DE60016700T3 - Bracket design for a glow plug - Google Patents

Description

BACKGROUND OF THE INVENTION

1. Field of the invention:

The The present invention relates to a support structure for a glow plug a pressure sensor for use in an internal combustion engine.

2. Description of the Related Art:

JP-A-7-139736 discloses a glow plug with a combustion pressure sensor. In the JP-A-7-139736 For example, the glow plug is attached to a diesel vehicle engine and has a plug body having a heater and a pressure sensor that detects the combustion pressure based on the force acting on the plug body according to a combustion pressure.

How out 12 is apparent, is a first glow plug 100 with a pressure sensor 300 and second to fourth glow plugs 200 on a cylinder head 1 appropriate.

Every glow plug 100 . 200 has a candle body 700 and is with a common metal plate connecting rod 2 with a connection screw 204a a metal bar 204 connected. The connecting rod 2 has four holes or grooves through which the terminal screw 204a the glow plugs 100 . 200 penetrate accordingly.

A ring crimp connection 4 is on a battery wire 3 crushed. The ring crimp connection 4 is made of metal and has a hole or groove through which the terminal screw 204a penetrates. The ring crimp connection 4 is with the leftmost fourth glow plug 200 connected. The connecting rod 2 is on the top surface of a mother 210 through a connecting nut 211 attached.

A battery voltage is through the battery wire 3 and the connecting rod 2 parallel to the metal bars 204 the glow plugs 100 . 200 created. The battery voltage is with the cylinder head 1 through a heating coil 203 , a jacketing tube 202 and housing 201 grounded. This heats a radiator 206 with the heating coil 203 and the sheath tube 202 every machine cylinder.

In the first glow plug 100 with the pressure sensor 300 is the ring-like pressure sensor 300 through the screw 201 to the housing 201 fitted and attached. The pressure sensor 300 captures the combustion pressure based on the force exerted on the plug body 700 acts. Namely, the combustion pressure becomes a displacement of the plug body 700 in the first candle 100 detected. The displacement becomes a piezoelectric element of the pressure sensor 300 transmitted and converted into an electrical output signal. The electrical output signal is through a wire 500 sent to a vehicle ECU to be used for the engine controls.

However, in a diesel engine, where the vibrations of the engine are significantly greater than in a gasoline engine, the connecting rod is against repeated tension 2 made of a highly rigid material.

In this way, a mechanical vibration due to a bending of the connecting rod at the connecting rod 2a between each glow plug 100 . 200 through the candle body 700 on the pressure sensor 300 transferred without passing through the connecting rod 2 to be included. Because the pressure sensor 300 also detects the mechanical vibration and counts to the combustion pressure, detects the pressure sensor 300 the combustion pressure inaccurate.

In addition, if the pressure sensor 300 not firmly on the cylinder head 1 is attached, the screw connection between the pressure sensor 300 and the candle body 700 through the screw 201 to be released by a vibration of the machine, causing the pressure sensor 300 itself mechanically vibrated. In this case, the mechanical vibration of the pressure sensor deteriorates 300 the accuracy of the detection of the combustion pressure.

How out 12 is apparent, the candle body has 700 also a lead 200a coming from the top surface of the cylinder head 1 projects. The pressure sensor 300 is on the outer surface of the plug housing 201 within the projection 200a attached while holding the top surface of the cylinder head 1 touched.

According to the prior art, a protrusion length L of the protrusion 200a which is a length from the upper surface of a hexagon section 312 of the pressure sensor 300 to the top of the projection 200a corresponds to too long (about 60 mm). The long projections 200a cause the mechanical vibration of the candle body 700 while the frequency is relatively close to a repetition frequency of the connecting rod 2 is, thereby reducing the accuracy of the detection of the combustion pressure.

SUMMARY OF THE INVENTION

An object of the present invention is to suppress that a mechanical Vibrati influenced on an output of a combustion pressure sensor.

