EP2768276A1 - Heating device - Google Patents

Heating device Download PDF

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Publication number
EP2768276A1
EP2768276A1 EP20120839896 EP12839896A EP2768276A1 EP 2768276 A1 EP2768276 A1 EP 2768276A1 EP 20120839896 EP20120839896 EP 20120839896 EP 12839896 A EP12839896 A EP 12839896A EP 2768276 A1 EP2768276 A1 EP 2768276A1
Authority
EP
European Patent Office
Prior art keywords
heating element
resistance value
power supply
heating
deterioration
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
EP20120839896
Other languages
German (de)
French (fr)
Other versions
EP2768276B1 (en
EP2768276A4 (en
Inventor
Masashi Irie
Takeshi Fukazawa
Hironao Yamaguchi
Naoto Hayashi
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Denso Corp
Original Assignee
Denso Corp
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Filing date
Publication date
Application filed by Denso Corp filed Critical Denso Corp
Publication of EP2768276A1 publication Critical patent/EP2768276A1/en
Publication of EP2768276A4 publication Critical patent/EP2768276A4/en
Application granted granted Critical
Publication of EP2768276B1 publication Critical patent/EP2768276B1/en
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Anticipated expiration legal-status Critical

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Classifications

    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B1/00Details of electric heating devices
    • H05B1/02Automatic switching arrangements specially adapted to apparatus ; Control of heating devices
    • H05B1/0227Applications
    • H05B1/023Industrial applications
    • H05B1/0236Industrial applications for vehicles
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02PIGNITION, OTHER THAN COMPRESSION IGNITION, FOR INTERNAL-COMBUSTION ENGINES; TESTING OF IGNITION TIMING IN COMPRESSION-IGNITION ENGINES
    • F02P19/00Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition
    • F02P19/02Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs
    • F02P19/021Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs characterised by power delivery controls
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02PIGNITION, OTHER THAN COMPRESSION IGNITION, FOR INTERNAL-COMBUSTION ENGINES; TESTING OF IGNITION TIMING IN COMPRESSION-IGNITION ENGINES
    • F02P19/00Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition
    • F02P19/02Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs
    • F02P19/027Safety devices, e.g. for diagnosing the glow plugs or the related circuits
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23QIGNITION; EXTINGUISHING-DEVICES
    • F23Q7/00Incandescent ignition; Igniters using electrically-produced heat, e.g. lighters for cigarettes; Electrically-heated glowing plugs
    • F23Q7/001Glowing plugs for internal-combustion engines
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02PIGNITION, OTHER THAN COMPRESSION IGNITION, FOR INTERNAL-COMBUSTION ENGINES; TESTING OF IGNITION TIMING IN COMPRESSION-IGNITION ENGINES
    • F02P19/00Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition
    • F02P19/02Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs
    • F02P19/021Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs characterised by power delivery controls
    • F02P19/022Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs characterised by power delivery controls using intermittent current supply
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02PIGNITION, OTHER THAN COMPRESSION IGNITION, FOR INTERNAL-COMBUSTION ENGINES; TESTING OF IGNITION TIMING IN COMPRESSION-IGNITION ENGINES
    • F02P19/00Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition
    • F02P19/02Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs
    • F02P19/021Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs characterised by power delivery controls
    • F02P19/023Individual control of the glow plugs
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02PIGNITION, OTHER THAN COMPRESSION IGNITION, FOR INTERNAL-COMBUSTION ENGINES; TESTING OF IGNITION TIMING IN COMPRESSION-IGNITION ENGINES
    • F02P19/00Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition
    • F02P19/02Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs
    • F02P19/025Incandescent ignition, e.g. during starting of internal combustion engines; Combination of incandescent and spark ignition electric, e.g. layout of circuits of apparatus having glowing plugs with means for determining glow plug temperature or glow plug resistance
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B2203/00Aspects relating to Ohmic resistive heating covered by group H05B3/00
    • H05B2203/02Heaters using heating elements having a positive temperature coefficient
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B2203/00Aspects relating to Ohmic resistive heating covered by group H05B3/00
    • H05B2203/027Heaters specially adapted for glow plug igniters

