JP5632508B2 - Engine equipment - Google Patents

Description

  The present invention relates to an engine apparatus such as a diesel engine having an exhaust manifold, and more specifically, removes particulate matter (soot, particulates), NOx (nitrogen oxide), or the like in exhaust gas discharged from the engine. The present invention relates to an engine device provided with a gas purification filter.

  Conventionally, a diesel particulate filter (or NOx catalyst) or the like is provided in an exhaust gas exhaust path of a diesel engine mounted on a traveling machine body, and the exhaust gas exhausted from the diesel engine is converted into a diesel particulate filter (or NOx). There is a technique in which purification treatment is performed using a catalyst) (Patent Document 1, Patent Document 2, and Patent Document 3). Further, a technique in which a filter case (inner case) is provided in a casing (outer case) and a particulate filter is disposed in the filter case is also known (see Patent Document 4).

JP 2000-145430 A Japanese Patent Laid-Open No. 2003-27922 JP 2008-82201 A JP 2001-173429 A

  In a structure where a particulate filter is placed in the exhaust gas discharge path of a diesel engine, when the particulate filter is assembled away from the diesel engine, a particulate filter is installed on each device such as a vehicle equipped with the diesel engine. It is necessary to install. For example, when a diesel engine and a particulate filter are separately assembled in a device such as a vehicle, there is a problem that exhaust gas countermeasures of the diesel engine differ for each device such as a vehicle. In addition, when the particulate filter is installed in the diesel engine instead of the silencer installed in the diesel engine, the particulate filter becomes heavier than the silencer, so just using the silencer support structure, There is a problem that a particulate filter cannot be assembled.

  It is an object of the present invention to provide a particulate filter with high rigidity as one of engine components, to eliminate exhaust gas countermeasures for each device such as a vehicle, and to improve the versatility of the engine. An engine device is provided.

To achieve the above object, the inventions according to claim 1, an engine (70) having an exhaust manifold (71), and said gas cleaning filter engine (70) for purifying the exhaust gas discharged (1) The engine device comprises a cooling fan (76) on one side of the engine (70), and a flywheel housing (78) on the side of the engine (70) opposite to the cooling fan (76). provided, the gas cleaning filter (1), the lower position of said flywheel housing of the engine (70) (78), and one side of the oil pan (81) on the lower side of the engine (70) the installed fly so as to face to the lower surface of the wheel housing (78), said exhaust Maniho the exhaust gas inlet (16) of the gas cleaning filter (1) And de (71) arranged on the same side of the engine (1), wherein the connecting the exhaust gas inlet (16) through said exhaust pipe (85) to the exhaust manifold (71), wherein the gas cleaning filter One end side of the filter support (19) is fixed to the outer peripheral surface of (1), and the filter support (19) is attached to the engine leg mounting portion (82) provided on the side surface of the flywheel housing (78). The other end is attached .

  According to the present invention, since the gas purification filter can be installed at the lower position of the flywheel housing where the cooling fan wind does not directly hit the engine cooling fan, the center of gravity of the engine is lowered to improve vibration isolation. it can. At this time, for example, the gas purification filter can be installed compactly adjacent to the side surface of the oil pan, the flywheel housing, or the like. In addition, the maintenance workability of the engine can be improved by simply configuring the upper surface side of the engine.

  Further, one end side of the filter support is fixed to the outer peripheral surface of the gas purification filter, and the other end side of the filter support is attached to the left and right engine leg mounting portions provided on the left and right side surfaces of the flywheel housing in the engine. Therefore, the gas purification filter can be supported with high rigidity by utilizing the engine leg mounting portion of the flywheel housing. It is possible to prevent the gas purification filter from being damaged by vibration or the like.

Moreover, the left and right both sides of the flywheel housing, lever provided distributed exhaust gas outlet and the exhaust gas inlet of the gas cleaning filter, in close proximity to the lower surface of the flywheel housing can support the gas purifying filter. A gas purification filter can be communicated with the exhaust manifold at a close distance, the gas purification filter can be easily maintained at an appropriate temperature, and high exhaust gas purification performance can be maintained.

1 is a front sectional view of an exhaust gas purification device according to an embodiment of the present invention. It is the same external appearance bottom view. It is the left view seen from the exhaust gas inflow side. It is right side sectional drawing seen from the exhaust gas discharge side. FIG. 2 is an exploded front sectional view of FIG. 1. It is a front view expanded sectional view of the exhaust gas discharge side. It is a side view enlarged sectional view on the same exhaust gas discharge side. It is an enlarged bottom view of the same exhaust gas inflow side. It is an enlarged sectional view in plan view of the exhaust gas inflow side. FIG. 10 is an enlarged cross-sectional view in plan view of the exhaust gas inflow side showing a modification of FIG. 9. FIG. 10 is an enlarged cross-sectional view in plan view of the exhaust gas inflow side showing a modification of FIG. 9. FIG. 10 is an enlarged cross-sectional view in plan view of the exhaust gas inflow side showing a modification of FIG. 9. FIG. 10 is an enlarged cross-sectional view in plan view of the exhaust gas inflow side showing a modification of FIG. 9. FIG. 10 is an enlarged cross-sectional view in plan view of the exhaust gas inflow side showing a modification of FIG. 9. It is a left view of a diesel engine. It is a top view of a diesel engine. It is a front view of a diesel engine. It is a rear view of a diesel engine. It is a side view of a backhoe. It is a top view of a backhoe. It is a side view of a forklift car. It is a top view of a forklift car.

