JP6010470B2 - Gas sensor - Google Patents

Description

  The present invention relates to a gas sensor that is mounted on, for example, a motorcycle (motorcycle) or the like and detects the concentration of a specific gas, such as oxygen gas, in exhaust gas discharged from the internal combustion engine (engine).

2. Description of the Related Art Conventionally, a gas sensor that is mounted on, for example, a motorcycle (motorcycle) and detects the concentration of a specific gas, for example, oxygen gas, in exhaust gas discharged from the internal combustion engine (engine) is known. In such a gas sensor, for example, a solid electrolyte body made of ZrO ₂ or the like in which Y ₂ O ₃ or CaO is dissolved is used as a gas sensor element for detecting a gas concentration. Needs to heat the gas sensor element to a predetermined temperature or higher. For this reason, many heaters for heating the gas sensor element are used, but a heaterless gas sensor that does not include a heater for cost reduction and heats the gas sensor element until it reaches a detectable temperature by exhaust gas is also available. (For example, refer to Patent Document 1).

  As described in Patent Document 1, the gas sensor has a gas detection part (tip side) of the gas sensor element in a state of protruding, a casing that holds the gas sensor element, and a gas detection part of the gas sensor element that is fixed to the casing. Is generally covered with a protector.

JP 2010-261880 A

  As described above, in the heaterless gas sensor that does not include the heater, the gas sensor element is heated by the heat of the exhaust gas exhausted from the internal combustion engine (engine). Therefore, the gas concentration is higher than that of the gas sensor that includes the heater. It takes a relatively long time until it can be detected, and it is desired to reduce this time.

  The present invention has been made in response to the above-described conventional circumstances, and an object of the present invention is to provide a gas sensor capable of starting detection of a gas concentration in a relatively short time in a heaterless gas sensor.

One aspect of the gas sensor of the present invention includes an element main body made of a bottomed cylindrical solid electrolyte body that extends in the axial direction and whose front end is blocked, and an inner electrode and an outer electrode provided inside and outside the element main body. A gas detection element comprising: a cylindrical casing that holds the gas detection element in a through-hole penetrating in the axial direction in a state in which a tip portion of the gas detection element protrudes; and A gas sensor that is disposed and includes a protector surrounding the tip of the gas detection element and does not include a heater for heating, the protector comprising a single cylindrical body having a side wall and a bottom; The side wall portion of the cylindrical body has a front end side in the axial direction and a plurality of front end openings disposed along the circumferential direction, a rear end side in the axial direction with respect to the front end opening, and a peripheral side. along the direction Separately from said distal end opening, provided with a plurality disposed a rear end opening, the rear end opening, the first rear end opening area larger than the respective opening area of the front end side opening as well as have the open, the protector is configured to engage the casing in the through hole, it extends between the outer peripheral surface of the distal end side inner surface and the gas detecting element of the casing, said first A part of the rear end side opening is disposed so as to enter the inside of the casing .

  The gas sensor of the present invention includes a first rear end having an opening area larger than each opening area of the front end side opening at a rear end side opening provided in a side wall portion of a protector surrounding the bottomed cylindrical gas detection element. The side opening is used. The exhaust gas passing through the front end opening provided on the front end side in the axial direction of the protector and the exhaust gas passing through the rear end opening provided in the rear end side in the axial direction relative to the front end opening are The exhaust gas that passes through has a higher temperature. This is because the exhaust gas passing through the inside of the flow path passes through the opening on the front end side so that the front end side of the gas sensor is disposed inside the flow path through which the exhaust gas flows. On the other hand, by providing the first rear end opening having a relatively large opening area in the rear end opening, the capacity of the exhaust gas exposed to the gas detection element can be increased. As a result, even when the temperature of the exhaust gas passing through the first rear end side opening is low, the amount of heat applied to the gas detection element can be increased, and the gas detection element can be heated satisfactorily.

  In addition, in the bottomed cylindrical gas detection element, the volume of the part facing the rear end side opening (hereinafter referred to as the rear end side part) is often larger than the volume of the part facing the front end side opening. Therefore, by providing the first rear end side opening at the rear end side opening, the capacity of the exhaust gas passing through the first rear end side opening can be increased, and the exhaust gas in contact with the rear end side portion of the gas detection element. The gas capacity can be increased. Therefore, even at the rear end side portion of the gas detection element having a large volume, the amount of heat applied to the gas detection element can be increased, and the gas detection element can be heated satisfactorily.

  Note that by exposing the entire tip of the gas detection element to the outside without providing a protector, the amount of heat to the gas detection element can be increased more than when the gas detection element is covered with a protector. It seems that the gas detection element can be heated well. However, the exhaust gas flows in a fixed direction through the flow path of the exhaust gas (that is, it flows from the upstream side toward the downstream side). For this reason, in the case of a gas detection element with the entire tip exposed to the outside, the exhaust gas can be exposed to the gas detection element at the part facing the upstream side, and the amount of heat of the exhaust gas can be increased, but the downstream side In the portion facing, the exhaust gas cannot be exposed to the gas detection element, and the amount of heat of most exhaust gas cannot be obtained. Therefore, it is difficult to increase the amount of heat of the entire gas detection element. On the other hand, the front end side of the gas detection element is covered with a protector, and a plurality of front end side openings and rear end side openings are provided along the circumferential direction on the side wall portion, so that the gas detection element enters the protector from the upstream side. The exhaust gas is circulated to the downstream side in the protector, and the detection part of the gas detection element can be entirely heated by the exhaust gas from the circumferential direction. As a result, the temperature of the detection part of the gas detection element can be increased by the exhaust gas in a shorter time, and detection of the gas concentration can be started in a shorter time.

  Further, by providing a single opening by connecting the front end opening and the rear end opening of the protector, the capacity of the exhaust gas passing through the opening can be increased, and the amount of heat applied to the gas detection element is further increased. It seems that the gas detection element can be heated well. However, even with a protector having such an opening, it is difficult to go around to the downstream side in the protector, and it is difficult to expose the exhaust gas to the gas detection element at a portion facing the downstream side. On the other hand, by disposing the front end opening and the rear end opening separately in the protector, the exhaust gas that has entered the protector from the upstream side travels to the downstream side in the protector and is detected by the gas detection element. It becomes possible to heat the part entirely from the circumferential direction by the exhaust gas. As a result, the temperature of the detection part of the gas detection element can be increased by the exhaust gas in a shorter time, and detection of the gas concentration can be started in a shorter time.

