JP2018084561A - Pressure detection device and internal combustion with pressure detection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce errors of output values that are attributed to thermal expansion of a pressure reception unit receiving pressure.SOLUTION: A pressure detection device, which detects combustion pressure in a combustion chamber in an internal combustion, has: a cylindrical first housing 31; a stainless steel-made diaphragm head 40 that has a cylinder-like cylindrical part 41 and a closure part 42 closing the cylindrical part 41 on a tip end side of the cylindrical part 41, has a rear end side of the cylindrical part 41 provided on a tip end side of the first housing 31, and in which the closure part 42 receives pressure from an outside; a piezoelectric element 10 that is provided on an inner side of the first housing 31, and generates signals in accordance with the pressure received by the diaphragm head 40; and an annular suppression ring 80 that is composed of alumina ceramics lower in thermal expansion than the diaphragm head 40, and is attached on an outer side of the cylindrical part 41 of the diaphragm head 40, and suppresses a supply of heat to the cylindrical part 41 from the outside.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a pressure detection device and an internal combustion engine with a pressure detection device.

  In Patent Document 1, a cylindrical housing (body portion), a diaphragm head (pressure receiving portion) attached to the front end side of the housing, an axial direction in the housing and disposed on the rear end side of the diaphragm head, The diaphragm head is opposed to the combustion chamber by inserting a pressure detection device including a piezoelectric element (signal generation unit) that detects pressure acting through the head into a communication hole provided in a cylinder block of the internal combustion engine. It is described that they are arranged.

JP 2013-174552 A

  Here, when a configuration is adopted in which the pressure received by the pressure receiving part is transmitted to the signal generating part, when heat is applied to the pressure receiving part together with the pressure, the pressure receiving part is deformed by thermal expansion and is transmitted from the pressure receiving part to the signal generating part. A situation occurs in which the applied pressure increases or decreases compared to the magnitude that should be transmitted. Then, the output value generated in the signal generator increases or decreases compared to the size that should be output originally, and an error is included in the pressure obtained based on the output of the signal generator. End up.

  An object of the present invention is to reduce an error in an output value caused by thermal expansion of a pressure receiving portion that receives pressure.

The pressure detection device of the present invention has a cylindrical body portion, a cylindrical cylindrical portion, and a closing portion that closes the cylindrical portion on one end side of the cylindrical portion. The end portion side is provided on one end portion side of the body portion and the closed portion is provided with a pressure receiving portion that receives pressure from the outside, and is provided inside the body portion, and generates a signal corresponding to the pressure received by the pressure receiving portion. It includes a signal generator and an annular member made of an inorganic material having a lower thermal conductivity than the pressure receiver and attached to the outside of the tubular part.
Here, the surface on the one end portion side of the annular member is disposed to face the abutting surface provided on the pressure receiving portion, and the surface on the other end portion side of the annular member is provided on the body portion. It is good to arrange | position facing an abutting surface.
From another point of view, the internal combustion engine with a pressure detection device according to the present invention includes a cylinder head in which a communication hole is formed to communicate the combustion chamber on the front end side and the outside on the rear end side, A cylindrical body part which is attached to the cylinder head by being inserted into the communication hole and which detects a pressure in the combustion chamber, and the pressure detection device is disposed in the communication hole. And a cylindrical tubular portion and a closing portion that closes the tubular portion on one end portion side of the tubular portion, and the other end portion side of the tubular portion is provided on one end portion side of the body portion. In addition, the closed portion receives pressure from the combustion chamber, the signal generating portion is provided inside the body portion, and generates a signal corresponding to the pressure received by the pressure receiving portion, and is heated more than the pressure receiving portion. Consists of inorganic material with low conductivity, outside of the cylindrical part With attached comprises an annular member of annular arranged on the inner circumferential surface and the non-contact of the communicating hole.

  According to the present invention, it is possible to reduce an error in the output value caused by the thermal expansion of the pressure receiving portion that receives pressure.

1 is a schematic configuration diagram of an internal combustion engine according to an embodiment. It is an enlarged view of the II section of FIG. It is a schematic block diagram of a pressure detection apparatus. It is sectional drawing of the IV-IV part of FIG. It is an enlarged view of the V section of FIG. It is an enlarged view of the VI section of FIG. It is a disassembled perspective view of the 1st housing, diaphragm head, and suppression ring in a pressure detection apparatus. (A) is a figure which shows the time passage of the output value at the time of using the conventional pressure detection apparatus, (b) is a figure which respectively shows the time passage of the output value at the time of using this pressure detection apparatus.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
[Internal combustion engine]
FIG. 1 is a schematic configuration diagram of an internal combustion engine 1 according to the present embodiment.
FIG. 2 is an enlarged view of a portion II in FIG.
The internal combustion engine 1 includes a cylinder block 2 having a cylinder 2a, a piston 3 that reciprocates in the cylinder 2a, a cylinder head 4 that is fastened to the cylinder block 2 and forms a combustion chamber C together with the cylinder 2a, the piston 3, and the like, It has. The internal combustion engine 1 is mounted on the cylinder head 4 to detect the pressure in the combustion chamber C, and a control device that controls the operation of the internal combustion engine 1 based on the pressure detected by the pressure detection device 5. 6, an electric signal is transmitted between the pressure detection device 5 and the control device 6, and between the pressure detection device 5 and the control device 6, which is interposed between the pressure detection device 5 and the cylinder head 4 and maintains the airtightness in the combustion chamber C. A transmission cable 8.

  The cylinder head 4 is formed with a communication hole 4a that allows the combustion chamber C to communicate with the outside. The communication hole 4a includes, from the combustion chamber C side, a first hole 4b, an inclined portion 4c whose diameter gradually increases from the hole diameter of the first hole 4b, and a hole diameter of the first hole 4b. And a second hole portion 4d having a large hole diameter. A female screw 4e into which a male screw 332a of the housing 30 (described later) formed in the pressure detection device 5 is screwed is formed on the surrounding wall forming the second hole 4d.

