JP5080137B2 - Pressure detection device - Google Patents

Description

  The present invention relates to a pressure detection device.

  Conventionally, as this type of pressure detection device, a cylinder internal pressure detection device disclosed in Patent Document 1 below has been proposed.

  The cylinder internal pressure detection device includes a cylindrical storage body and an annular accumulation body. The cylindrical storage body is formed in a double cylindrical shape with an inner cylindrical fitting and an outer cylindrical fitting, and is inserted into a plug insertion hole of a cylinder head of an internal combustion engine. And the said cylindrical storage body is seated on the bottom face of the plug insertion hole with an annular inner flange formed at each tip of the inner cylindrical fitting and the outer cylindrical fitting.

  The annular assembly is formed by laminating each annular insulating plate, electrode plate, piezoelectric element, and metal plate packing, and this annular assembly is fitted to the inner peripheral wall portion of the annular inner flange portion of the cylindrical storage body. Is mounted and accommodated in the annular inner collar.

  Here, the spark plug is inserted into the inner cylindrical fitting of the cylindrical housing, and this spark plug is inserted into a plug screw hole provided at the lower end of the plug insertion hole of the cylinder head. It is screwed. As a result, the spark plug clamps the annular integrated body on the bottom surface of the plug insertion hole with the metal shell through the inner flange portion.

Thus, when a combustion pressure is generated according to the combustion of the air-fuel mixture in the combustion chamber of the internal combustion engine, the combustion pressure is detected by the cylinder internal pressure detection device with the piezoelectric element of the annular integrated body.
JP-A-6-281524

  By the way, when the internal combustion engine vibrates with its operation, the cylindrical storage body inserted into the plug insertion hole of the cylinder head as described above vibrates at its natural frequency.

  Here, since the axial length of the plug insertion hole of the cylinder head has tended to become longer in recent years, in the cylinder internal pressure detection device configured as described above, the axial length of the cylindrical storage body is usually the same as that of the plug insertion. Long to match the axial length of the hole. Moreover, since the inner cylindrical fitting and the outer cylindrical fitting constituting the cylindrical storage body are formed of metal as a whole, the cylindrical storage body has high rigidity.

  From such a configuration of the cylindrical storage body, the natural frequency when the cylindrical storage body vibrates as described above is several kHz. However, since the natural frequency of several kHz is included in the frequency region of the combustion pressure generated by the combustion of the air-fuel mixture in the combustion chamber of the internal combustion engine, the vibration component based on the natural frequency of the cylindrical container is It will be superimposed as noise on the detected pressure as the internal pressure detecting device. As a result, there is a problem that the accuracy of the detected pressure of the cylinder internal pressure detecting device is lowered.

  Therefore, in order to deal with the above-described problems, the present invention has been devised in the configuration of the cylindrical body in the pressure detecting device including the cylindrical body and the pressure detecting body provided at the distal end portion of the cylindrical body. An object of the present invention is to attenuate the natural vibration component of the cylinder more than when the entire cylinder is formed of a metal material.

In solving the above-described problem, the pressure detection device according to the present invention, according to the description of claim 1,
A cylindrical body (1200) and a cylindrical pressure detector (1500) supported coaxially at the tip of the cylindrical body are provided.

In the pressure detection device, the cylinder is coaxially formed by at least one metal cylinder part (1220) and at least one damper cylinder part (1230) adjacent to the at least one metal cylinder part. Formed,
The cylindrical pressure detector includes a cylindrical casing (1510) and an annular laminate (1540) made up of each annular positive electrode plate (1543), piezoelectric body (1542) and negative electrode plate (1541). And
The cylindrical casing is a double cylindrical wall (1520, 1530) formed by coaxially extending from the tip of the cylindrical body and forming an annular accommodating portion (1522, 1523, 1524, 1532) inside. It is configured with
The annular laminate is housed in the annular housing portion of the cylindrical casing.

  With such a configuration, if the pressure detection device is inserted into the plug insertion hole formed in the cylinder head of the internal combustion engine from the cylindrical pressure detection body side, the cylindrical pressure detection body becomes the cylindrical casing. And is seated on the bottom surface of the plug insertion hole on the annular housing side.

  Next, the spark plug is inserted into the cylinder of the pressure detection device, and is fastened to the screw hole formed in the portion of the cylinder head that is coaxially located at the center of the bottom of the plug insertion hole with the mounting screw. Then, the spark plug clamps the pressure detection body between the bottom surface of the plug insertion hole at the annular flange of the metal shell.

  In such a state, when the internal combustion engine operates with combustion of the air-fuel mixture in the combustion chamber, the combustion pressure generated in the combustion chamber is transmitted as vibration to the annular pressure detector through the spark plug. For this reason, the combustion pressure is detected by the annular pressure detector with the piezoelectric body.

  Here, when the internal combustion engine operates as described above, the pressure detection device vibrates in the cylindrical body based on the vibration of the internal combustion engine. Therefore, this vibration is transmitted to the pressure detector.

  However, the cylinder is coaxially formed with at least one metal cylinder part and at least one damper cylinder part adjacent to the at least one metal cylinder part. Therefore, even if the vibration of the cylinder is transmitted to the pressure detection body as described above, the vibration of the cylinder is absorbed and attenuated by the damper effect by the damper cylinder body portion, and then is transmitted to the pressure detection body. .

