JP2017026369A - Particle sensor - Google Patents

Abstract

Provided is a technique for efficiently bringing fine particles into contact with ions. A fine particle sensor for detecting fine particles in a gas to be measured is a sensor element extending along an axial direction, the sensor element having an ion generating part 131s for generating ions on the tip side, and the ion generating part. A first casing that covers the first inflow hole 60c into which the gas to be measured flows, and the first casing is located on the tip side of the first inflow hole. It has an outflow hole 60e that flows out, and a protrusion 60f that protrudes to the inside of the first casing, and the distance between the protrusion and the ion generator is smaller than the distance between the ion generator and the first casing. In the axial direction, the root of the protrusion is disposed on the tip side of the first inflow hole. [Selection] Figure 5

Description

  The present invention relates to a particle sensor.

  The exhaust gas of an internal combustion engine such as a diesel engine contains particulates such as soot. Conventionally, a fine particle sensor for detecting the amount of fine particles in the exhaust gas is known (for example, Patent Document 1).

International Publication No. 2014/054390

  In general, when this type of particulate sensor is mounted on a vent pipe of an internal combustion engine, an ion source is provided in a casing protruding into the vent pipe, and ions are generated by the ion source. Charges the fine particles contained in the gas to be measured introduced into the mixing region of the casing with ions. However, in the conventional fine particle sensor, no particular consideration has been given to efficiently bringing the fine particles into contact with the ions. For this reason, a technique for efficiently bringing fine particles into contact with ions has been desired.

  The present invention has been made to solve the above-described problems, and can be realized as the following forms.

(1) According to one aspect of the present invention, there is provided a fine particle sensor that detects fine particles in a gas to be measured. The fine particle sensor is a sensor element that extends along the axial direction, and includes a sensor element having an ion generation part that generates ions on a tip end side thereof, and a first casing that covers the ion generation part, 1 casing has a first inflow hole into which the measurement gas flows, a distal end side of the first inflow hole, an outflow hole through which the measurement gas flows out, and the first A protrusion projecting inside the casing, and a distance between the protrusion and the ion generation unit is smaller than a distance between the ion generation unit and the first casing, and in the axial direction, The base of the protrusion is arranged on the tip side of the first inflow hole. According to the particulate sensor of this embodiment, since the distance between the protrusion and the ion generator is smaller than the distance between the ion generator and the first casing, ions are released from the ion generator toward the protrusion. The On the other hand, in the axial direction, the base of the protrusion is disposed on the tip side of the inflow hole, so that the gas to be measured flowing from the first inflow hole has the protrusion (tip of the protrusion) and the ion generating part. It flows to the outflow hole via between. For this reason, the ions and the gas to be measured are likely to come into contact between the protrusion and the ion generating part. As a result, the fine particles and ions can be contacted efficiently. Note that the distance between the protrusion and the ion generation unit and the distance between the ion generation unit and the first casing all indicate the shortest distance in this specification.

(2) In the particulate sensor of the above aspect, the protrusion may be formed by bending a part of the first casing to the inside. According to the particulate sensor of this form, the protrusion and the casing can be integrally formed.

(3) In the fine particle sensor according to the above aspect, the base of the protrusion may be disposed on the tip side in the axial direction with respect to the tip of the protrusion. According to the particulate sensor of this embodiment, since the base of the protrusion is disposed on the tip side in the axial direction with respect to the tip of the protrusion, the measurement target flowing in from the inflow hole by the gas guide action by the surface of the protrusion The gas is guided to the rear end side of the first casing and flows between the protrusion and the ion generation unit. As a result, the gas to be measured that has flowed into the first casing easily flows to the rear end side of the first casing, and a large amount of the gas to be measured can be quickly distributed in the first casing. And ions can be contacted more efficiently.

(4) The fine particle sensor according to the above aspect further includes a second casing that covers at least a part of an outer periphery of the first casing via a space, and the gas to be measured flows into the second casing. A second inflow hole may be provided, and the second inflow hole may be disposed closer to the distal end side than the first inflow hole in the axial direction. By providing the second casing, it is possible to suppress foreign matters (for example, water droplets) contained in the gas to be measured from adhering to the sensor element disposed inside the first casing. In addition, in the axial direction, the second inflow hole is arranged on the front end side of the first inflow hole of the first casing, so that even if foreign matter enters the inside of the second casing, It is difficult for the first inflow hole to flow, and it is possible to further suppress foreign matters from adhering to the sensor element.

  In addition, this invention can be implement | achieved with various forms, for example, can be implement | achieved in aspects, such as a manufacturing method of a fine particle sensor.

It is a schematic block diagram of the vehicle carrying the particulate sensor of this embodiment. The figure which shows the attachment state of the particulate sensor to the exhaust gas piping 415 of a vehicle, and the internal structure of a sensor drive part. FIG. The exploded perspective view of the sensor element 120. FIG. The figure which shows typically the cross section of the front-end | tip part 300e of the fine particle sensor 300. FIG. A sectional view of particulate sensor 300A.