[Pressure detection device]
Below, the pressure detection apparatus 5 is explained in full detail.
FIG. 3 is a schematic configuration diagram of the pressure detection device 5. 4 is a cross-sectional view taken along a line IV-IV in FIG. FIG. 5 is an enlarged view of a portion V in FIG. FIG. 6 is an enlarged view of a portion VI in FIG. FIG. 7 is an exploded perspective view of the first housing 31, the diaphragm head 40, and the suppression ring 80 in the pressure detection device 5.

  The pressure detection device 5 includes a sensor unit 100 having a piezoelectric element 10 that converts the pressure in the combustion chamber C into an electric signal, a signal processing unit 200 that processes an electric signal from the sensor unit 100, and a signal processing unit 200. Holding member 300. When the pressure detection device 5 is mounted on the cylinder head 4, the diaphragm head 40 (described later) of the sensor unit 100 is inserted into the communication hole 4 a formed in the cylinder head 4 first. In the following description, the left side of FIG. 4 is the front end side of the pressure detection device 5, and the right side is the rear end side of the pressure detection device 5.

(Sensor part)
First, the sensor unit 100 will be described.
The sensor unit 100 includes a piezoelectric element 10 that converts received pressure into an electrical signal, and a housing 30 that is cylindrical and in which a cylindrical hole that accommodates the piezoelectric element 10 and the like is formed. . Hereinafter, the center line direction of the cylindrical hole formed in the housing 30 is simply referred to as a center line direction.
The sensor unit 100 is provided so as to close the opening on the distal end side of the housing 30, and is provided between the diaphragm head 40 on which the pressure in the combustion chamber C acts, and between the diaphragm head 40 and the piezoelectric element 10. The first electrode unit 50 and the second electrode unit 55 disposed on the opposite side of the piezoelectric element 10 from the first electrode unit 50 are provided.
The sensor unit 100 is provided with an insulating ring 60 that electrically insulates the second electrode unit 55 and a rear end side of the insulating ring 60, and an end portion of a cover member 23 described later of the signal processing unit 200. Is provided on the rear end side of the outer peripheral surface of the diaphragm head 40, and is provided from the outside to the diaphragm head. And a suppression ring 80 that suppresses the entry of heat into 40.

  A piezoelectric element 10 as an example of a signal generating unit has a piezoelectric body that exhibits a piezoelectric action of a piezoelectric longitudinal effect. The piezoelectric longitudinal effect refers to the action of generating charges on the surface of the piezoelectric body in the direction of the charge generation axis when an external force is applied to the stress application axis in the same direction as the charge generation axis of the piezoelectric body. The piezoelectric element 10 according to the present embodiment is housed in the housing 30 so that the center line direction is the direction of the stress application axis.

  Next, a case where the piezoelectric lateral effect is used for the piezoelectric element 10 will be illustrated. The piezoelectric transverse effect is an action in which charges are generated on the surface of the piezoelectric body in the direction of the charge generation axis when an external force is applied to the stress application axis at a position orthogonal to the charge generation axis of the piezoelectric body. A plurality of thinly formed piezoelectric bodies may be laminated, and by laminating in this way, the charge generated in the piezoelectric bodies can be efficiently collected to increase the sensitivity of the sensor. As a piezoelectric single crystal, a langasite crystal having a piezoelectric longitudinal effect and a piezoelectric transverse effect (Langasite, Langatate, Langanite, Langatate (LTGA) in which a part of gallium is replaced with aluminum), crystal, gallium phosphate, etc. Can be illustrated. In the piezoelectric element 10 of the present embodiment, a langasite single crystal is used as the piezoelectric body.

The housing 30 includes a first housing 31 provided on the front end side and a second housing 32 provided on the rear end side.
The first housing 31 as an example of the body portion is a thin-walled cylindrical member having a cylindrical hole 310 formed therein so that the diameter thereof is gradually changed from the front end side to the rear end side. . On the outer peripheral surface, a projecting portion 315 that protrudes from the outer peripheral surface is provided in the central portion in the center line direction over the entire region in the circumferential direction.
The hole 310 includes a first hole 311 and a second hole 312 having a diameter larger than the diameter of the first hole 311 formed in order from the front end side to the rear end side. The protrusion 315 has an inclined surface 315a whose diameter gradually increases from the front end side to the rear end side at the front end portion, and a vertical surface 315b perpendicular to the center line direction at the rear end portion.

The second housing 32 is a cylindrical member having a cylindrical hole 320 formed therein so that the diameter gradually changes from the front end side to the rear end side, and from the front end side to the outside. An outer peripheral surface 330 is provided so that the diameters are gradually changed toward the rear end side.
The hole 320 includes a first hole 321, a second hole 322 having a smaller diameter than the first hole 321, and a hole diameter of the second hole 322, which are sequentially formed from the front end side to the rear end side. A third hole 323 having a larger hole diameter, a fourth hole 324 having a larger hole diameter than the third hole 323, and a fifth hole 325 having a larger hole diameter than the fourth hole 324. Composed.
The diameter of the first hole 321 is the outer peripheral surface of the first housing 31 so that the front end of the second housing 32 is fitted (press-fit) to the rear end of the first housing 31 with an interference fit. The diameter is set to be equal to or less than.