  As a result, even if the natural vibration component of the cylinder is superimposed on the detection pressure of the pressure detection body as noise, the natural vibration component is attenuated as described above, so that the noise is also attenuated and the pressure detection body is detected. Good pressure accuracy can be secured.

According to a second aspect of the present invention, in the pressure detection device according to the first aspect,
The at least one metal cylinder part is configured as a single main cylinder part (1220) made of a metal material,
The at least one damper cylinder part is a single sub cylinder part (1230) made of a damper material that is coaxially joined to and extended from the tip part of the single main cylinder part. Configured,
The double cylinder wall constituting the cylindrical casing is characterized by extending from an extending end of the single sub cylinder part.

  Thus, the at least one metal cylinder part is configured as a single main cylinder part made of a metal material, and the at least one damper cylinder part is formed at the tip of the single main cylinder part. It was made to comprise as a single sub cylinder part which consists of damper material extended from the part.

  For this reason, the single sub cylinder part which consists of damper materials will intervene between the single main cylinder part which consists of metal materials, and an annular pressure detector. Therefore, the natural vibration component of the cylinder transmitted to the pressure detection body is attenuated by the damper effect of the single sub cylinder immediately before being transmitted to the pressure detection body and is transmitted to the pressure detection body.

  As a result, the noise superimposed on the detected pressure of the pressure detector described above can be attenuated more satisfactorily, so that the operational effect of the invention of claim 1 can be further improved.

According to a third aspect of the present invention, in the pressure detection device according to the second aspect,
The damper material is a polymer material having rigidity lower than that of the metal material.

  Thereby, since a single sub cylinder part can exhibit a damper effect satisfactorily, the operation effect according to claim 2 can be further improved.

The pressure detecting apparatus according to the present invention,
A metal cylinder (1200) and a cylindrical pressure detector (1500) supported coaxially at the tip of the metal cylinder.

In the pressure detection device, the metal cylinder is formed with at least one opening in the peripheral wall,
The at least one opening is closed with a damper member made of a polymer material having a lower rigidity than the metal material in the hollow portion,
The cylindrical pressure detector includes a cylindrical casing (1510) and an annular laminate (1540) made up of each annular positive electrode plate (1543), piezoelectric body (1542) and negative electrode plate (1541). And
The cylindrical casing is configured with double cylindrical walls (1520, 1530) that extend from the distal end of the cylindrical body and form annular housing portions (1522, 1523, 1524, 1532) inside,
The annular laminate is housed in the annular housing portion of the cylindrical casing.

  In this way, the metal cylinder has at least one opening formed in the peripheral wall thereof, and the at least one opening is a polymer having lower rigidity than the metal material in the hollow portion. Even if the metal cylinder is closed with a damper member made of a material, the metal cylinder exhibits a damper effect based on the damper member, so that substantially the same effect as that of the first aspect of the invention can be achieved.

Moreover, according to the description of Claim 4 , this invention WHEREIN: In the pressure detection apparatus as described in any one of Claims 1-3 ,
A lead wire (1544) extending from the annular piezoelectric body into the annular housing portion of the cylindrical casing;
A strip-shaped metal lead covering member (1300) fixed along the axial direction to the outer surface of the cylindrical body,
The double cylindrical wall constituting the cylindrical casing is joined to and extended from the tip of the cylindrical body at its inner wall,
The lead wire extends from the annular housing portion of the cylindrical casing, is covered with a metal lead covering member, and extends toward the base end portion (1210) of the cylindrical body.

  Since the lead wire is covered with the metal lead covering member in this way, even if the spark plug in the cylinder causes an electromagnetic induction effect due to its ignition action, this electromagnetic induction action is at least a lead coating made of metal. Good shielding with components. As a result, in achieving the operation and effect of the invention according to any one of claims 1 to 4, the electromagnetic induction operation does not affect the detected pressure passing through the lead wire as noise.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows the correspondence with the specific means as described in embodiment mentioned later.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows an embodiment of a pressure detection device 1000 according to the present invention applied to a cylinder head 100 of an internal combustion engine.

  The pressure detection device 1000 is configured by a cylindrical support member 1100, a connector 1400, and a cylindrical pressure detection body 1500, and the cylindrical support member 1100 is inserted into a plug insertion hole 110 formed in the cylinder head 100. It is inserted from the annular opening 111.

  As shown in FIGS. 1 and 2, the cylindrical support member 1100 is configured by a longitudinal cylindrical body 1200 and a strip-shaped lead covering member 1300, and the longitudinal cylindrical body 1200 is formed at a base end portion 1210 thereof. The connector 1400 is supported by the annular opening 111 of the plug insertion hole 110 of the cylinder head 100.

  In the present embodiment, the plug insertion hole 110 described above is formed from the outer surface 120 of the cylinder head 100 toward the combustion chamber 130 of the internal combustion engine, as shown in FIG. The annular opening 111 of 110 is formed so as to project outward from the outer surface 120 of the cylinder head 100 in an annular shape.