  The front end side opening and the rear end side opening are such that the front end side opening is provided on the front end side in the axial direction of the side wall portion compared to the rear end side opening, and the rear end side opening is the side wall portion compared to the front end side opening. As long as it is provided on the rear end side in the axial direction, the side wall portion may have an opening in addition to the front end side opening and the rear end side opening. In addition, the first rear end side opening may be one or a plurality of the rear end side openings, but a plurality of the first rear end side openings are preferably provided.

  Further, when the protector is viewed in the radial direction perpendicular to the axial direction, it is preferable that the distal end portion of the gas detection element is exposed in the distal end side opening and the first rear end side opening. Thereby, the exhaust gas which passes through each of the front end side opening and the first rear end side opening can be efficiently exposed to the gas detection element. As a result, the amount of heat applied to the gas detection element can be increased efficiently, and the gas detection element can be efficiently heated.

  Moreover, it is preferable that the total opening area of the rear end side opening is larger than the total opening area of the front end side opening. Thereby, the amount of heat applied to the gas detection element can be further increased, and the gas detection element can be heated more favorably.

  The first rear end side opening is preferably formed in a long hole shape having a major axis in the direction along the axial direction, for example. Thereby, more first rear end side openings can be formed along the circumferential direction, and the capacity of the exhaust gas passing through the first rear end side opening due to the influence of the gas sensor mounting direction (circumferential direction) can be reduced. Variations can be suppressed.

  When the first rear end side opening is formed in the shape of a long hole whose major axis is the direction along the axial direction, the long axis length of the first rear end side opening is the tip of the gas detection element. It is preferably 50% or more of the axial length of the portion. Thereby, the capacity | capacitance of the exhaust gas which passes the 1st rear end side opening and is exposed to a gas detection element can be increased. As a result, even if the temperature of the exhaust gas passing through the first rear end side opening is low and the volume of the rear end side portion of the gas detection element is large, the amount of heat applied to the gas detection element can be increased, and the gas detection The element can be heated satisfactorily.

  Moreover, it is preferable that the said 1st rear end side opening is formed in the elongate hole shape which makes the direction along the circumferential direction of a protector a long axis, for example. Thereby, when the first rear end side opening is directed to the upstream side of the flow path, more exhaust gas can pass through the first rear end side opening. As a result, the gas detection element can be heated satisfactorily.

  In addition, when the 1st rear end side opening is formed in the long hole shape which makes the direction along the circumferential direction of a protector a long axis, the long-axis length of the 1st rear end side opening is 1st back It is preferable that it is larger than the maximum width of the part of the gas detection element corresponding to the end side opening. Thereby, the capacity | capacitance of the exhaust gas which passes the 1st rear end side opening and is exposed to a gas detection element can be increased. As a result, even if the temperature of the exhaust gas passing through the first rear end side opening is low and the volume of the rear end side portion of the gas detection element is large, the amount of heat applied to the gas detection element can be increased, and the gas detection The element can be heated satisfactorily.

  Moreover, the said front end side opening can be made into circular shape etc., for example. Moreover, it is preferable that a plurality of the first rear end side openings are arranged at equal intervals along the circumferential direction of the protector. Thereby, the capacity | capacitance of the exhaust gas which contacts a gas detection element can be increased over the circumferential direction of a protector. As a result, the amount of heat to the gas detection element can be further increased, and the gas detection element can be further heated.

  The protector engages with the casing in the through hole, and extends between the front end side inner surface of the casing and the outer peripheral surface of the gas detection element, and a part of the first rear end side opening is It is preferable to be disposed so as to enter the inside of the casing. As a result, the entire gas detection element exposed from the casing can be satisfactorily exposed to the exhaust gas, and the gas detection element can be heated even better.

  Furthermore, when the gas sensor is attached to the flow path, the front end side opening and the first rear end side opening are preferably provided on at least a part of the side wall portion of the protector facing the upstream side of the flow path. Thereby, the exhaust gas flowing through the flow path can be efficiently passed through each of the front end side opening and the first rear end side opening. As a result, the amount of heat applied to the gas detection element can be increased efficiently, and the gas detection element can be efficiently heated. A part of the front end side opening and the first rear end side opening may be provided on a side wall portion of the protector facing upstream, and the front end side opening and the first rear end side opening as a whole face upstream. It may be provided on the side wall of

  ADVANTAGE OF THE INVENTION According to this invention, in a heaterless gas sensor, the gas sensor which can start the detection of gas concentration in a comparatively short time can be provided.

The figure which shows the longitudinal cross-sectional structure of the gas sensor which concerns on 1st Embodiment of this invention. The figure which shows the structure of the gas detection element of the gas sensor of FIG. The figure which shows the principal part structure of the gas sensor of FIG. The figure which shows the principal part structure of the gas sensor of FIG. The figure which shows the longitudinal cross-sectional structure of the gas sensor which concerns on 2nd Embodiment of this invention. The figure which shows the principal part structure of the gas sensor of FIG. The figure which shows the principal part structure of the gas sensor of FIG. The graph which shows the example of a sensor output waveform. The graph which shows the measurement result of light-off time. The graph which shows a temperature measurement result. The figure for demonstrating a temperature measurement location.

  Embodiments of the present invention will be described below with reference to the drawings.

  In the following description, in the direction along the axis O, the side on which the protector 15 is attached will be referred to as the front end side, and the opposite side will be described as the rear end side.

  As shown in FIG. 1, the gas sensor 1 of the first embodiment includes a gas detection element 3, a separator 5, a closing member 7, a terminal fitting 9, a lead wire 11, and a metal shell 13 so as to cover the periphery thereof. , A protector 15, an outer cylinder 17, a protective outer cylinder 19 and the like. A casing 20 is constituted by the metal shell 13 and the outer cylinder 17.

  The gas sensor 1 is a so-called heater-less sensor that does not include a heater for heating the gas detection element 3, and activates the gas detection element 3 using the heat of exhaust gas to measure the oxygen concentration. Is.