  The outer peripheral surface 330 has a first outer peripheral surface 331, a second outer peripheral surface 332 having an outer diameter larger than the outer diameter of the first outer peripheral surface 331, and a second outer peripheral surface 332 from the front end side to the rear end side. Than the outer diameter of the third outer peripheral surface 333, the fourth outer peripheral surface 334 having an outer diameter larger than the outer diameter of the third outer peripheral surface 333, and the outer diameter of the fourth outer peripheral surface 334. And a fifth outer peripheral surface 335 having a small outer diameter. A male screw 332 a that is screwed into the female screw 4 e of the cylinder head 4 is formed at the distal end portion of the second outer peripheral surface 332. A first seal member 71, which will be described later, is fitted into the third outer peripheral surface 333 with a clearance fit, and the dimensional tolerance between the outer diameter of the third outer peripheral surface 333 and the inner diameter of the first seal member 71 is, for example, zero. To 0.2 mm. The rear end portion of the fourth outer peripheral surface 334 is formed as a regular hexagonal column having six chamfers at equal intervals in the circumferential direction. When the pressure detecting device 5 is fastened to the cylinder head 4, the portion formed in the regular hexagonal column is a portion into which a tightening tool is fitted and a rotational force applied to the tool is transmitted. A concave portion 335a that is recessed from the outer peripheral surface is formed over the entire circumference in the center portion of the fifth outer peripheral surface 335 in the center line direction.

  The second housing 32 is a transition portion from the fourth hole 324 to the fifth hole 325, and a substrate of a cover member 23, which will be described later, of the signal processing unit 200 is provided at the tip of the fifth hole 325. An abutting surface 340 against which an end surface on the front end side of the covering portion 232 abuts is provided. On the abutting surface 340, a pin recess 340a into which a second connection pin 21b of a printed wiring board 210 of the signal processing unit 200 described later is inserted is formed.

  Since the first housing 31 and the second housing 32 exist in a position close to the combustion chamber C, it is preferable to manufacture the first housing 31 and the second housing 32 by using a material that can withstand at least a use temperature environment of −40 to 350 [° C.]. Specifically, it is desirable to use a stainless steel material having high heat resistance, for example, JIS standard SUS630, SUS316, SUS430, or the like.

  A diaphragm head 40 as an example of a pressure receiving portion includes a cylindrical portion 41 that has a cylindrical shape, and a blocking portion 42 that has a plate shape and is provided on the distal end side of the cylindrical portion 41 to block the distal end side of the cylindrical portion 41. ,have. The diaphragm head 40 further includes a chamfered portion 43 provided by chamfering the outer peripheral surface at the boundary portion between the cylindrical portion 41 and the closed portion 42 to 45 °. The material of the diaphragm head 40 is preferably made of an alloy having high elasticity and excellent durability, heat resistance, touch resistance, and the like because it exists in the combustion chamber C at a high temperature and a high pressure. For example, SUH660 can be exemplified.

  The cylindrical portion 41 is adjacent to the chamfered portion 43, so that the distal end cylindrical portion 411 positioned closest to the distal end side, the intermediate cylindrical portion 412 positioned on the rear end side of the distal end cylindrical portion 411, and the intermediate cylindrical shape A rear end cylindrical portion 413 located on the rear end side and the rear end side of the portion 412. In the cylindrical portion 41, the outer cylindrical portion 412 has an outer diameter smaller than that of the front end cylindrical portion 411, and the rear end cylindrical portion 413 has an outer diameter smaller than that of the intermediate cylindrical portion 412. Further, the tubular portion 41 includes a front end step portion 414 that connects the front end tubular portion 411 and the intermediate tubular portion 412, and a boundary portion between the intermediate tubular portion 412 and the rear end tubular portion 413. And a rear end step portion 415 for connecting the two. The inner diameter of the cylindrical portion 41 is the same regardless of the position in the axial direction.

  The blocking portion 42 is provided at the front end side, that is, the central portion of the surface thereof, and is recessed on the surface of the piezoelectric element 10, and the rear surface is provided at the rear end side, ie, the center portion of the back surface thereof, and protrudes toward the piezoelectric element 10 side. And a convex portion 422. In the closed portion 42, the back surface convex portion 422 is located on the back surface of the front surface concave portion 421.

The first electrode portion 50 is a columnar member formed so that the diameters are gradually changed from the front end side to the rear end side. The first cylindrical portion 51 and the outer diameter of the first cylindrical portion 51 And a second cylindrical portion 52 having a larger outer diameter. The outer diameter of the first cylindrical portion 51 is smaller than the inner diameter of the cylindrical portion 41 of the diaphragm head 40, and the outer diameter of the second cylindrical portion 52 is substantially the same as the hole diameter of the first hole 311 of the first housing 31. It is. The end surface on the front end side of the first cylindrical portion 51 is the back surface convex portion 422 of the closing portion 42 of the diaphragm head 40, and the end surface on the rear end side of the second cylindrical portion 52 is the surface on the front end side of the piezoelectric element 10. Arranged to touch. When the outer peripheral surface of the second cylindrical portion 52 is in contact with the inner peripheral surface of the first housing 31 and / or the end surface on the distal end side of the first cylindrical portion 51 is in contact with the diaphragm head 40, the piezoelectric element 10 is electrically connected to the housing 30.
The first electrode portion 50 applies pressure in the combustion chamber C to the piezoelectric element 10, and the end surface on the rear end side of the second cylindrical portion 52 that is the end surface on the piezoelectric element 10 side is the piezoelectric element 10. It is formed in a size that can push the entire end face. Further, the first electrode portion 50 has both end faces in the center line direction parallel (perpendicular to the center line direction) and smooth so that the pressure received from the diaphragm head 40 can be applied to the piezoelectric element 10 evenly. Is formed.
An example of the material of the first electrode unit 50 is stainless steel.

