The present invention relates to an internal combustion engine provided with a heating device in a combustion chamber, and to a control method for the heating device.
As is known, the combustion chambers of internal combustion engines, in particular diesel engines, are provided with heating devices, known typically as “glow plugs”, whose function is appropriately to heat the combustion chambers and the operating fluid in these chambers so as to ensure a certain efficiency of the combustion process, even in operating conditions which are not optimal, for instance at a low temperature of the combustion chamber and/or of the operating fluid.
In internal combustion engines, one of the most critical of the operating conditions to which the combustion process is subject, and in which the use of glow plugs is required, is in particular the engine ignition phase.
In this phase, in practice, the temperature of the combustion chamber is low, i.e. it is lower than the working temperature required to obtain a sufficiently efficient combustion process; a supply voltage is therefore supplied to the glow plug so to bring the temperature of the latter to a value equal to an objective temperature to be reached in working conditions.
It is also known that one of the most important requirements for the drivers of vehicles with internal combustion engines is the need to reduce to a minimum the preheating time of the glow plug, which corresponds to the time interval taken by the plug, during the ignition phase of the engine, to bring its temperature to a value equal to the objective temperature.
For this purpose, open loop electronic control systems adapted to drive the glow plug so as to reduce the preheating time have been proposed in the latest generation internal combustion engines. During the engine ignition phase, these electronic control systems in particular boost the supply voltage of the glow plug, i.e. they increase the supply voltage to a value greater than the nominal voltage supplied to the glow plug in normal working conditions, in order to cause the temperature of the glow plug to increase extremely rapidly, thereby obtaining a reduction of the preheating time.
At the end of the ignition phase, the control system stabilises the supply voltage of the glow plug to the nominal value in order to maintain its temperature at a value substantially equal to the objective temperature.
Although they reduce the preheating time of the glow plug, the electronic control systems discussed above have a number of drawbacks: first, the supply of an overvoltage to the glow plug may damage it when the initial conditions of the plug and the combustion chamber differ from the conditions set in the control; in practice, if the ignition, rather than taking place from a “cold” engine, takes place from a “hot” engine, i.e. at a temperature slightly lower than the working temperature, then the supply of an overvoltage to the glow plug may generate an extremely high temperature which is higher than the temperature that can be tolerated by the glow plug, thereby subjecting the latter to excessive thermal stresses which it is unable to withstand.
A second drawback lies in the fact that the open loop electronic control systems discussed above do not ensure that the plug temperature remains stable enough with variations of those of the engine operating parameters which to some extent cause a change of temperature in the combustion chamber. In other words, the control of the glow plug temperature carried out by the above-mentioned electronic control systems is not very reliable as the temperature parameter to be controlled is conditioned by a number of engine parameters and by a number of environmental conditions to which the plug is exposed.
In order to reduce the preheating time, self-regulating glow plugs have also been proposed and are provided with an internal varistor which varies their resistance as a function of temperature so as to cause an automatic regulation of the thermal power generated, thereby obtaining an automatic control of the temperature of the glow plug.
These self-regulating glow plugs have the drawback that they are subject to a degree of temperature dispersion in the various operating conditions of the engine; in practice, as the engine operating point varies there is a change in the heat exchange and the self-regulating glow plug is unable appropriately to adapt its heating power, and is thus subject to higher temperature variations.
EP-1408233 discloses a process for controlling the heating of glow plugs in a diesel engine comprises emulating the thermal behavior of the plug on heating, and WO-9506203 relates to a method of driving a heating element such as a glow plug from an electrical power supply.
The object of the present invention is to provide an internal combustion engine provided with a heating device and a control method for the heating device, which makes it possible to reduce the preheating time of the heating device and, at the same time, ensures that the temperature of the heating device remains very stable in any operating condition of the engine.
The present invention relates to an internal combustion engine provided with a heating device as claimed in the attached Claims.
The present invention further relates to a control method for a heating device in an internal combustion engine, as claimed in the attached Claims.
The present invention further relates to an electronic control unit for the control of a heating device in an internal combustion engine as claimed in the attached Claims.
The present invention is described below with reference to the accompanying drawings, which show various non-limiting embodiments thereof, and in which:
The principle on which the present invention is based is essentially that of carrying out a feedback control (i.e. a closed loop control) of the temperature of the heating device in a variable volume combustion chamber of an internal combustion engine, as a function of an estimation of the temperature of this heating device; this estimate is carried out using an energy balance model of the thermal powers generated and exchanged within the combustion chamber.
In other words, the present invention is based on the notion of estimating the temperature of the heating device on the basis of an energy balance between the thermal power developed by the heating device, and the thermal power exchanged between the combustion chamber and the operating fluid contained in this combustion chamber, and of driving the heating device as a function of the difference between the estimated temperature and an objective temperature which needs to be reached by the heating device in a particular engine operating condition.
With reference to
Each cylinder 2 is coupled to a piston 6 which is adapted to slide in a linear manner along the cylinder 2 and is mechanically coupled to a drive shaft 7 by a connecting rod 8. The free space within the cylinder 2 and bounded by the piston 6 forms, as is known, a variable volume combustion chamber 9 in the cylinder 2.