  As shown in FIG. 2, in the configuration of the gas sensor 1, the gas detection element 3 is made of a solid electrolyte having oxygen ion conductivity, and has a cylindrical shape extending in the direction of the axis O with a bottom having a closed end 25. An element body 21 is provided. On the outer periphery of the element body 21, a flange portion 23 projecting radially outward is provided.

As the solid electrolyte constituting the element body 21, for example, ZrO _{2 in} which Y ₂ O ₃ or CaO is dissolved is representative, but other alkaline earth metal or rare earth metal oxides and ZrO 2 are used. A solid solution with ₂ may be used. Furthermore, HfO ₂ may be contained therein.

  An outer electrode 27 is formed on the outer peripheral surface of the element main body 21 at a part of the distal end portion 25 of the gas detection element 3. The outer electrode 27 is made of porous Pt or Pt alloy. A vertical lead portion 29 made of Pt or the like is formed so as to extend from the outer electrode 27 to the rear end side in the axial direction, and the vertical lead portion 29 is formed on the lower surface side (lower side in FIG. 2) of the flange portion 23. ) Is connected to an annular lead portion 31 made of Pt or the like formed in an annular shape. On the other hand, an inner electrode 33 is formed on the inner peripheral surface of the element body 21. This inner electrode 33 is also formed by forming Pt or a Pt alloy in a porous manner.

  Returning to FIG. 1, the separator 5 is a cylindrical member made of alumina or the like having electrical insulation, and a through hole 35 through which the lead wire 11 is inserted is formed at the center of the axis.

  The closing member 7 is a cylindrical sealing member made of, for example, fluoro rubber, and a through hole 37 into which the lead wire 11 is inserted is formed at the center of the shaft. The front end surface 95 of the closing member 7 is in close contact with the rear end surface 97 of the separator 5, and the outer periphery on the rear end side thereof is in close contact with the inner peripheral surface of the outer cylinder 17 and the inner peripheral surface of the protective outer cylinder 19. The inside and outside are separated. That is, the rear end side of the casing 20 is closed by the closing member 7.

  The terminal fitting 9 is made of, for example, Inconel 750 (British Inconel, trade name) or the like, and is a substantially cylindrical member for taking out the sensor output to the outside. The terminal fitting 9 is connected to the lead wire 11 and is configured to contact the inner electrode 33 (see FIG. 2) of the gas detection element 3.

  The metal shell 13 is a cylindrical member made of, for example, SUS430. In order to support the flange 23 of the gas detection element 3, the metal shell 13 is provided with a stepped portion 39 projecting radially inward from the inner peripheral surface. Then, by supporting the flange portion 23 of the gas detection element 3 on the stepped portion 39, the distal end portion 25 of the gas detection element 3 protrudes from the metal shell 13 toward the distal end side.

  Further, a screw part 41 for attaching the gas sensor 1 to the exhaust pipe is formed on the outer peripheral surface on the front end side of the metal shell 13, and the screw part 41 is attached to the exhaust pipe on the rear end side of the screw part 41. A hexagonal portion 43 is provided around which a mounting tool for screwing is engaged. Further, a cylindrical portion 45 is provided on the rear end side of the hexagonal portion 43 of the metal shell 13.

  As shown in FIG. 1, a ceramic powder 47 made of talc and a ceramic sleeve 49 made of alumina are disposed between the metal shell 13 and the gas detection element 3 from the front end side. Further, a distal end portion 55 of the outer cylinder 17 made of, for example, SUS304L is disposed inside the rear end portion 51 of the tubular portion 45 of the metal shell 13 through a metal ring 53 made of, for example, SUS430. The front end portion 55 is caulked at the rear end portion 51 of the cylindrical portion 45, whereby the outer cylinder 17 is fixed to the metal shell 13.

  Further, a cylindrical filter 57 made of, for example, PTFE is fitted on the outer circumference of the outer cylinder 17, and a protective outer cylinder 19 made of, for example, SUS304L is fitted on the outer circumference of the filter 57. The filter 57 can be ventilated but can prevent moisture from entering.

  The outer cylinder 17, the filter 57, and the protective outer cylinder 19 are integrally fixed by crimping from the outer peripheral side of the protective outer cylinder 19. Since the outer cylinder 17 and the protective outer cylinder 19 are provided with vent holes 59 and 61, respectively, the inside and outside of the gas sensor 1 can be ventilated through the vent holes 59 and 61 and the filter 57. is there.

  The terminal fitting 9 is fitted in the internal space 63 of the gas detection element 3 to contact the inner electrode 33, and the tip of the lead wire 11 is connected and fixed in the internal space 63. The lead wire 11 includes a core wire 65 and a covering portion 67 that covers the outer periphery of the core wire 65.

  As shown in FIG. 4, the terminal fitting 9 is obtained by processing a single metal plate, and is in close contact with the inner electrode 33 and has an electrode contact portion 69 having a substantially vertical C-shaped cross section in the axial direction. A first fixing portion 71 provided on the distal end side of the electrode contact portion 69 to grip and fix the covering portion 67 of the lead wire 11 from the outside, and provided on the distal end side of the first fixing portion 71 to grip the core wire 65. And a plurality of second fixing portions 73 to be fixed. A plurality of flange pieces 75 are formed on the rear end side of the terminal fitting 9 and are in contact with the rear end face of the gas detection element 3.

  Next, the protector 15 which is the main part of the present invention will be described. The protector 15 is made of a metal such as SUS310S, and is a protective member that covers the distal end side of the gas detection element 3. The protector 15 extends to the rear end side, and is fixed so that the rear end edge 16 is sandwiched between the flange portion 23 of the gas detection element 3 and the step portion 39 of the metal shell 13.

