMS value calculation.
This is demonstrated by the signal V7 in
In order to calculate the real RMS voltage, the values Vsample, max, Δt=t2−t1, of ΔV1 and ΔV2 are evaluated. The Vsample, min value is used for a coherency check with the maximal value.
Isample is measured by the current monitors 8a, 10a, 11a, 8b, 9b, 11b during the on/off periods of the PWM commands. The pulse width modulation duty cycles and the pulse width modulation shift are known from the PWM generator 507, such that the values for t1, t2 and t3 can be calculated. The calibration parameters identify the values of the wiring harness power supply input path and the glow plug wiring harness resistances. From these values Δt=t2−t1, ΔV1 and ΔV2 and the correct effective voltage at the glow plug B is evaluated.
The control method 1) compensates the air flow cooling effect and the combustion heat release by calibrating for engine operating condition in the thermal status estimation 503. In this block, the cooling due to thermal exchange inside the cylinder chamber during the engine cycle is taken into account and compared with nominal operating condition typically defined in still air.
The control method 1) estimates the initial thermal status of the glow plug by monitoring the time elapsed from last active period and the environmental operating condition. This period is correlated with a thermal decay model to estimate its thermal status of the glow plugs.
The control provides the capability to set the delays between the pulse width modulated commands during the temperature holding phase depending on the glowing operating conditions. The goal is to minimize the total effective current and the related EMC potential problems.
The glowing function is integrated inside the engine control module providing a unique solution for the complete management of the engine with an evident advantage on the cost. The glowing function integrated inside the engine control module provides a unique possibility to interact with all the other engine control functions offering a very flexible solution with easy adaptation to new requirements for the glowing subsystem, including new glow plug characteristics. The control architecture provides a redundant switch off functionality that permits to elimination of the external relay in a direct battery connection.
The control methods provide several solutions, applicable depending on the engine operating conditions and on the glow plug technology, to guarantee that target temperature is reached with acceptable accuracy.
The control methods provide different solutions, applicable depending on the engine operating conditions and on the electrical subsystem architecture, to compensate the effects of system parameters variations that could affect the overall temperature control accuracy and to improve the electromagnetic compatibility (EMC) of the vehicle electrical system.
While at least one exemplary embodiment has been presented in the foregoing summary and detailed description, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration in any way. Rather, the foregoing summary and detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment, it being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope as set forth in the appended claims and their legal equivalents.
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0801214.8 | Jan 2008 | GB | national |
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20080163840 | Toedter et al. | Jul 2008 | A1 |
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Number | Date | Country |
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Number | Date | Country | |
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20090183718 A1 | Jul 2009 | US |