  DESCRIPTION OF EMBODIMENTS Embodiments embodying the present invention will be described below with reference to the drawings. 1 is a front sectional view of the exhaust gas purification device, FIG. 2 is a bottom view of the same, FIG. 3 is a left side view of the exhaust gas inflow side, and FIG. 4 is a right side sectional view of the exhaust gas purification device. 5 is an exploded front sectional view of FIG. 1, FIG. 6 is an enlarged front sectional view of the exhaust gas discharge side, FIG. 7 is an enlarged sectional side view of the exhaust gas discharge side, and FIG. FIG. 9 is an enlarged sectional view of the exhaust gas inflow side in plan view. The overall structure of the exhaust gas purification apparatus will be described with reference to FIGS. 1 to 5. In the following description, the exhaust gas inflow side is simply referred to as the left side, and the exhaust gas discharge side is also simply referred to as the right side.

  The structure of a continuously regenerating diesel particulate filter 1 (hereinafter referred to as DPF) will be described with reference to FIGS. As shown in FIGS. 1 to 5, the DPF 1 is for physically collecting particulate matter (PM) and the like in the exhaust gas. The DPF 1 exhausts a diesel oxidation catalyst 2 such as platinum that generates nitrogen dioxide (NO2) and a soot filter 3 having a honeycomb structure that continuously oxidizes and removes the collected particulate matter (PM) at a relatively low temperature. The gas is arranged in series in the gas movement direction (from left to right in FIG. 1). The DPF 1 is configured so that the soot filter 3 is continuously regenerated. The DPF 1 can reduce carbon monoxide (CO) and hydrocarbons (HC) in the exhaust gas in addition to the removal of particulate matter (PM) in the exhaust gas.

  With reference to FIG.1 and FIG.5, the attachment structure of the diesel oxidation catalyst 2 is demonstrated. As shown in FIGS. 1 and 5, a diesel oxidation catalyst 2 as a gas purification filter for purifying exhaust gas discharged from an engine is installed in a substantially cylindrical catalyst inner case 4 made of a heat-resistant metal material. The catalyst inner case 4 is provided in a substantially cylindrical catalyst outer case 5 made of a heat-resistant metal material. That is, the catalyst inner case 4 is fitted on the outside of the diesel oxidation catalyst 2 via the mat-shaped ceramic fiber catalyst heat insulating material 6. Further, the catalyst outer case 5 is fitted on the outer side of the catalyst inner case 4 via a thin plate support 7 having an I-shaped end face. Note that the diesel oxidation catalyst 2 is protected by the catalyst heat insulating material 6. The stress (deformation force) of the catalyst outer case 5 transmitted to the catalyst inner case 4 is reduced by the thin plate support 7.

  As shown in FIGS. 1 and 5, a disc-shaped left lid 8 is fixed to the left end of the catalyst inner case 4 and the catalyst outer case 5 by welding. A sensor connection plug 10 is fixed to the left lid body 8 through a seat plate body 9. The left end face 2a of the diesel oxidation catalyst 2 and the left lid 8 are opposed to each other with a predetermined distance L1 for gas inflow space. An exhaust gas inflow space 11 is formed between the left end face 2 a of the diesel oxidation catalyst 2 and the left lid 8. The sensor connection plug 10 is connected to an unillustrated inlet side exhaust gas pressure sensor, an inlet side exhaust gas temperature sensor, and the like.

As shown in FIGS. 1, 5, and 9, an elliptical exhaust gas inlet 12 is opened at the left end of the catalyst inner case 4 and the catalyst outer case 5 in which the exhaust gas inflow space 11 is formed. The elliptical exhaust gas inlet 12 has a short diameter in the exhaust gas movement direction (center line direction of the cases 4 and 5) and a direction orthogonal to the exhaust gas movement direction (circumferential direction of the cases 4 and 5). It has a long diameter. A closing ring body 15 is fixed between the opening edge 13 of the catalyst inner case 4 and the opening edge 14 of the catalyst outer case 5 in a sandwiched manner. A gap between the opening edge 13 of the catalyst inner case 4 and the opening edge 14 of the catalyst outer case 5 is closed by the closing ring body 15. An exhaust ring 15 prevents the exhaust gas from flowing between the catalyst inner case 4 and the catalyst outer case 5.