The second electrode portion 55 is a cylindrical member, and is arranged so that the end surface on the front end side contacts the end surface on the rear end side of the piezoelectric element 10 and the end surface on one end side contacts the insulating ring 60. Is done. A columnar projecting portion 55 a that projects from the end surface to the rear end side is provided on the end surface on the rear end side of the second electrode portion 55. The protrusion 55a has a base end portion on the end face side and a tip end portion having an outer diameter smaller than the outer diameter of the base end portion. The outer diameter of the protruding portion 55a is set smaller than the inner diameter of the insulating ring 60, and the length of the protruding portion 55a is set longer than the width of the insulating ring 60 (the length in the center line direction). The tip is exposed from the insulating ring 60. The second electrode portion 55 is a member that acts so as to apply a certain load to the piezoelectric element 10 with the first electrode portion 50, and the end face on the piezoelectric element 10 side is the surface of the piezoelectric element 10. It is formed in such a size that the entire end surface can be pushed and formed in a parallel and smooth surface. The outer diameter of the second electrode portion 55 is set to be smaller than the hole diameter of the second hole 312 of the first housing 31, and the outer peripheral surface of the second electrode portion 55 and the first housing 31 There is a gap between the inner peripheral surface.
The material of the second electrode portion 55 can be exemplified by stainless steel.

  The insulating ring 60 is a cylindrical member formed of alumina ceramic or the like, and the inner diameter (hole diameter at the center) is slightly larger than the outer diameter of the base end portion of the protruding portion 55a of the second electrode portion 55, The outer diameter is set to be approximately the same as the hole diameter of the second hole 312 of the first housing 31. The second electrode portion 55 is arranged such that the protruding portion 55 a is inserted into the central hole of the insulating ring 60, so that the center position and the center of the second hole 312 of the first housing 31 are the same. It is arranged to become.

The support member 65 is a cylindrical member in which a plurality of cylindrical holes 650 having different diameters are formed inside from the front end side to the rear end side, and the outer peripheral surface is the same.
The holes 650 are formed in order from the front end side to the rear end side, based on the first hole 651, the second hole 652 having a larger diameter than the first hole 651, and the hole diameter of the second hole 652. And a third hole 653 having a larger hole diameter. The hole diameter of the first hole 651 is larger than the outer diameter of the base end portion of the protruding portion 55 a of the second electrode portion 55, and the protruding portion 55 a is exposed to the inside of the support member 65. The hole diameter of the second hole 652 is larger than the outer diameter of the distal end portion of the conductive member 22 of the signal processing unit 200 described later. The hole diameter of the third hole 653 is smaller than the outer diameter of the end portion of the covering member 23 of the signal processing unit 200 described later, and the covering member 23 fits into the surrounding wall forming the third hole 653 with an interference fit. Combined. Thereby, the support member 65 functions as a member that supports the end portion of the covering member 23.

  The coil spring 70 has an inner diameter that is equal to or larger than the outer diameter of the distal end portion of the protruding portion 55a of the second electrode portion 55 and smaller than the outer diameter of the proximal end portion, and the outer diameter is a diameter of an insertion hole 22a of the conductive member 22 described later. Smaller than. The distal end portion of the protruding portion 55a of the second electrode portion 55 is inserted inside the coil spring 70, and the coil spring 70 is inserted into an insertion hole 22a of the conductive member 22 described later. The length of the coil spring 70 is set to a length that can be interposed in a compressed state between the second electrode portion 55 and the conductive member 22. As a material of the coil spring 70, an alloy having high elasticity and excellent durability, heat resistance, touch resistance and the like may be used. Further, it is preferable to increase electrical conduction by applying gold plating to the surface of the coil spring 70.

  The restraining ring 80 as an example of the annular member is a cylindrical member formed of alumina ceramic or the like, and the inner diameter thereof is slightly larger than the outer diameter of the intermediate cylindrical portion 412 in the diaphragm head 40, and the outer diameter thereof. Is set to be substantially the same as the outer diameter of the distal cylindrical portion 411 in the diaphragm head 40. Further, the suppression ring 80 is provided on the front end side and the front end surface 81 facing the front end step portion 414 of the diaphragm head 40, and the rear end surface 82 provided on the rear end side and facing the end surface 31 a of the first housing 31. And have.

  Here, the relationship between the characteristics of the diaphragm head 40 and the suppression ring 80 provided on the distal end side of the pressure detection device 5 will be described.

  In the present embodiment, the diaphragm head 40 is made of a metal material (in this example, stainless steel) as described above. In contrast, the suppression ring 80 is made of an inorganic material (in this example, alumina) as described above. Furthermore, the suppression ring 80 of the present embodiment is made of a polycrystalline body, that is, ceramics. Therefore, in the present embodiment, the conductivity of the suppression ring 80 is lower than the conductivity of the diaphragm head 40.

  In the present embodiment, each material is selected so that the thermal conductivity of the suppression ring 80 is lower than the thermal conductivity of the diaphragm head 40. In this example, the thermal conductivity of alumina ceramics is 15 to 45 (W / m · K), and the thermal conductivity of stainless steel is 16 to 27 (W / m · K).

  In the present embodiment, each material is selected such that the melting point of the suppression ring 80 is higher than the melting point of the diaphragm head 40. In this example, the melting point of alumina ceramics is 2072 (° C.), and the melting point of stainless steel is 1400 to 1500 (° C.).

Further, in the present embodiment, each material is selected so that the linear expansion coefficient of the suppression ring 80 is smaller than the linear expansion coefficient of the diaphragm head 40. In this example, the linear expansion coefficient of alumina ceramics is 7 to 8 (10 ⁻⁶ / K), and the linear expansion coefficient of stainless steel is 9 to 18 (10 ⁻⁶ / K).

(Signal processing part)
Next, the signal processing unit 200 will be described.
The signal processing unit 200 includes a circuit board unit 21 that at least amplifies an electric signal that is a weak charge obtained from the piezoelectric element 10 of the sensor unit 100, and a rod-shaped guide that guides the charge generated in the piezoelectric element 10 to the circuit board unit 21. A conductive member 22, a cover member 23 that covers the circuit board portion 21, the conductive member 22, and the like, and an O-ring 24 that seals the circuit board portion 21 and the like are provided.