Definitions

  • the present invention relates to heating elements and heating devices.
  • a resistance value of the heating element changes in a positive correlation according to a change of a heating temperature thereof.
  • the heating device of a control section integrated-type is equipped with the heating element and a power supply control module.
  • the power supply control module is capable of controlling a power supply from an electric power source to the heating element.
  • the heating device of a control section integrated-type has a simple structure, provides a stable power supply control and detects an abnormality deterioration state of the heating element.
  • the present invention is preferably applied to a glow plug of a control section integrated-type, which is mounted to a respective cylinder of a diesel internal combustion engine.
  • the glow plug of a control section integrated-type is comprised of the heating element and the power supply control module assembled together in a housing casing having a cylindrical shape.
  • Conventional abnormality detection devices are known, which are capable of detecting abnormal wire break and abnormal over current in a glow plug.
  • the glow plug assists ignition of a diesel engine.
  • the conventional abnormality detection device has a current detection means such as a current sensor, a shunt resistance arranged between a glow plug and a switching means.
  • the switching means adjusts a power supply to the glow plug.
  • the current detection means calculates a resistance value of the glow plug on the basis of a current which flows in the glow plug and a voltage applied to the glow plug.
  • a known conventional abnormality detection device detects deterioration of the glow plug and abnormal wire break on the basis of the calculated resistance value of the glow plug.
  • a patent document 1 discloses a deterioration detection device for a glow plug comprised of a detection means and a judgment means.
  • the detection means detects a detection value corresponding to a resistance of a glow plug when a power supply device supplies an electric power to the glow plug.
  • the glow plug assists ignition of an internal combustion engine.
  • the judgment means instructs the power supply device to supply an electric power to the glow plug immediately after the internal combustion engine has stopped, and judges deterioration of the glow plug on the basis of a resistance value detected by the detection means.
  • a patent document 2 discloses a heater deterioration detection device comprised of a first voltage output means, a second voltage output means and a comparison judgment means.
  • the first voltage output means converts a current which flows in a heater to a first voltage and outputs the converted first voltage.
  • the second voltage output means is electrically connected to a power source, and outputs a second voltage which corresponds to a voltage of the power source.
  • the comparison judgment means receives the first voltage supplied from the first voltage output means and the second voltage supplied from the second voltage output means.
  • the comparison judgment means compares the first voltage with the second voltage.
  • the comparison judgment means judges whether or not deterioration of the heater occurs on the basis of the comparison result.
  • a patent document 3 discloses a power supply control device for a heating device.
  • the heating device has a heating resistance element.
  • a resistance value of the heating resistance element changes in a positive correlation according to a change of a heating temperature thereof.
  • the heating device generates heat energy when receiving an electric power.
  • the power supply control device controls the power supply on the basis of a resistance value of the heating resistance element so that the resistance value of the heating resistance element becomes equal to a target resistance value.
  • the power supply control device for a heating device disclosed in the patent document 3 is comprised of a first obtaining means, an environmental information obtaining means, a calculation means and a power supply control means.
  • the first obtaining means supplies an electric power to the heating resistance element while an internal combustion engine is stopping, to which the heating device is mounted.
  • the environmental information obtaining means obtains environmental information around the heating device when the first obtaining means obtains the first resistance value of the heating resistance element.
  • the calculation means calculates the target resistance value on the basis of the first resistance value and the environmental information.
  • the power supply control means controls the power supply to the heating resistance element so that the resistance value of the heating resistance element becomes equal to the target resistance value when the internal combustion engine is driven.
  • the conventional deterioration judgment devices disclosed in the patent documents 1 and 2 use the current detection means and a shunt resistance, etc.
  • the current detection means detects a current flowing in the glow plug.
  • the shunt resistance is used as a threshold value in order to judge deterioration of the glow plug.
  • the resistance of the glow plug generally contains an unavoidable individual resistance value
  • a deterioration state of the glow plug neglects such unavoidable individual resistance value when the deterioration state of the glow plug is detected on the basis of a plug current, and a comparison result between a resistance value calculated by using a voltage supplied to the glow plug and a reference resistance having a constant resistance value.
  • a power supply control device in a conventional power supply control device for a glow plug controls the power supply to all of plural glow plugs mounted to corresponding cylinders of an internal combustion engine. Because each of the glow plugs has an unavoidable individual resistance value, a PWM control determines an average voltage V AVG to be supplied to the glow plugs on the basis of the minimum resistance value in the normal rated resistance value of the glow plugs and supplies an electric power determined by V AVR 2 / R GP to the glow plugs in order to avoid an excessive temperature rise of the glow plugs.
  • the glow plug power supply control device disclosed in the patent document 3 performs a complicated control because of using environmental information such as a temperature of the internal combustion engine.
  • the glow plug power supply control device has a large circuit size because of requiring a CPU having a high arithmetic processing capability and an interrupt timer, etc. This introduces a difficulty to mount the glow plug power supply control device into a limited engine mounting space in which highly integrated electric control devices are arranged.
  • the conventional glow plug power supply control device performs a A/D conversion of a plug current flowing in the glow plug and a plug voltage supplied to the glow plug, and transmits the converted values to the ECU.
  • the ECU performs an arithmetic process of the converted values.
  • the ECU stops the operation of the glow plug power supply control device and performs a temperature compensation process on the basis of the results of the arithmetic process.
  • This requires a high performance CPU and a high speed data communication means such as CAN because a large amount of data must be transmitted between the glow plug power supply control device and the ECU. This increases a manufacturing cost therefor.
  • the method disclosed in the patent document 3 has a large problem of decreasing an actual temperature of the glow plug, which is lower than the target temperature, caused by the influence of swirl when a constant target power is supplied to the glow plug.
  • a purpose of the present invention is to provide a heating device of a control section integrated-type having a simple and easy mounting structure.
  • the heating device of a control section integrated-type is capable of judging occurrence of deterioration of a heating element having different individual characteristics, irreversibly present, and adjusting the heating element in each heating device independently with high accuracy when a plurality of the heating devices is used simultaneously in an internal combustion engine.
  • the heating device is comprised of a heating element, a power supply control module and a housing casing.
  • the heating element and the power supply control module are assembled together in the housing casing.
  • the power supply control module is comprised of a reference resistance value storage means and a resistance value change reflecting means. A resistance value of the heating element changes in a positive correlation to a temperature change of the heating element.
  • the power supply control module controls a power source to supply electric power to the heating element so that the resistance value of the heating element becomes equal to a target resistance value.
  • the reference resistance value storage means stores, as a reference resistance value, a resistance value of the heating element at a predetermined target temperature, which is previously measured by the power supply control module.
  • a resistance value change reflecting means uses the reference resistance value as a threshold value, and allows the power supply to the heating element when the resistance value of the heating element is lower than the reference resistance value during the power supply to the heating element.
  • the resistance value change reflecting means halts the power supply to the heating element when the resistance value of the heating element exceeds the reference resistance value during the power supply to the heating element in order to reflect, to the power supply control, the resistance value change due to the temperature change of the heating element.
  • the heating device is comprised of a heating element, a power supply control module and a housing casing.
  • the heating element and the power supply control module are assembled together in the housing casing.
  • the power supply control module is comprised of a reference resistance value storage means, a resistance value change reflecting means and a deterioration judgment means. A resistance value of the heating element changes in a positive correlation to a temperature change of the heating element itself.
  • the power supply control module controls a power supply from a power source to the heating element so that the resistance value of the heating element becomes equal to a target resistance value.
  • the reference resistance value storage means stores, as a reference resistance value, a resistance value of the heating element at a predetermined target temperature, which is previously measured by the power supply control module.
  • a resistance value change reflecting means uses the reference resistance value as a threshold value, and allows the power supply to the heating element when the resistance value of the heating element is lower than the reference resistance value during the power supply to the heating element.
  • the resistance value change reflecting means halts the power supply to the heating element when the resistance value of the heating element exceeds the reference resistance value during the power supply to the heating element in order to reflect, to the power supply control, the resistance value change due to the temperature change of the heating element.
  • the deterioration judgment means judges whether or not the heating element is deteriorated on the basis of a deterioration power value in a deterioration state of the heating element, as a power threshold value, to be supplied to the heating element at a predetermined deterioration limit-temperature.
  • the deterioration power value in the deterioration state is calculated by multiplying together a predetermined rate and an initial power value, to be supplied to the heating element in a normal state at a predetermined temperature previously detected.
  • the reference resistance value of the heating element is adjusted by an electrical trimming.
  • the electrical trimming is a digital trimming by using a Zener zapping or a poly silicon fuse.
  • the heating element is a glow plug which is mounted to a respective cylinder of an internal combustion engine.
  • the deterioration judgment means performs a deterioration judgment of the heating element at a time selected from the time before a cranking of the internal combustion engine, the time immediately after the stop of the internal combustion engine, and the time during an idling stop operation.
  • the heating element and the power supply control module are assembled together in the housing casing. This makes it possible to adjust the reference resistance value of each heating element having an unavoidable different individual resistance value generated in a manufacturing process.
  • the resistance value change reflecting means performs a temperature control independently to the heating element with a high accuracy without considering the state of other heating devices.
  • the heating device can perform a self-contained temperature control without using any external information such as a temperature of water used in the engine, like the conventional device, it is possible for the heating device according to the present invention to have a very simple and easy mounting structure, and decrease the manufacture cost of the heating device.
  • the heating device when the heating device performs the temperature control so that a resistance value of the heating element becomes equal to the reference resistance value, there is a possibility of increasing a resistance value of the heating element after the long use of time. This decreases an effective power value and an actual heating temperature of the heating device.
  • the deterioration judgment means sets the effective power value to be not more than the power value when the heating element is deteriorated, and it is possible for the deterioration judgment means to judge occurrence of deterioration of the heating element when the heating temperature of the heating element is not more than a usable limit temperature.
  • the deterioration judgment means it is not necessary for the deterioration judgment means to use external environmental information, and transmit a lot of such information between the heating device and an external arithmetic processing device, and not necessary for the external arithmetic processing unit to perform the deterioration judgment process.
  • the conventional heating device requires for the external arithmetic processing unit to perform the deterioration judgment process. It is therefore possible for the heating device according to the present invention to perform a fast and self-contained judgment process for judging occurrence of deterioration of each of the heating elements with a simple structure. This makes it possible to allow an operator to do prompt countermeasure against the occurrence of deterioration of the heating element.
  • the glow plug 1 is comprised of a heating element 10 mounted to a corresponding cylinder in a plurality of cylinders mounted to an internal combustion engine, a detail of which is omitted from the drawings, a power supply control module 20 and a housing casing 30.
  • the power supply control module 20 performs a power supply control from a power source 6 to the heating element 10.
  • the housing casing 30 accommodates the heating element 10 and the power supply control module 20 together.
  • the glow plug 1 of a control section integrated-type is comprised of the heating element 10, the power supply control module 20, and the housing casing 30.
  • the heating element 10 generates heat energy when receiving an electric power.
  • a resistance value of the heating element 10 changes in a positive correlation to its temperature change.
  • the power supply control module 20 adjusts a power supply from the power source 6 to the heating element 10 so that the resistance value R GP of the heating element 10 becomes equal to a target resistance value R TRG .
  • the housing casing 30 accommodates the heating element 10 and the power supply control module 20 so that the heating element 10, the power supply control module 20 and the housing casing 30 are integrated together.
  • the power supply control module 20 is comprised of a reference resistance value storage means 231 and a resistance value change reflecting means 233.
  • the reference resistance value storage means 231 stores a resistance value of the heating element 10, as the reference resistance value R C , at a predetermined target temperature T TRG measured in advance.
  • the resistance value change reflecting means 233 uses the reference resistance value R C as a threshold value, and allows the power source to supply electric power to the heating element 10 when the resistance value R GP of the heating element 10 is lower than the reference resistance value R C during the power supply.
  • the resistance value change reflecting means 233 halts the power supply to the heating element 10 when the resistance value R GP of the heating element 10 exceeds the reference resistance value R C during the power supply to the heating element 10 in order to reflect, to the power supply control, the resistance value change due to the temperature change of the heating element 10.
  • the power supply control module 20 further has a deterioration judgment means 234.
  • the deterioration judgment means 234 judges whether or not the heating element 10 is deteriorated on the basis of a deterioration power value P WRN in a deterioration state, as a power threshold value P REF , to be supplied to the heating element 10 at a predetermined deterioration limit-temperature T WRN .
  • the power value P WRN in a deterioration state is calculated by multiplying together a predetermined rate and an initial reference power value P INT , to be supplied to the heating element 10 in a normal state, previously detected at a predetermined temperature.
  • the deterioration judgment means 234 has a self-diagnosis means for determining occurrence of deterioration of the heating element and outputs a self-diagnosis signal DI.
  • the self-diagnosis means judges the deterioration of the heating element when an effective power value P ACT becomes not more than the predetermined deterioration limit-temperature T WRN .
  • the effective power value P ACT is calculated on the basis of a plug current I GP actually flowing in the heating element 10 and a plug voltage V GP applied to the heating element 10 while considering a target power P TRG as a reference of a predetermined target temperature T TRG .
  • a concrete value of the deterioration power value P WRN a value obtained by multiplying a constant rate (for example, 90 %) and the initial reference power value P INT necessary for the heating element to reach a target temperature T TRG determined at a manufacturing process.
  • the glow plug 1 is comprised of the heating element 10 (1 ⁇ n) and the power supply control module 20 (1 ⁇ n) which are integrated together in the housing casing 30 (1 ⁇ n) .
  • the glow plug 1 of a control section integrated-type is connected to an engine control unit (ECU) 7 through connector terminals (41, 42, 43).
  • the heating element 10 (1 ⁇ n) is mounted to a respective cylinder of the internal combustion engine 8 (not shown in detail).
  • the power supply control module 20 (1 ⁇ n) receives a drive signal SI transmitted from the ECU 7.
  • a target temperature T TRG is determined on the basis of the drive signal SI.
  • the drive signal SI corresponds to a working state of the internal combustion engine 8.
  • the power supply control module 20 (1 ⁇ n) compares an actually-detected plug resistance value R GP with the reference resistance value R C , and adjusts the power supply from the power source 6 to the heating element 10 (1 ⁇ n) in synchronization with the drive signal SI on the basis of the comparison result.
  • the power supply control module 20 (1 ⁇ n) has a mold package 200 which accommodates at least a semiconductor open/close element 21, a drive circuit section 22 and a heating element control IC 23.
  • a power input terminal 201, a drive signal input terminal 202, a self-diagnosis signal output terminal 203, an output terminal 204 and a ground terminal 205 are outwardly arranged on the mold package 200 of the power supply control module 20.
  • MOS 21 N channel power MOS FET
  • the MOS 21 has a plurality of control MOS 210 (hereinafter, referred as main MOS 210) for opening/ closing a large current flowing in the heating element 10.
  • a current detection MOS 211 (hereinafter, referred to as a sense MOS 211) is used, as a part of the MOS 21, for detecting a current flowing in the heating element 10.
  • the main MOS 210 and the sense MOS 211 make a current mirror circuit.
  • a current detection resistance 212 is connected to the MOS 211.
  • the current detection resistance 212 is connected to a heating element control IC 23 through a sense terminal SEN.
  • the heating element control IC 23 is equipped with a deterioration judgment means 234 which is a main section of the present invention.
  • the drive circuit section (DRV) 22 is equipped with a booster means such as a charge pump.
  • the drive circuit section 22 outputs a predetermined drive voltage V GG which is boosted in order to drive the MOS 21 in synchronization with a falling edge of the drive signal SI.
  • the drive signal SI is outputted from the ECU 7 to the power supply control module 20 in order to determine a duty ratio T ON/ T with which the heating element generates heat energy to reach a target temperature T TRG which corresponds to the operation state of the internal combustion engine 8.
  • Timing charts shown in FIG. 6 and FIG. 7 show an example to initiate a power supply in synchronization with a falling edge of the drive signal SI. However, it is possible to optionally select one of a high level Hi and a low level Lo of the drive signal SI in order to drive the MOS 21 according to demand.
  • the charge pump is for example comprised of an operational amplifier 220, a charge capacitance 222, an output capacitance 224 and diodes 221 and 223.
  • the charging operation and the discharging operation are repeatedly performed by a switching operation of the operational amplifier 220.
  • the electric energy charged in the output capacitor 224 is discharged multiple times to boost the power source voltage V B to a gate voltage V GG .
  • the gate voltage V GG is twice as much as the power source voltage V B .
  • the boosted gate voltage V GG is supplied to a node between the gate and the source of the semiconductor open/close element 21.
  • FIG. 1 (a) shows the charge pump comprised of the operational amplifier 220, the diodes 221 and 223, and the capacitors 222 and 224.
  • the concept of the present invention is not limited by the boosting structure shown in (a) in FIG. 1 . It is acceptable to use a DC-DC converter of a chopper type comprised of a combination of a choke coil, a capacitor, a diode, etc. or a DC-DC converter of a fly-back type having a booster transformer, etc.
  • the heating element control IC 23 as a main part of the present invention is comprised of a resistance value arithmetic means 230, a reference resistance storage means (a reference resistance forming section) 231, a reference resistance adjusting means (Zener zap circuit) 232, a resistance value change reflecting means (F/B means) 233, an initial power reference resistance, an initial power reference resistance adjusting means (Zener zap circuit) and a deterioration judgment means 234.
  • the resistance value arithmetic means 230 calculates a plug resistance value R GP of the heating element 10 on the basis of the plug current I GP detected by the current detection resistance 212 previously described, and the plug voltage V GP (which is equal to the source voltage V SS of the semiconductor open/close element 21) applied from the semiconductor open/close element 21 to the heating element 10.
  • the sense MOS 211 detects the current I GP when the resistance value R GP is calculated.
  • the concept of the present invention is not limited by the exemplary method previously described.
  • the plug resistance value R GP of the heating element 10 is determined on the basis of resistance temperature characteristics of the heating element 10. There is a constant correlation between the heating temperature of the heating element 10 and the plug resistance value R GP .
  • the heating element 10 After the heating element 10 is connected to the power supply control module 20 during a manufacturing process of the glow plug 1 of a control section integrated-type, a power is supplied to the heating element 10 to increase a temperature thereof to a predetermined target temperature (T 1 ). At this time, an external device measures a resistance value of the heating element at the temperature (T 1 ) thereof, and uses the detected temperature as the reference resistance value R C .
  • the reference resistance value R C is stored in the reference resistance value storage means 231 (hereinafter, referred as "MEM 231") on the basis of a timing when receiving an external signal.
  • the resistance value change reflecting means (F/B means) 233 compares the reference resistance value R C stored in the MEM 231 with the plug resistance R GP detected when the heating element 10 is actually used.
  • the resistance value change reflecting means (F/B means) 233 outputs the comparison result to perform the feedback control.
  • the power supply control is performed by opening and closing the semiconductor open/close element 21 in order to maintain the reference resistance value R C of the heating element 10 on the basis of the reference resistance value R C corresponding to the individual resistance temperature characteristics of the heating element 10, it is possible to adjust the temperature of the heating element 10 to a desired heating temperature with a high accuracy when compared with a case in which the power supply to a plurality of heating elements is adjusted on the basis of a single control condition.
  • a long use of the heating element 10 makes a diffusion of metal forming electrodes into an insulation layer, and occurs a migration in which conductive components move between the heating element to the insulation layer, or increases the plug resistance value R GP because of increasing a contact resistance by separation of the electrodes and oxidation of the electrodes.
  • the glow plug 1 of a control section integrated-type performs the temperature control of the heating element without detecting an actual temperature of the heating element, that is, performs the power supply control so that the resistance value R GP becomes equal to the reference resistance value R C . It is therefore impossible to judge whether or not deterioration of the heating element occurs on the basis of an actual heating temperature of the heating element 10.
  • An initial power reference resistance value R PINT is obtained by performing an electric trimming of the initial reference power value P INT at an initial target temperature T TRG , for example, as a change of the effective power P ACT when it is adjusted so that the plug resistance value R GP is equal to the reference resistance value R C in order for a temperature of the heating element to reach the target temperature T TRG .
  • the obtained initial power reference resistance value R PINT is then stored. Occurrence of deterioration of the heating element is judged when the resistance of the heating element changes from the initial power reference resistance value P INT by not less than a constant value and the effective power P ACT becomes not more than the power threshold value P REF .
  • the feature of the present invention is that the resistance value R GP of the heating element 10 is not calculated and the judgment of the occurrence of deterioration of the heating element 10 is performed on the basis of a comparison result between the resistance value R GP of the heating element 10 and the threshold value. That is, the feature of the present invention is to perform the power supply control so that the resistance value R GP of the heating element 10 becomes equal to the reference resistance value R C having a constant value. Further, the feature of the present invention is to detect the occurrence of deterioration of the heating element 10 when the resistance value R PG at the predetermined temperature increases and the effective power P ACT is decreased due to the deterioration of the heating element 10, when the heating temperature of the heating element 10 is maintained constant.
  • the initial reference power value PINT As a reference value to be used for judging the occurrence of deterioration, it is possible to judge the deterioration of the heating element having different individual characteristics by using the resistance or a memory element which can be processed by a trimming process.
  • the reference resistance adjusting means 232 performs an electric trimming of the initial power reference resistance value R PINT . This allows the initial power reference resistance value R PINT to become an adjustable resistance.
  • the electric trimming is performed by a digital trimming which uses a Zener zapping or a poly silicon fuse.
  • the glow plug 1 of a control section integrated-type has a structure in which the housing casing 30, the heating element 10, the power supply control module 20 and the connector section 40 are assembled together.
  • the housing casing 30 has substantially a cylindrical shape.
  • the heating element 10 is arranged at a front section of the housing casing 30.
  • the housing casing 30 accommodates the power supply control module 20.
  • the connector section 40 allows the glow plug to communicate with external devices.