A. First embodiment:
A1. Configuration of vehicle equipped with particle sensor:
FIG. 1 is a schematic configuration diagram of a vehicle on which the particle sensor of the present embodiment is mounted. As shown in FIG. 1, the vehicle 500 includes an internal combustion engine 400, a fuel supply unit 410, and a vehicle control unit 420. The internal combustion engine 400 is a power source of the vehicle 500, and is constituted by, for example, a diesel engine. The fuel supply unit 410 supplies fuel to the internal combustion engine 400 via the fuel pipe 411.

  The vehicle control unit 420 is configured by a microcomputer, for example, and controls the driving state of the entire vehicle 500. Specifically, the vehicle control unit 420 controls the combustion state of the fuel in the internal combustion engine 400, the amount of fuel supplied from the fuel supply unit 410, and the like. An exhaust gas pipe 415 is connected to the internal combustion engine 400, and exhaust gas from the internal combustion engine 400 is discharged to the outside of the vehicle 500 through the exhaust gas pipe 415. The exhaust gas pipe 415 is provided with a filter device 416 (for example, DPF (Diesel particulate filter)) for removing particulates such as soot contained in the exhaust gas.

  The vehicle 500 is further equipped with a sensor system 330 that detects the amount of fine particles in the exhaust gas. The sensor system 330 includes a particle sensor 300, a sensor driving unit 310, and a cable 320 that connects the particle sensor 300 and the sensor driving unit 310. The particulate sensor 300 is attached downstream of the filter device 416 in the exhaust gas pipe 415.

  In the present embodiment, the fine particle sensor 300 charges the soot that is fine particles with cations generated by corona discharge. Then, by separating the cations used for charging (also referred to as “adhesion cations”) and the cations that were not used for charging (also referred to as “surplus cations”), the fine particle sensor 300 is provided. The detection signal is output to the sensor driving unit 310.

  The sensor driving unit 310 drives the particulate sensor 300 and detects the amount of soot in the exhaust gas based on the detection signal from the particulate sensor 300. In the present embodiment, the vehicle control unit 420 diagnoses the performance of the filter device 416 based on the detected amount of soot. For example, when the detected amount of soot exceeds a predetermined value, the vehicle control unit 420 determines deterioration or abnormality of the filter device 416 and notifies the user by displaying the determination result on a monitor or the like. . In the present embodiment, the amount of soot in the exhaust gas is based on the concentration of soot in the exhaust gas, but the surface area may be the unit, the mass may be the unit, or the number of soot may be the unit.

  FIG. 2 is a diagram showing the state of attachment of the particle sensor to the exhaust gas pipe 415 of the vehicle and the internal configuration of the sensor driving unit. Here, in the fine particle sensor, the lower side in FIG. 2 is also referred to as “tip side”, and the upper side in FIG. 2 is also referred to as “base side”. As shown in FIG. 2, the particle sensor 300 has a tip portion 300 e located on the tip side inserted into the exhaust gas pipe 415 and exposed to the exhaust gas flowing through the exhaust gas pipe 415.

  The particulate sensor 300 is located on the tip side of the second inflow hole 65c for allowing the exhaust gas, which is the gas to be detected, to flow into the casing 25, and the second inflow hole 65c, and flows into the casing 25. And an outflow hole 60e through which exhaust gas flows out.

  A flexible cable 320 is connected to the base end side of the particle sensor 300. The cable 320 electrically connects the particle sensor 300 and the sensor driving unit 310.

  The sensor driving unit 310 includes a sensor control unit 311 and an electric circuit unit 312. The sensor control unit 311 is constituted by, for example, a microcomputer, controls the electric circuit unit 312, and transmits the detection result by the particle sensor 300 to the vehicle control unit 420.

  The electric circuit unit 312 supplies power to the particle sensor 300 via the electric wires 171, 173, 175 accommodated in the cable 320. In addition, the electric circuit unit 312 receives the sensor signal of the fine particle sensor 300 via the electric wires 161 and 163 accommodated in the cable 320 and transmits a detection result based on the sensor signal to the sensor control unit 311.

A2. Particle sensor configuration:
FIG. 3 is a cross-sectional view of the particle sensor 300. Here, FIG. 3 shows XYZ axes orthogonal to each other. In FIG. 3, the Z-axis positive direction side is the front end side, and the Z-axis negative direction side is the base end side. The XYZ axes in FIG. 3 correspond to the XYZ axes in the drawings after FIG.