  As shown in any of FIGS. 1 to 7, the longitudinal cylindrical body 1200 is configured by a main cylindrical body portion 1220 and a secondary cylindrical body portion 1230. The main cylinder portion 1220 is formed in a cylindrical shape with a metal plate material such as a stainless steel plate, and the main cylinder portion 1220 is formed on the base end portion (on the base end portion 1210 of the above-described long cylindrical body 1200). And the like, and is supported and extended by the annular opening 111 in the plug insertion hole 110 through the connector 1400. In the present embodiment, the main cylindrical portion 1220 has an axial length that is half the axial length of the longitudinal cylindrical body 1200. The base end portion of the main cylindrical body portion 1220 is also indicated by reference numeral 1210.

  The sub cylinder portion 1230 is integrally assembled with the main cylinder portion 1220 and the strip-shaped lead covering member 1300. The sub cylinder portion 1230 is provided adjacent to the cylindrical pressure detector 1500, and the sub cylinder portion 1230 is formed in a cylindrical shape with a damper material. Further, as shown in FIG. 5, a band-shaped opening 1231 is formed in the peripheral wall of the sub-cylindrical portion 1230 in a slit shape along the axial direction of the sub-cylindrical portion 1230.

  In the present embodiment, the damper material includes a polymer material such as a synthetic resin material or a rubber material. Examples of the synthetic resin material include those having heat resistance and lower rigidity than the main cylindrical portion 1220, such as polyphenylene sulfide (PPS) and polybutylene terephthalate (PBT). Examples of the rubber material include heat resistance and a material having rigidity lower than that of the main cylindrical body portion 1220, such as silicon rubber and fluorine rubber.

  In the sub-cylindrical portion 1230, both opposing surface portions 1232 and 1233 of the band-shaped opening portion 1231 are in the respective radial inner portions (the radial inner portion of the peripheral wall of the sub-cylindrical portion 1230) as shown in FIG. The strip-shaped recesses 1234 and 1235 are cut out in an L-shaped cross section so as to form the respective strip-shaped recesses 1234 and 1235.

  Here, in the present embodiment, the basis for configuring the long cylindrical body 1200 with the main cylindrical body portion 1220 and the secondary cylindrical body portion 1230 as described above will be described.

  When the internal combustion engine vibrates with its operation, the vibration is transmitted to the cylindrical body 1200 via the cylinder head 100. Accordingly, the cylindrical body 1200 vibrates at the natural frequency.

  Here, the overall length of the cylindrical body 1200 is long in accordance with the overall length of the plug insertion hole 110 of the cylinder head 100, and the cylindrical body 1200 is formed of a metal plate material such as a stainless steel plate over the entire length. Suppose that it is a metal cylinder. In this case, since the metal cylinder has high rigidity, if the metal cylinder vibrates with the vibration of the internal combustion engine as described above, the metal cylinder vibrates with a natural frequency of several kHz. It will be. This means that this natural vibration is transmitted to the pressure detector 1500 connected to the metal cylinder.

  However, the natural frequency of several kHz of the metal cylinder is included in the frequency region of the combustion pressure generated by the combustion of fuel in the combustion chamber 130 of the internal combustion engine. For this reason, when the combustion pressure is transmitted to the cylindrical pressure detector 1500 and detected by the cylindrical pressure detector 1500 as will be described later, the vibration component based on the natural frequency of the metal cylinder described above, that is, the natural vibration component. Is superimposed on the detected pressure of the pressure detector 1500 as noise. As a result, the detection accuracy of the pressure detector 1500 decreases.

  For such a phenomenon, the natural vibration component of the metal cylinder may be attenuated more than the vibration component of the combustion pressure. For this reason, in this embodiment, the longitudinal cylindrical body 1200 is composed of a main cylindrical body portion 1220 made of a metal plate material and a sub-cylindrical body portion 1230 made of a damper material. Effect).

  In addition, as described above, the axial lengths of the sub-cylindrical body portion 1230 and the main cylindrical body portion 1220 are set to half of the axial length of the longitudinal cylindrical body 1200. It is for making it exhibit well.

  In addition, as described above, in the cylindrical body 1200, the sub-cylindrical body portion 1230 is positioned closer to the pressure detection body 1500 than the main cylindrical body portion 1220 in order to better convey the above-described damper effect to the pressure detection body 1500. It is.

  As shown in any of FIGS. 2 to 4, 6, and 7, the strip-shaped lead covering member 1300 includes a strip-shaped inner wall 1310 and a strip-shaped outer wall 1320 having a circular arc cross section. The belt-like inner wall 1310 is fixed by laser welding along the axial portion of the outer peripheral surface of the main cylindrical body portion 1220 at the cross-section arc-shaped inner surface of the upper portion thereof, and the belt-like inner wall 1310 is fixed to the longitudinal cylindrical body 1200. It extends toward the cylindrical pressure detector 1500 along the axial direction. In the present embodiment, the belt-like inner wall 1310 is formed of a metal plate material such as a stainless steel plate.

  The belt-like outer wall 1320 is formed of a metal plate material such as a stainless steel plate so as to have the cross-sectional shape shown in FIGS. 6 and 7. The strip-shaped outer wall 1320 is integrally formed with both width-direction side portions 1321 and 1322 and a width-direction center portion 1323, and the width-direction side portions 1321 and 1322 are formed on the width-direction both sides of the band-shaped inner wall 1310 in the longitudinal direction. And are fixed by laser welding. Thus, the strip-shaped lead covering member 1300 is integrated with the main cylindrical portion 1220 at the upper portion of the strip-shaped inner wall 1310.

