JP2012066188A - Electrically-heating type catalyst - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electrically-heating type catalyst for preventing an electrode from deforming or breaking.SOLUTION: The electrically-heating type catalyst 200 includes: a SiC carrier 12 held at an outer pipe of a case 14 through a mat 202; an electrode 204; a base layer 22 existing between the SiC carrier 12 and the electrode 204; and a fixing layer 24 connected with the base layer 22 to thereby fix the electrode 204 thereto. The fixing layer 24 has at least two parts each of which is formed to be linearly extended, and each of the parts is connected with the base layer 22 to thereby fix the electrode 204 thereto. The electrode 204 has a bent portion 206 provided between the parts for fixing the electrode 204 to the fixing layer 24. Moreover, the mat 202 has an opening 212 that opens between the parts of the electrode 204 which are fixed to the fixing layer 24.

Description

  The present invention relates to a catalyst, and more particularly, to an electrically heated catalyst that is energized and heated to effectively purify exhaust gas discharged from, for example, an automobile.

  Conventionally, an electrically heated catalyst that is electrically heated to purify exhaust gas is known (see, for example, Patent Document 1). The electrically heated catalyst includes a ceramic carrier and an electrode joined to the ceramic carrier to energize the ceramic carrier. The electrode supplies power supplied from an external power source such as a battery toward the ceramic carrier. The ceramic carrier is heated and activated by being energized through the electrodes. Therefore, according to the electrically heated catalyst, exhaust gas can be effectively purified by forcibly heating the ceramic carrier by energization.

JP-A-6-327937

  By the way, in the electrically heated catalyst, if the entire electrode is bonded to the ceramic carrier, the electrode may be peeled off from the ceramic carrier due to the difference between the thermal expansion coefficient of the electrode and that of the ceramic carrier. is there. Further, if the entire electrode is sandwiched and fixed between the base layer and the fixing layer interposed between the ceramic carrier and the electrode, the electrode cannot freely thermally expand or contract. For this reason, in such a structure, there is a disadvantage that the possibility that the electrode is deformed or broken increases.

  The present invention has been made in view of the above points, and an object of the present invention is to provide an electrically heated catalyst capable of suppressing deformation and fracture of an electrode.

  The above object includes a ceramic carrier, an electrode, an underlayer interposed between the ceramic carrier and the electrode, and a fixing layer for fixing the electrode by bonding to the underlayer, and the fixing The layer is formed to extend linearly at each of at least two locations, and is achieved by an electrically heated catalyst that fixes the electrode by bonding to the base layer at each location.

  According to the present invention, deformation and fracture of an electrode can be suppressed.

It is a block diagram of the electrically heated catalyst which is 1st Example of this invention. It is sectional drawing when the electrically heated catalyst of 1st Example of this invention is cut | disconnected by III-III shown in FIG. It is a block diagram of the electrically heated catalyst which is 2nd Example of this invention. It is sectional drawing at the time of cut | disconnecting the electrically heated catalyst of 2nd Example of this invention by IV-IV shown in FIG. It is a block diagram of the electrically heated catalyst which is 3rd Example of this invention. It is a perspective view of the principal part of the electrically heated catalyst of 3rd Example of this invention. It is sectional drawing of the electrically heated catalyst of 3rd Example of this invention.

  Hereinafter, specific embodiments of the electrically heated catalyst according to the present invention will be described with reference to the drawings.

  FIG. 1 shows a configuration diagram of an electrically heated catalyst 10 according to a first embodiment of the present invention. FIG. 2 shows a cross-sectional view of the electric heating type catalyst 10 of this example cut along III-III shown in FIG. The electrically heated catalyst 10 of the present embodiment is a catalyst for purifying exhaust gas discharged from, for example, an automobile, and is a catalyst that is activated when heated by energization.