According to one The first aspect of the present invention is a glow plug with independent of a pressure sensor with a supply part for electrical Power connected, which is separate from the other glow plugs. The glow plug with namely, the pressure sensor is not with a common connecting rod with the other glow plugs connected, as in the prior art, so that a mechanical Vibration due to a bending of the connecting rod between each glow plug the glow plug not influenced by the pressure sensor.

According to one Second aspect of the present invention are all glow plugs connected together with a flexible supply part for electric power, whose resonance frequency is lower than a combustion pressure frequency, so that the mechanical vibration frequency of the flexible supply part for electrical Power does not overlap the combustion pressure frequency. In this way, the mechanical vibration frequency of the flexible supply part for electrical Power simply removed from the output signal of the pressure sensor.

On this way will according to the above described first and second aspects of the present Invention a mechanical vibration noise substantially completely from removed from the output signal of the pressure sensor.

According to one The third aspect of the present invention is a combustion pressure sensor with a piezoelectric element at least partially in one Cylinder head embedded, with the embedded portion of the combustion pressure sensor in an axial direction of the glow plug and pushed in other directions against the cylinder head. In this way, the pressure sensor in which the piezoelectric Element is installed, supported in a variety of directions. Of the Pressure sensor is namely firmly attached to the cylinder head, thereby suppressing the mechanical Vibration of the pressure sensor generated vibration noise, the Affect the output of the pressure sensor.

According to one Fourth aspect of the present invention has a plug body Projection from an upper surface of a cylinder head in an axial direction of the glow plug protrudes, and a connection section for connection to a Feed part for Electric current flowing at the end of the tip of the projection is provided. A combustion pressure sensor is on an outer surface of the Attached to the projection which is in abutment with the upper surface of the Cylinder head is. A projection length (L) of the section, at the combustion pressure sensor is attached to the tip end of the projection is less than 45 mm. In this way, the resonance frequency of the glow plug is higher than the combustion pressure frequency and does not overlap with the Combustion pressure frequency, thereby suppressing that by the mechanical Vibration of the glow plug generated vibration noise affects the output of the pressure sensor.

BRIEF DESCRIPTION OF THE DRAWINGS

additional Objects and advantages of the present invention will become apparent from the following detailed description of preferred embodiments to be better recognized when combined with the accompanying drawings be taken into account in which:

1 is a cross-sectional view showing a glow plug in a cylinder head (first embodiment);

2A is a cross-sectional view showing a pressure sensor (first embodiment);

2 B is a bottom view showing the pressure sensor;

3 is an enlarged view showing a piezoelectric element (first embodiment);

4 Fig. 16 is a cross-sectional view showing a lead connector (first embodiment);

5 is a plan view showing a conductor wire (first embodiment);

6A to 6E Diagrams are illustrating the effects of the first embodiment;

7A Fig. 12 is a cross-sectional view showing a pressure sensor (second embodiment);

7B is a bottom view showing the pressure sensor (second embodiment);

8th Fig. 12 is a cross-sectional view showing a pressure sensor of a modification (second embodiment);

9A and 9B Diagrams are illustrating the effects of the second embodiment;

10 FIG. 12 is a graph showing a relationship between a protrusion length L of the glow plug and a resonance frequency of the glow plug (third embodiment); FIG.

11A to 11C Are diagrams showing the effects of the third embodiment, and

12 is a cross-sectional view showing a glow plug on a cylinder head (prior art).

DETAILED DESCRIPTION PREFERRED EMBODIMENTS

First Embodiment

How out 1 it can be seen are a first glow plug 100 and second to fourth glow plugs 200 on a cylinder head 1 appropriate. The first glow plug 100 has a candle body 700 and a pressure sensor 300 , The candle body 700 heats up by receiving an electrical current. The pressure sensor 300 detects an engine combustion pressure based on a force passing through the plug body 700 acting combustion pressure is caused. The second, third or fourth glow plug 200 also has a candle body 700 ,

The cylinder head 1 has a glow hole through the cylinder head 1 from the outside to the inside of a combustion chamber 1a permeates for each machine cylinder. The candle body 700 are inserted into the light holes accordingly. The candle body 700 has a metal case 201 , on its outer surface a screw 201 has formed. The screw 201 is screwed into the glow hole to the housing 201 on the cylinder head 1 to fix.