  As shown in FIG. 3, the particle sensor 300 includes a sensor element 120 that extends along the direction of the axis CL, an ion generator 131s (see FIG. 4) that is provided on the tip side of the sensor element 120 and generates ions. The casing 25 etc. which cover the front end side of the sensor element 120 and the ion generation part 131s are provided. In addition, the particle sensor 300 includes the inner metal fitting 20 including the casing 25, the outer metal fitting 70 positioned on the outer periphery of the inner metal fitting 20, the first insulating spacer 100 provided between the inner metal fitting 20 and the outer metal fitting 70, and the first 2 insulation spacers 110 are provided.

  The outer metal fitting 70 of the particle sensor 300 is attached to a metal exhaust pipe 415 having a ground potential PVE (chassis GND of the vehicle 500) via a metal boss BO. Thereby, the outer metal fitting 70 is set to the ground potential PVE. Further, the casing 25 is disposed in the exhaust gas pipe 415 in a state where the particulate sensor 300 is mounted.

  The inner metal fitting 20 is a metal member, and the inner metal fitting 20 is held inside the outer metal fitting 70 while being insulated from the outer metal fitting 70 via the first insulating spacer 100 and the second insulating spacer 110. The first potential PV1 is different from the ground potential PVE of the outer metal fitting 70. The inner metal fitting 20 is electrically connected to the electric wires 161 and 163. The inner metal fitting 20 includes a casing 25, a main metal fitting 30, an inner cylinder 40, and an inner cylinder connecting metal fitting 50 in this order from the front end side.

  The metal shell 30 of the inner metal fitting 20 is a cylindrical member that extends along the direction of the axis CL, and is formed of stainless steel. The metal shell 30 has a flange portion 31 protruding outward in the radial direction. A metal cup 33 is disposed inside the metal shell 30. A hole is formed on the tip side of the metal cup 33, and the sensor element 120 is inserted through this hole. Further, inside the metal shell 30, around the sensor element 120, in order from the tip side, a cylindrical ceramic holder 34 made of alumina and a first powder filled by compressing talc powder A layer 35 and a second powder-filled layer 36, and a cylindrical ceramic sleeve 37 formed of alumina are disposed. The ceramic holder 34 and the first powder filling layer 35 are disposed inside the metal cup 33. Further, the most proximal end caulking portion 30 kk of the metal shell 30 is caulked radially inward and presses the ceramic sleeve 37 toward the distal end side via the caulking ring 38.

  The inner cylinder 40 of the inner metal fitting 20 is a cylindrical member that extends along the direction of the axis CL, and is formed of stainless steel. The inner cylinder 40 has a flange portion 41 protruding outward in the radial direction. The inner cylinder 40 is externally fitted to the proximal end portion 30k of the metal shell 30, and is welded to the proximal end portion 30k in a state where the flange portion 41 of the inner cylinder 40 is overlapped with the flange portion 31 of the metal shell 30. .

  Inside the inner cylinder 40, an insulating holder 43, a first separator 44, and a second separator 45 are arranged in this order from the tip side. The insulation holder 43 is a cylindrical member and is formed of an insulator. The insulating holder 43 is in contact with the ceramic sleeve 37 disposed on the tip side of the insulating holder 43. The sensor element 120 is inserted inside the insulating holder 43. The first separator 44 is a cylindrical member and is formed of an insulator. Inside the first separator 44, the sensor element 120 is inserted, and a portion on the tip side of a discharge potential terminal 46 described later is accommodated. The discharge potential terminal 46 is in contact with the sensor element 120 inside the first separator 44.

  The second separator 45 is a cylindrical member and is formed of an insulator. Inside the second separator 45, there are a first insertion hole 45c and a second insertion hole 45d extending in the direction of the axis CL. In the first insertion hole 45c, a portion on the proximal end side of the discharge potential terminal 46 and a discharge potential lead wire 162 described later are in contact with each other. In the second insertion hole 45d, the element base end portion 120k of the sensor element 120 is disposed. The second insertion hole 45d is a terminal connected to the sensor element 120, and an auxiliary potential terminal 47, a 2-1 heater terminal 48, and a 2-2 heater terminal 49, which will be described later, are accommodated in an insulated state. Has been. In the second insertion hole 45d, as will be described later in FIG. 4, (i) the auxiliary potential terminal 47 is electrically connected to the auxiliary potential pad 147 provided in the sensor element 120, and (ii) the second 2- The 1 heater terminal 48 is electrically connected to the 2-1 heater pad 156 provided in the sensor element 120, and (iii) the 2-2 heater terminal 49 is the 2-2 provided in the sensor element 120. The heater pad 158 is electrically connected.

  The inner tube connection fitting 50 of the inner fitting 20 is a cylindrical member that extends along the direction of the axis CL, and is formed of stainless steel. The inner cylinder connection fitting 50 is fitted on the proximal end portion 40k of the inner cylinder 40 while covering the portion on the proximal end side of the second separator 45, and the distal end portion 50s of the inner cylinder connection fitting 50 is the proximal end of the inner cylinder 40. It is welded to the portion 40k. The four electric wires 161, 163, 173, and 175 except for the electric wire 171 are inserted inside the inner cylinder connection fitting 50, respectively.