  The circuit board unit 21 includes a printed wiring board 210 on which electronic components constituting a circuit for amplifying a weak charge obtained from the piezoelectric element 10 of the sensor unit 100 are mounted. A first connection pin 21a for electrically connecting a rear end portion of the conductive member 22 and a second connection pin 21b for grounding and positioning are soldered to the front end portion of the printed wiring board 210. Connected by. Further, three third connection pins 21c that are electrically connected to the control device 6 via the connector 8a at the front end of the transmission cable 8 are connected to the rear end of the printed wiring board 210 by soldering or the like. ing. The three third connection pins 21 c are used for supplying a power supply voltage and a GND voltage from the control device 6 to the printed wiring board 210 and for supplying an output voltage from the printed wiring board 210 to the control device 6, respectively.

  The conductive member 22 is a rod-shaped (columnar) member, and an insertion hole 22a into which the distal end portion of the protruding portion 55a of the second electrode portion 55 is inserted is formed at the distal end portion. The rear end portion of the conductive member 22 is electrically connected to the printed wiring board 210 of the circuit board portion 21 via a conductive wire. Examples of the material of the conductive member 22 include brass and beryllium copper. In this case, brass is desirable from the viewpoint of workability and cost. On the other hand, beryllium copper is desirable from the viewpoints of electrical conductivity, high temperature strength, and reliability.

  The covering member 23 includes a conductive member covering portion 231 that covers the outer periphery of the conductive member 22, a substrate covering portion 232 that covers the side and bottom surfaces of the printed wiring board 210 of the circuit board portion 21, and a third connected to the printed wiring board 210. And a connector portion 233 into which the connector 8a at the tip of the transmission cable 8 is fitted.

  The conductive member covering portion 231 covers the center line direction so as to expose the front end portion of the conductive member 22, and an outer peripheral surface 240 formed so that the diameter gradually changes from the front end side to the rear end side. Is provided. The outer peripheral surface 240 has a first outer peripheral surface 241, a second outer peripheral surface 242 having an outer diameter larger than the outer diameter of the first outer peripheral surface 241, and a second outer peripheral surface 242 from the front end side to the rear end side. A third outer peripheral surface 243 having an outer diameter larger than that of the third outer peripheral surface, and a fourth outer peripheral surface 244 having an outer diameter larger than the outer diameter of the third outer peripheral surface 243. The diameter of the first outer peripheral surface 241 is larger than the diameter of the third hole 653 of the support member 65, and the peripheral wall in which the distal end portion of the conductive member covering portion 231 forms the third hole 653 of the support member 65. It is fitted (press-fit) with a tight fit. The diameter of the second outer peripheral surface 242 is smaller than the diameter of the second hole 322 of the second housing 32, and the diameter of the third outer peripheral surface 243 is the third hole 323 of the second housing 32. It is formed smaller than the hole diameter. The diameter of the fourth outer peripheral surface 244 is larger than the diameter of the fourth hole 324 of the second housing 32, and the rear end portion of the conductive member covering portion 231 is the fourth hole of the second housing 32. It is fitted (press-fit) to the surrounding walls forming 324 with an interference fit. Accordingly, the conductive member covering portion 231 is supported by contacting at least both ends in the center line direction with the support member 65 and the second housing 32, respectively. The adverse effect on the member 22 can be suppressed, and it is possible to avoid disconnection of the connecting portion of the conductive member 22 and poor contact due to vibration.

  The substrate covering portion 232 is basically a cylindrical portion, and a rectangular opening 232a for installing the printed wiring board 210 therein is provided on the side surface thereof. Further, a ring groove 232 b for the O-ring 24 for sealing the inside of the housing 30 and the installation portion of the printed wiring board 210 is formed on the rear end side of the substrate covering portion 232.

  The connector portion 233 is a thin portion that protrudes from the end surface 232 c on the rear end side of the substrate covering portion 232 and is formed so as to cover the periphery of the three third connection pins 21 c connected to the printed wiring board 210. The rear end portion of the connector portion 233 is open so that the connector 8a provided at the front end portion of the transmission cable 8 can be received therein. Further, a hole 233a that communicates the inside and the outside is formed on the rear end side of the connector portion 233, and a hook provided on the connector 8a of the transmission cable 8 is hooked into the hole 233a, so that the transmission cable The eight connectors 8a are prevented from dropping from the connector portion 233.

  The covering member 23 configured as described above is formed of an insulating material such as resin. The cover member 23 is integrally formed with the conductive member 22, the first connection pin 21a, the second connection pin 21b, and the three third connection pins 21c. More specifically, in the covering member 23, the heated resin is pushed into a mold in which the conductive member 22, the first connection pin 21a, the second connection pin 21b, and the three third connection pins 21c are set. It is molded by

  In order to unitize the signal processing unit 200, the printed wiring board 210 of the circuit board unit 21 is inserted from the opening 232 a of the formed covering member 23 and is installed at the center of the board covering unit 232. When installing the printed wiring board 210, the tips of the first connection pin 21a, the second connection pin 21b, and the three third connection pins 21c are passed through the through-holes penetrating in the plate thickness direction and soldered. . Then, the 1st connection pin 21a and the conduction member 22 are connected using a conducting wire. Further, the O-ring 24 is attached to the ring groove 232 b of the substrate covering portion 232 of the covering member 23. The O-ring 24 is a well-known O-shaped ring made of fluorine-based rubber.

(Holding member)
Next, the holding member 300 will be described.
The holding member 300 is a thin cylindrical member, and is provided with a protruding portion 300a protruding inward from the inner peripheral surface at the rear end portion. After the holding member 300 is mounted on the second housing 32, the holding member 300 is caulked by pressing a portion corresponding to the concave portion 335 a provided on the fifth outer peripheral surface 335 from the outside. Thereby, the holding member 300 becomes difficult to move with respect to the housing 30, and the signal processing unit 200 is prevented from moving with respect to the housing 30.