  The width direction central portion 1323 is formed to protrude outwardly between the width direction both side portions 1321 and 1322 so as to have a curved cross section. The width direction central portion 1323 is formed with the width direction central portion of the belt-shaped inner wall 1310. A band-shaped hollow portion 1324 is formed therebetween.

  The strip-shaped hollow portion 1324 is covered with a positive-side coated lead wire 1544 (described later), and the positive-side coated lead wire 1544 is covered with a mold member 1325 made of an electrically insulating resin material. Molded inside.

  Next, an assembly configuration of the strip-shaped lead covering member 1300 and the main cylindrical portion 1220 and the sub cylindrical portion 1230 will be described. As described above, the strip-shaped lead covering member 1300 is integrated with the main cylindrical portion 1220, and the sub-cylindrical portion 1230 is configured as shown in FIG.

  Therefore, the sub cylinder portion 1230 is assembled to the strip-shaped lead covering member 1300 and the main cylinder portion 1220 as follows. That is, as shown in FIG. 7, the sub-cylindrical portion 1230 is fitted between the main cylindrical portion 1220 and the cylindrical pressure detector 1500 so that the lower portion of the strip-shaped lead covering member 1300 is fitted into the strip-shaped opening 1231. The belt-like lead covering member 1300 and the main cylindrical body portion 1220 are assembled by being coaxially fitted in an axial space formed therebetween (see FIGS. 3 and 4).

  Here, the lower portion of the above-described band-shaped lead covering member 1300 and the band-shaped opening 1231 of the sub-cylindrical body 1230 are fitted as follows. That is, the band-shaped lead covering member 1300 is opposed to the band-shaped opening 1231 at the lower portions of the widthwise opposite side portions 1321 and 1322 of the band-shaped outer wall 1320 together with the lower portions of the widthwise opposite side portions of the band-shaped inner wall 1310. The surface portions 1232 and 1233 are fitted in the respective band-like recesses 1234 and 1235. Further, this fitting is performed so that the lower portion of the widthwise central portion 1323 of the belt-like outer wall 1320 faces the outside from the belt-like opening portion 1231.

  Further, such fitting is performed by pushing the belt-like inner wall 1310 and the belt-like outer wall 1320 between the opposing surface portions 1232 and 1233 of the belt-like opening 1231 against the elasticity of the sub-cylindrical body portion 1230 at the lower portions thereof. Therefore, the band-shaped lead covering member 1300 is sandwiched between the opposed surface portions 1232 and 1233 of the band-shaped opening 1231 on the band-shaped inner wall 1310 and the band-shaped outer wall 1320.

  However, in the present embodiment, the sub-cylindrical body portion 1230 is bonded to the annular axial end surface of the main cylindrical body portion 1220 facing the main cylindrical body portion 1220 by an adhesive. Thus, they are coaxially joined. Further, the sub-cylindrical portion 1230 is bonded to the annular axial facing end surface of the inner casing member 1520 facing the inner casing member 1520 facing the inner casing member 1520 (described later) of the cylindrical pressure detector 1500. Coaxially bonded with adhesive.

  Further, the band-shaped opening 1231 of the sub-cylindrical body portion 1230 is located on the inner surfaces of the concave portions 1234 and 1235 of the opposing surface portions 1232 and 1233, and the lower portions on both sides in the width direction of the band-shaped inner wall 1310 of the band-shaped lead covering member 1300. The belt-shaped outer wall 1320 is joined to the lower portions of the widthwise side portions 1321 and 1322 by bonding with an adhesive.

  As shown in FIG. 1, the connector 1400 includes a connector main body 1410 and a grommet 1420. The connector main body 1410 includes a cylindrical portion 1411, a flange portion 1412 that extends radially from the central portion in the axial direction of the outer peripheral surface of the cylindrical portion 1411, and a radially outward portion from a portion of the flange portion 1412. It is integrally formed of an electrically insulating resin material so as to have a connector portion 1413 that extends.

  The grommet 1420 is formed by using an electrically insulating rubber material so as to be an annular body having a U-shaped cross section with the inner annular wall portion 1421, the outer annular wall portion 1422, and the annular coupling wall portion 1423. The grommet 1420 is fitted from the lower side to the cylindrical part 1411 of the connector main body 1410 by the inner annular wall part 1421, and is seated and fixed to the flange part 1412 of the connector main body 1410 from the lower side by the annular connecting wall part 1423. Yes.

  Here, the grommet 1420 is configured such that the tubular portion 1411 of the connector main body 1410 is attached to the cylinder head so that the annular opening 111 of the plug insertion hole 110 is sandwiched between the inner annular wall portion 1421 and the outer annular wall portion 1422. It is maintained substantially coaxial with the 100 plug insertion holes 110.

  Therefore, specifically, the above-described support for the annular opening 111 of the plug insertion hole 110 of the long cylindrical body 1200 (or the main cylindrical body 1220) is performed as follows. That is, the longitudinal cylindrical body 1200 (or the main cylindrical body portion 1220) is coaxially fitted into the cylindrical portion 1411 of the connector 1400 as shown in FIG. The connector 1400 is supported by the annular opening 111 of the plug insertion hole 110.