  The casing 25 includes a first casing 60 that covers the distal ends of the sensor element 120 and the discharge electrode body 130, a second casing 65 that covers at least a part of the outer periphery of the first casing 60 via a space, It is composed of The first casing 60 is a bottomed cylindrical member and is formed of stainless steel. The second casing 65 is a cylindrical member and is made of stainless steel. The first casing 60 and the second casing 65 are fitted on the distal end side 30s of the metal shell 30, and are welded to the distal end side 30s.

  The first casing 60 includes a first inflow hole 60c into which exhaust gas as a gas to be measured flows, and an outflow hole 60e that is located on the tip side of the first inflow hole 60c and through which the exhaust gas flows out. . The outflow hole 60e is provided at the front end of the first casing 60, and the front end 60s including the outflow hole 60e protrudes from the front end opening 65s of the second casing 65 to the front end side.

  In addition, the first casing 60 includes a protrusion 60 f that protrudes inside the first casing 60. The shortest distance between the projection 60f and an ion generator 131s described later is smaller than the shortest distance between the ion generator 131s and the casing 25. The root 60g of the protrusion 60f is disposed on the distal end side in the axis CL direction with respect to the first inflow hole 60c. In addition, the root 60g of the protrusion 60f is disposed closer to the front end side in the axis CL direction than the front end 60h of the protrusion 60f. In the present embodiment, the protrusion 60f is formed by welding a member having a cylindrical rear end side (base 60g side) and a tapered tip end side to the inside of the first casing 60. The portion in contact with the first casing 60 is referred to as a root 60g.

  As shown in FIG. 3, the second casing 65 includes a second inflow hole 65 c into which exhaust gas as a measurement target gas flows. The second inflow hole 65c is disposed on the tip side of the first inflow hole 60c of the first casing 60 in the direction of the axis CL.

  Next, the outer metal fitting 70 of the particle sensor 300 will be described. The outer metal fitting 70 is composed of an attachment metal 80 and an outer cylinder 90.

  The mounting bracket 80 is a cylindrical member extending along the direction of the axis CL, and is formed of stainless steel. The mounting bracket 80 covers the metal shell 30 and the inner cylinder 40 around the radial direction so as to be separated from these. The mounting bracket 80 has a flange portion 81 protruding outward in the radial direction so that the outer periphery has a hexagonal shape. A stepped portion 83 is provided inside the mounting bracket 80. Further, a screw groove (not shown) is formed on the outer periphery of the distal end portion 80 s of the mounting bracket 80 on the distal end side from the flange portion 81. The particle sensor 300 is attached to a boss BO separately fixed to the exhaust gas pipe 415 by a screw groove at the tip 80s, and is fixed to the exhaust gas pipe 415 via the boss BO.

  The caulking portion 80kk of the mounting bracket 80 presses the second insulating spacer 110 toward the distal end side via the wire packing 87. Thereby, the front end portion 111 of the second insulating spacer 110 presses the flange portion 41 of the inner cylinder 40 and the flange portion 31 of the metal shell 30 toward the front end side. Further, the flange portion 41 and the flange portion 31 press the spacer intermediate portion 102 of the first insulating spacer 100 toward the distal end side, and the spacer intermediate portion 102 engages with the stepped portion 83 of the mounting bracket 80.

  A first insulating spacer 100 and a second insulating spacer 110 formed of an insulator are disposed between the mounting bracket 80 and the inner bracket 20. Further, between the mounting bracket 80 and the inner bracket 20, a heater 105 for heating the first insulating spacer 100, a heater connection bracket 85 connected to the heater 105, and an electric wire connected to the heater connection bracket 85. A distal end portion 171 is disposed. Since the heater 105 is formed so as to have a predetermined pattern inside the first insulating spacer 100, FIG. 3 shows the heater 105 pointing to the inside of the first insulating spacer 100, and the detailed form is shown in FIG. Not shown. Note that one end of the pattern of the heater 105 is exposed on the outer surface of the first insulating spacer 100, contacts the stepped portion 83 of the mounting bracket 80, and is electrically connected to the mounting bracket 80. On the other hand, the other end of the pattern of the heater 105 is exposed on the inner surface of the first insulating spacer 100, contacts the heater connection fitting 85, and is electrically connected to the electric wire 171 through the heater connection fitting 85. The heater 105 is heated when supplied with electric power via the electric wire 171 and heats the first insulating spacer 100 to burn particulates such as soot adhering to the front end side of the first insulating spacer 100, thereby It functions to maintain insulation between 70 and the inner metal fitting 20.