  As shown in FIGS. 1, 3, 5, and 8, an exhaust gas inlet pipe 16 is disposed on the outer surface of the catalyst outer case 5 in which the exhaust gas inlet 12 is formed. An exhaust connection flange body 17 is welded to a true circular opening end portion 16 a on the small diameter side of the exhaust gas inlet pipe 16. The exhaust connection flange body 17 is fastened to an exhaust manifold 71 of a diesel engine 70 described later via bolts 18. A large circular opening end 16 b on the large diameter side of the exhaust gas inlet pipe 16 is welded to the outer surface of the catalyst outer case 5. The exhaust gas inlet pipe 16 is formed in a divergent shape (a trumpet shape) from the small-diameter-side perfect circular opening end 16a toward the large-diameter-side perfect circular opening end 16b.

  As shown in FIGS. 1, 5, and 8, of the outer surface of the catalyst outer case 5, a large circular opening end 16 b is formed on the outer surface of the left end of the opening edge 14 of the catalyst outer case 5. The left end of is welded. That is, with respect to the elliptical exhaust gas inlet 12, the exhaust gas inlet pipe 16 (the large circular opening end 16b) is offset downstream of the exhaust gas movement (on the right side of the catalyst outer case 5). Are arranged. That is, the elliptical exhaust gas inlet 12 is offset to the exhaust gas moving upstream side (the left side of the catalyst outer case 5) with respect to the exhaust gas inlet pipe 16 (the large circular opening end 16b). The catalyst outer case 5 is formed.

  With the above configuration, the exhaust gas of the diesel engine 70 enters the exhaust gas inlet pipe 16 from the exhaust manifold 71, enters the exhaust gas inflow space 11 from the exhaust gas inlet pipe 16 through the exhaust gas inlet 12, and the diesel oxidation catalyst. 2 is supplied from the left end face 2a. Nitrogen dioxide (NO 2) is generated by the oxidation action of the diesel oxidation catalyst 2. Further, the DPF 1 is fixed to the diesel engine 70 described later via the support leg 19.

  With reference to FIG.1 and FIG.5, the attachment structure of the soot filter 3 is demonstrated. As shown in FIGS. 1 and 5, the soot filter 3 as a gas purification filter for purifying exhaust gas discharged from the diesel engine 70 is provided in a substantially cylindrical filter inner case 20 made of a heat-resistant metal material. The inner case 4 is provided in a substantially cylindrical filter outer case 21 made of a heat-resistant metal material. That is, the filter inner case 20 is fitted on the outside of the soot filter 3 via the mat-shaped ceramic fiber filter heat insulating material 22. The soot filter 3 is protected by the filter heat insulating material 22.

  As shown in FIGS. 1 and 5, the catalyst side flange 25 is welded to the exhaust gas movement downstream side (right side) of the catalyst outer case 5. The filter-side flange 26 is welded to the middle of the filter inner case 20 in the exhaust gas movement direction and the end of the filter outer case 21 on the upstream side (left side) of the exhaust gas movement. The catalyst side flange 25 and the filter side flange 26 are detachably fastened by bolts 27 and nuts 28. The diameter of the cylindrical catalyst inner case 4 and the diameter of the cylindrical filter inner case 20 are substantially the same. Further, the diameter of the cylindrical catalyst outer case 5 and the diameter of the cylindrical filter outer case 21 are substantially the same.

  As shown in FIG. 1, in a state where the filter outer case 21 is connected to the catalyst outer case 5 via the catalyst side flange 25 and the filter side flange 26, the exhaust gas movement downstream side (right side) end of the catalyst inner case 4 is shown. The end portion on the upstream side (left side) of the exhaust gas movement of the filter inner case 20 faces the portion spaced apart by a fixed interval L2 for sensor attachment. In other words, the sensor mounting space 29 is formed between the exhaust gas movement downstream side (right side) end of the catalyst inner case 4 and the exhaust gas movement upstream side (left side) end of the filter inner case 20. A sensor connection plug 50 is fixed to the catalyst outer case 5 at the sensor mounting space 29 position. The sensor connection plug 50 is connected to a filter inlet side exhaust gas pressure sensor (not shown), a filter inlet side exhaust gas temperature sensor (thermistor), and the like.

  As shown in FIG. 5, the cylindrical length L4 of the catalyst outer case 5 in the exhaust gas movement direction is longer than the cylindrical length L3 of the catalyst inner case 4 in the exhaust gas movement direction. The cylindrical length L6 of the filter outer case 21 in the exhaust gas movement direction is shorter than the cylindrical length L5 of the filter inner case 20 in the exhaust gas movement direction. A length (L2 + L3 + L5) obtained by adding the constant interval L2 of the sensor mounting space 29, the cylindrical length L3 of the catalyst inner case 4 and the cylindrical length L5 of the filter inner case 20 is the cylindrical length L4 of the catalyst outer case 5. And a length (L4 + L6) obtained by adding the cylindrical length L6 of the filter outer case 21 to be substantially equal to each other. The exhaust gas movement upstream side (left side) end of the filter outer case 21 and the exhaust gas movement upstream side (left side) end of the filter inner case 20 are only the difference in length (L7 = L5−L6). Protruding. That is, when the filter outer case 21 is connected to the catalyst outer case 5, the exhaust gas movement upstream side (left side) end of the filter inner case 20 is the overlap dimension L7, and the exhaust gas movement downstream side of the catalyst outer case 5 (Right side) is interpolated.