The candle body 700 has a sheath tube 202 that through the case 201 is supported. The jacket tube 202 is made of a heat-resistant and corrosion-resistant alloy (for example, stainless SUS 310 ) and formed as a cylindrical tube. The lower end of the sheath tube 202 is closed and its upper end is open. A heating coil made of a resistance wire such as NiCr, CoFe 203 is in the lower region of the sheath tube 202 provided. A metal bar 204 is in the upper part of the sheath tube 202 inserted.

The heating coil 203 connects the lower end of the sheath tube 202 and the lower end of the metal tube 204 , A heat-resistant, insulating powder 205 such as magnesia is between the heating coil 203 and the sheath tube 202 as well as between the metal bar 204 and the sheath tube 202 provided. The jacket tube 202 is formed by reducing, so that the density of the insulating powder 205 is increased, and the sheath tube 202 , the heating coil 203 and the metal bar 204 are firmly attached.

The jacket tube 202 , the heating coil 203 and the insulating powder 205 form a radiator 206 , the radiator 206 is in the case 201 provided in a way that the lower end of the sheath tube 202 to the combustion chamber 201 is exposed. The radiator 206 gets into the case 201 pressure inserted or by silver soldering to the housing 201 soldered.

A disc made of an insulating bakelite 207 and an O-ring made of silicone or fluororubber are in the upper portion of the metal rod 204 provided. The disc 207 centers the metal bar 204 , where the O-ring 208 in a space between the metal bar 204 and the housing 201 seals.

The metal bar 204 is by a bush made of an insulating resin such as phenol 209 and a mother 210 running along a connecting screw (connecting section) 204a the metal bar 204 screwed to the case 201 attached. The insulating socket 209 prevents an electrical short circuit between the metal bar 204 and the housing 201 ,

Every second, third and fourth glow plug 200 is with a common connecting rod 2 at the connection screw 204a connected. Namely divide the second, third and fourth glow plug 200 the common connecting rod 2 , The first glow plug 100 with the pressure sensor 300 is independent with a ring crimp connection (supply part for electric current) 400 connected, which one to the connecting rod 2 different part is.

The crimp connection 400 is made of metal and has a hole or slot through which the terminal screw 204a is inserted. The crimp connection 400 is through the mother 210 and a connecting nut 211 on the connection screw 204a attached. A battery wire 401 is electrical with the crimp connection 400 connected. Another battery wire 3 is electric with the connecting rod 2 through another ring crimp connection 4 connected.

The electric wires 3 . 401 are made of a soft material, and their outer surfaces are electrically insulated. The electric wires 3 . 401 are connected by a relay to a vehicle battery (not shown). The battery supplies electrical power to each glow plug 100 . 200 , the radiator 206 each cylinder heats up at the same time and supports the ignition of a diesel machine.

The radiator 206 is a metal radiator made of a metal resistance wire. Alternatively, the radiator 206 a ceramic heater made of an electrically conductive ceramic with nitrile silicone and silicone molybdenum, which is insulated by an insulator made of a nitride silicone insulating ceramic.

How out 1 is apparent, is the pressure sensor 300 formed in a ring and on a projection 200a of the mantle 700 attached by the top surface of the cylinder head 1 projects. The pressure sensor 300 touches the upper surface of the cylinder head 1 ,

How out 2A and 2 B it can be seen, the pressure sensor has 300 A mother 310 , a piezoelectric element 320 , a lead 330 , a pedestal 340 and a metal case 350 , The mother 310 also attaches a sensor body to the plug body 700 , The piezoelectric element 320 outputs an electrical signal based on the force caused by the combustion pressure sensor. The administration 330 conducts the electrical signal to a conductor wire 500 , The mother 310 and the pedestal 340 support the piezoelectric element 320 and part of the line 330 , The metal case 350 protects the piezoelectric element 320 from dust and water. The mother 310 is made of metal and attached to the case 201 attached. The mother 310 has a screw 311 to the sensor body through the screw 201 on the housing 201 to attach, and a hexagon section 312 , The mother 310 also has a section 313 large diameter and a section 314 small diameter under the hexagon section 312 , An insulating tube made of silicon 315 is around the section 314 provided with a small diameter.