  • the present invention to use, as the heating element 10, a metal heater 10 shown in FIG. 2 (d) or a ceramic heater 10a shown in FIG. 2 (e).
  • the metal heater 10 is comprised of a metal protection tube 103, a heating coil 102, a control coil 104 and insulation material 100.
  • the metal protection tube 103 has substantially a cylindrical shape having a base section, a distal end of the metal heater 10 is open, and a front section of the metal heater 10 is closed.
  • Each of the heating coil 102 and the control coil 104 is made of metal resistance wire coil.
  • the insulation material 100 is magnesia powder, etc. and stored in the metal protection tube 103.
  • a ground section 101 arranged at the front side of the heating coil 102 is electrically connected to the metal protection tube 103.
  • the distal end of the control coil 103 is connected to an input terminal 106.
  • the input terminal 106 allows the power supply control module 20 to communicate with the metal heater 10.
  • the heating coil 102 and the metal protection tube 103 are made of known material such as Fe-Cr-Al alloy, Fe-Cr alloy, Ni-Cr alloy and are formed to have a predetermined resistance value.
  • the ceramic heater 10a is comprised of a ceramic resistance member 102a, a pair of lead sections 103a and 104a, and an insulation member 100a.
  • the ceramic resistance member 12a has a character U-like shape. Through the lead sections 103a and 104a, external devices communicate with the ceramic resistance member 102a.
  • the insulation member 100a has substantially a rod-like shape with which the lead sections 103a and 104a are covered. One end part of the lead section 103a connected to one end part of the ceramic resistance member 102a is extended toward a direction of a side surface of the insulation member 100a.
  • a ground terminal 101a is formed at the side surface of the insulation member 100a.
  • a front end section of the lead section 104a connected to the other end part of the ceramic resistance member 102a is extended to the distal end section of the insulation member 100a, at which an input terminal 105a is formed.
  • the input terminal 105a is connected to the power supply control module 20 through an input terminal metallic part 106a.
  • the ceramic resistance member 102a is made of a conductive ceramic material, for example, a sintered member of a mixture of silicon nitride and tungsten carbide.
  • lead sections 103a and 104a are made of heat resistant metal material such as tungsten.
  • the insulation member 100a is made of insulation ceramic material such as silicon nitride.
  • the metal heater 10 or the ceramic heater 10a is supported and fixed by a heating-member supporting member having substantially a cylindrical shape.
  • the heating-member supporting member is made of metal such as SUS (Stainless steel in Japanese Industrial standards), and has substantially a cylindrical shape.
  • the metal heater 10 or the ceramic heater 10a is supported and fixed in the inside of the heating-member supporting member.
  • the heating-member supporting member is electrically connected to the metal protection tube 103 or the ground terminal 101a so that one end of the heating element 10 is grounded and connected to the internal combustion engine through the housing casing 30.
  • the metal protection tube 103 is fixed together to the heating-member supporting member by a known method such as laser welding, brazing and screws.
  • the insulation member 100a and the heating-member supporting member are fitted together or fixed together by known methods such as brazing.
  • the housing casing 30 is comprised of a housing base member 300 which has substantially a cylindrical shape.
  • a front side cylinder section is formed at the front side of the housing casing 30 in order to support the heating-member supporting member.
  • a distal end cylindrical section of the heating-member supporting member is inserted into and fitted to the front side cylinder section of the housing casing 30 by welding, etc.
  • a screw section 303 is formed on an outer periphery of the housing casing 30 to screw and fix the glow plug 1 to the combustion chamber of the internal combustion engine.
  • the power supply control module 20 and the connector section 40 is accommodated in the inside of the distal end section of the housing casing 30. Through the connector section 40, the power supply control module 20 communicates with the external devices.
  • a hexagonal section 304 is formed at the outer periphery of the distal end side of the housing casing 30 to screw up the screw section 303.
  • the connector section 40 is covered with a collar which has substantially a cylindrical shape and fixed to the distal end side of the housing casing 30.
  • the connector section 40 is comprised of a resin formation section and the connector terminals 41, 42 and 43.
  • the resin formed section is made of plastic resin, etc. and has substantially a cylindrical shape.
  • the connector terminals 41, 42 and 43 are fixed to the inside of the resin formation section.
  • the connector terminals 41, 42 and 43 communicate with the external devices.
  • a fitting section 401 is formed at a distal end side of the connector section 40.
  • the fitting section 401 has substantially a cylindrical shape.
  • the fitting section 401 and a connector of the external device are fitted together.
  • a terminal fixing section is formed at a middle part of the connector section 40.
  • the connector terminals 41, 42 and 43 are inserted and fixed to the terminal fixing section.
  • the connector terminals 41, 42 and 43 communicate with the external devices.
  • the connector terminals 41, 42 and 43 correspond to the power input terminal, the drive signal input terminal and the self-diagnosis signal output terminal, respectively. It is possible to increase and decrease the number of the connector terminals according to a necessity.
  • a control module accommodation space is partitioned by a front end side partition section.
  • the control module accommodation space accommodates the power supply control module 20.
  • the power input terminal 41, the drive signal input terminal 42 and the self-diagnosis signal output terminal 43 are connected to the power input terminal 201, the drive signal input terminal 202 and the self-diagnosis signal output terminal 203 of the power supply control module 20, respectively
  • the output terminal 204 (source terminal V SS ) of the power supply control module 20 is connected to the heating element 10, 10a through a central axis 24 to supply electric power.
  • a GND terminal 205 is connected to the housing casing 30 through a ground terminal 250, and further connected to the internal combustion engine through the housing casing 30.
  • the MOS 21, DRV 22, JDG 23, etc. are assembled together, covered with epoxy resin and accommodated in the mold package 200. Further, lead frames are extended from the mold package 200 to form the power input terminal 41 (BAT), the drive signal input terminal 42 (SI), the self-diagnosis signal output terminal 43 (DI), the output terminal 204 (V SS ), and the ground terminal 205 (GND).
  • the power supply control module 20 shown in FIG. 1 is a DIP type (Dual Inline Package type) package.
  • DIP type Dual Inline Package type
  • the concept of the present invention is not limited by the structure. It is possible to use a SIP type (Single Inline Package type) or another known IC package according to a necessity.
  • a small-size discrete semiconductor element package such as a TO-220 type package. That is, the input terminal, the ground terminal and the output terminal are sequentially arranged and expended from the small-size discrete semiconductor element package, in which a power MOS FET and a control IC can be implemented together, for example, made of mold resin package having a size of approximately 10 mm x 17 mm x 4.5 mm.
  • FIG. 3 shows a normal state, that is, a relationship between a temperature of the heating element and a resistance value of the heating element under a saturation state of the temperature and the resistance value of the heating element after the elapse of a predetermined time counted from the time when an electric power is supplied to the heating element.
  • the alternate long and short dash line indicates the initial resistance temperature characteristics R INT
  • the dotted line indicates the resistance temperature characteristics R ACT
  • the solid line indicates the deterioration resistance temperature characteristics R WRN under deterioration.
  • the initial state and the deterioration state have the same slope of the resistance temperature characteristics, that is, the slope of the resistance temperature characteristics is not changed in the initial state and the deterioration state.
  • the resistance temperature characteristics R WRN of the heating element is shifted in parallel from the initial resistance temperature characteristics R INT so that the resistance value of the heating element increases as deterioration goes on when compared with the initial resistance value thereof.
  • FIG. 4 is a flow chart showing an initial temperature rising mode (M INT ).
  • the process in step S100 starts the initial temperature rising mode (M INT ) starts when an operator turns on a key switch SW.
  • step S110 recognizes a drive signal SI transmitted from the ECU 30.
  • the operation flow goes to step S120.
  • the process in step S120 starts the power supply to the heating element 10.
  • step S130 detects the plug voltage V GP and the plug current I GP flowing in the heating element 10.
  • step S140 calculates the plug resistance value R GP on the basis of the detected plug current I GP and the detected plug voltage V GP .
  • step S150 compares the plug resistance value R GP with the reference resistance value R C corresponding to the target temperature at the initial state. Further, the process in step S150 detects whether or not the plug resistance value R GP reaches the reference resistance value R C , that is, whether or not the heating temperature of the heating element reaches the target temperature.
  • step S120 it is possible to perform a pre heating control mode (M PRE ) in steps S121, S122 and S123 in order to prevent excessive temperature rise.
  • M PRE pre heating control mode
  • step S121 compares the plug resistance value R GP with a pre-heating control mode switching reference resistance value R CH , where the pre-heating control mode switching reference resistance value R CH indicates a resistance value (which corresponds to a pre-heating target temperature, for example, corresponding to 1,000 °C) which is slightly lower than the reference resistance value R C .
  • the comparison result indicates No.
  • the operation flow goes to step S123.
  • the process in step S123 supplies an electric power having approximately 100 % duty which exceeds a normal rated power in order to quickly increase the temperature of the heating element 10 to the pre-heating target temperature.
  • step S121 when the plug resistance value R GP exceeds the pre-heating control mode switching reference resistance value R CH , the judgment result indicates Yes.
  • the operation flow goes to step S122 in order to perform the pre-heating control mode (M PRE ).
  • the process in step S122 performs the on/off control of the pre-heating control mode so that a temperature of the heating element becomes a constant temperature which is lower than the target temperature during approximately one second only, for example, using the pre-heating control mode switching reference resistance value R CH as a threshold value.
  • step S1221 it is judged whether or not a constant time t ref is elapsed from the time at which the pre-heating control mode starts.
  • step S1222 performs a power supply allowable judgment.
  • the process in step S1222 compares the plug resistance value R GP with the pre-heating control mode switching reference resistance value R CH in order to judge whether or not there is a necessity of the power supply.
  • step S1222 When the comparison result in step S1222 indicates R GP > R CH , the judgment result indicates Yes.
  • the operation flow goes to step S1223.
  • the process in step S1223 halts the power supply, i.e., the state of the power supply is turned off in step S1223.
  • the comparison result in step S1222 indicates R GP ⁇ R CH , the judgment result indicates No.
  • the operation flow goes to step S1224.
  • step S1224 allows the power supply, i.e., the state of the power supply is turned on in step S1224.
  • step S1225 which performs the resistance value calculation process.
  • step S1225 the plug resistance value R GP is calculated again.
  • the operation flow returns to step S1221 and the operation loop is repeated.
  • the operation flow completes the pre-heating control mode and goes to the main routine.
  • the pre-heating control mode (M PRE ) in step S122 prevents an over-heating of the heating element during the temperature rising process (transition mode M TRN ) to the normal control mode (M CST ) because of maintaining the heating element at a temperature which is lower than the target temperature of 1,250 °C, for example by approximately 250 °C for a predetermined period of time.
  • the deterioration judgment is not performed during the initial temperature rising mode (M INT ) because the plug resistance value R GP changes according to the temperature rise of the heating element.
  • pre-temperature control modes for example, a first pre-temperature control mode having a first pre-heating target temperature of 1,000 °C, a second pre-temperature control mode having a second pre-heating temperature of 1,100°C, etc.
  • the present invention stores in the control module 20 the information regarding the first pre-heating reference resistance and the second pre-heating reference resistance which correspond to the respective target temperatures in order for the control module 20 to independently process even if using a plurality of the pre-heating control modes.
  • control module 20 Similar to the pre-heating control mode having a single pre-heating target temperature, it is possible for the control module 20 to perform the pre-heating control without the process of the ECU, that is, to judge whether or not there is a necessity of the power supply, for example, in step S121 or step S150, on the basis of the comparison result between the plug resistance value R GP and the corresponding reference resistance value, and perform the on/off control of the MOS 21 so that the plug resistance value R GP becomes equal to the corresponding reference resistance value.
  • the power source 6 has an adequate amount of electric power, there is a possibility of delaying the temperature rising speed of the heating elements when the electric power is supplied simultaneously to a plurality of the heating elements 10 (1 ⁇ n) and a large amount of inrush current is generated and the power source 6 has a heavy load.
  • each of the glow plugs 1 (1 ⁇ n) of a control section integrated-type, which is mounted to the corresponding cylinder in the internal combustion engine, is independently equipped with the power supply control module 20.
  • An electric power is supplied independently to the heating element 10 (1 ⁇ 10) of each of the glow plugs 1 (1 ⁇ n) .
  • each of the glow plugs 1 (1 ⁇ n) it is preferable for each of the glow plugs 1 (1 ⁇ n) to have a self-cylinder position judgment means and a driving-time delay means.
  • the self-cylinder position judgment means detects a position of the cylinder which corresponds to the own glow plug 1.
  • the driving-time delay means delays the timing to initiate the power supply according to the cylinder corresponding to the own glow plug 1.
  • FIG. 5 is a flow chart showing the normal control mode.
  • step S200 the power supply control is performed on the basis of the drive signal SI, and the reference resistance value R C of each of the heating elements 10. Further, it is possible to provide the warning on the basis of the judgment result of deterioration of the heating element.
  • step S210 the power supply to the heating element 10 is initiated.
  • step S220 the plug current I GP flowing in the heating element 10 and the plug voltage V GP are detected.
  • the effective power value P ACT and the plug resistance value R GP are calculated on the basis of the plug current I GP and the plug voltage V GP .
  • step S240 detects the occurrence of deterioration based on a comparison result between the effective power value P ACT and the power threshold value P REF by using a threshold value.
  • the deterioration power value P WRN in the deterioration state is used as the power threshold value P REF , which is a decreased power value, for example 90 % of the initial reference power value P INT at the initial state.
  • step S240 it is judged that the heating element is not deteriorated when the effective power value P ACT is not less than the power threshold value P REF .
  • the judgment result indicates Yes and the operation flow goes to step S250 in order to perform the resistance value change reflecting means (F/B process).
  • step S240 it is judged that the heating element is deteriorated when the effective power value P ACT is lower than the power threshold value P REF (for example, when the effective power value is not more than 90 % of the initial reference power value P INT ).
  • the judgment result indicates No and the operation flow goes to step S260 in order to perform the abnormality judgment signal output process.
  • the resistance value change reflecting means (F/B process) in step S250 compares the plug resistance value R GP with the reference resistance value R C in order to perform the feedback of the plug resistance value. When the plug resistance value R GP exceeds the reference resistance value R C , the judgment result indicates Yes. The operation flow goes to step S270 in order to perform the power supply stop process. When the plug resistance value R GP is not more than the reference resistance value R C , the judgment result indicates No. The operation flow goes to step S280 in order to perform the power supply continuation process.
  • step S270 the power supply is stopped because it is judged that the heating temperature of the heating element 10 reaches the target temperature value.
  • the operation flow returns to step S210.
  • step S280 the power supply is continued because it is judged that the heating temperature value of the heating element does not reach the target temperature value.
  • step S210 to step S280 are repeated in order to control the power supply to the heating element and maintain the plug resistance value R GP of each of the glow plugs 1 (1 ⁇ n) at a resistance value close to the individual reference resistance value R C .
  • the abnormality judgment signal output process in step S260 outputs the self-diagnosis signal DI, in order for example to turn on a warning lamp, inform occurrence of the abnormality deterioration state, recommend the replacement of the glow plug to the driver of the motor vehicle, and/or stop the power supply to the heating element 10.
  • FIG. 6 shows a control result without performing the pre-heating mode.
  • the drive signal SI determines the duty ratio in order to determine the target temperature T TRG which corresponds to the driving state of the internal combustion engine.
  • the MOS 21 is opened and closed in synchronization with a rising edge or a falling edge of the drive signal SI on the basis of the judgment result regarding the necessity of the power supply detected by the resistance value change reflecting means 233, as previously described.
  • step S250 indicates yes when the plug resistance value R GP exceeds the reference resistance value R C .
  • the resistance value change reflecting means 233 outputs a value of zero, and the power supply to the heating element 10 is not performed.
  • the power supply to the heating device 10 is not immediately stopped, but is continued by the duty ratio (for example, 90 % duty ratio) indicated by the drive signal SI after an elapse of one pulse.
  • the MOS 21 is turned on at a following rising edge of the drive signal SI in order to halt the power supply to the heating element 10.
  • the judgment result in step S250 indicates No.
  • the resistance value change reflecting means 233 outputs a value of one, and the MOS 21 is turned off at a falling edge of the following drive signal SI in order to perform the power supply to the heating element 10.
  • the reference resistance value R C is used to determine whether the power supply to the heating element 10 starts as shown in FIG. 6 (c) .
  • the MOS 21 is turned off in synchronization with a rising edge of the drive signal SI during the OFF state of the judgment result (JDG) shown in FIG. 6 (c) , and the MOS 21 is turned on in synchronization with a falling edge of the drive signal SI during the ON state of the judgment result (JDG) shown in FIG. 6 (c) .
  • the control module 20 in each heating device can independently perform the feedback F/B control of the plug resistance R GP so that the plug resistance R GP becomes equal to the reference resistance value R C . This makes it possible to perform the control of the temperature of the heating element 10 to be equal to the target temperature T TRG without using any temperature of engine cooling water and other temperature information.
  • FIG. 7 shows timing charts from the initial state to the deterioration state of the heating element in the heating device during the normal control mode according to the present invention.
  • the ECU 7 outputs the drive signal SI which is determined according to the target temperature TTRG without regard for the deterioration state of the heating element 10.
  • the heating element 10 is gradually deteriorated due to a long use thereof, and a resistance value R GP of the heating element 10 to a constant heating temperature also gradually increases.
  • the timing indicates a time when the resistance value R GP of the heating element 10 exceeds the reference resistance value Rc after the power supply is started in synchronization with a falling edge of the drive signal SI. Further, when the power supply is performed on the basis of a constant duty ratio, the maximum value of the resistance value R GP during a period also increases.
  • the plug current I GP becomes low, as shown in FIG. 7 (e) , and as a result, the effective power value P ACT gradually decreases, as shown in FIG. 7 (f) .
  • the heating temperature T of the heating element is maintained with the target temperature T TRG and the heating temperature T is decreased by not less than ⁇ T together with the deterioration progress. Finally, the heating temperature is decreased to a value of not more than predetermined deterioration limit-temperature T WRN . In this case, the self-diagnosis signal DI is outputted.
  • the reference resistance value R C and the initial reference power value P INT of each of the heating elements 10 are stored in the MEM 232.
  • the power supply control module 20 corresponding to each of the heating elements 10 performs the power supply control and the abnormality deterioration judgment process on the basis of the corresponding reference resistance value R C and initial reference power value P INT of each of the heating elements 10. It is therefore possible to maintain the temperature of the heating element with high accuracy without being affected by deterioration of other glow plugs, and to provide warning information at an optimum and correct timing.
  • the deterioration of the heating element is detected in the normal control mode when the power supply to the glow plug 1 is performed, i.e. the pre-glow control is performed, where the pre-glow control assists the ignition of the internal combustion engine.
  • the pre-glow control assists the ignition of the internal combustion engine.
  • step S340 the second deterioration current I WRN2 is used as a threshold value with which the plug current I GP is compared.
  • the resistance value change reflecting means (F/B process) in step S350 compares the plug resistance value R GP with a second reference resistance value R C2 which is calculated on the basis of the plug resistance value R GP and the reference resistance value R C in order to perform the threshold judgment.
  • the second deterioration power value P WRN2 and the second reference resistance value R C2 are lower than those in the normal control mode, respectively.
  • the conventional deterioration judgment devices perform the deterioration judgment of the glow plug within a limited period of time immediately after the power supply is stopped.
  • the glow plug 1 of a control section integrated-type according to the present invention always performs the deterioration judgment of the glow plug 1 during both the normal control mode and the after glow control mode. This makes it possible to quickly detect occurrence of abnormality deterioration of the glow plug and take necessary measures.
  • FIG. 9 (a) is a characteristic view showing a temperature control state of the glow plug 1 of a control section integrated-type without performing the pre-heating control mode.
  • FIG. 9 (b) is a characteristic view showing a temperature control state of the glow plug 1 of a control section integrated-type when the pre-heating control mode is performed.
  • FIG. 9 (c) is a characteristic view showing a temperature control state of the glow plug 1 of a control section integrated-type in the after glow control mode.
  • a temperature of the heating element is quickly increased by using approximately 100 % duty ratio or an excessive power supply in the initial temperature rising mode (M INT ). Further, because the rapid temperature rapid rising control is switched to the temperature rising suppress control in the mode switching temperature T CH which is lower than the first target temperature T 1 , an excessive temperature rising of the glow plug is suppressed. Because the power supply control is performed on the basis of the feedback using the drive signal with the reference resistance value R C as the threshold value corresponding to the resistance temperature characteristics of the individual glow plug after the temperature of the heating element reaches the first target temperature, it is possible to always perform the abnormality deterioration judgment during the normal control mode quickly detect the abnormality deterioration. Further, it is possible to maintain the temperature of the heating element at the second target temperature with high accuracy during the after glow control mode. Still further, it is possible to always perform the abnormality deterioration judgment during the after glow control mode and quickly detect the abnormality deterioration.
  • the pre-heating control mode M PRE when the pre-heating control mode M PRE , as shown in FIG. 9 (b) , it is possible to securely prevent an over-temperature rising of the heating element because the temperature of the heating element is maintained lower than the target temperature for a predetermined period of time.
  • the normal control mode M CST is performed to maintain the heating element at the target temperature. In this case, the deterioration judgment is performed under the condition in which a temperature of the heating element under one of the pre-heating control mode M PRE and the normal control mode M CST becomes stable.
  • the exemplary embodiment previously described show the method of detecting deterioration and the power supply control which are performed simultaneously during the normal control mode and the after glow control mode.
  • the exemplary embodiment shown in FIG. 10 shows the method of performing the deterioration judgment before a cranking or a time immediately after the internal combustion engine has stopped, or during the idle stop control, as a method of eliminating disturbance caused by an operation state and detecting occurrence of deterioration with high accuracy.
  • step S400 In the drive state recognition process in step S400 shown in FIG. 10 , information regarding operation state such as engine rotation speed, etc. is inputted. In the deterioration judgment process in step S410, it is detected that the current state is one of the state before the cranking, the state immediately after the internal combustion engine has stopped, and the state during the idle stop control on the basis of the information input in step S400.
  • the judgment result indicates Yes when the current state is one of the state before the cranking, the state immediately after the internal combustion engine has stopped, and the state during the idle stop control.
  • the operation flow goes to step S430.
  • the judgment result indicates No when the current state is not one of the state before the cranking, the state immediately after the internal combustion engine has stopped, and the state during the idle stop control.
  • the operation flow returns to step S400 without performing the deterioration detection process.
  • the effective power value P ACT is calculated on the basis of the plug voltage V GP applied to the heating element 10 and the plug current I GP flowing in the heating element 10.
  • the calculated effective power value P ACT is compared with the predetermined power threshold value P REF .
  • the exemplary embodiment shows the example in which the N channel power MOS FET is arranged at an upstream side of the load, and driven to open and close by using a high-side driver.
  • the concept of the present invention is not limited by this structure. It is possible to arrange a P channel power MOS FET at a high side instead of the N channel power MOS FET.
  • N channel power MOS FET in order to perform the open and close control by using a low side driver. Although this case causes a problem to supply a voltage to the glow plug during no operation of the glow plug, this does not require a boosting means such as a charge pump, and provides a simple circuit structure.