  With the above configuration, nitrogen dioxide (NO2) generated by the oxidation action of the diesel oxidation catalyst 2 is supplied to the soot filter 3 from the left end face 3a. The collected particulate matter (PM) in the exhaust gas of the diesel engine 70 collected by the soot filter 3 is continuously oxidized and removed at a relatively low temperature by nitrogen dioxide (NO2). In addition to the removal of particulate matter (PM) in the exhaust gas of the diesel engine 70, carbon monoxide (CO) and hydrocarbons (HC) in the exhaust gas of the diesel engine 70 are reduced.

  As shown in FIGS. 1 to 5, a diesel oxidation catalyst 2 or soot filter 3 as a gas purification filter for purifying exhaust gas discharged from a diesel engine 70, and a catalyst inner case in which the diesel oxidation catalyst 2 or soot filter 3 is installed. 4, a filter inner case 20, a catalyst outer case 5 in which the catalyst inner case 4 and the filter inner case 20 are installed, and a filter outer case 21, a plurality of sets of diesel oxidation catalysts 2 and soot The filter 3, the catalyst inner case 4, the filter inner case 20, the catalyst outer case 5, and the filter outer case 21 are provided, and the catalyst outer case 5 and the filter outer case 21 with respect to the connection boundary position of the diesel oxidation catalyst 2 and the soot filter 3. Catalyst side flange 25 and filter as flange body connecting Since the flange 26 is obtained by configured to offset, by reducing the distance between the junction of the diesel oxidation catalyst 2 or the soot filter 3 can shorten the connection length of the catalyst outer case 5 and the filter outer case 21. Further, a gas sensor or the like can be easily arranged at the connection boundary position of the diesel oxidation catalyst 2 or the soot filter 3. Since the length of the catalyst outer case 5 and the filter outer case 21 in the exhaust gas movement direction can be shortened, the rigidity and weight reduction of the catalyst outer case 5 and the filter outer case 21 can be achieved.

  As shown in FIGS. 1 to 5, two types of diesel oxidation catalysts 2 and soot filters 3 are provided, and a filter inner case 20 in which one soot filter 3 is installed is provided in the catalyst of the other diesel oxidation catalyst 2. Since the catalyst outer case 5 in which the inner case 4 is installed is configured to overlap, the catalyst outer case 5 or the soot filter 3 is secured while maintaining the length of the diesel oxidation catalyst 2 or the soot filter 3 in the exhaust gas movement direction. The length of the filter outer case 21 in the exhaust gas movement direction can be shortened. Further, since the catalyst inner case 4 (the other diesel oxidation catalyst 2) where the catalyst outer case 5 overlaps is largely exposed to the outside by the separation (disassembly) of the catalyst outer case 5 and the filter outer case 21, the catalyst inner case 4 is exposed. The exposure range of the case 4 (the other diesel oxidation catalyst 2) is increased, and maintenance work such as soot removal of the one soot filter 3 can be easily performed.

  As shown in FIGS. 1 to 5, a diesel oxidation catalyst 2 and a soot filter 3 are provided as a plurality of sets of gas purification filters, and the catalyst side flange 25 and the filter side flange 26 are offset on the outer peripheral side of the soot filter 3. Therefore, by separating the catalyst outer case 5 and the filter outer case 21, the end of the inner case 20 on the exhaust gas inlet side of the soot filter 5 can be greatly exposed from the end surface of the outer case 21. Maintenance work such as removal of soot adhering to the case 20 can be easily performed.

  As shown in FIG. 1 to FIG. 5, two types of diesel oxidation catalysts 2 and soot filters 3 are provided, and a catalyst inner case 4 in which one diesel oxidation catalyst 2 is installed, and the other soot filter 3 in the interior. Since the sensor mounting space 29 is formed between the filter inner case 20 and the filter outer case 20 to be provided, the connection length of the catalyst outer case 5 and the filter outer case 21 in the exhaust gas moving direction is shortened, and the catalyst outer case 5 is reduced. In addition, a gas sensor or the like can be easily arranged in the sensor mounting space 29 at the connection boundary position between the diesel oxidation catalyst 2 and the soot filter 3 while improving the rigidity and weight of the filter outer case 21 and the like.

  As shown in FIGS. 1 to 5, a sensor connection plug 50 as a sensor support is assembled to the catalyst outer case 5 that overlaps the filter inner case 20, and the sensor is installed at the connection boundary position of the diesel oxidation catalyst 2 and the soot filter 3. Since a gas sensor such as a filter inlet side exhaust gas pressure sensor or a filter inlet side exhaust gas temperature sensor (thermistor) (not shown) is arranged through the connection plug 50, the catalyst outer case 5 and the filter outer case are arranged. The sensor connection plug 50 can be compactly installed at the connection boundary position between the diesel oxidation catalyst 2 and the soot filter 3 while improving the rigidity and weight of the engine 21 and the like.