  As shown in FIGS. 1 and 8, the cylindrical pressure detector 1500 is coaxially supported by the distal end portion of the longitudinal cylindrical body 1200, that is, the distal end portion 1236 of the sub-cylindrical body portion 1230. The cylindrical pressure detector 1500 is configured by a casing 1510, an annular laminate 1540, and both electrical insulating members 1550 and 1560.

  The casing 1510 includes an inner casing member 1520 and an outer casing member 1530. The inner casing member 1520 is formed by pressing so as to have the cross-sectional shape shown in FIGS. 1 and 8, and this inner casing member 1520 includes a cylindrical large-diameter portion 1521, an upper annular bottom wall portion 1522, A cylindrical small-diameter portion 1523 and a lower annular bottom wall portion 1524 are integrally formed. Note that the inner casing member 1520 and the outer casing member 1530 correspond to the double cylindrical wall referred to in the present invention.

  As shown in FIG. 8, the cylindrical large diameter portion 1521 protrudes in an annular shape upward from the upper end portion of the outer casing member 1530, and the annular upper end portion of the cylindrical large diameter portion 1521 is The sub-cylindrical portion 1230 is coaxially fitted to the distal end portion 1236 by laser welding.

  The upper annular bottom wall portion 1522 is bent from the lower end portion of the cylindrical large-diameter portion 1521 to the inside thereof so as to be perpendicular to the axis of the cylindrical large-diameter portion 1521 and extends in an annular shape. The small diameter portion 1523 extends in a cylindrical shape downward from the inner peripheral edge of the annular bottom wall portion 1522.

  Further, as shown in FIG. 8, the lower annular bottom wall portion 1524 extends radially outward from the annular extension end of the cylindrical small diameter portion 1523, and this lower annular bottom wall 1524. The wall 1524 is seated on the bottom surface 112 of the plug insertion hole 110 of the cylinder head 100.

  The outer casing member 1530 is positioned coaxially with the inner casing member 1520 so as to surround the inner casing member 1520 from the periphery thereof. The outer casing member 1530 includes a cylindrical surrounding portion 1531 and an annular bottom wall portion. 1532. The annular bottom wall portion 1532 extends inward from the lower end portion of the cylindrical surrounding portion 1531 so as to be perpendicular to the axis of the cylindrical surrounding portion 1531, and the annular bottom wall portion 1532 is formed on the inner casing. The member 1520 is fixed to the lower annular bottom wall portion 1524 by welding. In this embodiment, the upper annular bottom wall portion 1522, the cylindrical small diameter portion 1523, and the lower annular bottom wall portion 1524 of the inner casing member 1520, together with the annular bottom wall portion 1532 of the outer casing member 1530, are annular double bottom wall portions. Configure.

  As can be seen from FIG. 8, the annular laminated body 1540 is coaxially fitted to the cylindrical small diameter portion 1523, and in other words, between the inner casing member 1520 and the outer casing member 1530, in other words, the annular double bottom wall. The annular laminate 1540 is constituted by each annular negative electrode plate 1541, piezoelectric plate 1542, and positive electrode plate 1543.

  The negative electrode plate 1541 is coaxially fitted to the cylindrical small diameter portion 1523 and is seated on the annular bottom wall portion 1532 of the outer casing member 1530. The piezoelectric plate 1542 is coaxially fitted to the cylindrical small diameter portion 1523 and stacked on the negative electrode plate 1541. Further, the positive electrode plate 1543 is coaxially fitted to the cylindrical small diameter portion 1523 and laminated on the piezoelectric plate 1542. As a result, the piezoelectric plate 1542 exhibits a piezoelectric conversion action while being sandwiched between the negative electrode plate 1541 and the positive electrode plate 1543. Note that the piezoelectric plate 1542 is formed of a piezoelectric material.

  The cylindrical pressure detector 1500 has a positive-side covered lead wire 1544, and this positive-side covered lead wire 1544 is electrically connected to the positive-side electrode plate 1543 by soldering at its inner end connection portion. It is connected to the. The positive side covered lead wire 1544 is inserted and covered into the inside of the band-like lead covering member 1300 from the annular upper opening of the casing 1510, and the positive side covered lead wire 1544 is formed at the front end portion of the band-like lead covering member 1300. And is electrically connected to the inner end of the terminal 1414 (see FIG. 1) in the connector main body 1410 of the connector 1400.

  In the present embodiment, the negative electrode plate 1541 serves as a ground terminal of the pressure detection device 1000 via the casing 1510. Note that the extending tip end portion of the positive-side covered lead wire 1544 is covered with an insulating rubber member 1546 (see FIGS. 1 to 4) fixed to the opening portion 1210 of the cylindrical body 1200. The terminal 1414 is provided in the connector portion 1413 of the connector 1400 so that it can be connected to an external circuit (not shown).

  The electrically insulating member 1550 is formed of an electrically insulating material in the shape of a ring plate, and the electrically insulating member 1550 is stacked on the positive electrode plate 1543 so that the cylindrical small diameter portion 1523 of the inner casing member 1520 is stacked. Is fitted between the annular bottom wall portion 1522 of the inner casing member 1520 and the positive electrode plate 1543. Accordingly, the electrical insulating member 1550 electrically insulates the inner casing member 1520 from the positive electrode plate 1543.