As shown in FIG. 3, the protector 15 is composed of a single cylindrical body having a side wall portion 150 and a bottom portion 151, and the side wall portion 150 is disposed at the front end side in the axis O direction and is arranged along the circumferential direction of the protector 15. A plurality of front-end openings 152 (six in this embodiment) provided, and a plurality of rear-ends disposed on the rear end side in the axis O direction from the front-end openings 152 and disposed along the circumferential direction of the protector 15 Side openings 153 (six in this embodiment) are provided. In this embodiment, since the opening area of the front end side opening 152 is about 3 mm ² and the opening area of the rear end side opening 153 is about 7 mm ² , all of the rear end side openings 153 are each of the front end side openings 152. The opening area is larger than the opening area. That is, in the present embodiment, all of the rear end side openings 153 are the first rear end side openings 153. In the first embodiment, the front end side opening 152 has a circular shape, and the rear end side opening 153 has a long hole shape with the direction along the axis O direction as the long axis. Further, the rear end side opening 153 has a part on the rear end side so as to enter the inside of the metal shell 13 (casing 20), that is, the rear end of the rear end side opening 153 is the metal shell 13 (casing 20). It is formed so that it may be located in the back end side rather than the front-end | tip.

  By using the protector 15 configured as described above, it is possible to increase the capacity of the exhaust gas exposed to the rear end side portion of the gas detection element corresponding to the first rear end opening 153. As a result, even if the temperature of the exhaust gas passing through the first rear end side opening 153 is low, the amount of heat applied to the gas detection element 3 can be increased, and the gas detection element 3 can be heated satisfactorily.

  Further, by using the protector 15 having the above-described configuration, the capacity of the exhaust gas passing through the first rear end side opening 153 can be increased, and the rear end of the gas detection element 3 corresponding to the first rear end side opening 153. The capacity of the exhaust gas that contacts the side portion can be increased. Therefore, even in the rear end side portion of the gas detection element 3 having a larger volume than the front end side portion, the amount of heat applied to the gas detection element 3 can be increased, and the gas detection element 3 can be heated favorably.

  Further, by using the protector 15 having the above-described configuration, the exhaust gas that has entered the protector 15 from the upstream side travels to the downstream side in the protector 15, and the detection unit of the gas detection element 3 is entirely moved from the circumferential direction. It becomes possible to heat with exhaust gas. As a result, the temperature of the detection part of the gas detection element 3 can be increased by the exhaust gas in a shorter time, and detection of the gas concentration can be started in a shorter time.

  In addition, since a part of the first rear end opening 153 is disposed so as to enter the inside of the metal shell 13 (casing 20), the entire gas detection element exposed from the casing is good for exhaust gas. And the gas detection element 3 can be heated more satisfactorily.

  As shown in FIG. 3, the distal end portion 25 of the gas detection element 3 is exposed to the distal end side opening 152 and the first rear end side opening 153. In other words, this means that the front end portion 25 of the gas detection element 3 can be seen when the insides of the front end side opening 152 and the first rear end side opening 153 are visually recognized. Thereby, the exhaust gas passing through each of the front end side opening 152 and the first rear end side opening 153 can be efficiently exposed to the gas detection element 3. As a result, the amount of heat applied to the gas detection element 3 can be increased efficiently, and the gas detection element 3 can be efficiently heated.

Further, the total opening area of the first rear end side opening 153 is 42 mm ² (about 7 mm ² × 6 pieces), and is larger than the total opening area of the front end side opening 152 of about 18 mm ² (about 3 mm ² × 6 pieces). Is preferred. Thereby, the amount of heat applied to the gas detection element 3 can be further increased, and the gas detection element 3 can be heated more favorably.

  Further, since the first rear end side opening 153 is formed in the shape of a long hole whose major axis is the direction along the axial direction, the first rear end side opening 153 can be easily formed along the circumferential direction. In addition, it is possible to suppress variation in the volume of exhaust gas passing through the first rear end opening 153 due to the influence of the mounting direction (circumferential direction) of the gas sensor 1.

  Further, as shown in FIG. 3, the major axis length L1 of the first rear end opening 153 is 70% of the axial length L2 of the distal end portion 25 of the gas detection element 3, and is 50% or more. Yes. Thereby, the capacity | capacitance of the exhaust gas which passes the 1st rear end side opening 153 and is exposed to the gas detection element 3 can be increased. As a result, even if the temperature of the exhaust gas passing through the first rear end side opening 153 is low and the volume of the rear end side portion of the gas detection element 3 is large, the amount of heat applied to the gas detection element 3 can be increased. The gas detection element 3 can be heated satisfactorily.

  Further, the front end side opening 152 and the first rear end side opening 153 are arranged at equal intervals along the circumferential direction of the protector 15. Therefore, when the gas sensor 1 is attached to the exhaust pipe, the front end side opening 152 and the first rear end side opening 153 are provided on the side wall 150 of the protector 15 facing the upstream side of the exhaust pipe. Thereby, the exhaust gas flowing through the exhaust pipe can be efficiently passed through the front end side opening 152 and the first rear end side opening 153. As a result, the amount of heat applied to the gas detection element 3 can be increased efficiently, and the gas detection element 3 can be efficiently heated.

  In the protector 15, at least a part of the rear end openings 153 among the plurality of rear end openings 153 has a first rear end opening 153 having an opening area larger than that of the front end opening 152. The shape may be other than the shape shown in FIG. Further, the bottom portion 151 of the protector 15 does not need to cover the entire bottom surface, and may have a configuration having an opening on the bottom surface.

  Next, a manufacturing procedure of the gas sensor 1 of the first embodiment will be briefly described. As shown in FIG. 1, the protector 15 is pushed into the through hole 87 of the metal shell 13 from above in the figure.

Next, the gas detection element 3 is inserted into the through hole 87 of the metal shell 13.
Next, the ceramic powder 47 and the ceramic sleeve 49 are disposed in the space between the metal shell 13 and the gas detection element 3.

  Next, the distal end portion 55 of the outer cylinder 17 whose distal end side expands in the radial direction is disposed thereon, and the metal ring 53 is fitted on the distal end portion 55 of the outer cylinder 17. In this state, the outer end 17 is fixed via the metal ring 53 by caulking the rear end portion 51 of the metallic shell 13. Thereafter, the filter 57 is fitted on the outer periphery of the outer cylinder 17.

  Separately from this, as shown in FIG. 4, the lead wire 11 is passed through the through hole 35 of the separator 5, the through hole 37 of the closing member 7, and the through hole 89 of the protective outer cylinder 19, and a terminal is connected to the tip of the lead wire 11. The metal fitting 9 is fixed, and the composite member 91 is created.