  The outer cylinder 90 is a cylindrical member that extends along the direction of the axis CL, and is formed of stainless steel. The distal end portion 90s of the outer cylinder 90 is fitted on the base end portion 80k of the mounting bracket 80 and is welded to the base end portion 80k. Outer cylinder 90 has an outer cylinder connection fitting 95 and a grommet 97 arranged in this order from the distal end side inside small diameter portion 91 located on the proximal end side. Five electric wires 161, 163, 171, 173, and 175 are inserted through the outer tube connection fitting 95 and the grommet 97, respectively. The outer cylinder connection fitting 95 is reduced in diameter in the radial direction together with the small diameter portion 91 of the outer cylinder 90 by caulking, whereby the outer cylinder connection fitting 95 and the grommet 97 are fixed within the small diameter portion 91 of the outer cylinder 90. Yes.

  FIG. 4 is an exploded perspective view of the sensor element 120. The sensor element 120 is a plate-like member that extends along the direction of the axis CL, and has an insulating member 121 formed of an insulator. The sensor element 120 is formed by integrally sintering the insulating member 121 in a state where the discharge electrode body 130, the auxiliary electrode body 140, and the element heater 150 are embedded.

  The insulating member 121 is formed by laminating three ceramic layers 122, 123, and 124 formed from alumina derived from an alumina green sheet. Between these layers, 2 is formed from alumina formed by printing. Two insulating coating layers 125 and 126 are interposed, respectively. The ceramic layer 122 and the insulating coating layer 125 are formed shorter than the ceramic layers 123 and 124 and the insulating coating layer 126 in the direction of the axis CL on the distal end side and the proximal end side, respectively. A discharge electrode body 130 is disposed between the ceramic layer 123 and the insulating coating layer 125, and an auxiliary electrode body 140 is disposed between the ceramic layer 123 and the insulating coating layer 126. An element heater 150 is disposed between the insulating coating layer 126.

  The discharge electrode body 130 is a member extending along the direction of the axis CL, and connects the needle-like needle electrode portion 131 located on the distal end side and the discharge potential pad 135 located on the proximal end side. And a lead portion 133. In the present embodiment, the needle electrode portion 131 is made of platinum, and the lead portion 133 and the discharge potential pad 135 are made of tungsten. In the discharge electrode body 130, the base end portion 131 k of the needle electrode portion 131 and the entire lead portion 133 are embedded in the insulating member 121. On the other hand, in the needle-like electrode portion 131, the ion generating portion 131 s protrudes from the insulating member 121 on the tip side of the ceramic layer 122. Thereby, the ion generator 131s functions as an ion source that generates corona discharge with the first casing 60 (specifically, the protrusion 60h) and generates ions (positive ions in the present embodiment). doing. The discharge potential pad 135 is exposed on the base end side of the insulating member 121 with respect to the ceramic layer 122. The discharge potential pad 135 is connected to the discharge potential terminal 46 in the insertion hole 44 c of the first separator 44. In addition, the surface of the front end side portion of the insulating member 121 is in contact with the exhaust gas taken into the casing 25.

  The auxiliary electrode body 140 is a member that extends along the direction of the axis CL, and is embedded in the insulating member 121. The auxiliary electrode body 140 is located on the distal end side, and is composed of a rectangular auxiliary electrode portion 141 and a lead portion 143 connected to the auxiliary electrode portion 141 and extending along the axis CL direction. A base end portion 143k of the lead portion 143 is connected to a conductive pattern 145 formed on one main surface 124a of the ceramic layer 124 through a through hole 126c of the insulating coating layer 126. The conductive pattern 145 is connected to an auxiliary potential pad 147 formed on the other main surface 124 b of the ceramic layer 124 via a through-hole conductor 146 formed on the ceramic layer 124. The auxiliary potential pad 147 is connected to the auxiliary potential terminal 47 in the second insertion hole 45 d of the second separator 45.

  The element heater 150 is a member that extends along the direction of the axis CL, and is embedded in the insulating member 121. The element heater 150 is located on the distal end side, and is connected to both ends of the heating resistor 151 that heats the sensor element 120 and the heating resistor 151, and a pair of heater lead portions 152 and 153 that extend along the proximal end side. It consists of and.

  A base end portion 152k of the heater lead portion 152 is connected to a 2-1 heater pad 156 formed on the main surface 124b of the ceramic layer 124 via a through-hole conductor 155 formed on the ceramic layer 124. As described above, the 2-1 heater pad 156 is connected to the 2-1 heater terminal 48 in the second insertion hole 45d of the second separator 45. Further, the base end portion 153k of the heater lead portion 153 is connected to the 2-2 heater pad 158 formed on the main surface 124b of the ceramic layer 124 via the through-hole conductor 157 formed on the ceramic layer 124. Yes. As described above, the 2-2 heater pad 158 is connected to the 2-2 heater terminal 49 in the second insertion hole 45d of the second separator 45.