  In addition, the electrical insulating member 1560 is formed in a cylindrical shape with an electrical insulating material, and the electrical insulating member 1560 is coaxially fitted to the cylindrical small diameter portion 1523 of the inner casing member 1520 to form an inner casing. The member 1520 is electrically insulated from the positive electrode plate 1542.

  Of the annular laminate 1540, the two electrical insulating members 1550 and 1560, and the positive-side covered lead wire 1544, the portion located between the inner casing member 1520 and the outer casing member 1530 is the inner casing member 1520 and outer casing member 1530. Is molded by filling a mold member 1545 made of an electrically insulating resin material. Accordingly, the positions of the piezoelectric plate 1542 and the positive electrode plate 1543 between the inner and outer casing members 1520 and 1530 can be maintained more securely, and the inner casing member of the piezoelectric plate 1542 and the positive electrode plate 1543 can be maintained. The electrical insulation from 1520 can be secured even better in combination with both electrical insulation members 1550 and 1560.

  In the present embodiment, the spark plug 2000 is inserted into the plug insertion hole 110 of the cylinder head 100 through the cylindrical portion 1411 of the connector 1400 as shown in FIG. The spark plug 2000 includes an insulating cylinder 2100, and a conductive rod 2200 is inserted into the insulating cylinder 2100 together with the center electrode 2300 from the base end side of the insulating cylinder 2100.

  The metal shell 2400 is fitted to the tip side portion of the insulating cylinder 2100, and the metal shell 2400 has a mounting screw portion 2410 at the tip. Further, the metal shell 2400 has an annular flange 2420, and the annular flange 2420 is formed to project outward in a ring shape at a position directly above the attachment screw portion 2410 in the metal shell 2400. Further, the center electrode 2300 protrudes from the mounting screw portion 2410 of the metal shell 2400 into the combustion chamber 130 and constitutes a discharge portion together with the outer electrode 2430 of the metal shell 2400.

  Thus, the spark plug 2000 is fastened to the screw hole 140 formed in the portion of the cylinder head 100 that is coaxially positioned at the center of the bottom of the plug insertion hole 110 at the attachment screw 2424 of the metal shell 2400. Has been. As a result, the spark plug 2000 is configured such that the annular laminate 1540 is connected to the plug insertion hole 110 via the bottom wall portion 1522 of the inner casing member 1520 and the electrical insulating member 1550 at the annular flange 2420 of the metal shell 2400. It is sandwiched between the bottom surface 112 and exposed to the combustion chamber 130 of the internal combustion engine at the discharge portion.

  Further, as shown in FIG. 1, the cylindrical member 2500 made of an electrically insulating rubber material passes through the cylindrical portion 1411 of the connector 1400 and is inserted into the cylindrical body 1200 disposed in the plug insertion hole 110 of the cylinder head 100. In addition, the cylindrical member 2500 is fitted from the outside into the upper side of the metal shell 2400 in the insulating cylindrical body 2100 of the spark plug 2000 at the distal end thereof.

  The ignition device 3000 is supported by the upper end portion of the cylindrical portion 1411 of the connector 1400 with a grommet 3110 (having the same configuration as the grommet 1420) provided on the bottom wall of the casing 3100. The ignition device 3000 The covered lead wire 3200 passes through the inside of the cylindrical member 2500 and is electrically connected to the proximal end portion of the conductive rod 2200 of the spark plug 2000.

  In the present embodiment configured as described above, when the internal combustion engine operates as the air-fuel mixture burns in the combustion chamber 130, the combustion pressure generated in the combustion chamber 130 is transmitted to the spark plug 2000. For this reason, the spark plug 2000 receives vibration based on the combustion pressure, vibrates in the axial direction thereof, and transmits the vibration to the annular laminate 1540 through the annular double bottom wall portion of the casing 1510. For this reason, the piezoelectric plate 1542 of the annular laminate 1540 detects the axial vibration of the spark plug 2000 as the combustion pressure based on the piezoelectric conversion action, and the external plate through the positive side covered lead wire 1544 and the terminal 1414 of the connector 1400. Output to the circuit.

  Here, when the internal combustion engine operates as described above, the vibration of the internal combustion engine is transmitted to the cylinder 1200 of the pressure detection device via the cylinder head 100. For this reason, this cylindrical body 1200 vibrates based on the vibration of the internal combustion engine. Therefore, this vibration is transmitted to the pressure detector 1500.

  However, as described above, the cylindrical body 1200 is coaxially formed by the main cylindrical body portion 1220 made of a stainless steel plate and the auxiliary cylindrical body portion 1230 made of a damper material. And the damper material which forms the sub cylinder part 1230 has rigidity lower than metal plate materials, such as a stainless steel plate. For this reason, the cylindrical body 1200 exhibits a damper effect.

  Therefore, even if the vibration of the cylindrical body 1200 is transmitted to the pressure detecting body 1500 as described above, the vibration of the cylindrical body 1200 is absorbed and attenuated by the cylindrical body 1200 due to its damper effect, and then to the pressure detecting body 1500. It will be transmitted.

  As a result, even if the natural vibration component of the cylinder 1200 is superimposed on the detection pressure of the pressure detection body 1500 as noise, the natural vibration component is attenuated as described above, so that the accuracy of the detection pressure of the pressure detection body 1500 is reduced. Can be ensured well. Note that, since the damper material has heat resistance, for example, even if the cylinder 1200 is heated by the operation of the internal combustion engine, the sub-cylinder part 1230 of the cylinder 1200 can appropriately withstand the generated heat.