  As shown in FIG. 1, the tip of the terminal fitting 9 of the composite member 91 is inserted into the internal space 63 of the gas detection element 3 so that the terminal fitting 9 and the inner electrode 33 are brought into contact with each other. At this time, the plurality of flange pieces 75 formed on the rear end side of the terminal fitting 9 are brought into contact with the rear end face of the gas detection element 3, whereby the terminal fitting 9 is positioned.

  At the same time, the separator 5, the closing member 7, and the protective outer cylinder 19 are pressed toward the distal end side, and a part of the separator 5 and the closing member 7 is disposed in the outer cylinder 17, and Fit.

  Thereafter, the protective outer cylinder 19 and the outer cylinder 17 are integrally fixed by caulking from the outer peripheral side of the protective outer cylinder 19. Thereby, the gas sensor 1 is completed.

  Next, the gas sensor which concerns on 2nd Embodiment is demonstrated with reference to FIGS. As shown in FIG. 5, the gas sensor unit 300 is used by being attached to an exhaust path H of an automobile. Hereinafter, in the direction of the axis O, the side (lower side in FIG. 5) inserted into the exhaust path H of the gas sensor unit 300 is defined as the front end side of the gas sensor unit 300, and the opposite side (upper side in FIG. 5). Is described as the rear end side.

  As shown in FIG. 5, the gas sensor unit 300 includes a gas sensor main body 100 and a sensor cap 200 that is detachably attached to the gas sensor main body 100 on the rear end side of the gas sensor main body 100. The gas sensor main body 100 includes a gas detection element 110 that is exposed to exhaust gas and outputs a detection signal corresponding to the oxygen concentration in the exhaust gas. The sensor cap 200 is attached to the gas sensor main body 100, and a cap terminal 210 provided in the sensor cap 200 is electrically connected to the gas detection element 110, and an output signal output from the gas detection element 110 is output to an external device (for example, an engine control). Unit (ECU)).

  First, the structure of the gas sensor main body 100 will be described with reference to FIG. The gas sensor main body 100 has a structure in which a cylindrical gas detection element 110 whose front end is closed is disposed in a housing 162. A connection terminal 171 for taking out a signal output from the gas detection element 110 is fitted inside the rear end of the gas detection element 110. A cylindrical ceramic enclosure 164 is provided so as to surround the outer periphery of the connection terminal 171. The ceramic enclosure 164 surrounds the connection terminal 171 together with the outer peripheral portion on the rear end side of the gas detection element 110. A cap terminal 210 (see FIG. 5) described later is connected to the connection terminal 171.

  The housing 162 has a metal shell 121 and a protector 122. The metal shell 121 is made of, for example, SUS430 or the like, and is formed in a substantially cylindrical shape. A screw portion 124 for attaching the gas sensor main body 100 to the exhaust path H is formed on the outer peripheral surface of the front end portion of the metal shell 121. On the rear end side of the screw portion 124, an attachment portion 129 for engaging with a mounting tool for screwing the screw portion 124 into the exhaust path H is provided.

  Moreover, the cylindrical hole of the metal shell 121 has a three-stage uneven shape, and the distal end portion is formed as a distal cylindrical hole 128 having a minimum inner diameter. The rear end portion of the cylinder hole is formed as a rear end cylinder hole 125 having the maximum inner diameter, and an intermediate cylinder having an intermediate inner diameter between the front end cylinder hole 128 and the rear end cylinder hole 125. A hole 127 is formed.

  The rear end cylindrical hole 125 is disposed at a position surrounding the outer periphery of the front end portion 141 of the ceramic enclosure 164. Further, the step portion between the rear end cylindrical hole 125 and the intermediate cylindrical hole 127 is configured as a filler receiving portion 126, and the inner periphery of the cylindrical hole extending from the filler receiving portion 126 to the rear end cylindrical hole 125; A filler 102 is filled in a gap with the outer periphery of the gas detection element 110.

  The intermediate cylinder hole 127 is formed at a position where a later-described flange portion 112 of the gas detection element 110 is disposed. A step portion between the intermediate tube hole 127 and the tip tube hole 128 is configured as a flange receiving portion 123. The collar portion 112 of the gas detection element 110 is supported by the collar receiving portion 123. The distal end cylindrical hole 128 is formed at a position surrounding the gas detection element 110.

  A protector 122 is attached to the tip of the metal shell 121. The protector 122 has a bottomed cylindrical shape, and covers and protects a detection unit 111 (corresponding to a distal end portion of claims), which will be described later, of the gas detection element 110 exposed from the metal shell 121. The protector 122 has an opening for introducing the exhaust gas in the exhaust path H into the protector 122 and bringing it into contact with the gas detection element 110.

  As shown in FIG. 6, the gas detection element 110 held inside the housing 162 has a bottomed cylindrical shape with a closed tip, and a solid electrolyte mainly composed of zirconia is used as the base 113. On the outer periphery of the gas detection element 110, a flange portion 112 protruding outward in the radial direction is provided. The gas detection element 110 is in a state where a metal packing 101 is interposed between a surface facing the distal end side of the flange portion 112 (hereinafter referred to as “front end facing surface”) and the flange receiving portion 123 of the metal shell 121. Thus, it is arranged in the metal shell 121.

  The detection unit 111 is disposed on the front end side of the gas detection element 110 with respect to the flange portion 112, and the rear end side of the gas detection portion 112 is configured as a rear end portion 115. The detection unit 111 is exposed from the metal shell 121 and exposed to the exhaust gas, and detects the oxygen concentration in the exhaust gas. The rear end 115 extends in a cylindrical shape with substantially the same outer diameter. A detection electrode (outer electrode) 151 formed by plating Pt or a Pt alloy is provided on the outer peripheral surface of the detection unit 111. The detection electrode 151 is electrically connected to the tip-facing surface of the flange portion 112, and is further electrically connected to the metal shell 121 via the metal packing 101. Therefore, the potential of the detection electrode 151 can be taken out from the metal shell 121. The surface of the detection unit 111 is covered with a porous electrode protection layer (not shown) made of heat-resistant ceramic.

  A reference electrode (inner electrode) 155 is provided on the inner peripheral side of the base 113 so as to cover the inner peripheral surface. The reference electrode 155 is formed by plating the entire inner peripheral surface of the gas detection element 110 with Pt or a Pt alloy. The reference electrode 155 and the detection electrode 151 are disposed at positions corresponding to each other with the base 113 that is a solid electrolyte body interposed therebetween, and this portion functions as a gas detection unit that detects the oxygen concentration in the exhaust gas. .