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Abstract

A heating device (1) has a heating element (10) capable of generating heat energy when receiving an electric power, and a power supply control module (20) for performing a power supply so that a plug resistance value RGP of the heating element becomes equal to a target resistance value RTRG. The heating element and the electric power supply control module are accommodated together in a housing casing (30) of a cylinder-like shape. The power supply control device (20) has a reference resistance value storage means (231) for storing a resistance value of the heating device, as a reference resistance value RC, at a predetermined target temperature TTRG, a resistance value change reflecting means (233) and a deterioration judgment means (234). The resistance value change reflecting means (233) allows the power supply to the heating element (10) when the plug resistance value RGP of the heating element (10) is lower than the reference resistance value RC during the power supply to the heating element (10), and halts the power supply to the heating element (10) when the plug resistance value RGP of the heating element (10) exceeds the reference resistance value RC during the power supply to the heating element (10) in order to reflect, to the power supply control, the resistance value change due to the temperature change of the heating element (10). The deterioration judgment means (234) judges whether or not the heating element (10) is deteriorated by using a deterioration power value PWRN in a deterioration state, as a power threshold value PREF, calculated by multiplying an initial reference power value PINT with a predetermined rate.

Description

    Technical Field
  • The present invention relates to heating elements and heating devices. A resistance value of the heating element changes in a positive correlation according to a change of a heating temperature thereof. The heating device of a control section integrated-type is equipped with the heating element and a power supply control module. The power supply control module is capable of controlling a power supply from an electric power source to the heating element. The heating device of a control section integrated-type has a simple structure, provides a stable power supply control and detects an abnormality deterioration state of the heating element. In particular, the present invention is preferably applied to a glow plug of a control section integrated-type, which is mounted to a respective cylinder of a diesel internal combustion engine. The glow plug of a control section integrated-type is comprised of the heating element and the power supply control module assembled together in a housing casing having a cylindrical shape.
  • Background art
  • Conventional abnormality detection devices are known, which are capable of detecting abnormal wire break and abnormal over current in a glow plug. The glow plug assists ignition of a diesel engine. The conventional abnormality detection device has a current detection means such as a current sensor, a shunt resistance arranged between a glow plug and a switching means. The switching means adjusts a power supply to the glow plug. The current detection means calculates a resistance value of the glow plug on the basis of a current which flows in the glow plug and a voltage applied to the glow plug. A known conventional abnormality detection device detects deterioration of the glow plug and abnormal wire break on the basis of the calculated resistance value of the glow plug.
  • A patent document 1 discloses a deterioration detection device for a glow plug comprised of a detection means and a judgment means. The detection means detects a detection value corresponding to a resistance of a glow plug when a power supply device supplies an electric power to the glow plug. The glow plug assists ignition of an internal combustion engine. The judgment means instructs the power supply device to supply an electric power to the glow plug immediately after the internal combustion engine has stopped, and judges deterioration of the glow plug on the basis of a resistance value detected by the detection means.
  • A patent document 2 discloses a heater deterioration detection device comprised of a first voltage output means, a second voltage output means and a comparison judgment means. The first voltage output means converts a current which flows in a heater to a first voltage and outputs the converted first voltage. The second voltage output means is electrically connected to a power source, and outputs a second voltage which corresponds to a voltage of the power source. The comparison judgment means receives the first voltage supplied from the first voltage output means and the second voltage supplied from the second voltage output means. The comparison judgment means compares the first voltage with the second voltage. The comparison judgment means judges whether or not deterioration of the heater occurs on the basis of the comparison result.
  • A patent document 3 discloses a power supply control device for a heating device. The heating device has a heating resistance element. A resistance value of the heating resistance element changes in a positive correlation according to a change of a heating temperature thereof. The heating device generates heat energy when receiving an electric power. The power supply control device controls the power supply on the basis of a resistance value of the heating resistance element so that the resistance value of the heating resistance element becomes equal to a target resistance value. The power supply control device for a heating device disclosed in the patent document 3 is comprised of a first obtaining means, an environmental information obtaining means, a calculation means and a power supply control means. The first obtaining means supplies an electric power to the heating resistance element while an internal combustion engine is stopping, to which the heating device is mounted. The environmental information obtaining means obtains environmental information around the heating device when the first obtaining means obtains the first resistance value of the heating resistance element. The calculation means calculates the target resistance value on the basis of the first resistance value and the environmental information. The power supply control means controls the power supply to the heating resistance element so that the resistance value of the heating resistance element becomes equal to the target resistance value when the internal combustion engine is driven.
  • Prior Art technical document Patent document
    • Patent document 1: Japanese patent laid open publication No. JP 2009-36092 ;
    • Patent document 2: Japanese patent laid open publication No. JP 2009-191842 ; and
    • Patent document 3: Japanese patent laid open publication No. JP 2010-127487 .
    Summary of the Invention Problem to be solved by the Invention
  • The conventional deterioration judgment devices disclosed in the patent documents 1 and 2 use the current detection means and a shunt resistance, etc. The current detection means detects a current flowing in the glow plug. The shunt resistance is used as a threshold value in order to judge deterioration of the glow plug.
  • Because the resistance of the glow plug generally contains an unavoidable individual resistance value, a deterioration state of the glow plug neglects such unavoidable individual resistance value when the deterioration state of the glow plug is detected on the basis of a plug current, and a comparison result between a resistance value calculated by using a voltage supplied to the glow plug and a reference resistance having a constant resistance value.
  • For example, under a condition in which a glow plug has a high initial resistance value, and a temperature of the glow plug can reach a target temperature value even if the resistance value thereof slightly increases according to the use, there is a possibility of judging that the glow plug deteriorates when a detected resistance value of the glow plug exceeds a threshold value even though the glow plug has not deteriorated. On the other hand, when a glow plug has a low initial resistance, there is a possibility of judging that the glow plug has not deteriorated and correctly works even if a resistance value increases according to the use because the glow plug has the low initial resistance value and a resistance value of the glow plug does not exceed its threshold value.
  • Further, a power supply control device in a conventional power supply control device for a glow plug controls the power supply to all of plural glow plugs mounted to corresponding cylinders of an internal combustion engine. Because each of the glow plugs has an unavoidable individual resistance value, a PWM control determines an average voltage VAVG to be supplied to the glow plugs on the basis of the minimum resistance value in the normal rated resistance value of the glow plugs and supplies an electric power determined by VAVR 2/ RGP to the glow plugs in order to avoid an excessive temperature rise of the glow plugs.
  • Accordingly, even if the PMW control avoids the excessive temperature rise of the glow plug having the minimum resistance value, there is a possibility of decreasing a reached temperature value and a temperature rising speed of the glow plug having a high resistance value.
  • Further, the glow plug power supply control device disclosed in the patent document 3 performs a complicated control because of using environmental information such as a temperature of the internal combustion engine. The glow plug power supply control device has a large circuit size because of requiring a CPU having a high arithmetic processing capability and an interrupt timer, etc. This introduces a difficulty to mount the glow plug power supply control device into a limited engine mounting space in which highly integrated electric control devices are arranged.
  • Further, in order to control a heating temperature of the glow plug with high accuracy and detect an abnormality state of the glow plug, the conventional glow plug power supply control device performs a A/D conversion of a plug current flowing in the glow plug and a plug voltage supplied to the glow plug, and transmits the converted values to the ECU. The ECU performs an arithmetic process of the converted values. The ECU stops the operation of the glow plug power supply control device and performs a temperature compensation process on the basis of the results of the arithmetic process. This requires a high performance CPU and a high speed data communication means such as CAN because a large amount of data must be transmitted between the glow plug power supply control device and the ECU. This increases a manufacturing cost therefor.
  • In addition, the method disclosed in the patent document 3 has a large problem of decreasing an actual temperature of the glow plug, which is lower than the target temperature, caused by the influence of swirl when a constant target power is supplied to the glow plug.
  • A purpose of the present invention is to provide a heating device of a control section integrated-type having a simple and easy mounting structure. The heating device of a control section integrated-type is capable of judging occurrence of deterioration of a heating element having different individual characteristics, irreversibly present, and adjusting the heating element in each heating device independently with high accuracy when a plurality of the heating devices is used simultaneously in an internal combustion engine.
  • Means for solving the problem
  • In the invention recited in claim 1, the heating device is comprised of a heating element, a power supply control module and a housing casing. The heating element and the power supply control module are assembled together in the housing casing. The power supply control module is comprised of a reference resistance value storage means and a resistance value change reflecting means. A resistance value of the heating element changes in a positive correlation to a temperature change of the heating element. The power supply control module controls a power source to supply electric power to the heating element so that the resistance value of the heating element becomes equal to a target resistance value. The reference resistance value storage means stores, as a reference resistance value, a resistance value of the heating element at a predetermined target temperature, which is previously measured by the power supply control module. A resistance value change reflecting means uses the reference resistance value as a threshold value, and allows the power supply to the heating element when the resistance value of the heating element is lower than the reference resistance value during the power supply to the heating element. The resistance value change reflecting means halts the power supply to the heating element when the resistance value of the heating element exceeds the reference resistance value during the power supply to the heating element in order to reflect, to the power supply control, the resistance value change due to the temperature change of the heating element.
  • In the invention recited in claim 2, the heating device is comprised of a heating element, a power supply control module and a housing casing. The heating element and the power supply control module are assembled together in the housing casing. The power supply control module is comprised of a reference resistance value storage means, a resistance value change reflecting means and a deterioration judgment means. A resistance value of the heating element changes in a positive correlation to a temperature change of the heating element itself. The power supply control module controls a power supply from a power source to the heating element so that the resistance value of the heating element becomes equal to a target resistance value. The reference resistance value storage means stores, as a reference resistance value, a resistance value of the heating element at a predetermined target temperature, which is previously measured by the power supply control module. A resistance value change reflecting means uses the reference resistance value as a threshold value, and allows the power supply to the heating element when the resistance value of the heating element is lower than the reference resistance value during the power supply to the heating element. The resistance value change reflecting means halts the power supply to the heating element when the resistance value of the heating element exceeds the reference resistance value during the power supply to the heating element in order to reflect, to the power supply control, the resistance value change due to the temperature change of the heating element. The deterioration judgment means judges whether or not the heating element is deteriorated on the basis of a deterioration power value in a deterioration state of the heating element, as a power threshold value, to be supplied to the heating element at a predetermined deterioration limit-temperature.
    The deterioration power value in the deterioration state is calculated by multiplying together a predetermined rate and an initial power value, to be supplied to the heating element in a normal state at a predetermined temperature previously detected.
  • In the invention recited in claim 3, the reference resistance value of the heating element is adjusted by an electrical trimming.
  • In the invention recited in claim 4, the electrical trimming is a digital trimming by using a Zener zapping or a poly silicon fuse.
  • In the invention recited in claim 5, the heating element is a glow plug which is mounted to a respective cylinder of an internal combustion engine.
  • In the invention recited in claim 6, the deterioration judgment means performs a deterioration judgment of the heating element at a time selected from the time before a cranking of the internal combustion engine, the time immediately after the stop of the internal combustion engine, and the time during an idling stop operation.
  • Effects of the invention
  • According to the invention recited in claim 1, the heating element and the power supply control module are assembled together in the housing casing. This makes it possible to adjust the reference resistance value of each heating element having an unavoidable different individual resistance value generated in a manufacturing process. When considering a change of a resistance value accompanied with a temperature change, the resistance value change reflecting means performs a temperature control independently to the heating element with a high accuracy without considering the state of other heating devices.
  • In addition, because the heating device can perform a self-contained temperature control without using any external information such as a temperature of water used in the engine, like the conventional device, it is possible for the heating device according to the present invention to have a very simple and easy mounting structure, and decrease the manufacture cost of the heating device.
  • According to the invention recited in claim 2, in addition to the effects of the invention recited in claim 1, when the heating device performs the temperature control so that a resistance value of the heating element becomes equal to the reference resistance value, there is a possibility of increasing a resistance value of the heating element after the long use of time. This decreases an effective power value and an actual heating temperature of the heating device. But, the deterioration judgment means sets the effective power value to be not more than the power value when the heating element is deteriorated, and it is possible for the deterioration judgment means to judge occurrence of deterioration of the heating element when the heating temperature of the heating element is not more than a usable limit temperature. Accordingly, it is not necessary for the deterioration judgment means to use external environmental information, and transmit a lot of such information between the heating device and an external arithmetic processing device, and not necessary for the external arithmetic processing unit to perform the deterioration judgment process. On the other hand, the conventional heating device requires for the external arithmetic processing unit to perform the deterioration judgment process. It is therefore possible for the heating device according to the present invention to perform a fast and self-contained judgment process for judging occurrence of deterioration of each of the heating elements with a simple structure. This makes it possible to allow an operator to do prompt countermeasure against the occurrence of deterioration of the heating element.
  • According to the invention recited in claim 3, it is possible to form a desired reference resistance value by using a part of elements which form the power supply control module. This makes it possible to provide the heating device of a control section integrated-type capable of performing the deterioration judgment of the heating element with a simple structure and without increasing a size of the power supply control module because the heating device is equipped with the power supply control module capable of adjusting a temperature of the heating element with high accuracy.
  • According to the invention recited in claim 4, it is possible to easily adjust the reference resistance value corresponding to the different individual characteristics of the heating element by the digital trimming with high accuracy.
  • According to the invention recited in claim 5, it is possible to independently perform the temperature control of each of plural glow plugs without being affected to each other even if the glow plugs have different individual characteristics. It is further possible for the heating device of a control section integrated-type according to the invention to perform a fast judgment of detecting occurrence of deterioration of the glow plugs with a good accuracy. This makes it possible to provide the glow plug of a control section integrated-type with a simple structure and high accuracy.