(Electrical connection structure in pressure detector)
Next, an electrical connection structure in the pressure detection device 5 described above will be described.
First, the end face on the front end side of the piezoelectric element 10 is electrically connected to the metal housing 30 via the metal first electrode portion 50 and the diaphragm head 40.

  On the other hand, the end surface on the rear end side of the piezoelectric element 10 is electrically connected to the metal second electrode portion 55, and the second electrode portion 55 is made of a metal coil spring via the protruding portion 55 a. 70 is electrically connected. The coil spring 70 is electrically connected to the metallic conductive member 22, and the conductive member 22 is electrically connected to the printed wiring board 210. On the other hand, the outer diameter of the protruding portion 55 a of the second electrode portion 55 is smaller than the hole diameter of the first hole 651 of the support member 65, and the outer diameter of the tip portion of the conductive member 22 is the second hole 652 of the support member 65. Is smaller than the pore diameter. That is, the second electrode portion 55, the coil spring 70, and the conductive member 22 are not electrically connected to the support member 65. Therefore, the charge signal transmission path from the second electrode portion 55 to the printed wiring board 210 via the coil spring 70 and the conductive member 22 is an insulating ring 60 and a covering member 23 each made of an insulator. Is electrically insulated from the metal housing 30.

(Attaching the pressure detector)
When the pressure detecting device 5 configured as described above is attached to the cylinder head 4, the diaphragm head 40 of the sensor unit 100 is inserted into the communication hole 4a formed in the cylinder head 4 first, The male screw 332 a formed in the second housing 32 of the housing 30 is screwed into the female screw 4 e formed in the communication hole 4 a of the cylinder head 4.
By mounting the pressure detection device 5 on the cylinder head 4, the housing 30 is electrically connected to the metal cylinder head 4. Since the cylinder head 4 is in a state of being electrically grounded, in the pressure detection device 5, the tip portion of the piezoelectric element 10 is grounded via the housing 30. At this time, on the distal end side of the pressure detection device 5, the outer peripheral surface of the suppression ring 80 attached to the tubular portion 41 of the diaphragm head 40 is connected to the inner periphery of the communication hole 4 a formed in the cylinder head 4 via a gap. Face to face. That is, the suppression ring 80 and the communication hole 4a are set in a non-contact state. Further, a gap is provided between the side surface of the piezoelectric element 10 and the inner wall surface of the housing 30 so that the piezoelectric element 10 and the housing 30 do not directly contact each other.

[Seal material]
Next, the seal member 7 will be described.
The seal member 7 has a cylindrical shape provided with an end surface in the tightening direction of the pressure detection device 5 on the surrounding wall forming the communication hole 4 a in the cylinder head 4 and a fourth outer peripheral surface 334 of the housing 30 of the pressure detection device 5. And a first seal member 71 that seals between the cylinder head 4 and the pressure detection device 5. Further, the seal member 7 is disposed between the inclined portion 4c of the communication hole 4a of the cylinder head 4 and the inclined surface 315a of the first housing 31 of the housing 30 of the pressure detecting device 5, and the cylinder head 4 and the pressure detecting member are detected. A second seal member 72 that seals between the device 5 is provided.

  It can be exemplified that the first seal member 71 is a metal gasket formed by punching a metal plate such as copper, stainless steel, or aluminum. The cross-sectional shape is preferably S-shaped or substantially rectangular. When the pressure detection device 5 is tightened to the cylinder head 4, the first seal member 71 receives a force in the tightening direction and is deformed so that the length in the tightening direction is shortened. To increase. That is, when the pressure detection device 5 is screwed into the cylinder head 4, the contact pressure generated between the first seal member 71 and the cylinder head 4, and the first seal member 71 and the housing 30 of the pressure detection device 5 The contact pressure generated during the period increases. Thereby, the leakage of combustion gas from between the first seal member 71 and the cylinder head 4 and between the first seal member 71 and the housing 30 of the pressure detection device 5 is suppressed.

  The second seal member 72 can be exemplified by a ring-shaped O-ring made of fluoro rubber (FKM) and having a circular cross section. When the pressure detection device 5 is fastened to the cylinder head 4, the second seal member 72 is formed by the inclined portion 4 c of the communication hole 4 a of the cylinder head 4 and the inclined surface 315 a of the first housing 31 of the housing 30. It is deformed by receiving a force in a direction crossing the tightening direction, and the airtightness in the combustion chamber C is enhanced. That is, when the pressure detection device 5 is screwed into the cylinder head 4, the contact pressure generated between the second seal member 72 and the inclined portion 4 c of the communication hole 4 a of the cylinder head 4, and the second seal member 72 The contact pressure generated between the housing 30 and the inclined surface 315a of the first housing 31 is increased. Thereby, it is suppressed that combustion gas leaks between the second seal member 72 and the cylinder head 4 and between the second seal member 72 and the housing 30 of the pressure detection device 5.

[Manufacturing method of pressure detection device]
Next, a manufacturing method of the pressure detection device 5 will be described.
First, the diaphragm head 40 and the suppression ring 80 are fitted (press-fitted) until the leading end step portion 414 of the diaphragm head 40 and the leading end surface 81 of the suppression ring 80 come into contact with each other. Subsequently, the first housing 31 and the diaphragm head 40 are fitted (press-fitted) until the rear end step portion 415 of the diaphragm head 40 to which the suppression ring 80 is attached and the end surface 31a of the first housing 31 come into contact with each other. To do. Thereafter, a laser beam is emitted from a direction intersecting the center line direction (for example, a direction orthogonal to the center line direction) to a portion where the end surface 31a of the first housing 31 and the rear end step portion 415 of the diaphragm head 40 are in contact with each other. Irradiation is performed to weld (join) the first housing 31 and the diaphragm head 40.