The administration 330 connects the electrical element 320 electrically with the conductor wire 500 , The administration 330 has an electrode 331 , an insulator 332 and a fitting part 333 , The electrode 331 is made of metal and designed as a ring. The insulator 332 is between the electrode 331 and the nut provided to isolate these components from each other. The insulator 332 is formed as a ring and made of an insulating material such as mica, alumina or the like. The electrode 331 and the insulator 332 are through the insulating tube 315 to the outer edge of the section 314 small diameter fit.

The conductor wire 500 is through the concentric layers of a signal output wire 501 , an insulating cover 502 , a grounded, sealed wire 503 and an insulating cover 504 constructed from inside to outside. The signal output wire 501 is from the earthed, sealed wire 503 isolated. How out 2A is apparent, are the signal output wire 501 , the insulating cover 502 and the grounded, sealed wire 503 partially at one end of the conductor wire 500 exposed.

The signal output wire 501 enters through a hole 316 mother 310 and a section 332a of the insulator 332 , and is at the hole 331a the electrode 331 at the electrode 331 welded. The other end of the conductor wire 500 is connected to an external circuit (for example, ECU) through a connector (not shown).

The fitting part 333 is cylindrical and in the outer edge region of the conductor wire 500 provided to the conductor wire 500 at the mother 313 to fix. The hole 316 has a holding hole 316a in the upper area, and the fitting part 333 gets into the holding hole 316a inserted. The fitting part 333 is mechanically on the lead wire 500 attached and electrically connected to the earthed, sealed wire 503 connected. An insulating cover made of silicon 333a covers the outer surface of the fitting part 333 coming from the cylinder head 1 projects.

The piezoelectric element 320 is designed as a ring and through the insulating tube 315 around the section 314 provided with a small diameter. How out 3 is apparent, is the piezoelectric element 320 by stacking three layers of piezoelectric ceramics 321 designed to have a signal output ring 322 and a grounded disc ring 323 combine. Every piezoelectric ceramic 321 is formed as an annular disc and formed of lead titanate, lead titanate acetate zirconate or the like. Both disc rings 322 and 323 do not touch each other. In the out 3 apparent piezoelectric element 320 a positive electrode is provided around the signal output disc ring 322 to touch, and a negative electrode is provided to the grounded disc ring 322 to touch. In this way, the three piezoelectric ceramics 321 arranged electrically in parallel so that the output sensitivities of these piezoelectric ceramics 321 are summed, and thereby the sensitivity of the piezoelectric element 320 is improved.

The pedestal 340 is made of metal and designed as a ring. How out 2 B is apparent, has the pedestal 340 a small, disc-like block of rotation 341 at the area that the cylinder head 1 touched to easily become a disc-like turning block 317 mother 310 fit. The turning block 317 is at the bottom of the section 314 small diameter formed. That's the mother 310 firmly on the pedestal 340 attached and does not turn with respect to it.

The cylindrical, made of a metal such as SUS 304 manufactured metal housing 350 is in the outer edge area of the pedestal 340 provided. The metal case 350 covers the entire outer edge area of the pressure sensor 300 , The metal case 350 is made by the cylindrical drawing of a thin metal plate having a thickness of less than 0.5 mm, and completely on the pedestal 340 Laser-welded or copper-soldered.

In that with the metal case 350 integrally executed pedestal 340 is the rotation block 341 the turning block 317 mother 310 suitable opposite. One in a cutout groove of the section 314 small diameter provided O-ring 343 touches an inner diameter surface 342 of the pedestal 340 firmly. In addition, the metal case 350 at the section 313 big diameter of the mother 310 fitted, and completely at an inner contact area 351 to the section 313 large diameter YAG laser welded.

In this way pushes a screwing the mother 310 , where the pedestal 340 on the cylinder head 1 is attached.