  The electrically heated catalyst 10 includes a SiC carrier 12 on which a ceramic catalyst formed of silicon carbide (SiC) is supported. The SiC carrier 12 can exhibit a catalytic function when heated and heated. The SiC carrier 12 is formed in a cylindrical shape. The SiC carrier 12 is held in a case 14 formed in a cylindrical shape. A mat 16 is interposed between the SiC carrier 12 and the outer tube of the case 14. That is, the SiC carrier 12 is held on the outer tube of the case 14 via the mat 16 over the entire outer peripheral surface of the SiC carrier 12. The mat 16 is made of an alumina fiber aggregate and functions as an electrical insulator layer and a heat insulating layer.

  An electrode 20 for energizing and heating the SiC carrier 12 is joined to the SiC carrier 12. The electrode 20 is formed in a flat plate shape, and is formed in a comb-teeth shape such that a plurality of teeth extend in parallel with the longitudinal direction. The electrode 20 is disposed on the base layer 22. The underlayer 22 is a porous film or the like formed by thermal spraying, and is formed in a substantially flat plate shape. The electrode 20 is fixed by bonding the fixed layer 24 to the electrode 20 and the base layer 22 on the base layer 22.

  The fixed layer 24 is formed by thermal spraying, and has a shape extending linearly at two locations. The two linear portions of the fixed layer 24 are arranged so as to extend in a direction orthogonal to the longitudinal direction in which the teeth of the electrode 20 extend. The fixed layer 24 is joined to the base layer 22 and the electrode 20 by two linear portions extending in parallel to each other so as to cross the comb teeth of the electrode 20. The fixing layer 24 and the base layer 22 are joined at both ends of each linear portion of the fixing layer 24, and the fixing layer 24 has a gap between the comb teeth of the electrode 20 between both ends of each linear portion of the fixing layer 24. To enter. The fixing of the electrode 20 is realized by joining the two linear portions of the fixing layer 24 to the base layer 22 and the electrode 20 at a predetermined interval.

  The electrode 20, the base layer 22, and the fixed layer 24 are covered with a ceramic paste 26. The ceramic paste 26 is made of alumina, silica, cordierite, sialon, boron nitride, aluminum nitride, silicon carbide, etc., but has a thermal expansion coefficient close to that of the SiC support 12 and a high volume resistivity value. Things are desirable. The ceramic paste 26 is cured by being dried while covering the electrode 20, the base layer 22, and the fixed layer 24.

  The mat 16 has a recess that can accommodate the ceramic paste 26 cured as described above. The ceramic paste 26 is stored in the recess of the mat 16 after being cured, and is held between the SiC carrier 12 and the mat 16, so that the ceramic paste 26 is held on the outer tube of the case 14 via the mat 16.

  The ceramic paste 26 is provided with an outlet 26 a that is opened to take out one end of the electrode 20. Further, the mat 16 is provided with an outlet 16a opened to take out one end of the electrode 20. Each of the outlets 26a and 16a only needs to be formed in a minimum size necessary for taking out one end of the electrode 20. Specifically, the outlets 26a and 16a have a side slightly longer than the width in a direction orthogonal to the longitudinal direction in which the teeth of the electrode 20 extend, and the other side is an electrode. What is necessary is just to form so that it may have a length slightly larger than 20 thickness.

  In the electrically heated catalyst 10, when the electrode 20 is energized from the outside, the current flows through the electrode 20, the base layer 22, and the ceramic paste 26 to the SiC carrier 12, thereby heating the SiC carrier 12. When the SiC carrier 12 is heated, it can be activated to purify the exhaust gas. Therefore, according to the electrically heated catalyst 10 of the present embodiment, exhaust gas can be effectively purified by forcibly heating the SiC carrier 12 by energization.