  As shown in FIGS. 1 to 5 and 8, a diesel oxidation catalyst 2 or soot filter 3 as a gas purification filter for purifying exhaust gas discharged from the diesel engine 70 and a diesel oxidation catalyst 2 or soot filter 3 are installed. An exhaust gas purifying apparatus comprising a catalyst inner case 4 or a filter inner case 20 as an inner case, and a catalyst outer case 5 or a filter outer case 21 as an outer case in which the catalyst inner case 4 or the filter inner case 20 is provided. 1, an exhaust gas inlet 12 is formed on the peripheral surface of one end of the catalyst inner case 4 and the catalyst outer case 5, and an exhaust gas inlet pipe 16 is provided outside the exhaust gas inlet 12 in the outer periphery of the catalyst outer case 5. The exhaust gas inlet pipe 16 has an exhaust area larger than the area of the opening end face of the exhaust gas inlet pipe 16 on the exhaust gas inlet side. The area of the open end of the scan outlet side is larger. Therefore, the exhaust gas inlet pipe can be arranged near the diesel oxidation catalyst 2 installation portion, and the length of the catalyst outer case 5 (casing) on the exhaust gas upstream side of the diesel oxidation catalyst 2 in the exhaust gas movement direction can be easily reduced. That is, the end face of the diesel oxidation catalyst 2 can be easily brought close to the end face on the upstream side of the catalyst outer case 5 in the exhaust gas movement direction. Further, by forming the area of the opening end face of the exhaust gas inlet pipe 16 on the exhaust gas outlet side larger than the area of the opening end face of the exhaust gas inlet pipe 16 on the exhaust gas inlet side, the outer peripheral face of the catalyst outer case 5 is formed. The exhaust gas inlet pipe 16 can be welded, and without providing a reinforcing member for connecting the catalyst outer case 5 and the exhaust gas inlet pipe 16 as in the prior art, the exhaust gas inlet pipe 16 on the exhaust gas inlet side of the catalyst outer case 5 is provided. Exhaust gas pressure loss in the catalyst outer case 5 and the exhaust gas inlet pipe 16 can be reduced while maintaining the mounting strength.

  As shown in FIG. 1, FIG. 2, FIG. 5, and FIG. 8, the exhaust gas outlet side edge of the exhaust gas inlet pipe 16 is fixed to the outer peripheral surface of the exhaust gas inlet of the catalyst outer case 5. The exhaust gas inlet pipe 16 is configured to be offset from the gas inlet 12 to the exhaust gas downstream side of the catalyst outer case 5. Therefore, the exhaust gas upstream end face of the diesel oxidation catalyst 2 can be disposed upstream of the exhaust gas downstream side opening edge of the exhaust gas inlet pipe 16 and the length of the catalyst outer case 5 in the exhaust gas moving direction. Of these, the length upstream of the exhaust gas can be easily reduced. The length of the catalyst outer case 5 in the exhaust gas movement direction can be made compact. That is, the exhaust gas outlet side of the exhaust gas inlet pipe 16 can be disposed away from the upstream side end surface of the catalyst outer case 5 in the exhaust gas movement direction. By reducing the size of the catalyst outer case 5 in the exhaust gas movement direction, the number of parts can be reduced as compared with the conventional case, and the configuration can be made compact and lightweight at low cost.

  As shown in FIGS. 1, 2, 5, and 8, the exhaust gas inlet in the exhaust gas movement direction of the catalyst outer case 5 is larger than the opening size of the exhaust gas inlet 12 of the catalyst outer case 5 and the catalyst inner case 4. The opening size on the exhaust gas outlet side of the pipe 16 is made large. Therefore, the attachment strength of the exhaust gas inlet pipe 16 on the exhaust gas inlet side of the catalyst outer case 5 can be maintained without providing a reinforcing member as in the prior art, and the exhaust gas inlet pipe 16 or the exhaust gas inlet of the catalyst outer case 5 can be maintained. Exhaust pressure loss of 12 etc. can be reduced. Compared to a conventional structure provided with a reinforcing member, the number of components can be reduced and the structure can be reduced. While the outer shape of the catalyst outer case 5 can be compactly formed and the weight can be easily reduced, the exhaust gas inlet side such as the catalyst outer case 5 and the exhaust gas inlet pipe 16 can be configured with high rigidity. . That is, the exhaust gas inlets of the catalyst outer case 5 and the catalyst inner case 4 can be formed close to the upstream side end face of the catalyst outer case 5 in the exhaust gas movement direction. By reducing the size of the catalyst outer case 5 in the exhaust gas movement direction, the number of parts can be reduced as compared with the conventional case, and the configuration can be made compact and lightweight at low cost.