The screwing force of the nut 310 also holds the piezoelectric element 320 , the electrode 331 and the insulator 332 between the mother 310 and the pedestal 340 ,

An assembly process of the pressure sensor 300 is explained below.

The signal output wire 501 gets to the hole 331a the electrode 331 welded. The fitting part 333 gets into the holding hole 316a mother 310 inserted and welded or copper soldered. The insulator 332 is at the section 314 small diameter attached.

The conductor wire 500 is from the side of the insulator 332 in the hole 316 inserted, and those with the conductor wire 500 connected electrode 331 gets to the section 314 small diameter fit. After the electrode 331 is suitably positioned, the fitting part 333 mechanically on the earthed, sealed wire 503 attached. The insulating cover 333a covers the lead wire 500 and the fitting part 333 , This is the grounded, sealed wire 503 electrically with the fitting part 333 connected.

The piezoelectric element 320 is at the section 314 small diameter attached. The metal case 350 one-piece pedestal 340 is fitted up to the small diameter section while causing the rotary block 341 the turning block 317 touched. The metal case 351 is at the section 313 large diameter laser-welded while the pedestal 340 to the mother 310 is pressed.

In this way, the assembly of the pressure sensor 300 completed. The pressure sensor 300 gets from the radiator 206 in the candle body 700 fitted and through the screw 201 , the screw 311 and the hexagon section 312 on the candle body 700 screwed.

A detection mechanism of the pressure sensor 300 will be explained.

The combustion pressure inside the machine is controlled by the radiator 206 the first glow plug 100 around the case 201 to the screw 201 transfer. The combustion pressure releases the fastening torque of the screw 201 which the glow plug 100 on the cylinder head 1 attached.

In this way, an axial force is also released by attaching the pressure sensor 300 is caused and by the screw 311 mother 310 on the piezoelectric ceramics 321 acts, so that an electrical signal output from the piezoelectric ceramics 321 varies based on their piezoelectric characteristics. The electrical signal is transmitted through the electrode 331 and the lead wire 500 output to the outer circuit. The electrical signal is converted to electrical voltage and used as a combustion pressure wave signal for combustion control.

How out 1 is apparent, is the first glow plug 100 with the pressure sensor 300 independent with the ring crimp connection 400 connected by the common crimp terminal 4 and the common connecting rod 2 for the second to fourth glow plugs 200 is disconnected. The first glow plug 100 with the pressure sensor 300 is not like the prior art with the common connecting rod 2 with the other glow plugs 200 connected so that a mechanical vibration due to a connecting rod bending between each glow plug 200 the first glow plug 100 unaffected.

According to the embodiment described above, the ring crimping terminal 400 used as a first example. How out 4 can be seen, the ring crimp 400 with a cable connector (supply part for electric current) 410 be replaced as a second example. The cable connector 410 is with the connection screw 204a connected. The cable connector 410 has egg NEN cylindrical crimp connection 411 which can be easily installed and removed without tools.

A metallic connection nut 420 is through a connection screw 421 on the connection screw 204a the first candle 100 screwed. There is also a cutout groove 425 squeezed to the connecting nut 420 with the connection screw 204a with the insulating bush 209 to fix.

The cylindrical crimp connection 411 is with a battery wire 430 connected. The cable connector 410 has the cylindrical crimp connection 411 covered with a rubber cover made of silicone rubber 412 is integrally formed. The cable connector 410 also has a cutout groove 413 and a collar 414 , The connection nut 420 also has a projecting connection 423 and a collar 424 , The cable connector 410 is at the connection nut 420 by fitting the cylindrical pinch connection 411 at the projecting connection 423 attached by the cut-out groove 413 on the collar 424 is attached, and by inserting the collar 414 in the cut out groove 425 , In this way, the line connector 410 suitable through the connection nut 420 supported to master the mechanical vibration and displacement.

In the second example, as in the first example, the first glow plug is 100 with the pressure sensor 300 independent with the cable connector 410 connected by the common connecting rod 2 the other glow plugs 200 is separated, so that a mechanical vibration of the connecting rod, the first glow plug 100 unaffected.