Each cylinder 2 further comprises an injector 10 adapted cyclically to inject fuel into the cylinder 2 and at least one heating device which, in the embodiment shown, is formed by a glow plug 11 adapted to heat the combustion chamber 9.
With reference to
In particular, the electronic control unit 12 estimates, instant by instant, the temperature TGS of the glow plug 11 and adjusts the electrical power to be supplied to the glow plug 11 as a function of this estimated temperature TGS.
With reference to the embodiment shown in
The electronic control unit 12 further comprises, a summing circuit 14 which receives as input a signal indicating the estimated temperature TGs and a signal indicating an objective temperature TGO corresponding to the temperature that needs to be reached by the glow plug 11, and supplies as output an error signal eT showing the difference between the objective temperature TGO to be reached and the estimated temperature TGS.
The electronic control unit 12 further comprises a control module 15 which receives as input the error signal eT and generates, as a function of the latter, a control signal SCOM which drives the glow plug 11. In particular, the control module 15 preferably generates the control signal SCOM by a pulse width modulation PWM. In this case, the control signal SCOM comprises a series of pulses characterised by a voltage value Va and by a specific duty cycle whose value is shown below by DCY.
The control module 13 is adapted appropriately to modulate the duty cycle DCY and/or the voltage value Va of the control signal SCOM to be supplied to the glow plug 11 as a function of the error signal eT so as to supply thereto a specific electrical power such that a corresponding thermal power can be generated by means of this plug 11.
With reference to
The block 16 is adapted to process the parameters Va, DCY and RG so as to provide as output a signal indicating the thermal power PTG generated by the glow plug 11 when the latter is supplied with the control signal SCOM. In this case, the block 16 is adapted to calculate the thermal power PTG by implementing the following relationship:
PTG=(Va2·DCY)/(RG)
The estimation module 13 further comprises a block 17 which is adapted to calculate the mean temperature TCOMB in the combustion chamber 9 and a block 18 adapted to calculate a heat exchange coefficient hS.
The block 17 in particular receives as input a signal indicating the temperature TAIR of the intake air, a signal indicating the temperature TH2O of the cooling fluid, a signal indicating a parameter LOAD corresponding to the load measured in the engine 1, a signal indicating the number of engine revolutions RPM and a signal indicating the operating state of the engine SSTATE.
In this case, the signal indicating the operating state of the engine SSTATE comprises, alternatively, a first operating state corresponding to a condition in which the engine is caused to rotate by the combustion process, or a second state corresponding to a condition in which the engine is stationary, or a third state corresponding to a condition in which the engine is caused to rotate in the absence of a combustion process. In more detail, the first state may correspond, for instance, to the condition in which the engine is driven in rotation by the combustion process and has achieved a number of revolutions greater than a predetermined minimum value (for instance 780 RPM), the second operating state of the engine may correspond to a condition of non-combustion in which the engine is driven in rotation by an electrical starter device (starter motor) at a speed of rotation of approximately 250 RPM, while the third state may correspond to the condition in which the engine is stationary and the ignition key is in a Key On state.
It will be appreciated that the signal indicating the operating state of the engine SSTATE may be generated by a supervision module (not shown) of known type which is able, instant by instant, to determine the operating condition of the engine, while the signal indicating the parameter LOAD may be generated by a sensor mounted on the engine to measure its load (as shown in
The block 17 determines the temperature TCOMB of the combustion chamber 9 by means of a series of functions stored in a memory (not shown) of the electronic control unit 12, each of which is selected by the block 17 as a function of the engine operating state SSTATE. In this case, a first table containing a number of numerical values defining a first estimation function FST1 (RPM, LOAD) of the temperature TCOMB is stored in the memory (not shown) and is associated with the first engine operating state, making it possible to estimate, for each combination of the speed values RPM and the load LOAD, a corresponding value of the temperature TCOMB.
A second table containing a plurality of numerical values defining a second estimation function FST2 (TH2O) of the temperature TCOMB is further stored in the memory (not shown) and is associated with the second engine operating state, making it possible to estimate, for each value of the temperature of the cooling fluid TH2O, a corresponding value of the temperature TCOMB, as well as a third table containing a plurality of numerical values defining a third estimation function FST3 (TAIR) of the temperature TCOMB, which is associated with the third operating state of the engine, making it possible to estimate, for each value of the temperature of the intake air TAIR, a corresponding value of the temperature TCOMB.
The block 18 receives as input the signal indicating the number of revolutions RPM and calculates, by means of a heat exchange function H(RPM), the heat exchange coefficient hS of the combustion chamber 9. In this case, a fourth table containing a plurality of numerical values defining the heat exchange function H(RPM) is stored in the memory (not shown), making it possible to calculate a corresponding heat exchange coefficient hS for each value of the number of engine revolutions RPM.