  Next, the first electrode unit 50 and the piezoelectric element 10 are inserted from the opening on the rear end side in the first housing 31. Thereafter, the coil spring 70 is attached to the tip of the protruding portion 55a of the second electrode portion 55 and the insulating ring 60 is inserted into the protruding portion 55a of the second electrode portion 55. 31 is inserted through the opening on the rear end side. Then, the support member 65 is inserted from the opening on the rear end side in the first housing 31. Then, the supporting member 65 and the first housing 31 are fixed in a state where a predetermined load (preload) is applied to the piezoelectric element 10 in the first housing 31.

  After the support member 65 and the first housing 31 are fixed, the first housing 31 until the vertical surface 315b of the projecting portion 315 of the first housing 31 and the end surface on the front end side of the second housing 32 come into contact with each other. And the second housing 32 are fitted (press-fitted). Thereafter, the laser beam is irradiated from a direction intersecting the center line direction (for example, a direction orthogonal to the center line direction) to a portion where the vertical surface 315b of the first housing 31 and the end surface of the second housing 32 are in contact with each other. Then, the first housing 31 and the second housing 32 are welded.

  Next, the signal processing unit 200 is moved to the rear end side of the second housing 32 until the end surface on the front end side of the substrate covering portion 232 of the covering member 23 of the signal processing unit 200 hits the abutting surface 340 of the second housing 32. Insert through the opening. At that time, the coil spring 70 attached to the protruding portion 55a of the second electrode portion 55 enters the insertion hole 22a of the conductive member 22 of the signal processing portion 200 and is formed on the abutting surface 340 of the second housing 32. The signal processing unit 200 is inserted so that the second connection pin 21b connected to the printed wiring board 210 enters the recessed portion for pin 340a.

  Thereafter, the holding member 300 is fitted into the signal processing unit 200 from the rear end side until the protruding portion 300a of the holding member 300 hits the end surface 232c of the substrate covering portion 232 of the signal processing unit 200. In a state where the end surface 232c of the signal processing unit 200 and the protruding portion 300a of the holding member 300 are in contact with each other, a portion of the holding member 300 corresponding to the concave portion 335a of the fifth outer peripheral surface 335 of the second housing 32 is pressurized. As a result, the holding member 300 is caulked to the second housing 32. Accordingly, the holding member 300 is difficult to move with respect to the housing 30, and the signal processing unit 200 is difficult to move with respect to the housing 30.

[Pressure detection operation by pressure detector]
Now, the pressure detection operation of the internal combustion engine 1 by the pressure detection device 5 will be described.
When the internal combustion engine 1 is operating, pressure (combustion pressure) due to the combustion gas generated in the combustion chamber C is applied to the distal end side (surface) of the closing portion 42 in the diaphragm head 40. In the diaphragm head 40, the pressure received on the front surface concave portion 421 side is transmitted to the back surface convex portion 422 on the back surface side, and acts on the piezoelectric element 10 sandwiched between the first electrode portion 50 and the second electrode portion 55. Thus, an electric charge corresponding to the combustion pressure is generated in the piezoelectric element 10. Then, the electric charge generated in the piezoelectric element 10 is supplied to the circuit board portion 21 via the second electrode portion 55, the coil spring 70, and the conductive member 22. The charge supplied to the circuit board unit 21 is amplified in the circuit board unit 21, and then the voltage corresponding to the charge is supplied to the third connection pin 21 c connected to the circuit board unit 21 and the transmission cable 8. Is supplied to the control device 6.

[Relationship between combustion gas behavior and pressure detector]
Here, the relationship between the behavior of the combustion gas and the pressure detection device 5 in the pressure detection operation described above will be described.

  First, in the combustion chamber C of the internal combustion engine 1, the combustion gas generated as the fuel is burned is thermally expanded to generate combustion pressure. The combustion gas generated in the combustion chamber C acts on the closing portion 42 of the diaphragm head 40 of the pressure detection device 5. Accordingly, the pressure detection operation is performed according to the above-described procedure.

  On the other hand, the combustion gas generated in the combustion chamber C from the front end side of the pressure detection device 5, that is, the diaphragm head 40 side, and the inner peripheral surface of the communication hole 4a provided in the cylinder head 4 and the pressure detection device 5 (diaphragm head). 40, enters the air gap existing between the restraining ring 80 and the outer peripheral surface of the housing 30) and heads toward the rear end side.

  At this time, in the pressure detection device 5, the diaphragm head 40 is heated by being exposed to the high-temperature combustion gas, and is thermally expanded. When the tubular portion 41 of the diaphragm head 40 extends in the axial direction along with thermal expansion, it is preliminarily applied to the piezoelectric element 10 via the diaphragm head 40, the first electrode portion 50, the second electrode portion 55, and the like. The load decreases. When the next combustion is started in the combustion chamber C before the thermal expansion is eliminated, that is, before the diaphragm head 40 contracts, the output value from the pressure detection device 5 is reduced in the preload. Therefore, the output value will be lower than the original output value.

  Here, in the present embodiment, a suppression ring 80 having a thermal conductivity lower than that of the diaphragm head 40 is provided outside the tubular portion 41 of the diaphragm head 40 provided in the pressure detection device 5. As a result, the combustion gas that has entered the air gap between the inner peripheral surface of the communication hole 4 a provided in the cylinder head 4 and the outer peripheral surface of the pressure detection device 5 from the front end side of the pressure detection device 5. Compared with the case where the suppression ring 80 is not provided, the heat is less likely to be transmitted to the tubular portion 41 in the diaphragm head 40 (heat transmission is suppressed). As a result, thermal expansion of the tubular portion 41 in the diaphragm head 40 due to the heat of the combustion gas is less likely to occur. As a result, fluctuations in the preload applied to the piezoelectric element 10 using the diaphragm head 40 and the like, and consequently fluctuations in the output value from the pressure detection device 5 are less likely to occur.