In the first and second examples has only the first glow plug 100 the pressure sensor 300 , If two or more glow plugs respectively have a pressure sensor, each glow plug with the pressure sensor should be independent with each ring crimp connection 400 or pipe connector 410 be connected, which is connected to each battery wire, which is separated from the other. When two or more pressure sensors having glow plugs are provided in a machine cylinder, each glow plug should be independent with each ring crimp terminal 400 or pipe connector 410 be connected.

According to the third example, a single conductor wire connects (flexible supply part for electric current) 600 all glow plugs 100 . 200 , like out 5 is apparent. The conductor wire 600 is used instead of the connecting rod 2 in the prior art in 12 used.

The conductor wire 600 is made of a flexible material having a resonant frequency lower than a combustion pressure frequency. The conductor wire 600 has a variety of ring crimp terminals 610 according to each glow plug 100 . 200 and battery wires 620 who have this Ring Crimp Terminals 610 connect. The ring crimp connection 610 has one with the connection screw 204a the glow plug 100 . 200 connecting hole. The battery wire 620 is made of a flexible, thin copper wire having a resonant frequency lower than the combustion pressure frequency. The battery wire 620 is electrically isolated at its outer surface.

In this way, in the third example, all the glow plugs 100 . 200 together with the conductor wire 600 connected. The mechanical vibration frequency of the conductor wire 600 does not overlap with the combustion pressure frequency, so that the outer circuit easily changes the mechanical vibration frequency of the lead wire 600 from the output signal of the pressure sensor 300 away.

According to the above-described three examples of the first embodiment, the flexible material having a remarkably low rigidity connects the first one, the pressure sensor 300 having glow plug 100 instead of the known plate-like connecting rod 2 , which has a high rigidity and does not absorb vibration. In this way, a mechanical vibration sound (0.5 KHz-1.5 KHz) is substantially complete with the output signal of the pressure sensor 300 removed while a basic function of the glow plug is achieved.

The effect of the present embodiment will be described with reference to FIG 6A to 6E described.

6A to 6E show test results on the condition that the machine operates at full load at 4000 rpm. 6A shows an output waveform of the first glow plug 100 if the known connecting rod 2 all four glow plugs 100 . 200 combines.

6B shows an output waveform of the first glow plug 100 when the first example is applied. 6C shows an output waveform of the first glow plug 100 when the second example is applied. 6D shows an output waveform of the first glow plug 100 when the third example is applied. 6E shows an output waveform of the first glow plug 100 if no part with the first glow plug 100 connected is.

As can be seen from these waveforms, according to all the examples of the present application a sawtooth mechanical vibration sound (0.5 KHz to 1.5 KHz), which is apparent from the prior art, in an output waveform in 6E removed, in which the glow plug 100 is not influenced by any part.

Second Embodiment

How out 7A is apparent, according to the second embodiment is a part of the pedestal 340 at a contact area between the pressure sensor 300 and the cylinder head 1 in the cylinder head 1 embedded. The embedded portion of the pedestal is pushed in an axial direction of the candle and also in other directions, and on the cylinder head 1 attached.

The pedestal 340 has at its outer, lower area a conical seat 344 , The conical seat 344 For example, it is inclined by 123.0 degrees with respect to the touch area. The cylinder head 1 has a conical seat 1b to which the conical seat 344 is fitted. The conical seat 1b is inclined by 120 degrees with respect to the contact surface, which is insignificantly smaller than the inclination angle of the conical seat 344 so that the conical seat 344 by a line contact firmly on the conical seat 1b is fitted. The conical seat 344 is as an embedded section of the pedestal 340 in the cylinder head 1 embedded.

After the first glow plug 100 on the cylinder head 1 is attached, which is on the cylinder head 1 acting axial force of the glow plug 100 to a vertical force (axial direction of the candle) and a horizontal force (radial direction of the candle) against the conical seat 1b distributed.