  • According to the invention recited in claim 6, it is possible to perform a deterioration judgment of the glow plug with high accuracy and without being affected by the working state of the internal combustion engine.
  • BRIEF DESCRIPTION OF THE DRAWINGS
    • [Figure 1] (a) is a view showing a schematic structure of a heating device of a control section integrated-type according to exemplary embodiments of the present invention, and (b) is an overall view of a glow plug equipped with a control section capable of independently adjusting a power supply to each of a plurality of glow plugs which is mounted to a respective cylinder of an internal combustion engine.
    • [Figure 2] shows a structure of the glow plug of a control section integrated-type equipped with the control section shown in Figure 1, (a) is a view showing a vertical cross section of the structure of the glow plug of a control section integrated-type equipped with the control section shown in Figure 1, (b) is a view showing a lateral cross section along the line A-A shown in (a) of Figure 2, (c) is a view showing a vertical cross section of a schematic structure of a metal heater to be used as a glow plug to which the present invention is applied, and (d) is a view showing a vertical cross section of a schematic structure of a ceramic heater to be used as the glow plug to which the present invention is applied.
    • [Figure 3] is a characteristic view showing a correlation between a temperature of a glow plug, to which the present invention is applied, and a resistance value of the glow plug, where RINT indicates resistance temperature characteristics at an initial state (as initial resistance temperature characteristics), RACT indicates resistance temperature characteristics after a use of a constant time, and RWRN indicates resistance temperature characteristics under deterioration.
    • [Figure 4] is a flow chart showing an initial temperature rise control method to be used in the heating device according to the present invention.
    • [Figure 5] is a flow chart showing a normal control method to be used in the heating device according to the present invention.
    • [Figure 6] is a timing chart of the heating device according to the present invention, (a) is a timing chart showing a drive signal in the heating device according to the present invention, (b) is a timing chart showing a change of a plug resistance, (c) is a timing chart showing a judgment result of a temperature change reflecting means, (d) is a timing chart showing an operation state of a semiconductor open/close element when a feedback control of a temperature change is performed, (e) is a timing chart showing a change of a current to be supplied to the heating device, and (f) is a timing chart showing a change of a heating temperature.
    • [Figure 7] is a timing chart of the heating device according to the present invention from an initial state to a deterioration state under a normal control mode, (a) is a timing chart showing a drive signal in the heating device according to the present invention, (b) is a timing chart showing a change of a plug resistance, (c) is a timing chart showing a judgment result of a temperature change reflecting means, (d) is a timing chart showing an operation state of a semiconductor open/close element when a feedback control of a temperature change is performed, (e) is a timing chart showing a change of a current to be supplied to the heating device, (f) is a timing chart showing a change of an average power, and (g) is a timing chart showing a change of a heating temperature.
    • [Figure 8] is a flow chart showing an after glow control method used by the heating device according to the present invention;
    • [Figure 9] shows effects of the present invention, (a) shows characteristics of a temperature control state during a normal control mode of the heating device according to the present invention, (b) shows characteristics of a temperature control state during a pre heating control mode of the heating device according to the present invention, (c) shows characteristics of a temperature control state during the after glow control mode of the heating device according to the present invention; and
    • [Figure 10] is a flow chart of judging occurrence of deterioration of the heating device according to the present invention.
    Embodiments to execute the present invention
  • Next, a description will be given of a glow plug 1 of a control section integrated-type according to an exemplary embodiment of the present invention. The glow plug 1 is comprised of a heating element 10 mounted to a corresponding cylinder in a plurality of cylinders mounted to an internal combustion engine, a detail of which is omitted from the drawings, a power supply control module 20 and a housing casing 30. The power supply control module 20 performs a power supply control from a power source 6 to the heating element 10. The housing casing 30 accommodates the heating element 10 and the power supply control module 20 together.
  • As shown in FIG. 1, the glow plug 1 of a control section integrated-type according to the exemplary embodiment is comprised of the heating element 10, the power supply control module 20, and the housing casing 30. The heating element 10 generates heat energy when receiving an electric power. A resistance value of the heating element 10 changes in a positive correlation to its temperature change. The power supply control module 20 adjusts a power supply from the power source 6 to the heating element 10 so that the resistance value RGP of the heating element 10 becomes equal to a target resistance value RTRG. The housing casing 30 accommodates the heating element 10 and the power supply control module 20 so that the heating element 10, the power supply control module 20 and the housing casing 30 are integrated together. The power supply control module 20 is comprised of a reference resistance value storage means 231 and a resistance value change reflecting means 233. The reference resistance value storage means 231 stores a resistance value of the heating element 10, as the reference resistance value RC, at a predetermined target temperature TTRG measured in advance. The resistance value change reflecting means 233 uses the reference resistance value RC as a threshold value, and allows the power source to supply electric power to the heating element 10 when the resistance value RGP of the heating element 10 is lower than the reference resistance value RC during the power supply. The resistance value change reflecting means 233 halts the power supply to the heating element 10 when the resistance value RGP of the heating element 10 exceeds the reference resistance value RC during the power supply to the heating element 10 in order to reflect, to the power supply control, the resistance value change due to the temperature change of the heating element 10.
  • The power supply control module 20 further has a deterioration judgment means 234. The deterioration judgment means 234 judges whether or not the heating element 10 is deteriorated on the basis of a deterioration power value PWRN in a deterioration state, as a power threshold value PREF, to be supplied to the heating element 10 at a predetermined deterioration limit-temperature TWRN. The power value PWRN in a deterioration state is calculated by multiplying together a predetermined rate and an initial reference power value PINT, to be supplied to the heating element 10 in a normal state, previously detected at a predetermined temperature.
  • The deterioration judgment means 234 according to the exemplary embodiment has a self-diagnosis means for determining occurrence of deterioration of the heating element and outputs a self-diagnosis signal DI. The self-diagnosis means judges the deterioration of the heating element when an effective power value PACT becomes not more than the predetermined deterioration limit-temperature TWRN. The effective power value PACT is calculated on the basis of a plug current IGP actually flowing in the heating element 10 and a plug voltage VGP applied to the heating element 10 while considering a target power PTRG as a reference of a predetermined target temperature TTRG.
  • It is possible to use, as a concrete value of the deterioration power value PWRN, a value obtained by multiplying a constant rate (for example, 90 %) and the initial reference power value PINT necessary for the heating element to reach a target temperature TTRG determined at a manufacturing process.
  • A description will be given of the glow plug 1 of a control section integrated-type as the heating device according to the exemplary embodiment of the present invention with reference FIG. 1.
  • The glow plug 1 is comprised of the heating element 10 (1 ∼ n) and the power supply control module 20 (1 ∼ n) which are integrated together in the housing casing 30 (1 ∼ n). The glow plug 1 of a control section integrated-type is connected to an engine control unit (ECU) 7 through connector terminals (41, 42, 43). The heating element 10(1 ∼ n) is mounted to a respective cylinder of the internal combustion engine 8 (not shown in detail). The power supply control module 20(1 ∼ n) receives a drive signal SI transmitted from the ECU 7. A target temperature TTRG is determined on the basis of the drive signal SI. The drive signal SI corresponds to a working state of the internal combustion engine 8. The power supply control module 20(1 ∼ n) compares an actually-detected plug resistance value RGP with the reference resistance value RC, and adjusts the power supply from the power source 6 to the heating element 10(1 ∼ n) in synchronization with the drive signal SI on the basis of the comparison result.
  • The power supply control module 20 (1 ∼ n) has a mold package 200 which accommodates at least a semiconductor open/close element 21, a drive circuit section 22 and a heating element control IC 23. A power input terminal 201, a drive signal input terminal 202, a self-diagnosis signal output terminal 203, an output terminal 204 and a ground terminal 205 are outwardly arranged on the mold package 200 of the power supply control module 20.
  • The exemplary embodiment uses an N channel power MOS FET (hereinafter, referred as MOS 21) as the semiconductor open/close element 21.
  • The MOS 21 has a plurality of control MOS 210 (hereinafter, referred as main MOS 210) for opening/ closing a large current flowing in the heating element 10. A current detection MOS 211 (hereinafter, referred to as a sense MOS 211) is used, as a part of the MOS 21, for detecting a current flowing in the heating element 10. The main MOS 210 and the sense MOS 211 make a current mirror circuit. A current detection resistance 212 is connected to the MOS 211.
  • The current detection resistance 212 is connected to a heating element control IC 23 through a sense terminal SEN. The heating element control IC 23 is equipped with a deterioration judgment means 234 which is a main section of the present invention.
  • In the exemplary embodiment, the drive circuit section (DRV) 22 is equipped with a booster means such as a charge pump. For example, the drive circuit section 22 outputs a predetermined drive voltage VGG which is boosted in order to drive the MOS 21 in synchronization with a falling edge of the drive signal SI. The drive signal SI is outputted from the ECU 7 to the power supply control module 20 in order to determine a duty ratio TON/ T with which the heating element generates heat energy to reach a target temperature TTRG which corresponds to the operation state of the internal combustion engine 8.
  • Timing charts shown in FIG. 6 and FIG. 7 show an example to initiate a power supply in synchronization with a falling edge of the drive signal SI. However, it is possible to optionally select one of a high level Hi and a low level Lo of the drive signal SI in order to drive the MOS 21 according to demand.
  • The charge pump is for example comprised of an operational amplifier 220, a charge capacitance 222, an output capacitance 224 and diodes 221 and 223. The charging operation and the discharging operation are repeatedly performed by a switching operation of the operational amplifier 220. The electric energy charged in the output capacitor 224 is discharged multiple times to boost the power source voltage VB to a gate voltage VGG. For example, the gate voltage VGG is twice as much as the power source voltage VB. The boosted gate voltage VGG is supplied to a node between the gate and the source of the semiconductor open/close element 21.
  • FIG. 1 (a) shows the charge pump comprised of the operational amplifier 220, the diodes 221 and 223, and the capacitors 222 and 224. However, the concept of the present invention is not limited by the boosting structure shown in (a) in FIG. 1. It is acceptable to use a DC-DC converter of a chopper type comprised of a combination of a choke coil, a capacitor, a diode, etc. or a DC-DC converter of a fly-back type having a booster transformer, etc.
  • The heating element control IC 23 as a main part of the present invention is comprised of a resistance value arithmetic means 230, a reference resistance storage means (a reference resistance forming section) 231, a reference resistance adjusting means (Zener zap circuit) 232, a resistance value change reflecting means (F/B means) 233, an initial power reference resistance, an initial power reference resistance adjusting means (Zener zap circuit) and a deterioration judgment means 234. The resistance value arithmetic means 230 calculates a plug resistance value RGP of the heating element 10 on the basis of the plug current IGP detected by the current detection resistance 212 previously described, and the plug voltage VGP (which is equal to the source voltage VSS of the semiconductor open/close element 21) applied from the semiconductor open/close element 21 to the heating element 10.
  • Further, in the exemplary method previously described, the sense MOS 211 detects the current IGP when the resistance value RGP is calculated. However, the concept of the present invention is not limited by the exemplary method previously described.
  • For example, it is possible to detect the resistance value RGP of the heating element 10 with a more high accuracy by detecting the plug voltage VGP generated when a constant current within a relatively low range of several 10 mA to several 100 mA is supplied from the heating element control IC 23 to the heating element 10 under a condition when the MOS 21 is turned off.
  • The plug resistance value RGP of the heating element 10 is determined on the basis of resistance temperature characteristics of the heating element 10. There is a constant correlation between the heating temperature of the heating element 10 and the plug resistance value RGP.
  • After the heating element 10 is connected to the power supply control module 20 during a manufacturing process of the glow plug 1 of a control section integrated-type, a power is supplied to the heating element 10 to increase a temperature thereof to a predetermined target temperature (T1). At this time, an external device measures a resistance value of the heating element at the temperature (T1) thereof, and uses the detected temperature as the reference resistance value RC. The reference resistance value RC is stored in the reference resistance value storage means 231 (hereinafter, referred as "MEM 231") on the basis of a timing when receiving an external signal.
  • It is also acceptable to detect a resistance value of the heating element 10, to which the control module 20 is not connected, during the manufacturing process of the heating element 10, and then store the detected resistance value into the MEM 231 of the control module 20.
  • The resistance value change reflecting means (F/B means) 233 compares the reference resistance value RC stored in the MEM 231 with the plug resistance RGP detected when the heating element 10 is actually used. The resistance value change reflecting means (F/B means) 233 outputs the comparison result to perform the feedback control.
  • Because the power supply control is performed by opening and closing the semiconductor open/close element 21 in order to maintain the reference resistance value RC of the heating element 10 on the basis of the reference resistance value RC corresponding to the individual resistance temperature characteristics of the heating element 10, it is possible to adjust the temperature of the heating element 10 to a desired heating temperature with a high accuracy when compared with a case in which the power supply to a plurality of heating elements is adjusted on the basis of a single control condition.
  • By the way, a long use of the heating element 10 makes a diffusion of metal forming electrodes into an insulation layer, and occurs a migration in which conductive components move between the heating element to the insulation layer, or increases the plug resistance value RGP because of increasing a contact resistance by separation of the electrodes and oxidation of the electrodes.
  • It is accordingly to judge the occurrence of deterioration of the heating element when a heating temperature of the heating element is decreased to the predetermined deterioration limit-temperature TWRN (for example, 1,150 °C) from than the target temperature TTRG (for example, 1,250 °C) by a constant value ΔT (for example, 100 °C).
  • However, the glow plug 1 of a control section integrated-type according to the present invention performs the temperature control of the heating element without detecting an actual temperature of the heating element, that is, performs the power supply control so that the resistance value RGP becomes equal to the reference resistance value RC. It is therefore impossible to judge whether or not deterioration of the heating element occurs on the basis of an actual heating temperature of the heating element 10.
  • Furthermore, it is difficult to maintain an accuracy of judging the deterioration of the heating element on the basis of an average current because the current value IGP changes due to the battery voltage (as the power source voltage) +B.
  • An initial power reference resistance value RPINT is obtained by performing an electric trimming of the initial reference power value PINT at an initial target temperature TTRG, for example, as a change of the effective power PACT when it is adjusted so that the plug resistance value RGP is equal to the reference resistance value RC in order for a temperature of the heating element to reach the target temperature TTRG. The obtained initial power reference resistance value RPINT is then stored. Occurrence of deterioration of the heating element is judged when the resistance of the heating element changes from the initial power reference resistance value PINT by not less than a constant value and the effective power PACT becomes not more than the power threshold value PREF.
  • The feature of the present invention is that the resistance value RGP of the heating element 10 is not calculated and the judgment of the occurrence of deterioration of the heating element 10 is performed on the basis of a comparison result between the resistance value RGP of the heating element 10 and the threshold value. That is, the feature of the present invention is to perform the power supply control so that the resistance value RGP of the heating element 10 becomes equal to the reference resistance value RC having a constant value. Further, the feature of the present invention is to detect the occurrence of deterioration of the heating element 10 when the resistance value RPG at the predetermined temperature increases and the effective power PACT is decreased due to the deterioration of the heating element 10, when the heating temperature of the heating element 10 is maintained constant.
  • In order to store the initial reference power value PINT as a reference value to be used for judging the occurrence of deterioration, it is possible to judge the deterioration of the heating element having different individual characteristics by using the resistance or a memory element which can be processed by a trimming process.
  • Specifically, the reference resistance adjusting means 232 performs an electric trimming of the initial power reference resistance value RPINT. This allows the initial power reference resistance value RPINT to become an adjustable resistance.