  In the electrically heated catalyst 10 of the present embodiment, the electrode 20 joined to the SiC carrier 12 is fixed between the base layer 22 and the fixed layer 24 and covered with the ceramic paste 26 via the mat 16. The outer tube of case 14 is held. The mat 16 holds the electrode 20 between the SiC carrier 12 and the case 14 except for a portion corresponding to the outlet 16a. In such a structure, when the electrode 20 undergoes thermal expansion or contraction during the cooling / heating cycle, the expansion / contraction of the electrode 20 is absorbed by the ceramic paste 26 and the movement of the electrode 20 can be restricted. For this reason, according to the electrically heated catalyst 10 of the present embodiment, even if the electrode 20 undergoes thermal expansion or contraction, the occurrence of relative displacement between the electrode 20 and the mat 16 can be suppressed. While being able to suppress the deformation | transformation and fracture | rupture of the electrode 20 accompanying a displacement, the insulation of the electrode 20 can be improved.

  Further, the base layer 22 and the fixing layer 24 for fixing the electrode 20 are held on the outer tube of the case 14 via the mat 16 in a state of being covered with the ceramic paste 26 similarly to the electrode 20. For this reason, the base layer 22 and the fixed layer 24 are sandwiched between the SiC carrier 12 and the mat 16 and restrained. Therefore, according to the structure of the electric heating catalyst 10 of the present embodiment, it is possible to prevent the base layer 22 from peeling or floating from the SiC carrier 12 side or the electrode 20 side, and the fixed layer 24 is on the electrode 20 side. Can be prevented from peeling off or floating.

  In the first embodiment, the SiC carrier 12 corresponds to the “ceramic carrier” recited in the claims.

  In the first embodiment described above, it is necessary to cover the electrode 20, the base layer 22, and the fixed layer 24 with the ceramic paste 26. Therefore, in manufacturing the electric heating catalyst 10, the electrode 20, the base layer 22, and the fixed layer. A process for covering 24 with the ceramic paste 26 and a process for drying the ceramic paste 26 after that are required, which takes time in manufacturing and increases costs. Further, since the heat capacity of the electrically heated catalyst 10 is increased by the ceramic paste 26 that covers the electrode 20, the base layer 22, and the fixed layer 24, the energy required to heat the SiC carrier 12 until it is activated increases. End up. On the other hand, the second embodiment of the present invention is characterized in that the above disadvantages are solved.

  FIG. 3 shows a configuration diagram of an electrically heated catalyst 100 according to the second embodiment of the present invention. FIG. 4 shows a cross-sectional view of the electrically heated catalyst 100 of this example cut along IV-IV shown in FIG. 3 and 4, the same components as those shown in FIGS. 1 and 2 are denoted by the same reference numerals, and the description thereof is omitted or simplified.

  In the electrically heated catalyst 100, a mat 102 is interposed between the SiC carrier 12 and the outer tube of the case 14. That is, the SiC carrier 12 is held by the outer tube of the case 14 via the mat 102 over the entire outer circumference of the SiC carrier 12. The mat 102 is made of an alumina fiber aggregate and functions as an electrical insulator layer and a heat insulating layer.

  The mat 102 is provided with an opening 104. The opening 104 is slightly larger than the upper surface of the electrode 20 excluding one end for taking out to the outside, and opens to a size that can restrain the four corners of the substantially flat base layer 22. Specifically, the opening 104 has a length that corresponds to the length of the comb teeth of the electrode 20 and the other side of the opening 104 with respect to the longitudinal direction in which the teeth of the electrode 20 extend. It is formed so as to have a length slightly larger than the width in the orthogonal direction and slightly smaller than the length of one side of the base layer 22.

  The base layer 22 is fixed on the SiC carrier 12 by sandwiching the four corners between the SiC carrier 12 and the outer tube of the case 14 via the mat 102. The electrode 20 is fixed by bonding the fixed layer 24 to the electrode 20 and the base layer 22 on the base layer 22. The fixing of the electrode 20 is realized by joining the two linear portions of the fixing layer 24 to the base layer 22 and the electrode 20 at a predetermined interval. There is no mat 102 between the fixed layer 24 and the outer tube of the case 14, and a gap 106 is formed on the outer diameter side of the electrode 20 and the fixed layer 24.