  As shown in FIG. 1, FIG. 2, FIG. 5, and FIG. 8, the exhaust gas movement of the diesel oxidation catalyst 2 or the soot filter 3 rather than the end of the exhaust gas outlet side of the exhaust gas inlet pipe 16 on the downstream side of the exhaust gas movement. The upstream end surface is configured to be disposed on the exhaust gas movement upstream side of the catalyst outer case 5. Therefore, the length of the catalyst outer case 5 in the exhaust gas movement direction can be easily reduced, and the length of the catalyst outer case 5 in the exhaust gas movement direction can be made compact.

  As shown in FIGS. 1, 2, 5, and 8, among the opening edges of the exhaust gas inlet 12 of the catalyst outer case 5, the exhaust gas inlet is connected to the opening edge of the exhaust gas inlet 12 upstream of the exhaust gas movement. Since the exhaust gas outlet side end of the pipe 16 is connected, the length on the exhaust gas upstream side of the length of the catalyst outer case 5 in the exhaust gas movement direction can be easily reduced. However, the exhaust pressure loss of the exhaust gas in the catalyst outer case 5 and the exhaust gas inlet pipe 16 can be reduced.

  As described above, the diesel oxidation catalyst 2 and the soot filter 3 are provided as gas purification filters for purifying the exhaust gas discharged from the engine. However, instead of the diesel oxidation catalyst 2 and the soot filter 3, urea (reducing agent) is used. NOx selective reduction catalyst (NOx removal catalyst) for reducing nitrogen oxide (NOx) in the exhaust gas of the engine 70 by ammonia (NH3) generated by the addition of)) and residual ammonia discharged from the NOx selective reduction catalyst You may provide the ammonia removal catalyst to remove.

  As described above, when a NOx selective reduction catalyst (NOx removal catalyst) is provided in the catalyst inner case 4 and an ammonia removal catalyst is provided in the filter inner case 20 as a gas purification filter, nitrogen oxidation in the exhaust gas exhausted by the engine is performed. The substance (NOx) is reduced and can be discharged as harmless nitrogen gas (N2).

  As shown in FIGS. 1 to 5, a diesel oxidation catalyst 2 or soot filter 3 as a gas purification filter for purifying exhaust gas discharged from a diesel engine 70, and a catalyst inner case in which the diesel oxidation catalyst 2 or soot filter 3 is installed. 4, a filter inner case 20, and a catalyst outer case 5 and a filter outer case 21 in which the catalyst inner case 4 and the filter inner case 20 are installed. Are connected to the catalyst outer case 5 and the filter outer case 21, and an exhaust gas inlet pipe 16 as an inlet component to which an external stress is applied and a support leg 19 as a support body are arranged on the catalyst outer case 5. Yes.

  Therefore, external stress can be supported by the catalyst outer case 5, and external stress acting as a deformation force on the catalyst inner case 4 and the filter inner case 20 can be reduced. The double structure of the catalyst inner case 4 or the filter inner case 20 and the catalyst outer case 5 or the filter outer case 21 improves the heat insulating properties of the diesel oxidation catalyst 2 or the soot filter 3, thereby treating the diesel oxidation catalyst 2 or the soot filter 3. In addition to improving the capacity and the regeneration capacity, it is possible to easily prevent improper support of the diesel oxidation catalyst 2 and the soot filter 3 due to, for example, conduction of vibrations from the engine or distortion in welding processing.

  As shown in FIGS. 1 to 5, a plurality of sets of diesel oxidation catalysts 2 and soot filters 3, a catalyst inner case 4 and a filter inner case 20, and a catalyst outer case 5 and a filter outer case 21 are provided. The case 5 and the filter outer case 21 are connected by a catalyst side flange 25 and a filter side flange 26 as flange bodies. Accordingly, in consideration of the configuration of the exhaust gas inlet pipe 16 and the support leg 19 and the movement of exhaust gas between the plurality of sets of diesel oxidation catalyst 2 and the soot filter 3, a plurality of sets of catalyst inner cases 4 and filter inner cases are used. 20 and a plurality of sets of the catalyst outer case 5 and the filter outer case 21 can be functionally configured. The processing capacity, regeneration capacity, etc. of a plurality of sets of diesel oxidation catalysts 2 and soot filters 3 can be easily improved.

  As shown in FIGS. 1 to 5, the length of the catalyst inner case 4 and the filter inner case 20 in the exhaust gas moving direction is different from the length of the catalyst outer case 5 and the filter outer case 21 in the exhaust gas moving direction. Yes. Accordingly, the flange body connecting the catalyst outer case 5 and the filter outer case 21 can be offset with respect to the joining position of the plurality of sets of the diesel oxidation catalyst 2 and the soot filter 3. The mounting interval of the plurality of sets of diesel oxidation catalysts 2 and soot filters 3 can be easily reduced or expanded.