  Further, the filler 102 made of ceramic powder is between the outer peripheral surface of the rear end portion 115 of the gas detection element 110 and the inner peripheral surface of the metal shell 121 from the filler receiving portion 126 to the rear end cylindrical hole 125. Filled.

  The ceramic enclosure 164 described above is disposed on the rear end side of the filler 102. The ceramic enclosure 164 is formed in a cylindrical shape from an insulating ceramic, and the tip portion 141 of the ceramic enclosure 164 protrudes outward in the radial direction. The front end portion 141 is disposed between the outer peripheral surface of the rear end portion 115 of the gas detection element 110 and the inner peripheral surface of the rear end cylindrical hole 125 so as to be interposed at the rear end position of the filler 102. . The packing 104 is disposed on the surface facing the rear end of the front end 141, and the front end 141 is filled via the packing 104 by caulking the portion 131 formed at the rear end of the metal shell 121 toward the front end. It is pressed against the material 102. As a result, the gap between the inner peripheral surface of the metal shell 121 and the outer peripheral surface of the gas detection element 110 is hermetically filled with the filler 102. In this way, the gas detection element 110 is held inside the metal shell 121 via each member sandwiched between the flange receiving portion 123 and the caulking portion 131.

  Further, a connection terminal 171 is inserted on the rear end side in the cylindrical hole of the gas detection element 110. The connection terminal 171 has a substantially cylindrical shape, an electrode contact portion 172 connected to the reference electrode 155 is provided on the front end side, and a cap connection portion 173 connected to a cap terminal 210 (described later) is formed on the rear end side. .

Next, the protector 122 which is the main part of the present invention will be described. As shown in FIG. 7, the protector 122 is composed of a single cylindrical body having a side wall portion 450 and a bottom portion 451, and the side wall portion 450 is disposed at the front end side in the axis O direction and is arranged along the circumferential direction of the protector 122. A plurality of front end openings 452 (six in the present embodiment) provided, and a plurality of rear ends disposed on the rear end side in the axis O direction from the front end openings 452 and disposed along the circumferential direction of the protector 122 Side openings 453 (three in this embodiment) are provided. In this embodiment, since the opening area of the front end side opening 452 is about 3 mm ² and the opening area of the rear end side opening 453 is about 9 mm ² , all of the rear end side openings 453 are each of the front end side openings 452. The opening area is larger than the opening area. That is, in the present embodiment, all of the rear end side openings 453 are the first rear end side openings 453. In the second embodiment, the front end side opening 452 has a circular shape, and the rear end side opening 453 has a long hole shape whose major axis is a direction along the circumferential direction orthogonal to the axis O direction. In addition, the bottom 451 has an opening 454.

  By using the protector 122 configured as described above, it is possible to increase the capacity of the exhaust gas exposed to the rear end portion of the gas detection element corresponding to the first rear end opening 453. As a result, even if the temperature of the exhaust gas passing through the first rear end side opening 453 is low, the amount of heat applied to the gas detection element 110 can be increased, and the gas detection element 110 can be heated favorably.

  Further, by using the protector 122 having the above-described configuration, the capacity of exhaust gas passing through the first rear end side opening 453 can be increased, and the rear end of the gas detection element 110 corresponding to the first rear end side opening 453. The capacity of the exhaust gas that contacts the side portion can be increased. Therefore, even in the rear end portion of the gas detection element 110 having a larger volume than the front end portion, the amount of heat applied to the gas detection element 110 can be increased and the gas detection element 110 can be heated satisfactorily.

  Further, by using the protector 122 having the above-described configuration, the exhaust gas that has entered the protector 122 from the upstream side travels to the downstream side in the protector 122, and the detection unit of the gas detection element 110 is entirely moved from the circumferential direction. It becomes possible to heat with exhaust gas. As a result, the temperature of the detection part of the gas detection element 110 can be raised by the exhaust gas in a shorter time, and the detection of the gas concentration can be started in a shorter time.

  As shown in FIG. 7, the detection unit 111 of the gas detection element 110 is exposed to the front end side opening 452 and the first rear end side opening 453. In other words, this means that the detection unit 111 of the gas detection element 110 can be seen when the insides of the front end side opening 452 and the first rear end side opening 453 are visually recognized. Thereby, the exhaust gas passing through each of the front end side opening 452 and the first rear end side opening 453 can be efficiently exposed to the gas detection element 110. As a result, the amount of heat applied to the gas detection element 110 can be increased efficiently, and the gas detection element 110 can be efficiently heated.

Further, the total opening area of the first rear end side opening 453 is about 27 mm ² (about 9 mm ² × 3 pieces), which is larger than the total opening area of the front end side opening 452 of about 18 mm ² (about 3 mm ² × 6 pieces). It is preferable. Thereby, the amount of heat applied to the gas detection element 110 can be increased, and the gas detection element 110 can be heated more favorably.

  Further, when the first rear end side opening 453 is formed in the shape of a long hole whose major axis is the direction orthogonal to the axial direction, the first rear end side opening 453 is directed to the upstream side of the exhaust path H. In addition, more exhaust gas can pass through the first rear end opening 453. As a result, the gas detection element 110 can be heated satisfactorily.

  Further, as shown in FIG. 7, the major axis length L3 of the first rear end side opening 453 is larger than the maximum width L4 of the portion of the detection unit 111 of the gas detection element 110 corresponding to the first rear end side opening 453. It is getting bigger. That is, as shown in FIG. 7, when the inside of the opening of the first rear end side opening 453 is visually recognized, all the parts in the width direction of the detection unit 111 can be visually recognized in the first rear end side opening 453. Thereby, the capacity of the exhaust gas that passes through the first rear end side opening 453 and is exposed to the gas detection element 110 can be increased. As a result, even if the temperature of the exhaust gas passing through the first rear end side opening 453 is low and the volume of the rear end side portion of the gas detection element 110 is large, the amount of heat applied to the gas detection element 110 can be increased. The gas detection element 110 can be heated satisfactorily.