  Further, as described above, since the axial length of the sub-cylindrical body portion 1230 is set to half of the axial length of the longitudinal cylindrical body 1200, the above-described damper effect can be more effectively exhibited by the cylindrical body 1200. As a result, the noise superimposed on the detected pressure of the pressure detector 1500 described above can be attenuated more favorably, so that the accuracy of the detected pressure of the pressure detector 1500 can be further improved.

  Further, as described above, the sub-cylindrical portion 1230 is interposed in the cylindrical body 1200 on the pressure detection body 1500 side with respect to the main cylindrical body portion 1220, and thus the natural vibration component of the cylindrical body 1200 transmitted to the pressure detection body 1500. However, it is attenuated by the damper effect immediately before being transmitted to the pressure detector 1500 and directly transmitted to the pressure detector 1500. As a result, the noise superimposed on the detected pressure of the pressure detector 1500 described above can be attenuated more favorably, so that the accuracy of the detected pressure of the pressure detector 1500 can be further improved.

  Further, as described above, the strip-shaped lead coating member 1300 that covers the positive-side coated lead wire 1544 is provided in a strip shape in the axial direction along the outer peripheral surface of the cylindrical body 1200. Here, the strip-shaped lead covering member 1300 is in contact with the outer peripheral surface of the cylindrical body 1200 at a strip-shaped inner wall 1310 formed of a stainless steel plate. Moreover, the positive-side covered lead wire 1544 is covered with respective strip-shaped inner walls 1310 and outer walls 1320 made of stainless steel plates.

  For this reason, even if the spark plug 2000 in the cylindrical body 1200 generates an electromagnetic induction action due to its ignition action, this electromagnetic induction action is caused by the corresponding portions of the main cylindrical body portion 1220 and the strip-like inner wall 1310 and outer wall 1320 corresponding thereto. In addition, it can be well shielded by the corresponding portions of the belt-like inner wall 1310 and outer wall 1320 with respect to the sub-cylindrical body 1230. As a result, the electromagnetic induction action described above does not affect the detected pressure passing through the positive-side covered lead wire 1544 as noise.

  Further, the sub-cylindrical portion 1230 is assembled to both the main cylindrical portion 1220 and the belt-shaped lead covering member 1300 integrated with the main cylindrical portion 1220 as described above. Therefore, even if the sub-cylindrical portion 1230 is made of a damper material and has low rigidity, the sub-cylindrical portion 1230 is firmly and coaxially supported by the main cylindrical portion 1220 with the strip-shaped lead covering member 1300. obtain. As a result, the strength of the cylindrical body 1200 can be ensured satisfactorily.

  Incidentally, each detection characteristic of the pressure detection device according to the present embodiment and the conventional pressure detection device was examined by actual measurement. However, the conventional pressure detection device has a configuration in which the cylindrical body 1200 is changed to a metal cylindrical body in the pressure detection device referred to in the present embodiment.

  According to the above actual measurement, both graphs 1 and 2 as shown in FIG. 9 were obtained for the pressure detection device according to the present embodiment. Graph 1 shows the relationship between the detected pressure of the pressure detection device according to this embodiment and the crank angle of the internal combustion engine. Graph 2 shows the relationship between the detection output obtained by filtering the detection pressure of the pressure detection device according to the present embodiment with a high-pass filter (hereinafter referred to as HPF) and the crank angle of the internal combustion engine.

  On the other hand, both graphs 3 and 4 as shown in FIG. 10 were obtained for the conventional pressure detection device. Graph 3 shows the relationship between the detected pressure of the conventional pressure detecting device and the crank angle of the internal combustion engine. Graph 4 shows the relationship between the detected output obtained by filtering the detected pressure of the conventional pressure detecting device with HPF and the crank angle of the internal combustion engine.

  Comparing both graphs 1 and 3, it can be seen that in graph 3, the noise is largely superimposed, whereas in graph 1, the noise is hardly superimposed. The same applies when the graphs 2 and 3 are compared. Therefore, it can be seen that the detection characteristics of the pressure detection device according to the present embodiment are clearly improved with higher accuracy than the detection characteristics of the conventional pressure detection device.