  • More specifically, the electric trimming is performed by a digital trimming which uses a Zener zapping or a poly silicon fuse.
  • It is possible to provide the reference resistance value RC. This requires a microcomputer and increases significantly a circuit size.
  • A description will now be given of a structural feature of the glow plug 1 of a control section integrated-type as the heating device according to the exemplary embodiment of the present invention with reference to FIG. 2.
  • The glow plug 1 of a control section integrated-type has a structure in which the housing casing 30, the heating element 10, the power supply control module 20 and the connector section 40 are assembled together. The housing casing 30 has substantially a cylindrical shape. The heating element 10 is arranged at a front section of the housing casing 30. The housing casing 30 accommodates the power supply control module 20. The connector section 40 allows the glow plug to communicate with external devices.
  • It is possible for the present invention to use, as the heating element 10, a metal heater 10 shown in FIG. 2 (d) or a ceramic heater 10a shown in FIG. 2 (e).
  • The metal heater 10 is comprised of a metal protection tube 103, a heating coil 102, a control coil 104 and insulation material 100. The metal protection tube 103 has substantially a cylindrical shape having a base section, a distal end of the metal heater 10 is open, and a front section of the metal heater 10 is closed. Each of the heating coil 102 and the control coil 104 is made of metal resistance wire coil. The insulation material 100 is magnesia powder, etc. and stored in the metal protection tube 103. A ground section 101 arranged at the front side of the heating coil 102 is electrically connected to the metal protection tube 103. The distal end of the control coil 103 is connected to an input terminal 106. The input terminal 106 allows the power supply control module 20 to communicate with the metal heater 10. The heating coil 102 and the metal protection tube 103 are made of known material such as Fe-Cr-Al alloy, Fe-Cr alloy, Ni-Cr alloy and are formed to have a predetermined resistance value.
  • The ceramic heater 10a is comprised of a ceramic resistance member 102a, a pair of lead sections 103a and 104a, and an insulation member 100a. The ceramic resistance member 12a has a character U-like shape. Through the lead sections 103a and 104a, external devices communicate with the ceramic resistance member 102a. The insulation member 100a has substantially a rod-like shape with which the lead sections 103a and 104a are covered. One end part of the lead section 103a connected to one end part of the ceramic resistance member 102a is extended toward a direction of a side surface of the insulation member 100a. A ground terminal 101a is formed at the side surface of the insulation member 100a. A front end section of the lead section 104a connected to the other end part of the ceramic resistance member 102a is extended to the distal end section of the insulation member 100a, at which an input terminal 105a is formed. The input terminal 105a is connected to the power supply control module 20 through an input terminal metallic part 106a.
  • For example, the ceramic resistance member 102a is made of a conductive ceramic material, for example, a sintered member of a mixture of silicon nitride and tungsten carbide.
  • Further, the lead sections 103a and 104a are made of heat resistant metal material such as tungsten.
  • The insulation member 100a is made of insulation ceramic material such as silicon nitride.
  • The metal heater 10 or the ceramic heater 10a is supported and fixed by a heating-member supporting member having substantially a cylindrical shape.
  • The heating-member supporting member is made of metal such as SUS (Stainless steel in Japanese Industrial standards), and has substantially a cylindrical shape. The metal heater 10 or the ceramic heater 10a is supported and fixed in the inside of the heating-member supporting member. The heating-member supporting member is electrically connected to the metal protection tube 103 or the ground terminal 101a so that one end of the heating element 10 is grounded and connected to the internal combustion engine through the housing casing 30.
  • In the metal heater 10, the metal protection tube 103 is fixed together to the heating-member supporting member by a known method such as laser welding, brazing and screws.
  • In the ceramic heater 10a, the insulation member 100a and the heating-member supporting member are fitted together or fixed together by known methods such as brazing.
  • The housing casing 30 is comprised of a housing base member 300 which has substantially a cylindrical shape. A front side cylinder section is formed at the front side of the housing casing 30 in order to support the heating-member supporting member. A distal end cylindrical section of the heating-member supporting member is inserted into and fitted to the front side cylinder section of the housing casing 30 by welding, etc.
  • A screw section 303 is formed on an outer periphery of the housing casing 30 to screw and fix the glow plug 1 to the combustion chamber of the internal combustion engine.
  • The power supply control module 20 and the connector section 40 is accommodated in the inside of the distal end section of the housing casing 30. Through the connector section 40, the power supply control module 20 communicates with the external devices.
  • A hexagonal section 304 is formed at the outer periphery of the distal end side of the housing casing 30 to screw up the screw section 303.
  • The connector section 40 is covered with a collar which has substantially a cylindrical shape and fixed to the distal end side of the housing casing 30.
  • The connector section 40 is comprised of a resin formation section and the connector terminals 41, 42 and 43. The resin formed section is made of plastic resin, etc. and has substantially a cylindrical shape. The connector terminals 41, 42 and 43 are fixed to the inside of the resin formation section. The connector terminals 41, 42 and 43 communicate with the external devices. A fitting section 401 is formed at a distal end side of the connector section 40. The fitting section 401 has substantially a cylindrical shape. The fitting section 401 and a connector of the external device are fitted together. A terminal fixing section is formed at a middle part of the connector section 40. The connector terminals 41, 42 and 43 are inserted and fixed to the terminal fixing section. The connector terminals 41, 42 and 43 communicate with the external devices. The connector terminals 41, 42 and 43 correspond to the power input terminal, the drive signal input terminal and the self-diagnosis signal output terminal, respectively. It is possible to increase and decrease the number of the connector terminals according to a necessity.
  • For example, it is acceptable to form input terminals TZP1, TZP2 for the Zener zap in order to adjust the reference resistance value RC by using a Zener zap trimming, and a connector terminal for the Zener zap to communicate with the external devices.
  • In order to decrease the number of the terminals, it is possible to commonly use, as these terminals for the Zener zap, one or more of the drive signal input terminal 42, the self-diagnosis signal output terminal 43 and the power input terminal 41.
  • A control module accommodation space is partitioned by a front end side partition section. The control module accommodation space accommodates the power supply control module 20.
  • As shown in FIG. 2 (a), the power input terminal 41, the drive signal input terminal 42 and the self-diagnosis signal output terminal 43 are connected to the power input terminal 201, the drive signal input terminal 202 and the self-diagnosis signal output terminal 203 of the power supply control module 20, respectively
  • The output terminal 204 (source terminal VSS) of the power supply control module 20 is connected to the heating element 10, 10a through a central axis 24 to supply electric power. A GND terminal 205 is connected to the housing casing 30 through a ground terminal 250, and further connected to the internal combustion engine through the housing casing 30.
  • In the power supply control module 20 according to the exemplary embodiment having the structure shown in FIG. 1, the MOS 21, DRV 22, JDG 23, etc. are assembled together, covered with epoxy resin and accommodated in the mold package 200. Further, lead frames are extended from the mold package 200 to form the power input terminal 41 (BAT), the drive signal input terminal 42 (SI), the self-diagnosis signal output terminal 43 (DI), the output terminal 204 (VSS), and the ground terminal 205 (GND).
  • The power supply control module 20 shown in FIG. 1 is a DIP type (Dual Inline Package type) package. However, the concept of the present invention is not limited by the structure. It is possible to use a SIP type (Single Inline Package type) or another known IC package according to a necessity.
  • Specifically, in order to implement the power supply control module 20 into the housing casing 30 for the glow plug, it is preferable to use a small-size discrete semiconductor element package such as a TO-220 type package. That is, the input terminal, the ground terminal and the output terminal are sequentially arranged and expended from the small-size discrete semiconductor element package, in which a power MOS FET and a control IC can be implemented together, for example, made of mold resin package having a size of approximately 10 mm x 17 mm x 4.5 mm.
  • A description will be given of the temperature characteristics of heating element 10 used in the glow plug 1 of a control section integrated-type according to the present invention with reference FIG. 3.
  • FIG. 3 shows a normal state, that is, a relationship between a temperature of the heating element and a resistance value of the heating element under a saturation state of the temperature and the resistance value of the heating element after the elapse of a predetermined time counted from the time when an electric power is supplied to the heating element. In FIG. 3, the alternate long and short dash line indicates the initial resistance temperature characteristics RINT, the dotted line indicates the resistance temperature characteristics RACT, and the solid line indicates the deterioration resistance temperature characteristics RWRN under deterioration.
  • As shown in FIG. 3, the initial state and the deterioration state have the same slope of the resistance temperature characteristics, that is, the slope of the resistance temperature characteristics is not changed in the initial state and the deterioration state. The resistance temperature characteristics RWRN of the heating element is shifted in parallel from the initial resistance temperature characteristics RINT so that the resistance value of the heating element increases as deterioration goes on when compared with the initial resistance value thereof.
  • When the resistance to the target temperature TTRG in the initial state is used as the reference resistance value RC and an electric power is supplied in order to maintain the reference resistance value RC, a heating temperature of the heating element decreases. It is necessary to output a warning, etc. because it is judged that the heating temperature is decreased to the predetermined deterioration limit-temperature TWRN.
  • A description will be given of the power supply control method and the method of detecting deterioration of the glow plug 1 of a control section integrated-type according to the present invention with reference to FIG. 4 and FIG. 5.
  • FIG. 4 is a flow chart showing an initial temperature rising mode (MINT). The process in step S100 starts the initial temperature rising mode (MINT) starts when an operator turns on a key switch SW.
  • The process in step S110 recognizes a drive signal SI transmitted from the ECU 30. When the drive signal SI transmitted from the ECU 30 is detected, the operation flow goes to step S120. The process in step S120 starts the power supply to the heating element 10.
  • Next, the process in step S130 detects the plug voltage VGP and the plug current IGP flowing in the heating element 10.
  • Next, the process in step S140 calculates the plug resistance value RGP on the basis of the detected plug current IGP and the detected plug voltage VGP.
  • Next, the process in step S150 compares the plug resistance value RGP with the reference resistance value RC corresponding to the target temperature at the initial state. Further, the process in step S150 detects whether or not the plug resistance value RGP reaches the reference resistance value RC, that is, whether or not the heating temperature of the heating element reaches the target temperature.
  • When the plug resistance value RGP is not more than the reference resistance value RC, the judgment result indicates No, and the operation returns to step S110 to maintain the initial temperature rising mode (MINT).
  • When the plug resistance value RGP is larger than the reference resistance value RC, the judgment result indicates Yes. The initial temperature rising mode (MINT) is completed and the operation returns to step S200 to perform the normal control mode.
  • In step S120, it is possible to perform a pre heating control mode (MPRE) in steps S121, S122 and S123 in order to prevent excessive temperature rise.
  • Specifically, the process in step S121 compares the plug resistance value RGP with a pre-heating control mode switching reference resistance value RCH, where the pre-heating control mode switching reference resistance value RCH indicates a resistance value (which corresponds to a pre-heating target temperature, for example, corresponding to 1,000 °C) which is slightly lower than the reference resistance value RC. When the plug resistance value RGP, is not more than the pre-heating control mode switching reference resistance value RCH, the comparison result indicates No. The operation flow goes to step S123. The process in step S123 supplies an electric power having approximately 100 % duty which exceeds a normal rated power in order to quickly increase the temperature of the heating element 10 to the pre-heating target temperature.
  • In the pre-heating control mode switching judgment process in step S121, when the plug resistance value RGP exceeds the pre-heating control mode switching reference resistance value RCH, the judgment result indicates Yes. The operation flow goes to step S122 in order to perform the pre-heating control mode (MPRE). The process in step S122 performs the on/off control of the pre-heating control mode so that a temperature of the heating element becomes a constant temperature which is lower than the target temperature during approximately one second only, for example, using the pre-heating control mode switching reference resistance value RCH as a threshold value.
  • Specifically, it is possible to perform the pre-heating control mode MPRE by the process in steps S1221 to S1225.
  • In the time-up judgment process in step S1221, it is judged whether or not a constant time tref is elapsed from the time at which the pre-heating control mode starts.
  • The judgment result indicates Yes before the constant time is not elapsed (t < tref) from the time at which the pre-heating control mode starts. The operation flow goes to step S1222. The process in step S1222 performs a power supply allowable judgment. The process in step S1222 compares the plug resistance value RGP with the pre-heating control mode switching reference resistance value RCH in order to judge whether or not there is a necessity of the power supply.
  • When the comparison result in step S1222 indicates RGP > RCH, the judgment result indicates Yes. The operation flow goes to step S1223. The process in step S1223 halts the power supply, i.e., the state of the power supply is turned off in step S1223. On the other hand, when the comparison result in step S1222 indicates RGP ≤ RCH, the judgment result indicates No. The operation flow goes to step S1224. The process in step S1224 allows the power supply, i.e., the state of the power supply is turned on in step S1224. Further, the operation flow goes to step S1225 which performs the resistance value calculation process. In step S1225, the plug resistance value RGP is calculated again. The operation flow returns to step S1221 and the operation loop is repeated.
  • When a predetermined time is elapsed from the time at which the pre-heating control mode starts, the operation flow completes the pre-heating control mode and goes to the main routine.
  • The pre-heating control mode (MPRE) in step S122 prevents an over-heating of the heating element during the temperature rising process (transition mode MTRN) to the normal control mode (MCST) because of maintaining the heating element at a temperature which is lower than the target temperature of 1,250 °C, for example by approximately 250 °C for a predetermined period of time.
  • In addition, the deterioration judgment is not performed during the initial temperature rising mode (MINT) because the plug resistance value RGP changes according to the temperature rise of the heating element.
  • It is possible to use a plurality of pre-temperature control modes, for example, a first pre-temperature control mode having a first pre-heating target temperature of 1,000 °C, a second pre-temperature control mode having a second pre-heating temperature of 1,100°C, etc.
  • In these cases, it is possible to switch the first pre-heating target temperature and the second pre-heating target temperature by changing the duty ratio indicated by the drive signal SI. However, this requires for the ECU 7 to transmit large amounts of information regarding the plug resistance RGP, and therefore increases the total size of information to be transmitted, like the conventional techniques.
  • The present invention stores in the control module 20 the information regarding the first pre-heating reference resistance and the second pre-heating reference resistance which correspond to the respective target temperatures in order for the control module 20 to independently process even if using a plurality of the pre-heating control modes.
  • Similar to the pre-heating control mode having a single pre-heating target temperature, it is possible for the control module 20 to perform the pre-heating control without the process of the ECU, that is, to judge whether or not there is a necessity of the power supply, for example, in step S121 or step S150, on the basis of the comparison result between the plug resistance value RGP and the corresponding reference resistance value, and perform the on/off control of the MOS 21 so that the plug resistance value RGP becomes equal to the corresponding reference resistance value.
  • Further, although it is not necessary when the power source 6 has an adequate amount of electric power, there is a possibility of delaying the temperature rising speed of the heating elements when the electric power is supplied simultaneously to a plurality of the heating elements 10 (1 ∼n) and a large amount of inrush current is generated and the power source 6 has a heavy load.
  • In the heating device according to the present invention, each of the glow plugs 1 (1 ∼ n) of a control section integrated-type, which is mounted to the corresponding cylinder in the internal combustion engine, is independently equipped with the power supply control module 20. An electric power is supplied independently to the heating element 10 (1 ∼ 10) of each of the glow plugs 1 (1 ∼ n). In this structure, it is preferable for each of the glow plugs 1 (1 ∼ n) to have a self-cylinder position judgment means and a driving-time delay means. The self-cylinder position judgment means detects a position of the cylinder which corresponds to the own glow plug 1. The driving-time delay means delays the timing to initiate the power supply according to the cylinder corresponding to the own glow plug 1.
  • FIG. 5 is a flow chart showing the normal control mode.
  • In the normal control mode in step S200, the power supply control is performed on the basis of the drive signal SI, and the reference resistance value RC of each of the heating elements 10. Further, it is possible to provide the warning on the basis of the judgment result of deterioration of the heating element.