  In addition, the front end side opening 452 and the first rear end side opening 453 are arranged at equal intervals along the circumferential direction of the protector 122. Therefore, when the gas sensor unit 300 is attached to the exhaust path H, the front end side opening 452 and the first rear end side opening 453 are provided on the side wall portion 450 of the protector 122 facing the upstream side of the exhaust path H. Thereby, the exhaust gas flowing through the exhaust path H can be efficiently passed through the front end side opening 452 and the first rear end side opening 453. As a result, the amount of heat applied to the gas detection element 110 can be increased efficiently, and the gas detection element 110 can be efficiently heated.

  In the protector 122, at least a part of the rear end side openings 453 among the plurality of rear end side openings 453 has the first rear end side opening 453 having an opening area larger than that of the front end side opening 452. The shape may be other than the shape shown in FIG. Further, the bottom portion 451 of the protector 122 may cover the entire bottom surface, or may have a configuration having an opening 454 on the bottom surface as shown in FIG.

  Next, the structure of the sensor cap 200 will be described with reference to FIG. The sensor cap 200 includes a surrounding member 220 that surrounds the rear end side of the gas sensor main body 100, a cap terminal 210 that is electrically connected to the gas sensor main body 100, a lead wire 260 that is caulked and fixed to the cap terminal 210, and a filter member 250. With.

  First, the surrounding member 220 will be described. The surrounding member 220 is made of insulating fluorine-based rubber formed in a hollow shape. The surrounding member 220 includes a bottomed cylindrical sensor surrounding portion 221 whose rear end side (upper side in the drawing) is closed, a filter surrounding portion 222 that projects radially from the rear end side of the sensor surrounding portion 221, and a sensor. A lead wire surrounding portion 223 that protrudes from the rear end side of the surrounding portion 221 to the side opposite to the filter surrounding portion 222 is provided.

  The sensor surrounding portion 221 surrounds the rear end side of the gas sensor main body 100 in a state where the sensor cap 200 is attached to the gas sensor main body 100. The sensor surrounding part 221 is formed in a substantially cylindrical shape. The inner wall 227 of the sensor surrounding part 221 is provided with a tapered step for guiding the rear end of the gas sensor main body 100 to the center of its cylinder hole when the sensor cap 200 is attached to the gas sensor main body 100.

  In addition, a cap terminal 210 is provided in the sensor surrounding portion 221 so as to be electrically connected to the reference electrode 155 of the gas detection element 110 via the connection terminal 171 of the gas sensor main body 100. The cap terminal 210 has a sensor connecting portion 256 that protrudes from the bottom side (upper side in the drawing) of the cylindrical hole of the sensor surrounding portion 221 toward the open side (lower side in the drawing) within the sensor surrounding portion 221. . The sensor connection portion 256 is inserted into the cap connection portion 173 of the connection terminal 171 and makes an electrical connection with the connection terminal 171. The sensor connecting portion 256 is formed in a cylindrical shape, and ventilation is possible in the sensor surrounding portion 221 through its own cylindrical hole 216.

  Further, the cap terminal 210 is provided with a positioning portion 255 for positioning and holding the cap terminal 210 on the inner wall 227 of the sensor surrounding portion 221 near the base of the sensor connecting portion 256. The positioning portion 255 is formed in an annular portion 211 formed in an annular shape from the root of the sensor connecting portion 256 toward the inner wall 227, and in a cylindrical shape protruding from the outer edge of the annular portion 211 toward the same side as the sensor connecting portion 256. Gripping portion 212.

  In addition, at the bottom (upper side in the drawing) of the sensor surrounding part 221, the cap terminal 210 is mounted on the sensor surrounding part 221, and between the tube hole 216 of the sensor connecting part 256 and the filter surrounding part 222 described later. A groove portion 299 is formed so as to allow ventilation. Therefore, air can be passed from the filter surrounding part 222 to the open side of the sensor surrounding part 221 through the groove part 299 and the inside of the cylindrical hole 216 of the cap terminal 210.

  The lead wire 260 connected to the cap terminal 210 is drawn out of the sensor cap 200 from a lead wire insertion hole 261 opened in the lead wire surrounding portion 223. The opening diameter of the lead wire insertion hole 261 is slightly smaller than the diameter of the lead wire 260. As a result, the lead wire insertion hole 261 and the lead wire 260 are in close contact with each other, and air and water can be prevented from being introduced from the lead wire insertion hole 261.

The filter surrounding part 222 protrudes radially outward from the rear end side of the sensor surrounding part 221 and is formed in a substantially cylindrical shape. The filter enclosure 222 includes a communication hole 230 therein. The communication hole 230 allows the sensor surrounding part 221 to communicate with the outside of the surrounding member 220. A filter member 250 is disposed in the communication hole 230. In the vicinity of the outer opening of the communication hole 230, a filter pressing portion 235 that protrudes inward in the radial direction and is annularly connected in the circumferential direction is formed.
The filter retainer 235 prevents the filter member 250 from falling outside. The filter member 250 is formed in a cylindrical shape from PTFE having a porous structure in which fine pores are continuous, and has water tightness and air permeability.

  In a state where the sensor cap 200 is attached to the gas sensor main body 100, the sensor connection portion 256 of the cap terminal 210 is inserted inside the connection terminal 171, abuts on the connection terminal 171, and the cap terminal 210 and the connection terminal 171 are electrically connected. Conducted to.

  Further, the rear end side of the ceramic enclosure 164 is inserted into the gap between the grip portion 212 and the sensor connection portion 256, and the rear end face of the ceramic enclosure 164 contacts the annular portion 211. The inner wall 227 of the surrounding member 220 is in close contact with the outer peripheral surface of the ceramic surrounding body 164 and holds the ceramic surrounding body 164. When the inner wall 227 and the outer peripheral surface of the ceramic enclosure 164 are in close contact with each other, it is possible to prevent air from being introduced into the sensor cap 200 from below the sensor cap 200. As a result, the reference electrode 155 contacts only with air introduced from the outside through the communication hole 230.

  Next, the result of actually manufacturing the gas sensor 300 according to the second embodiment as Example 1 and measuring the light-off time will be described. The light-off time means that when a gas sensor is mounted in the exhaust pipe in a state where an exhaust gas having a predetermined gas temperature is caused to flow in the exhaust pipe and the rich atmosphere and the lean atmosphere are alternated in a predetermined cycle, the predetermined sensor output is It shows the time until detection.