  In the electrically heated catalyst 100, when the electrode 20 is energized from the outside, the current flows to the SiC carrier 12 through the electrode 20 and the underlayer 22, whereby the SiC carrier 12 is heated. When the SiC carrier 12 is heated, it can be activated to purify the exhaust gas. Therefore, according to the electrically heated catalyst 100 of the present embodiment, exhaust gas can be effectively purified by forcibly heating the SiC carrier 12 by energization.

  In the electric heating type catalyst 100 of the present embodiment, the electrode 20 joined to the SiC carrier 12 is fixed between the base layer 22 and the fixed layer 24, and the base layer 22 is connected to the case through the mats 102 at the four corners. 14 outer tubes. The electrode 20 itself is not held by the outer tube of the case 14 via the mat 102, but is displaced within the gap 106 while being fixed to the base layer 22 side by the two linear portions of the fixed layer 24. Is possible.

  In such a structure, when the electrode 20 undergoes thermal expansion or contraction during the cooling and heating cycle, the electrode 20 is expanded while being fixed to the base layer 22 side by the two linear portions of the fixed layer 24. -Shrinkage can be allowed freely in the gap 106. For this reason, according to the electrically heated catalyst 100 of the present embodiment, even if the electrode 20 undergoes thermal expansion or contraction, the occurrence of relative displacement between the electrode 20 and the mat 102 can be suppressed. The deformation and breakage of the electrode 20 due to the displacement can be suppressed.

  Further, the base layer 22 for fixing the electrode 20 is fixed and restrained by holding the four corners of the SiC carrier 12 on the outer tube of the case 14 via the mat 102. Therefore, according to the structure of the electric heating catalyst 100 of the present embodiment, it is possible to reliably prevent the base layer 22 from peeling or floating from the SiC carrier 12 side.

  In the electric heating type catalyst 100 of the present embodiment, unlike the electric heating type catalyst 10 of the first embodiment described above, it is not necessary to cover the electrode 20, the base layer 22, and the fixed layer 24 with the ceramic paste 26. Compared with the electric heating type catalyst 10, it is possible to reduce the manufacturing process or to reduce the cost. Further, since the heat capacity of the electric heating catalyst 100 is smaller than the heat capacity of the electric heating catalyst 10, the energy required to heat the SiC carrier 12 until activation is reduced as compared with the electric heating catalyst 10. It is possible.

  In the second embodiment described above, since it is necessary to form the opening 104 provided in the mat 102 in a size corresponding to the upper surface of the electrode 20, the SiC carrier 12 is held on the outer tube of the case 14 via the mat 102. There is a possibility that the holding power will be insufficient. On the other hand, the third embodiment of the present invention is characterized in that it solves the above problems.

  FIG. 5 shows a configuration diagram of an electrically heated catalyst 200 according to the third embodiment of the present invention. FIG. 6 shows a perspective view of the main part of the electrically heated catalyst 200 of the present embodiment. FIG. 7 shows a cross-sectional view of the electrically heated catalyst 200 of this example. 7A shows a cross-sectional view of the electric heating catalyst 200 taken along the line V-V shown in FIG. 5, and FIG. 7B shows the electric heating catalyst 200 in FIG. Cross-sectional views taken along VI-VI are shown respectively. 5, 6, and 7, the same components as those shown in FIGS. 1 and 2 are denoted by the same reference numerals, and description thereof is omitted or simplified.

  In the electrically heated catalyst 200, a mat 202 is interposed between the SiC carrier 12 and the outer tube of the case 14. That is, the SiC carrier 12 is held by the outer tube of the case 14 via the mat 202 over the entire outer circumference of the SiC carrier 12. The mat 202 is made of an alumina fiber aggregate and functions as an electrical insulator layer and a heat insulating layer.