  • When the drive signal SI is detected in the drive signal input recognition process in step S210 after the normal control mode in step S200 is initiated, the operation flow goes to step S210. In step S210, the power supply to the heating element 10 is initiated.
  • In the current and voltage detection process in step S220, the plug current IGP flowing in the heating element 10 and the plug voltage VGP are detected.
  • Next, in the process of calculation the effective power and the plug resistance value in step S230, the effective power value PACT and the plug resistance value RGP are calculated on the basis of the plug current IGP and the plug voltage VGP.
  • The following step S240 detects the occurrence of deterioration based on a comparison result between the effective power value PACT and the power threshold value PREF by using a threshold value.
  • The deterioration power value PWRN in the deterioration state is used as the power threshold value PREF, which is a decreased power value, for example 90 % of the initial reference power value PINT at the initial state.
  • In the deterioration judgment process in step S240, it is judged that the heating element is not deteriorated when the effective power value PACT is not less than the power threshold value PREF. The judgment result indicates Yes and the operation flow goes to step S250 in order to perform the resistance value change reflecting means (F/B process).
  • In the deterioration judgment process in step S240, it is judged that the heating element is deteriorated when the effective power value PACT is lower than the power threshold value PREF (for example, when the effective power value is not more than 90 % of the initial reference power value PINT). The judgment result indicates No and the operation flow goes to step S260 in order to perform the abnormality judgment signal output process.
  • The resistance value change reflecting means (F/B process) in step S250 compares the plug resistance value RGP with the reference resistance value RC in order to perform the feedback of the plug resistance value. When the plug resistance value RGP exceeds the reference resistance value RC, the judgment result indicates Yes. The operation flow goes to step S270 in order to perform the power supply stop process. When the plug resistance value RGP is not more than the reference resistance value RC, the judgment result indicates No. The operation flow goes to step S280 in order to perform the power supply continuation process.
  • In the power supply stop process in step S270, the power supply is stopped because it is judged that the heating temperature of the heating element 10 reaches the target temperature value. The operation flow returns to step S210.
  • In the power supply continuation process in step S280, the power supply is continued because it is judged that the heating temperature value of the heating element does not reach the target temperature value.
  • The processes in step S210 to step S280 are repeated in order to control the power supply to the heating element and maintain the plug resistance value RGP of each of the glow plugs 1 (1 ∼ n) at a resistance value close to the individual reference resistance value RC.
  • The abnormality judgment signal output process in step S260 outputs the self-diagnosis signal DI, in order for example to turn on a warning lamp, inform occurrence of the abnormality deterioration state, recommend the replacement of the glow plug to the driver of the motor vehicle, and/or stop the power supply to the heating element 10.
  • A description will be given of the operation of the glow plug 1 of a control section integrated-type as the heating device according to the exemplary embodiment of the present invention with reference to FIG. 6. FIG. 6 shows a control result without performing the pre-heating mode.
  • The drive signal SI determines the duty ratio in order to determine the target temperature TTRG which corresponds to the driving state of the internal combustion engine. The MOS 21 is opened and closed in synchronization with a rising edge or a falling edge of the drive signal SI on the basis of the judgment result regarding the necessity of the power supply detected by the resistance value change reflecting means 233, as previously described.
  • As shown in FIG. 6 (a), when the drive signal SI transmitted from the ECU 7 is received, the power supply to the heating element 10 starts and a temperature of the heating element 10 increases.
  • As previously described, the judgment result in step S250 indicates yes when the plug resistance value RGP exceeds the reference resistance value RC. At this time, as shown in FIG. 6 (c), the resistance value change reflecting means 233 outputs a value of zero, and the power supply to the heating element 10 is not performed.
  • However, the power supply to the heating device 10 is not immediately stopped, but is continued by the duty ratio (for example, 90 % duty ratio) indicated by the drive signal SI after an elapse of one pulse. The MOS 21 is turned on at a following rising edge of the drive signal SI in order to halt the power supply to the heating element 10. When the plug resistance value RGP becomes not more than the reference resistance value RC, the judgment result in step S250 indicates No. The resistance value change reflecting means 233 outputs a value of one, and the MOS 21 is turned off at a falling edge of the following drive signal SI in order to perform the power supply to the heating element 10.
  • According to the present invention as previously described, the reference resistance value RC is used to determine whether the power supply to the heating element 10 starts as shown in FIG. 6 (c). The MOS 21 is turned off in synchronization with a rising edge of the drive signal SI during the OFF state of the judgment result (JDG) shown in FIG. 6 (c), and the MOS 21 is turned on in synchronization with a falling edge of the drive signal SI during the ON state of the judgment result (JDG) shown in FIG. 6 (c).
  • Accordingly, because the operation of the MOS 21 is driven in synchronization with the rising edge or the falling edge of the drive signal SI as shown in FIG. 6 (d), the temperature change is slightly delayed from the change of the plug resistance RGP, as shown in FIG. 6(e). However, the control module 20 in each heating device can independently perform the feedback F/B control of the plug resistance RGP so that the plug resistance RGP becomes equal to the reference resistance value RC. This makes it possible to perform the control of the temperature of the heating element 10 to be equal to the target temperature TTRG without using any temperature of engine cooling water and other temperature information.
  • A description will be given of the deterioration judgment method used by the heating device according to the present invention with reference to FIG. 7.
  • FIG. 7 shows timing charts from the initial state to the deterioration state of the heating element in the heating device during the normal control mode according to the present invention.
  • As shown in FIG. 7 (a), the ECU 7 outputs the drive signal SI which is determined according to the target temperature TTRG without regard for the deterioration state of the heating element 10.
  • As shown in FIG. 3, the heating element 10 is gradually deteriorated due to a long use thereof, and a resistance value RGP of the heating element 10 to a constant heating temperature also gradually increases.
  • When the resistance value RGP of the heating element 10 increases due to a long use, a timing is gradually increased, where the timing indicates a time when the resistance value RGP of the heating element 10 exceeds the reference resistance value Rc after the power supply is started in synchronization with a falling edge of the drive signal SI. Further, when the power supply is performed on the basis of a constant duty ratio, the maximum value of the resistance value RGP during a period also increases.
  • Accordingly, a time period in which the plug resistance value RGP is higher than the reference resistance value RC in the deterioration state of the heating element, the number of frequencies when the MOS 21 is turned off increases.
  • Accordingly, the plug current IGP becomes low, as shown in FIG. 7 (e), and as a result, the effective power value PACT gradually decreases, as shown in FIG. 7 (f).
  • At this time, it is judged that the heating element is deteriorated when the effective power value PACT changes by not less than a constant rate of the initial reference power value PINT which corresponds to the predetermined temperature in the initial state and the effective power value PACT becomes not more than the power threshold value PREF.
  • As shown in FIG. 7 (e), during the initial state, the heating temperature T of the heating element is maintained with the target temperature TTRG and the heating temperature T is decreased by not less than ΔT together with the deterioration progress. Finally, the heating temperature is decreased to a value of not more than predetermined deterioration limit-temperature TWRN. In this case, the self-diagnosis signal DI is outputted.
  • During a manufacture process, the reference resistance value RC and the initial reference power value PINT of each of the heating elements 10 are stored in the MEM 232. The power supply control module 20 corresponding to each of the heating elements 10 performs the power supply control and the abnormality deterioration judgment process on the basis of the corresponding reference resistance value RC and initial reference power value PINT of each of the heating elements 10. It is therefore possible to maintain the temperature of the heating element with high accuracy without being affected by deterioration of other glow plugs, and to provide warning information at an optimum and correct timing.
  • A description will be given of the power supply control method in an after glow control mode with reference to FIG. 8.
  • In the exemplary embodiment previously described, the deterioration of the heating element is detected in the normal control mode when the power supply to the glow plug 1 is performed, i.e. the pre-glow control is performed, where the pre-glow control assists the ignition of the internal combustion engine. However, it is possible to perform the deterioration judgment of the glow plug of a control section integrated-type according to the present invention in the afterglow control mode for protecting a miss fire and decreasing emission.
  • This case can perform the deterioration judgment which is substantially equal to that of the normal control mode. But, in the deterioration judgment process in step S340, the second deterioration current IWRN2 is used as a threshold value with which the plug current IGP is compared. Further, the resistance value change reflecting means (F/B process) in step S350 compares the plug resistance value RGP with a second reference resistance value RC2 which is calculated on the basis of the plug resistance value RGP and the reference resistance value RC in order to perform the threshold judgment.
  • Because the target temperature in the after glow control mode is lower than that in the normal control mode, the second deterioration power value PWRN2 and the second reference resistance value RC2 are lower than those in the normal control mode, respectively.
  • The conventional deterioration judgment devices perform the deterioration judgment of the glow plug within a limited period of time immediately after the power supply is stopped. On the other hand, the glow plug 1 of a control section integrated-type according to the present invention always performs the deterioration judgment of the glow plug 1 during both the normal control mode and the after glow control mode. This makes it possible to quickly detect occurrence of abnormality deterioration of the glow plug and take necessary measures.
  • FIG. 9 (a) is a characteristic view showing a temperature control state of the glow plug 1 of a control section integrated-type without performing the pre-heating control mode. FIG. 9 (b) is a characteristic view showing a temperature control state of the glow plug 1 of a control section integrated-type when the pre-heating control mode is performed. FIG. 9 (c) is a characteristic view showing a temperature control state of the glow plug 1 of a control section integrated-type in the after glow control mode.
  • As shown in FIG. 9 (a), a temperature of the heating element is quickly increased by using approximately 100 % duty ratio or an excessive power supply in the initial temperature rising mode (MINT). Further, because the rapid temperature rapid rising control is switched to the temperature rising suppress control in the mode switching temperature TCH which is lower than the first target temperature T1, an excessive temperature rising of the glow plug is suppressed. Because the power supply control is performed on the basis of the feedback using the drive signal with the reference resistance value RC as the threshold value corresponding to the resistance temperature characteristics of the individual glow plug after the temperature of the heating element reaches the first target temperature, it is possible to always perform the abnormality deterioration judgment during the normal control mode quickly detect the abnormality deterioration. Further, it is possible to maintain the temperature of the heating element at the second target temperature with high accuracy during the after glow control mode. Still further, it is possible to always perform the abnormality deterioration judgment during the after glow control mode and quickly detect the abnormality deterioration.
  • As previously described, when the pre-heating control mode MPRE, as shown in FIG. 9 (b), it is possible to securely prevent an over-temperature rising of the heating element because the temperature of the heating element is maintained lower than the target temperature for a predetermined period of time. After the transition mode MTRN is performed, the normal control mode MCST is performed to maintain the heating element at the target temperature. In this case, the deterioration judgment is performed under the condition in which a temperature of the heating element under one of the pre-heating control mode MPRE and the normal control mode MCST becomes stable.
  • A description will be given of the explanation of determining an optimum period to perform the deterioration detection and the explanation of the judgment method of the deterioration detection with reference to FIG. 10.
  • The exemplary embodiment previously described show the method of detecting deterioration and the power supply control which are performed simultaneously during the normal control mode and the after glow control mode. The exemplary embodiment shown in FIG. 10 shows the method of performing the deterioration judgment before a cranking or a time immediately after the internal combustion engine has stopped, or during the idle stop control, as a method of eliminating disturbance caused by an operation state and detecting occurrence of deterioration with high accuracy.
  • For example, a rush current flows in a starter motor at the cranking, and a battery voltage is fluctuated. This causes a large fluctuation of the current IGP flowing in the heating element 10 by the battery voltage +B, and it is therefore difficult to precisely detect the plug resistance current RGP. Further, there is a possibility of fluctuating the battery voltage while the engine is driven, etc. and therefore difficult to precisely detect the plug resistance value RGP.
  • It is therefore preferable to perform the deterioration detection according to the present invention before the cranking of the internal combustion engine 8, at a time immediately after the internal combustion engine has stopped, or during the idle stop control.
  • In the drive state recognition process in step S400 shown in FIG. 10, information regarding operation state such as engine rotation speed, etc. is inputted. In the deterioration judgment process in step S410, it is detected that the current state is one of the state before the cranking, the state immediately after the internal combustion engine has stopped, and the state during the idle stop control on the basis of the information input in step S400.
  • The judgment result indicates Yes when the current state is one of the state before the cranking, the state immediately after the internal combustion engine has stopped, and the state during the idle stop control. The operation flow goes to step S430. On the other hand, the judgment result indicates No when the current state is not one of the state before the cranking, the state immediately after the internal combustion engine has stopped, and the state during the idle stop control. The operation flow returns to step S400 without performing the deterioration detection process.
  • In the deterioration detection process in step S430, similar to the exemplary embodiment previously described, the effective power value PACT is calculated on the basis of the plug voltage VGP applied to the heating element 10 and the plug current IGP flowing in the heating element 10. The calculated effective power value PACT is compared with the predetermined power threshold value PREF.
  • It is acceptable to always perform the deterioration detection process for the glow plug according to the operation state of the internal combustion engine detected by the ECU.
  • The exemplary embodiment shows the example in which the N channel power MOS FET is arranged at an upstream side of the load, and driven to open and close by using a high-side driver. The concept of the present invention is not limited by this structure. It is possible to arrange a P channel power MOS FET at a high side instead of the N channel power MOS FET.
  • In general, although such a P channel power MOS FET has a large ON resistance when compared with that of an N channel power MOS FET, it is possible to eliminate any gate voltage boosting means such as a charge pump circuit from the drive circuit 22 by using such a P channel power MOS FET.
  • It is possible to arrange the N channel power MOS FET in order to perform the open and close control by using a low side driver. Although this case causes a problem to supply a voltage to the glow plug during no operation of the glow plug, this does not require a boosting means such as a charge pump, and provides a simple circuit structure.
  • Explanation of reference numbers
  • 1
    Glow plug of a control section integrated-type (Heating device),
    10
    Glow plug (Heating element),
    20
    Power supply module,
    200
    Mold package,
    201
    Power input terminal,
    202
    Drive signal input terminal,
    203
    Self-diagnosis signal output terminal,
    204
    Output terminal,
    205
    Ground terminal,
    21
    Semiconductor open/close element,
    210
    Control MOS,
    211
    Current detection MOS (Mirror circuit section),
    212
    Current detection resistance (Zener zap resistance),
    22
    Drive circuit section (DRV),
    220
    Operational amplifier,
    221, 223
    Diode,
    222, 224
    Capacitor,
    23
    Heating element control IC,
    230
    Resistance value arithmetic means (Current · Voltage detection section),
    231
    Reference resistance value storage section (Reference resistance forming section),
    232
    Reference resistance adjusting means (Zener zap circuit),
    233
    Resistance value change reflecting means (F/B means),
    234
    Deterioration judgment means,
    30
    Housing casing,
    40
    Connector section,
    41
    Power input terminal,
    42
    Drive signal input terminal,
    43
    Self-diagnosis signal output terminal,
    6
    Power source,
    7
    Engine control unit (ECU),
    8
    Internal combustion engine,
    SI
    Drive signal,
    PACT
    Effective power value,
    PINT
    Initial reference power value,
    PREF
    Power threshold value,
    PWRN
    Deterioration power value,
    RC
    Reference resistance value,
    RCH
    Reference resistance value,
    T ZP1, T ZP2
    Zener zap input terminals,
    MINT
    Initial temperature rising mode,
    MPRE
    Pre-heating control mode,
    MTRN
    Transition mode, and
    MCST
    Normal control mode.