  Next, the electric wires 161, 163, 171, 173, and 175 will be described. As shown in FIG. 3, two of these wires 161 and 163 are triple coaxial cables, and the remaining three wires 171, 173 and 175 are single-core insulated wires. The electric wire 161 has a discharge potential lead wire 162 as a core wire, and the discharge potential lead wire 162 is connected to the discharge potential terminal 46 in the first insertion hole 45c of the second separator 45 as described above. The electric wire 163 has an auxiliary potential lead wire 164 as a core wire, and the auxiliary potential lead wire 164 is connected to the auxiliary potential terminal 47 in the second insertion hole 45 d of the second separator 45. Among the coaxial double outer conductors of the electric wires 161 and 163, the inner inner outer conductors 161g1 and 163g1 are connected to the inner cylinder connecting metal fitting 50 of the inner metal fitting 20, and are set to the first potential PV1. On the other hand, the outer outer conductors 161g2 and 163g2 on the outer side are connected to an outer tube connecting fitting 95 that is electrically connected to the outer fitting 70, and are set to the ground potential PVE. The particulate sensor 300 detects a change in the current flowing between the first potential PV1 and the ground potential PVE as a detection signal of the particulate sensor 300, and detects the amount of soot S contained in the exhaust gas based on the detection signal. To do.

  The electric wire 171 has the 1-1st heater lead wire 172 as a core wire. The 1-1 heater lead wire 172 is connected to the heater connection fitting 85 inside the attachment fitting 80. The electric wire 173 has a second heater lead wire as a core wire. The second heater lead wire is connected to the 2-1 heater terminal 48 in the second insertion hole 45 d of the second separator 45. The electric wire 175 has a 2-2 heater lead wire 176 as a core wire. The 2-2 heater lead wire 176 is connected to the 2-2 heater terminal 49 in the second insertion hole 45 d of the second separator 45.

A3. Detection operation of the particle sensor:
FIG. 5 is a diagram schematically showing a cross section of the tip portion 300 e of the particle sensor 300. FIG. 5 schematically shows the flow direction (arrow F) of the exhaust gas in the exhaust gas pipe 415 (FIG. 2) and the flow direction of the gas inside the tip portion 300e.

  In FIG. 5, the exhaust gas circulates from the left side to the right side of the drawing. When the exhaust gas passes around the second casing 65 and the first casing 60, the flow velocity rises outside the outflow hole 60e of the first casing 60, and a negative pressure is generated in the vicinity of the outflow hole 60e due to the so-called venturi effect. Arise. This is because the distal end portion of the second casing 65 and the distal end portion 60s (see FIG. 3) of the first casing 60 protruding from the distal end opening portion 65s of the second casing 65 are directed toward the distal end side as the outer diameter increases. This is because the taper shape is formed so as to gradually decrease.

  Due to this negative pressure, the exhaust gas taken into the first casing 60 is discharged from the outflow hole 60e to the exhaust gas pipe 415. At the same time, the exhaust gas around the second inflow hole 65c of the second casing 65 is taken into the second casing 65 from the second inflow hole 65c, and further, the first inflow hole of the first casing 60 is provided. It is taken into the first casing 60 through 60c. For this reason, in the 1st casing 60, as shown with the broken-line arrow EGI, the airflow which flows toward the outflow hole 60e from the 1st inflow hole 60c arises.

  When detecting the amount of soot S in the exhaust gas, the fine particle sensor 300 generates the cation PI by the discharge electrode body 130 (ion generator 131s). Specifically, a predetermined voltage is applied by the electric circuit unit 312 (FIG. 2) using the discharge electrode body 130 as an anode and the first casing 60 as a cathode, and the discharge electrode body 130 (specifically, the ion generation unit 131s). ) And the first casing 60 (protrusion 60f) to generate a corona discharge to generate cations PI in the casing 25.

  When the soot S that is fine particles is present in the exhaust gas, the soot S passes through the second inflow hole 65c of the second casing 65 and the first inflow hole 60c of the first casing 60, and the first It enters the casing 60. And in the area | region 12 in the 1st casing 60, the cation PI in air adsorb | sucks to the soot S, and the soot S is charged.

  The fine particle sensor 300 applies a predetermined voltage to the auxiliary electrode body 140. Thereby, repulsive force which goes to the 1st casing 60 of the radial direction outer side from the auxiliary electrode body 140 is added to the cation PI (surplus cation PI) which is not adsorb | sucking to the soot S among cations PI. As a result, surplus cation PI is trapped on the inner wall of the first casing 60.

  On the other hand, the cation PI (adsorption cation PI) adsorbed on the soot S has a mass larger than the surplus cation PI by the mass of the soot S. For this reason, the influence by an external electrical repulsive force and attractive force is small compared with the surplus cation PI. As a result, even if an electric force is received, the exhaust gas flows and is discharged from the outflow hole 60e into the exhaust gas pipe 415. Thereby, the surplus cation PI and the adsorption cation PI are separated.