  An electrode 204 for energizing and heating the SiC carrier 12 is joined to the SiC carrier 12. The electrode 204 is formed in a flat plate shape, and is formed in a comb-teeth shape such that a plurality of teeth extend in parallel to the longitudinal direction. The electrode 204 is disposed on the base layer 22. The electrode 204 is fixed by bonding the fixed layer 24 to the electrode 204 and the base layer 22 on the base layer 22. Specifically, the fixing of the electrode 204 is realized by joining the two linear portions of the fixing layer 24 to the base layer 22 and the electrode 204 with a predetermined interval.

  A bent portion 206 is provided between the portions of the electrode 204 fixed to the two linear portions of the fixed layer 24. That is, the electrode 204 has a shape that is bent between the portions fixed to the two linear portions of the fixed layer 24. The bent portion 206 may be provided on each comb tooth of the electrode 204. The bent portion 206 is formed so as to protrude outward in the radial direction in a state where the electrode 204 is fixed to the two linear portions of the fixed layer 24.

  The mat 202 is provided with an outlet 210 that is opened to take out one end of the electrode 204. The take-out port 210 may be formed in a minimum size necessary for taking out one end of the electrode 204. Specifically, the outlet 210 has a length that is slightly larger than the width in a direction perpendicular to the longitudinal direction in which the teeth of the electrode 204 extend, and the other side of the outlet 204. What is necessary is just to form so that it may have a length slightly larger than thickness.

  The mat 202 is further provided with an opening 212 opened at a portion corresponding to the bent portion 206 of the electrode 204. The opening 212 is formed in a size that does not contact the bent portion 206 even if the bent portion 206 of the electrode 204 is displaced within a certain range. Specifically, the opening 212 has a side slightly longer than the width in the direction orthogonal to the longitudinal direction in which the teeth of the electrode 204 extend, and the other side is fixed layer 24. Are formed so as to have a length corresponding to the distance between the two linear portions.

  In the electrically heated catalyst 200, when the electrode 204 is energized from the outside, the current flows to the SiC carrier 12 through the electrode 204 and the underlayer 22, whereby the SiC carrier 12 is heated. When the SiC carrier 12 is heated, it can be activated to purify the exhaust gas. Therefore, according to the electrically heated catalyst 200 of the present embodiment, exhaust gas can be effectively purified by forcibly heating the SiC carrier 12 by energization.

  In the electrically heated catalyst 200 of the present embodiment, the electrode 204 joined to the SiC carrier 12 is held on the outer tube of the case 14 via the mat 202 while being fixed between the base layer 22 and the fixed layer 24. Is done. The mat 202 holds the electrode 204 between the SiC carrier 12 and the case 14 except for a portion corresponding to the outlet 210 and a portion corresponding to the opening 212. The electrode 204 is fixed to the base layer 22 side by two linear portions of the fixing layer 24, and the case is interposed via the mat 202 except for a portion corresponding to the outlet 210 and a portion corresponding to the opening 212 of the mat 202. 14 outer tubes. The bent portion 206 of the electrode 204 can be displaced within the opening 212 of the mat 202.

  In this structure, when the electrode 204 undergoes thermal expansion or contraction during the cooling / heating cycle, the electrode 204 expands while the electrode 204 is fixed to the base layer 22 side by the two linear portions of the fixed layer 24. The shrinkage can be absorbed and freely allowed by bending the bent portion 206 at the opening 212 of the mat 202. Therefore, according to the electrically heated catalyst 200 of the present embodiment, even if the electrode 204 undergoes thermal expansion or contraction, the bending of the bent portion 206 suppresses the occurrence of relative displacement between the electrode 204 and the mat 202. Therefore, the deformation and breakage of the electrode 204 due to the relative displacement can be suppressed. Further, since the bent portion 206 of the electrode 204 absorbs the expansion / contraction, the stress that the fixed layer 24 receives from the electrode 204 during the cooling / heating cycle can be reduced.