The estimation module 13 further comprises a block 19 which receives as input the signal indicating the heat exchange coefficient hS, the signal indicating the temperature TCOMB and a signal indicating the temperature TGS of the glow plug 11. It will be appreciated that the temperature TGS may be stored from time to time in the memory (not shown) and that the block 19 receives as input the signal corresponding to the last value of the temperature TGS calculated by the estimation module 13 during the previous estimation. It will also be appreciated that during the initial setting of the electronic control unit 12, when the estimation module 13 is operating for the first time, it is possible to assign an appropriate predetermined value to the temperature TGS.
The block 19 processes the parameters TGS, TCOMB and hS in order to provide as output a signal indicating the thermal power PTS exchanged with the operating fluid in the combustion chamber 9. In this case, the block 19 calculates the thermal power PTS exchanged by means of the following relationship:
PTS=hS(TGS−TCOMB)
The estimation module 13 further comprises a summing circuit 20 which receives as input the signal corresponding to the thermal power PTG generated and the signal indicating the thermal power PTS exchanged and supplies as output a signal indicating the difference ΔP between the thermal power PTG generated and the thermal power PTS exchanged: ΔP=(PTG−PTS).
The estimation module 13 lastly comprises a block 21 which is adapted to receive as input the signal indicating the difference ΔP between the thermal power PTG generated and the thermal power PTS exchanged, and a signal indicating the thermal capacity CtGLOW of the glow plug 11, whose value is predetermined, and processes the latter in order to supply as output the signal indicating the estimated temperature TGS of the glow plug 11. In this case, the block 21 is adapted to estimate the temperature TGS of the glow plug 11 by means of the following relationship:
in which the instants to and t bound the time interval during which the energy balance between the thermal power PTG generated by the glow plug 11 and the thermal power PTS exchanged in the combustion chamber 9 with the operating fluid (exhaust gas) is carried out.
In the control method for the glow plug 11, the estimation module 13 of the electronic control unit 12 estimates, instant by instant, the temperature TGS on the basis of the different engine parameters discussed above and the state of operation of this engine (first, second or third state) and the control module 15 appropriately modulates the control signal (in particular the duty cycle DCY and/or the voltage Va) to be supplied to the glow plug 11, as a function of the error signal eT indicating the difference between the objective temperature TGO to be reached by the glow plug 11 and the estimated temperature TGS.
The block 17 in particular identifies in the memory (not shown), on the basis of the operating state SSTATE of the engine, the estimation function to be used to calculate the internal temperature TCOMB. In further detail, if the operating state SSTATE corresponds to the first state, the block 17 calculates the internal temperature TCOMB using the first estimation function FST1 (RPM, LOAD) on the basis of the speed RPM, and the load LOAD of the engine; while, if the operating state corresponds to the second or third state, the block 17 calculates the internal temperature TCOMB using the second and third estimation functions FST2 (TH2O), FST3 (TAIR) on the basis of the temperature of the fluid TH2O and the temperature of the air TAIR respectively.
During this phase, the block 19 receives as input the signals corresponding to the parameters TGS, TCOMB and hS, processes them and supplies as output the thermal power PTS exchanged, and at the same time the block 16 processes the parameters Va, DCY and RG to provide as output the signal indicating the thermal power PTG generated. At this point, the module 21, following the subtraction operation between the thermal power PTG generated and the thermal power PTS exchanged, implemented by the summing circuit 20, estimates the temperature TGS of the glow plug 11 to be provided as output in the form of an electrical signal to the summing circuit 14.
The engine 1 and the control method of the glow plug 11 described above have the advantage of ensuring a precise and stable control of the temperature of the glow plug in any operating condition of the engine, at the same time ensuring a major reduction of the preheating time of this plug during the ignition phase. In contrast to known electronic control systems which, as described above, implement an open loop control of the temperature, the method described above implements a feedback control of the temperature, thereby improving engine performance both in the ignition phase and in normal working conditions.
The engine and the control method of the heating device described above have the advantage that they are simple and economic to embody as they enable a direct closed loop control of the temperature of the heating device based on the engine magnitudes typically available, without needing to use a temperature sensor mounted directly on the heating device, which latter solution, in addition to being extremely complex to industrialise, would also entail very high costs. It will be appreciated that the engine and the control method of the heating device as described and illustrated may be modified and varied without thereby departing from the scope of the present invention as set out in the accompanying claims.
Number | Date | Country | Kind |
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BO2005A0326 | May 2005 | IT | national |
Number | Name | Date | Kind |
---|---|---|---|
3512221 | Schoerner | May 1970 | A |
3539970 | Rose et al. | Nov 1970 | A |
4002882 | McCutchen | Jan 1977 | A |
4552102 | Egle | Nov 1985 | A |
6148258 | Boisvert et al. | Nov 2000 | A |
6434944 | White | Aug 2002 | B2 |
6906288 | Toedter et al. | Jun 2005 | B2 |
20010027652 | White | Oct 2001 | A1 |
Number | Date | Country |
---|---|---|
103 18 241 | Nov 2004 | DE |
1 408 233 | Apr 2004 | EP |
WO 9506203 | Mar 1995 | WO |
Number | Date | Country | |
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20060289425 A1 | Dec 2006 | US |