This is the pressure sensor 300 in which the piezoelectric element 320 is installed, supported in two directions, preventing it from vibrating in the two directions. As a result, the pressure sensor 300 firmly to the cylinder head 1 fitted, while suppressing that due to the mechanical vibration of the pressure sensor 300 generated vibration noise affects the pressure waveform. Here, as a modification of the present embodiment, the vertical side wall of the pedestal 340 be inserted in the cylinder head, like out 8th is apparent. The effect of the present embodiment will be described with reference to FIG 9A and 9B explained.

9A and 9B show experimental results under the condition that the engine is operating at 4000 rpm with full load, and the glow plug used in the first example of the first embodiment 100 is used. 9A shows an output waveform of the first glow plug 100 if the known, flat seat of the pedestal 340 is used. 9B shows an output waveform of the first glow plug 100 when the pedestal 340 the in 7 shown conical seat 344 with 123 degrees. Like 9A and 9B To understand, the vibration noise is quite distant when the conical seat 344 to the cylinder head 1 is fit.

Third Embodiment

An object of the present invention is to provide a mechanical vibration sound due to a protrusion length L of the protrusion 200a to remove. How out 1 and 12 As can be seen, the projection length L is the length from the upper surface of the hexagon portion 312 of the pressure sensor 300 to the top of the projection 200a of the candle body 700 Are defined.

10 FIG. 10 shows a test result of a relationship between the protrusion length L and the resonance frequency of the first glow plug 100 , A shaker and a vibration analyzer perform this experiment. According to the present experiment, the resonance frequency is more than 5 KHz, which is higher than a frequency range of the combustion pressure when the projection length L is less than 45 mm (preferably less than 40 mm from points in 10 ).

Namely, when the protrusion length L is larger than 45 mm, the resonance frequency of the glow plug is 100 higher than 100 Hz to 5 KHz required for engine combustion control. Here, a 5 KHz low pass filter eliminates a high frequency above 5 KHz from the output signal of the pressure sensor 300 so that's in the glow plug 100 included mechanical vibration noise is easily removed at the frequency range required for the engine combustion control.

The effect of the present embodiment will be described with reference to FIG 11A to 11C described.

11A to 11C Test results show that the glow plug is working under the condition that the machine is operating at 4000 rpm with a full load 100 independent with the crimp connection 400 is connected, as described in the first example of the first embodiment, and that the pedestal 340 the conical seat 344 at 123.0 degrees as in the second embodiment. 11A shows an output waveform of the first glow plug 100 when the protrusion length L is about 60 mm as in the prior art. 11B shows an output waveform of the first glow plug 100 if the projection length is 60 mm and the 5 kHz low-pass filter is used becomes. 11C shows an output waveform of the first glow plug 100 if the protrusion length L is less than 45 mm and the 5 kHz low-pass filter is used. How out 11A to 11C To understand is the resonant frequency of the glow plug 100 by shortening the protrusion length L higher, whereby a high frequency of the resonance frequency is eliminated by the low-pass filter, thereby improving the S / N ratio of the combustion pressure waveform.

(AM)

Since the engine vibration varies according to a vehicle body, the above-described first to third embodiments should be appropriately combined. Even if each of the above-described first to third embodiments is used independently, the mechanical vibration noise that affects the output signal of the pressure sensor can be reduced. For example, the second embodiment or the third embodiment may be used independently in the 12 shown known construction, or the second embodiment can be applied to the known construction combined with the third embodiment.

In the embodiments described above For example, the piezoelectric element is used for the pressure sensor. Alternatively, a semiconductor pressure sensor and the like, which is the engine combustion pressure detected by the force generated by the combustion pressure on the candle body is caused, for the pressure sensor can be used.

A first glow plug ( 100 ) and second to fourth glow plugs ( 200 ) are on a cylinder head ( 1 ) appropriate. Each glow plug ( 100 . 200 ) has a candle body ( 700 ). The first glow plug ( 100 ) has a pressure sensor ( 300 ), and is independent with a ring crimp connection ( 400 ) connected to the other glow plugs ( 200 ) is disconnected. In this way, a mechanical vibration due to a bending of a connecting rod ( 2 ) between the second to fourth glow plugs ( 200 ) the first glow plug ( 100 ) that affect the pressure sensor ( 300 ) Has.