  Further, in the above structure, the size of the opening 212 of the mat 202 is smaller than the size of the opening 104 of the mat 102 in the electric heating catalyst 100 of the first embodiment described above, and most of the electrode 204 is formed. (Specifically, the portion excluding the bent portion 206) is held by the outer tube of the case 14 via the mat 202. Therefore, according to the electrically heated catalyst 200 of the present embodiment, the SiC carrier 12 is held on the outer tube of the case 14 via the mat 202 as compared with the electrically heated catalyst 100 of the first embodiment described above. Therefore, it is possible to prevent the holding force from being insufficient and to secure the holding force.

  Therefore, according to the electric heating type catalyst 200 of the present embodiment, it is possible to suppress deformation and breakage of the electrode 204 without reducing the holding power of the SiC carrier 12.

  Further, the opening 212 of the mat 202 has a length that is slightly larger than the width in the direction orthogonal to the longitudinal direction in which the teeth of the electrode 204 extend, and the other side of the fixing layer 24. Are formed so as to have a length corresponding to the distance between the two linear portions. In this case, the base layer 22 and the fixing layer 24 that fix the electrode 204 are fixed and restrained by being held on the outer tube of the case 14 via the mat 202. For this reason, the base layer 22 and the fixed layer 24 are sandwiched and restrained between the SiC carrier 12 and the mat 202. Therefore, according to the structure of the electric heating type catalyst 200 of the present embodiment, it is possible to prevent the base layer 22 from peeling or floating from the SiC carrier 12 side or the electrode 204 side, and the fixed layer 24 is on the electrode 204 side. Can be prevented from peeling off or floating.

  In the electric heating type catalyst 200 of the present embodiment, unlike the electric heating type catalyst 10 of the first embodiment described above, it is not necessary to cover the electrode 204, the base layer 22, and the fixed layer 24 with the ceramic paste 26. Compared with the electric heating type catalyst 10, it is possible to reduce the manufacturing process or to reduce the cost. In addition, since the heat capacity of the electric heating catalyst 200 is smaller than the heat capacity of the electric heating catalyst 10, the energy required to heat the SiC carrier 12 until activation is reduced as compared with the electric heating catalyst 10. It is possible.

  In the first to third embodiments, the ceramic support on which the ceramic catalyst is supported is the SiC support 12 made of silicon carbide. However, the present invention is not limited to this, and other ceramic materials may be used. It may be used.

  In the first to third embodiments, the electrodes 20 and 204 are formed in a comb shape. However, the present invention is not limited to this, and other shapes may be used as long as the plate shape is used. It is good also as forming in.

  Furthermore, in the first to third embodiments described above, in order to fix the electrodes 20 and 204 between the base layer 22 and the fixing layer 24, the fixing layer 24 has a shape extending linearly at two locations. However, this invention is not limited to this, It is good also as a shape extended linearly in three or more places. In this case, the number of linear portions of the fixed layer 24 may be set in consideration of both the fixation of the electrodes 20 and 204 and the allowable amount of expansion and contraction of the electrodes 20 and 204.

10, 100, 200 Electric heating type catalyst 12 SiC carrier 14 Case 16, 102, 202 Mat 20, 204 Electrode 22 Underlayer 24 Fixed layer 26 Ceramic paste 206 Bending portion 212 Opening portion

Claims (4)

A ceramic carrier;
Electrodes,
An underlayer interposed between the ceramic carrier and the electrode;
A fixing layer for fixing the electrode by bonding to the base layer,
The electric heating catalyst is characterized in that the fixing layer is formed so as to extend linearly at each of at least two locations, and the electrode is fixed by bonding to the base layer at each location.   The electric heating catalyst according to claim 1, wherein the electrode has a bent portion between portions fixed to the fixed layer. The electrode is a flat electrode formed in a comb shape in the longitudinal direction,
The electric heating catalyst according to claim 1, wherein the fixed layer is disposed so as to extend in a direction orthogonal to a longitudinal direction of the flat electrode. The ceramic carrier is held on the case outer tube via a mat,
The electric heating catalyst according to any one of claims 1 to 3, wherein the mat has an opening that opens between portions of the electrode fixed to the fixing layer.

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