  For example, a sensor output waveform is shown in the graph of FIG. 8 where the vertical axis represents sensor output and the horizontal axis represents time. In the case of FIG. 8, the time from when the gas sensor is mounted in the exhaust pipe until the sensor output of 450 mV is detected is the light-off time (T).

FIG. 9 is a graph in which the above-mentioned light time is measured for five samples for Example 1 and Comparative Examples 1 to 3, and the vertical axis is the light-off time. Comparative Example 1 is a measurement result for a conventional gas sensor having a protector having the same opening area and the same opening area at the front end side opening and the rear end side opening. The comparative example 2 is a measurement result about the gas sensor without a protector. In contrast to the example, Comparative Example 3 is a measurement result of a gas sensor having a protector in which the opening area of the front end side opening is larger than the opening area of the rear end side opening. FIG. 9 schematically shows the shape of the protector.
As a result, as shown in the graph of FIG. 9, in Example 1, the light-off time could be clearly shortened as compared with Comparative Examples 1 to 3.

  Next, as shown in FIG. 11, the result of measuring the temperature at the tip inner side A of the gas detection element is shown in the graph of FIG. In this temperature measurement, the gas was passed through an exhaust gas exhaust pipe having a predetermined gas temperature, and the temperature 60 seconds after the gas sensor was attached to this exhaust pipe (0 second) was measured. Example 1 and Comparative Examples 1 to 3 are the same as in the case of the above-described measurement of the light-off time, and Example 2 is an actual gas sensor of the first embodiment shown in FIGS. is there. As shown in the graph of FIG. 10, in Example 1 and Example 2, the temperature at the tip inner portion A of the gas detection element was also higher than in Comparative Examples 1 to 3.

Note that the present invention is not limited to the above-described embodiments and examples, and it is needless to say that various modifications are possible.
For example, the first rear end side openings 153 and 453 of the first embodiment and the second embodiment are each in the shape of a long hole whose major axis is the direction along the axis O direction or the direction perpendicular to the axis O direction. However, the shape is not limited to this, and may be circular, elliptical, or polygonal.
Further, in the first embodiment and the second embodiment, the front end side openings 152 and 452 and the rear end side openings 153 and 453 have a plurality of openings, but the present invention is not limited to this. The protectors 15 and 122 may have more than one row of openings. In this case, for example, a plurality of openings provided relatively on the front end side and extending in the circumferential direction are referred to as front end side openings, and one row provided on the rear end side from the plurality of openings. The opening may be a rear end side opening.
Furthermore, in 1st Embodiment and 2nd Embodiment, although all the rear-end side opening 153,453 was 1st rear-end side opening 153,453, it is not restricted to this, The rear-end side opening 153, Part of 453 may be used as the first rear end side openings 153 and 453. In this case, it is provided in the site | part which faces the upstream of the flow path (for example, exhaust path H of 2nd Embodiment) among the side wall parts 150 and 450, and more exhaust gas is put in protector 15 and 122 in it. It is possible to take in and is preferable.

  DESCRIPTION OF SYMBOLS 1 ... Gas sensor, 3 ... Gas detection element, 5 ... Separator, 7 ... Closure member, 9 ... Terminal metal fitting, 11 ... Lead wire, 13 ... Main metal fitting, 15 ... Protector, 17 ... Outside Cylinder, 19 ... protective outer cylinder, 20 ... casing, 150 ... side wall, 151 ... bottom, 152 ... front end side opening, 153 ... rear end side opening (first rear end side opening).

Claims (10)

A gas detection element comprising: an element body made of a bottomed cylindrical solid electrolyte body extending in the axial direction and closed at the tip end; and an inner electrode and an outer electrode provided inside and outside the element body; ,
A cylindrical casing that holds the gas detection element in a through-hole penetrating in the axial direction in a state in which a tip portion of the gas detection element protrudes;
A protector disposed in the casing and surrounding the periphery of the tip of the gas detection element;
A gas sensor without a heater for heating,
The protector is composed of a single cylindrical body having a side wall and a bottom, and the side wall of the cylindrical body is at the front end side in the axial direction, and a plurality of front end sides are arranged along the circumferential direction. An opening, a rear end side in the axial direction from the front end side opening, and a plurality of rear end openings provided separately from the front end side opening along the circumferential direction;
The rear end opening is configured to have a respective first end side opening aperture area is larger than the opening area of the tip side opening,
The protector is engaged with the casing in the through hole, and extends between the inner surface on the front end side of the casing and the outer peripheral surface of the gas detection element,
A part of said 1st rear end side opening is arrange | positioned so that it may enter the inside of the said casing, The gas sensor characterized by the above-mentioned. The gas sensor according to claim 1,
When the protector is viewed in a radial direction perpendicular to the axial direction, the distal end portion of the gas detection element is exposed to the distal end side opening and the first rear end side opening. The gas sensor according to claim 1 or 2,
A gas sensor, wherein a total opening area of the rear end side opening is larger than a total opening area of the front end side opening. The gas sensor according to any one of claims 1 to 3,
The first rear end side opening is formed in an elongated hole shape having a major axis in a direction along the axial direction. The gas sensor according to claim 4, wherein
The gas sensor according to claim 1, wherein the major axis length of the first rear end side opening is 50% or more of the axial length of the tip portion of the gas detection element. The gas sensor according to any one of claims 1 to 3,
The first rear end side opening is formed in an elongated hole shape having a major axis in a direction along a circumferential direction of the protector. The gas sensor according to claim 6,
The major axis length of the first rear end side opening is larger than the maximum width of the portion of the gas detection element corresponding to the first rear end side opening. The gas sensor according to any one of claims 1 to 7,
The gas sensor according to claim 1, wherein each of the front end openings is formed in a circular shape. The gas sensor according to any one of claims 1 to 8,
A plurality of the first rear end side openings are arranged at equal intervals along the circumferential direction of the protector. The gas sensor according to any one of claims 1 to 9 ,
When the gas sensor is attached to the flow path, the front end side opening and the first rear end side opening are provided at least partially on the side wall portion of the protector facing the upstream side of the flow path. Characteristic gas sensor.

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