Claims (7)

Mounting construction of glow plugs ( 100 . 200 ) with: a plurality of on a cylinder head ( 1 ) mounted glow plugs ( 100 . 200 ), wherein the glow plugs ( 100 . 200 ) according to incandescent bodies ( 700 ), and at least one of the glow plugs ( 100 . 200 ) a combustion pressure sensor ( 300 ), which has a combustion pressure of the engine starting from one on the incandescent body ( 700 ) acting force, characterized in that the at least one glow plug ( 100 ), which the combustion pressure sensor ( 300 ), independently with a feed part ( 400 . 410 ) is electrically and mechanically connected to other glow plugs ( 200 ), with other glow plugs ( 200 ) with a common connecting rod ( 2 ) are connected. Mounting construction of glow plugs ( 100 . 200 ) with: a plurality of on a cylinder head ( 1 ) mounted glow plugs ( 100 . 200 ), wherein the glow plugs ( 100 . 200 ) according to incandescent bodies ( 700 ), and at least one of the glow plugs ( 100 . 200 ) a combustion pressure sensor ( 300 ), which has a combustion pressure of the engine starting from one on the incandescent body ( 700 ) acting force, characterized in that the glow plugs ( 100 . 200 ) together with a flexible, electrical supply part ( 600 ) having a resonant frequency lower than a frequency of the combustion pressure. Mounting structure of glow plugs, with: one on a cylinder head ( 1 ) mounted glow plug ( 100 ), wherein the glow plug ( 100 ) a candle body ( 700 ), and the glow plug ( 100 ) a combustion pressure sensor ( 300 having a combustion pressure of the engine by converting a to the plug body ( 700 ) acting force in an electrical signal from piezoelectric characteristics of a piezoelectric element ( 321 ), wherein the combustion pressure sensor ( 300 ) at least partially into the cylinder head ( 1 ), characterized in that the embedded portion of the combustion pressure sensor ( 300 ) a conical seat ( 344 ), which with a conical seat ( 1b ) of the cylinder head ( 1 ) is fitted so that the embedded portion in an axial direction of the glow plug ( 100 ) and in other directions against the cylinder head ( 1 ) is pushed. A glow plug holding structure according to claim 1 or 2, wherein the combustion pressure sensor ( 300 ) at least partially into the cylinder head ( 1 ) and the embedded portion of the combustion pressure sensor ( 300 ) in an axial direction of the glow plug ( 100 ) and in other directions against the cylinder head ( 1 ) is pushed. A glow plug holding structure according to claim 1 or 2, wherein the plug body ( 700 ) of the glow plug ( 100 ) with the pressure sensor ( 300 ) a lead ( 200a ), the from an upper surface of the cylinder head ( 1 ) in an axial direction of the glow plug ( 100 ) projects a connection section ( 204a ), which at the area of the tip end of the projection ( 200a ) for connection to a supply part ( 400 . 410 . 600 ) is provided for electrical power, wherein the combustion pressure sensor ( 300 ) on an outer surface of the projection ( 200a ) in contact with the upper surface of the cylinder head ( 1 ), and a length (L) of the projection of the portion where the combustion pressure sensor (14) 300 ) is attached to the tip end ( 200a ) is less than 45 mm. A glow plug holding structure according to claim 3 or 4, wherein the plug body ( 700 ) of the glow plug ( 100 ) with the pressure sensor ( 300 ) a lead ( 200a ), which from an upper surface of the cylinder head ( 1 ) in an axial direction of the glow plug ( 100 ) projects a connection section ( 204a ), at the area of the tip end of the projection ( 200a ) for connection to a supply part ( 400 . 410 . 600 ) is provided for electrical power, wherein the combustion pressure sensor ( 300 ) on an outer surface of the projection ( 200a ) in contact with the upper surface of the cylinder head ( 1 ), and a length (L) of the projection of the portion where the combustion pressure sensor (14) 300 ) is attached to the tip end ( 200a ) is less than 45 mm. A support structure according to claim 1, further comprising: a battery wire ( 3 ) electrically connected to the connecting rod ( 2 ) connected is.