Claims (6)

  1. A heating device (1) comprising:
    a heating element (10), a resistance value of which changes in a positive correlation to a temperature change of the heating element (10);
    a power supply control module (20) for controlling a power source to supply an electric power to the heating element so that the resistance value of the heating element becomes equal to a target resistance value; and
    a housing casing (30) in which the heating element (10) and the power supply control module (20) are assembled together,
    wherein the power supply control module (20) comprises:
    a reference resistance value storage means (231) for storing, as a reference resistance value, a resistance value of the heating element (10) at a predetermined target temperature, which is previously measured by the power supply control module (20); and
    a resistance value change reflecting means (233) for using the reference resistance value as a threshold value, and allowing the power supply to the heating element (10) when the resistance value of the heating element (10) is lower than the reference resistance value during the power supply to the heating element (10), and halting the power supply to the heating element (10) when the resistance value of the heating element (10) exceeds the reference resistance value during the power supply to the heating element (10) in order to reflect, to the power supply control, the resistance value change due to the temperature change of the heating element (10).
  2. A heating device (1) comprising:
    a heating element (10), a resistance value of which changes in a positive correlation to a temperature change of the heating element (10);
    a power supply control module (20) for controlling a power supply from a power source to the heating element so that the resistance value of the heating element becomes equal to a target resistance value;
    a housing casing (30) in which the heating element (10) and the power supply control module (20) are assembled together; and
    a housing casing (30) in which the heating element (10) and the power supply control module (20) are assembled together,
    wherein the power supply control module (20) comprises:
    a reference resistance value storage means (231) for storing, as a reference resistance value, a resistance value of the heating element (10) at a predetermined target temperature, which is previously measured by the power supply control module (20);
    a resistance value change reflecting means (233) for using the reference resistance value as a threshold value, and allowing the power supply to the heating element (10) when the resistance value of the heating element (10) is lower than the reference resistance value during the power supply to the heating element (10), and halting the power supply to the heating element (10) when the resistance value of the heating element (10) exceeds the reference resistance value during the power supply to the heating element (10) in order to reflect, to the power supply control, the resistance value change due to the temperature change of the heating element (10); and
    a deterioration judgment means (234) for judging whether or not the heating element (10) is deteriorated on the basis of a deterioration power value in a deterioration state of the heating element (10), as a power threshold value, to be supplied to the heating element (10) at a predetermined deterioration limit-temperature, where the deterioration power value in the deterioration state is calculated by multiplying together a predetermined rate and an initial power value, to be supplied to the heating element (10) in a normal state at a predetermined temperature previously detected.
  3. The heating device as claimed in claim 1 or 2, wherein the reference resistance value of the heating element is adjusted by an electrically trimming.
  4. The heating device as claimed in claim 3, wherein the electrical trimming is a digital trimming by using a Zener zapping or a poly silicon fuse.
  5. The heating device as claimed in any one of claims 1 to 4, wherein the heating element (10) is a glow plug which is mounted to a respective cylinder of an internal combustion engine (8).
  6. The heating device as claimed in claim 2, wherein the deterioration judgment means (234) performs the deterioration judgment of the heating element at a time before a cranking of the internal combustion engine (8), immediately after the stop of the internal combustion engine (8) or an idle stop operation.
EP12839896.3A 2011-10-11 2012-08-24 Heating device Active EP2768276B1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
JP2011224286A JP5884390B2 (en) 2011-10-11 2011-10-11 Heating device
PCT/JP2012/071378 WO2013054598A1 (en) 2011-10-11 2012-08-24 Heating device

Publications (3)

Publication Number Publication Date
EP2768276A1 true EP2768276A1 (en) 2014-08-20
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WO2017140783A1 (en) * 2016-02-17 2017-08-24 Dbk David + Baader Gmbh Electric device, in particular heater, and device and method for actuating an electric device
TWI841942B (en) * 2021-07-09 2024-05-11 日商歐姆龍股份有限公司 Abnormality determination device, abnormality determination method, and abnormality determination system

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JP2022135161A (en) * 2021-03-04 2022-09-15 オムロン株式会社 Abnormality determination device
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CN114578136A (en) * 2022-03-11 2022-06-03 辽宁省鑫源温控技术有限公司 Method for detecting abnormal electric heating load

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EP2653714A4 (en) * 2010-12-16 2016-03-16 Bosch Corp Glow plug drive control method and glow plug drive control apparatus
EP2947310A1 (en) * 2014-05-19 2015-11-25 NGK Spark Plug Co., Ltd. Energization control apparatus for a glow plug
WO2017140783A1 (en) * 2016-02-17 2017-08-24 Dbk David + Baader Gmbh Electric device, in particular heater, and device and method for actuating an electric device
TWI841942B (en) * 2021-07-09 2024-05-11 日商歐姆龍股份有限公司 Abnormality determination device, abnormality determination method, and abnormality determination system

Also Published As

Publication number Publication date
JP2013084478A (en) 2013-05-09
EP2768276B1 (en) 2016-09-28
CN103875308B (en) 2016-03-23
CN103875308A (en) 2014-06-18
EP2768276A4 (en) 2015-07-01
JP5884390B2 (en) 2016-03-15
WO2013054598A1 (en) 2013-04-18

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