  As shown in FIGS. 1 to 5, a plurality of sets of diesel oxidation catalysts 2 and soot filters 3, a catalyst inner case 4 and a filter inner case 20, a catalyst outer case 5 and a filter outer case 21 are provided. The soot filter 3 is configured such that the catalyst side flange 25 and the filter side flange 26 connecting the plurality of sets of the catalyst outer case 5 and the filter outer case 21 are offset with respect to the joining position of the catalyst 2 and the soot filter 3. A catalyst outer case 5 facing the other diesel oxidation catalyst 2 is configured to overlap with the filter inner case 20 facing the other.

  Therefore, a sensor or the like can be easily disposed between the joints of the plurality of sets of diesel oxidation catalysts 2 and the soot filter 3 while the joint interval between the plurality of sets of diesel oxidation catalysts 2 and the soot filter 3 can be reduced. The lengths of the plurality of sets of catalyst outer cases 5 and filter outer cases 21 in the exhaust gas movement direction can be shortened, and the rigidity and weight of the plurality of sets of catalyst outer cases 5 and filter outer cases 21 can be improved. By shortening the joining interval of the plurality of sets of diesel oxidation catalysts 2 and soot filters 3, the length of the plurality of sets of catalyst outer case 5 and filter outer case 21 in the exhaust gas moving direction can be shortened.

  As shown in FIGS. 1, 5, 8 to 14, a diesel oxidation catalyst 2 or soot filter 3 as a gas purification filter for purifying exhaust gas discharged from a diesel engine 70, and a diesel oxidation catalyst 2 or soot filter 3 are provided. The catalyst inner case 4 or the filter inner case 20 as an inner case to be installed inside, and the catalyst outer case 5 or the filter outer case 21 as an outer case into which the catalyst inner case 4 or the filter inner case 20 is installed are provided. Further, an exhaust gas inlet pipe 16 is disposed outside the catalyst outer case 5 and is opposed to the exhaust gas outlet side of the exhaust gas inlet pipe 16 so as to face the catalyst inner case 4 or the filter inner case 20 and the catalyst outer case 5 or the filter outer side. The exhaust gas inlet 12 is opened in the case 21, and between the end face of the catalyst outer case 5 upstream of the catalyst outer case 5 or the filter outer case 21 in the exhaust gas movement direction and the end face of the diesel oxidation catalyst 2 or the soot filter 3. The exhaust gas inflow space 11 is formed as a rectifying chamber, and the exhaust gas inflow space 11 is communicated with the exhaust gas inlet pipe 16 via the exhaust gas inlet 12. Therefore, for example, in the structure in which the exhaust gas of the diesel engine 70 is introduced into the catalyst inner case 4 from the shear direction orthogonal to the center line thereof, it is not necessary to insert the exhaust gas inlet pipe 16 into the exhaust gas inflow space 11. . Therefore, the number of components of the structure of the catalyst outer case 5 provided with the exhaust gas inlet pipe 16 can be reduced and the cost can be reduced, and the catalyst inner case 4 or the filter inner side on the exhaust gas upstream side of the diesel oxidation catalyst 2 or the soot filter 3. The length of the case 20 and the catalyst outer case 5 or the filter outer case 21 in the exhaust gas moving direction can be easily shortened. That is, the relative distance between the exhaust gas inlet side of the diesel oxidation catalyst 2 and the upstream end face of the catalyst inner case 4 and the catalyst outer case 5 facing the exhaust gas moving direction can be easily shortened. The diesel oxidation catalyst 2 can be disposed close to the end surfaces of the catalyst inner case 4 and the catalyst outer case 5 on the upstream side of the exhaust gas movement, and the exhaust of the catalyst inner case 4 or the filter inner case 20 and the catalyst outer case 5 or the filter outer case 21 By reducing the dimension in the gas moving direction, the number of parts can be reduced as compared with the prior art, and the structure can be made compact and lightweight at low cost.

  As shown in FIGS. 1, 5, 8 to 14, the exhaust gas movement direction is larger than the opening size of the exhaust gas inlet 12 of the catalyst outer case 5 in the catalyst outer case 5 or the filter outer case 21 in the exhaust gas movement direction. Since the opening size of the exhaust gas inlet 12 in the direction perpendicular to the catalyst is formed large, the catalyst inner case 4 or the filter inner case 20 is maintained while maintaining the rigidity of mounting the exhaust gas inlet pipe 16 to the catalyst outer case 5. In addition, the size of the catalyst outer case 5 or the filter outer case 21 in the exhaust gas movement direction can be shortened, so that the number of parts can be reduced as compared with the conventional case, and the structure can be made compact and lightweight at low cost.

  As shown in FIGS. 1, 5, and 8 to 14, the exhaust gas inlet is larger than the opening size of the exhaust gas outlet of the exhaust gas inlet pipe 16 in the exhaust gas movement direction of the catalyst outer case 5 or the filter outer case 21. Since the opening size of 12 is made small, the exhaust gas can be evenly supplied from the exhaust gas inflow space 11 to the exhaust gas inlet side of the diesel oxidation catalyst 2, and while maintaining the gas purification function of the diesel oxidation catalyst 2, The catalyst inner case 4 or the filter inner case 20 and the catalyst outer case 5 or the filter outer case 21 can be configured to be compact and lightweight.