  FIG. 8 is a diagram showing the time lapse of the output value from the pressure detection device 5. Here, FIG. 8A shows the pressure detection device 5 in which the outer peripheral surface of the cylindrical portion 41 of the diaphragm head 40 is exposed by not providing the suppression ring 80 (hereinafter referred to as the conventional pressure detection device 5). FIG. 8B illustrates the case of the pressure detection device 5 provided with the suppression ring 80 (hereinafter referred to as the current pressure detection device 5). 8A and 8B, the horizontal axis represents time, and the vertical axis represents the output value from the pressure detection device 5.

  In the case of the conventional pressure detection device 5, the thermal expansion of the tubular portion 41 in the diaphragm head 40 cannot be eliminated in one thermal cycle, and the preload decreases with the passage of time. As a result, as shown in FIG. 8 (a), the reference value of the output value (output value at the time of non-combustion) gradually decreases with time, for example, the combustion pressure in each thermal cycle is the same. Even so, the peak value of the output value obtained gradually decreases.

  On the other hand, in the case of the pressure detection device 5 of this time, the thermal expansion of the cylindrical portion 41 in the diaphragm head 40 is less likely to occur, and therefore the preload fluctuation is less likely to occur. As a result, as shown in FIG. 8B, the reference value of the output value (output value at the time of non-combustion) becomes stable regardless of the passage of time, and the peak value of the output value in each thermal cycle becomes stable. Misalignment is less likely to occur.

According to the experiment by the inventor, it has been found that the temperature on the front end side (around the diaphragm head 40) of the pressure detection device 5 during combustion in the combustion chamber C is about 250 to 300 ° C. Here, when a resin such as PTFE (polytetrafluoroethylene) is used as a material constituting the suppression ring 80, the resin may be deteriorated or decomposed in the temperature range, and the function as the suppression ring 80 may not be performed. .
On the other hand, in this embodiment, since an inorganic material (ceramic material) that hardly deteriorates or decomposes in the temperature range is used, it can be said that such a problem hardly occurs.

[Others]
In the present embodiment, alumina is used as the suppression ring 80 used in the pressure detection device 5, but the present invention is not limited to this, and various oxides such as zirconia (including stabilized zirconia) and yttria, A nitride such as aluminum nitride or a carbide such as silicon carbide may be used.
Moreover, in this Embodiment, although the insulator (alumina ceramics) was used as the suppression ring 80 used with the pressure detection apparatus 5, if the relationship of the thermal conductivity between the diaphragm heads 40 is satisfy | filled, It may be a semiconductor or a conductor.
Furthermore, in the present embodiment, ceramics (polycrystal) is used as the inorganic material constituting the suppression ring 80 used in the pressure detection device 5, but glass may be used, for example.

In the present embodiment, the suppression ring 80 used in the pressure detection device 5 is provided on the rear end side of the outer peripheral surface of the diaphragm head 40. However, the present invention is not limited to this, and may be provided in the housing 30, for example. It doesn't matter. When the suppression ring 80 is provided in the housing 30, it is preferable to provide the suppression ring 80 on the distal end side of the housing 30 close to the diaphragm head 40. In the case of adopting this configuration, the restraining ring 80 makes it difficult for the housing 30 to thermally expand, and the preload variation of the pressure detection device 5 is also less likely to occur.
Furthermore, in the present embodiment, the case where the piezoelectric element 10 is used as the signal generation unit in the pressure detection device 5 has been described as an example. However, the present invention is not limited to this, for example, a strain gauge, a separated electrode, or the like May be used.
Furthermore, in the present embodiment, the pressure detection target by the pressure detection device 5 is the internal combustion engine 1, but the present invention is not limited to this and may be other than the internal combustion engine 1.

DESCRIPTION OF SYMBOLS 1 ... Internal combustion engine, 2 ... Cylinder block, 3 ... Piston, 4 ... Cylinder head, 5 ... Pressure detection apparatus, 6 ... Control apparatus, 7 ... Sealing member, 8 ... Transmission cable, 10 ... Piezoelectric element, 21 ... Circuit board part , 22 ... conductive member, 23 ... cover member, 24 ... O-ring, 30 ... housing, 40 ... diaphragm head, 50 ... first electrode portion, 55 ... second electrode portion, 60 ... insulating ring, 65 ... support member , 70 ... Coil spring, 80 ... Suppression ring, 100 ... Sensor part, 200 ... Signal processing part, 300 ... Holding member

Claims (3)

A cylindrical body,
A cylindrical tubular portion and a closed portion that closes the tubular portion on one end side of the tubular portion, and the other end portion side of the tubular portion is provided on one end portion side of the body portion, and A pressure receiving portion where the closed portion receives pressure from the outside;
A signal generator that is provided inside the body part and generates a signal corresponding to the pressure received by the pressure receiver;
A pressure detection device including an annular member made of an inorganic material having a lower thermal conductivity than the pressure receiving portion and attached to the outside of the cylindrical portion. The one end side surface of the annular member is disposed opposite to the abutting surface provided in the pressure receiving portion, and the other end surface of the annular member is provided on the body portion. The pressure detection device according to claim 1, wherein the pressure detection device is disposed so as to oppose to the surface. A cylinder head formed with a communication hole communicating the combustion chamber on the front end side and the outside on the rear end side;
A pressure detecting device that is attached to the cylinder head by being inserted into the communication hole and detects the pressure in the combustion chamber;
The pressure detection device includes:
A cylindrical body portion disposed in the communication hole;
A cylindrical tubular portion and a closed portion that closes the tubular portion on one end side of the tubular portion, and the other end portion side of the tubular portion is provided on one end portion side of the body portion, and A pressure receiving portion where the closed portion receives pressure from the combustion chamber;
A signal generator that is provided inside the body part and generates a signal corresponding to the pressure received by the pressure receiver;
The pressure detection is made of an inorganic material having a lower thermal conductivity than the pressure receiving portion, is attached to the outside of the cylindrical portion, and includes an annular annular member disposed in non-contact with the inner peripheral surface of the communication hole. Internal combustion engine with device.

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