In carrying out the present invention, the following various modifications are possible without being limited to the above embodiment.
(1) The sub-cylindrical body 1230 is not limited to bonding with an adhesive as described in the above embodiment, and is inserted into the main cylindrical body 1220 and the strip-shaped lead covering member 1300 integrally assembled by insert molding. You may shape | mold so that it may become the structure described in the said embodiment.
(2) The axial length of the sub-cylindrical body 1230 is not limited to half the axial length of the cylindrical body 1200 and may be changed as appropriate. Here, for example, the axial length of the sub-cylindrical body 1230 may be set so that the natural vibration component of the cylindrical body 1200 is attenuated more than the natural vibration component when the entire cylindrical body is formed of a metal material.
(3) The cylinder 1200 is not limited to the configuration of the main cylinder body 1220 and the sub cylinder body 1230, and the main cylinder body 1220 includes a plurality of metal cylinder portions, and a plurality of sub cylinder bodies 1230 are provided. The plurality of metal cylinder portions and the damper cylinder portions may be alternately and coaxially joined to form the cylinder body 1200, for example.
(4) The cylindrical body 1200 is not limited to the configuration including the main cylindrical body portion 1220 and the auxiliary cylindrical body portion 1230 described in the above embodiment, and at least one opening is formed in the peripheral wall of the cylindrical body 1200, and You may make it close | close the hollow part of this opening part with the damper member which consists of said damper material. Here, for example, the size of the at least one opening is set so that the natural vibration component of the cylindrical body 1200 is attenuated more than the natural vibration component when the entire cylindrical body is formed of a metal material. It is good to be. Note that the at least one opening may have various shapes such as a circular shape and a slit shape.
(5) In the above embodiment, as described above, the casing 1510 of the pressure detection body 1500 includes the inner casing member 1520 and the outer casing member 1530 that are coaxially extended from the tip end of the cylindrical body 1200. In this casing 1510, the annular double bottom wall portion includes an upper annular bottom wall portion 1522, a cylindrical small diameter portion 1523 and a lower annular bottom wall portion 1524 of the inner casing member 1520, and an outer casing. Although the example comprised by the annular bottom wall part 1532 of the member 1530 was demonstrated, it is not restricted to this, The casing 1510 is a double cylinder wall extended coaxially from the front-end | tip part of the cylinder 1200, It is a double cylinder wall formed by forming an annular double bottom wall part that is bent and closed radially toward the axial center of the cylinder at the extended end. It may be configured.

  Instead of such a casing 1510, a casing constituted by a double cylindrical wall extending from the tip of the cylindrical body 1200 and having an annular housing portion formed therein may be adopted. Here, in the double cylindrical wall forming the annular accommodating portion, the outer annular wall (corresponding to the outer casing member 1530) is formed so as to be located radially outward from the distal end portion of the cylindrical body 1200. It may be. Also by this, the same effect as the above embodiment can be achieved.

It is principal part sectional drawing which shows the state which mounted one Embodiment of the pressure detection apparatus based on this invention to the cylinder head. It is a front view of the pressure detection device. It is a front view which shows the pressure detection apparatus in the state which excluded the sub cylinder part in FIG. It is a side view which shows the pressure detection apparatus in the state which excluded the sub cylinder part in FIG. It is a perspective view of a sub cylinder part. FIG. 6 is a sectional view taken along line 6-6 in FIG. FIG. 7 is a cross-sectional view taken along line 7-7 in FIG. It is a half sectional view showing a detection object in relation to the metallic shell of the spark plug. It is a graph which shows the relationship between the detection output of the pressure detection apparatus (the said pressure detection apparatus) said to the said embodiment, and the filter detection pressure which filtered this detection output with HPF, and the crank angle of an internal combustion engine. It is a graph which shows the relationship between the detection output of the conventional pressure detection apparatus, the filter detection pressure which filtered this detection output with HPF, and the crank angle of an internal combustion engine.

Explanation of symbols

1200 ... cylindrical body, 1210 ... proximal end portion, 1220 ... main cylindrical body portion, 1230 ... sub-cylindrical body portion,
1300 ... strip-shaped lead covering member, 1500 ... pressure detector, 1510 ... cylindrical casing,
1520 ... Inner casing member, 1522 ... Upper annular bottom wall portion, 1523 ... Small diameter cylindrical portion,
1524 ... Lower annular bottom wall, 1530 ... Outer casing member, 1532 ... annular bottom wall,
1540: annular laminate, 1541 ... negative electrode plate, 1542 ... piezoelectric plate,
1543: Positive side electrode plate, 1544: Positive side covered lead wire.

Claims (4)

In a pressure detection device comprising a cylinder and a cylindrical pressure detection body that is coaxially supported at the tip of the cylinder,
The cylinder is formed coaxially with at least one metal cylinder part and at least one damper cylinder part adjacent to the at least one metal cylinder part,
The cylindrical pressure detector comprises a cylindrical casing and an annular laminated body composed of an annular positive electrode plate, a piezoelectric body and a negative electrode plate,
The cylindrical casing is configured with a double cylindrical wall that extends from the tip of the cylindrical body and forms an annular housing portion therein,
The annular laminate is accommodated in the annular accommodating portion of the cylindrical casing ,
The pressure detection device , wherein an axial length of the damper cylinder portion is half of an axial length of the cylinder body . The at least one metal cylinder part is configured as a single main cylinder part made of a metal material,
The at least one damper cylinder part is configured as a single sub cylinder part made of a damper material that is coaxially joined to and extended from the tip part of the single main cylinder part. And
The pressure detection device according to claim 1, wherein the double cylindrical wall constituting the cylindrical casing is extended from an extended end portion of the single sub-cylindrical body portion.   The pressure detecting device according to claim 2, wherein the damper material is a polymer material having rigidity lower than that of the metal material. A lead wire extending from the annular piezoelectric body into the annular housing portion of the cylindrical casing;
A strip-shaped metal lead covering member fixed along the axial direction to the outer surface of the cylindrical body,
The double cylindrical wall constituting the cylindrical casing is joined to the tip of the cylindrical body at its inner wall and extends,
The said lead wire is extended from the said annular accommodating part of the said cylindrical casing, is coat | covered inside the said metal lead coating | coated member, and is extended to the base end part side of the said cylinder. 4. The pressure detection device according to any one of 3 .

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