  The particulate sensor 300 can detect a change in current according to the amount of cations PI captured by the first casing 60. The sensor control unit 311 (FIG. 2) detects a change in the current in the particle sensor 300 as a detection signal of the particle sensor 300 via the electric circuit unit 312, and the soot S contained in the exhaust gas based on the detection signal. Detect the amount of.

  The fine particle sensor 300 of the present embodiment has a protrusion 60 f that protrudes into the first casing 60. As shown in FIG. 5, the shortest distance D1 between the protrusion 60f and the ion generator 131s is smaller than the shortest distance D2 between the ion generator 131s and the casing 25. For this reason, the cation PI is released from the ion generation part 131s toward the protrusion 60f. On the other hand, in the axis CL direction, the root 60g of the protrusion 60f is closer to the distal end than the first inflow hole 60c (in other words, the first inflow hole 60c located on the most distal end side of the first casing 60). Has been placed. For this reason, the exhaust gas flowing in from the first inflow hole 60c flows to the outflow hole 60e via the gap between the protrusion 60f and the ion generation part 131s. As a result, the soot S and the cation PI are likely to come into contact with each other between the protrusion 60f (specifically, the tip 60h of the protrusion 60f) and the ion generator 131s (gap). For this reason, according to the particulate sensor 300 of this embodiment, the soot S and the cation PI can be efficiently contacted. The shortest distance D1 is preferably 2 mm or more from the viewpoint of more reliably generating corona discharge.

  Further, in the fine particle sensor 300 of the present embodiment, the root 60g of the protrusion 60f is disposed on the tip side in the direction of the axis CL with respect to the tip 60h of the protrusion 60f. For this reason, the exhaust gas flowing in from the first inflow hole 60c is guided to the rear end side of the first casing 60 by the gas guide action by the surface of the protrusion 60f, and the protrusion 60f and the ion generator 131s It flows in between. As a result, the exhaust gas that has flowed into the first casing 60 easily flows to the rear end side of the first casing 60, and a large amount of the exhaust gas can be quickly distributed into the first casing 60. And ions can be contacted more efficiently.

  In the fine particle sensor 300 of the present embodiment, the second inflow hole 65c of the second casing 65 is arranged on the front end side with respect to the first inflow hole 60c of the first casing 60 in the axis line CL direction. By including the second casing 65, it is possible to suppress foreign matters (for example, water droplets) contained in the exhaust gas from adhering to the sensor element 120 including the ion generation unit 131 s disposed inside the first casing 60. can do. Moreover, even if a foreign substance enters the inside of the second casing 65 by disposing the second inflow hole 65c on the tip side of the first inflow hole 60c of the first casing 60 in the axis CL direction. In addition, it is difficult to flow into the first inflow hole 60c on the rear end side, and it is possible to further suppress foreign matters from adhering to the sensor element 120.

B. Second embodiment:
FIG. 6 is a cross-sectional view of the particle sensor 300A of the second embodiment. The particle sensor 300A of the second embodiment is different from the particle sensor 300 of the first embodiment in the protrusion 60fA and the first inflow hole 60cA, but is otherwise the same. The protrusion 60fA is formed by bending a part of the first casing 60A inward. More specifically, the protrusion 60fA is formed by providing a cut in a straight line in a part of the first casing 60A and pushing the leading end side of the cut into the inside. Further, the hole generated by forming the protrusion 60fA functions as the first inflow hole 60cA. According to the particulate sensor 300A of this form, the protrusion 60fA and the first casing 60A can be integrally formed. In addition to the first inflow hole 60cA, a flow hole may be provided in the first casing 60A.

C. Variations:
C1. Modification 1:
In the above-described embodiment, the root 60g of the protrusion 60f is disposed on the tip side in the axis CL direction with respect to the tip 60h of the protrusion 60f. However, the present invention is not limited thereto, and the root 60g of the protrusion 60f may be disposed at the same position in the axis CL direction with respect to the tip 60h of the protrusion 60f, or may be disposed on the rear end side.

C2. Modification 2:
In the above-described embodiment, the particle sensor 300 includes the second casing 65, but the second casing 65 may not be included. When the particulate sensor 300 includes the second casing 65, the second inflow hole 65 c of the second casing 65 is positioned at the same position as the first inflow hole 60 c of the first casing 60 in the direction of the axis CL. You may arrange | position and may arrange | position to a rear-end side. In addition, a second casing 65 having a cylindrical shape with an open front end that does not have a second inflow hole 65c provided as a horizontal hole is provided so as to surround the outside of the first casing 60, and the second casing The tip opening of 65 may be used as the second inflow hole 65c.

  The present invention is not limited to the above-described embodiments and modifications, and can be realized with various configurations without departing from the spirit thereof. For example, the technical features in the embodiments and the modifications corresponding to the technical features in each form described in the summary section of the invention are to solve some or all of the above-described problems, or In order to achieve part or all of the effects, replacement or combination can be performed as appropriate. Further, if the technical feature is not described as essential in the present specification, it can be deleted as appropriate.

DESCRIPTION OF SYMBOLS 12 ... Area | region 20 ... Inner metal fitting 25 ... Casing 30 ... Main metal fitting 30k ... Base end side part 30kk ... Clamping part 30s ... Tip side 31 ... Flange part 33 ... Metal cup 34 ... Ceramic holder 35 ... 1st powder filling layer 36 ... Second powder packed layer 37 ... Ceramic sleeve 38 ... Caulking ring 40 ... Inner cylinder 40k ... Base end part 41 ... Flange part 43 ... Insulating holder 44 ... First separator 45 ... Second separator 45c ... First insertion hole 45d ... First 2 Insertion hole 46 ... Discharge potential terminal 47 ... Auxiliary potential terminal 48 ... 2-1 heater terminal 49 ... 2-2 heater terminal 50 ... Inner tube fitting 50s ... Tip 60 ... 1st casing 60A ... 1st Casing 60c ... 1st inflow hole 60cA ... 1st inflow hole 60e ... Outflow hole 60f ... Projection part 60fA ... Projection part 60g ... Base 60h ... Tip 6 0s: distal end portion 65 ... second casing 65c ... second inflow hole 65s ... distal end opening portion 70 ... outer metal fitting 80 ... mounting bracket 80k ... proximal end portion 80kk ... caulking portion 80s ... distal end portion 81 ... flange portion 83 ... Stepped portion 85: Heater connection fitting 87 ... Wire packing 90 ... Outer cylinder 90s ... Tip portion 91 ... Small diameter portion 95 ... Outer cylinder connection fitting 97 ... Grommet 100 ... First insulating spacer 102 ... Spacer intermediate portion 105 ... Heater 110 ... First 2 Insulating spacer 111 ... Tip portion 120 ... Sensor element 120k ... Element base end portion 121 ... Insulating member 122 ... Ceramic layer 123 ... Ceramic layer 124 ... Ceramic layer 124a ... Main surface 124b ... Main surface 125 ... Insulating coating layer 126 ... Insulating coating Layer 126c ... Through hole 130 ... Discharge electrode body 131 ... Needle-shaped electrode part 131k ... Base end part 131s ... Ion generation DESCRIPTION OF SYMBOLS 133 ... Lead part 135 ... Discharge potential pad 140 ... Auxiliary electrode body 141 ... Auxiliary electrode part 143 ... Lead part 143k ... Base end part 145 ... Conduction pattern 146 ... Through-hole conductor 147 ... Auxiliary potential pad 150 ... Element heater 151 ... Heat generation Resistor 152 ... Heater lead portion 152k ... Base end portion 153 ... Heater lead portion 153k ... Base end portion 155 ... Through hole conductor 156 ... 2-1 heater pad 157 ... Through hole conductor 158 ... 2-2 heater pad 161 ... Electric wire 161g1 ... inner outer conductor 161g2 ... outer outer conductor 162 ... discharge potential lead wire 163 ... electric wire 164 ... auxiliary potential lead wire 171 ... electric wire 172 ... 1-1 heater lead wire 173 ... electric wire 175 ... electric wire 176 ... second 2-2 Heater lead wire 300 ... Particle sensor 300A ... Particle sensor 300e ... tip part 310 ... sensor drive part 311 ... sensor control part 312 ... electric circuit part 320 ... cable 330 ... sensor system 400 ... internal combustion engine 410 ... fuel supply part 411 ... fuel pipe 415 ... exhaust gas pipe 416 ... filter device 420 ... Vehicle control unit 500 ... vehicle BO ... boss D1 ... distance D2 ... distance PI ... positive ion S ... 煤

Claims (4)

A fine particle sensor for detecting fine particles in a gas to be measured,
A sensor element extending along the axial direction, the sensor element having an ion generating part for generating ions on the tip side;
A first casing covering the ion generator,
The first casing is
A first inflow hole through which the measurement gas flows;
An outflow hole which is located on the tip side of the first inflow hole and through which the gas to be measured flows out;
A protrusion projecting inside the first casing,
The distance between the protrusion and the ion generator is smaller than the distance between the ion generator and the first casing,
In the axial direction, the base of the protruding portion is disposed closer to the tip side than the first inflow hole. The fine particle sensor according to claim 1,
The fine particle sensor, wherein the protrusion is formed by bending a part of the first casing inward. The fine particle sensor according to claim 1 or 2,
The fine particle sensor, wherein a base of the protruding portion is disposed on a tip side in the axial direction with respect to a tip of the protruding portion. In the particulate sensor according to any one of claims 1 to 3,
And a second casing that covers at least a part of the outer periphery of the first casing through a space,
The second casing includes a second inflow hole through which the gas to be measured flows,
In the axial direction, the second inflow hole is disposed on the front end side of the first inflow hole, and the fine particle sensor.

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