  As shown in FIGS. 1, 5, and 8 to 14, the opening shape of the exhaust gas inlet 12 is formed into an elliptical shape, a rectangular shape, a long hole shape, or a similar shape thereof, and the outside of the catalyst is formed. The opening size of the exhaust gas inlet 12 of the catalyst outer case 5 in the exhaust gas movement direction of the case 5 or the filter outer case 21 and the opening diameter size of the exhaust gas inlet pipe 16 on the exhaust gas inlet side are formed to be approximately equal. Therefore, the opening area of the exhaust gas inlet 12 can be made larger than the opening area of the exhaust gas inlet pipe 16 on the exhaust gas inlet side. The exhaust gas can be moved from the exhaust gas inlet 12 into the exhaust gas inflow space 11 while dispersing the exhaust gas in a direction orthogonal to the exhaust gas movement direction of the diesel oxidation catalyst 2. Can be reduced.

  As shown in FIGS. 1, 5, 8 to 14, the opening size of the exhaust gas inlet 12 of the catalyst outer case 5 in the exhaust gas movement direction of the catalyst outer case 5 or the filter outer case 21, and the exhaust gas inlet pipe 16. Of the exhaust gas inlet side of the exhaust gas inlet pipe 16 and the opening diameter of the exhaust gas inlet pipe 16 on the exhaust gas outlet side. The end of the exhaust gas inlet pipe 16 on the exhaust gas outlet side is formed at the opening edge of the exhaust gas inlet 12 on the upstream side of the exhaust gas movement among the opening edges of the exhaust gas inlet 12. Are connected. Therefore, the exhaust gas can be dispersed in the direction orthogonal to the exhaust gas movement direction of the diesel oxidation catalyst 2, and the exhaust gas can be evenly moved from the exhaust gas inlet 12 to the exhaust gas inlet side of the diesel oxidation catalyst 2. The drift of the exhaust gas with respect to the diesel oxidation catalyst 2 can be reduced, and the exhaust gas purification ability of the diesel oxidation catalyst 2 can be improved.

  The mounting structure of the silencer 30 will be described with reference to FIGS. 1 to 3 and FIGS. 5 to 7. As shown in FIGS. 1 to 3 and 5, the silencer 30 for attenuating the exhaust gas sound discharged from the diesel engine 70 includes a substantially cylindrical silencer inner case 31 made of a heat resistant metal material, and an abbreviation made of a heat resistant metal material. It has a cylindrical silencing outer case 32 and a disc-shaped right lid 33 fixed to the right end of the silencing inner case 31 and the silencing outer case 32 by welding. A silencer inner case 31 is provided in the silencer outer case 32. Further, the diameter of the cylindrical catalyst outer case 5, the diameter of the cylindrical filter outer case 21, and the cylindrical silencing outer case 32 are substantially the same. The diameter size of the cylindrical catalyst inner case 4, the diameter size of the cylindrical filter inner case 20, and the cylindrical sound deadening inner case 31 are substantially the same size. The diameter size of the cylindrical catalyst inner case 4, the diameter size of the cylindrical filter inner case 20, and the cylindrical silencer inner case 31 may not be the same size.

  As shown in FIGS. 4 to 7, the exhaust gas outlet pipe 34 is passed through the silencer inner case 31 and the silencer outer case 32. One end side of the exhaust gas outlet pipe 34 is closed by an outlet lid 35. A number of exhaust holes 36 are formed in the entire exhaust gas outlet pipe 34 inside the silencer inner case 31. The interior of the muffler inner case 31 is communicated with an exhaust gas outlet pipe 34 via a number of exhaust holes 36. A silencer and a tail pipe (not shown) are connected to the other end side of the exhaust gas outlet pipe 34.

  As shown in FIGS. 6 and 7, the muffler inner case 31 has a large number of muffler holes 37. The interior of the silencer inner case 31 is communicated between the silencer inner case 31 and the silencer outer case 32 via a number of silencer holes 37. The space between the silencer inner case 31 and the silencer outer case 32 is closed by the right lid 33 and the thin plate support 38. A ceramic fiber silencer 39 is filled between the silencer inner case 31 and the silencer outer case 32. The exhaust gas movement upstream (left side) end of the muffler inner case 31 is connected to the exhaust gas movement upstream (left side) end of the muffler outer case 32 via a thin plate support 38.

  With the above configuration, exhaust gas is discharged from the muffler inner case 31 through the exhaust gas outlet pipe 34. Further, in the silencer inner case 31, exhaust gas sounds (mainly high frequency band sounds) are absorbed into the silencer 39 from the numerous silencer holes 37. The noise of the exhaust gas discharged from the outlet side of the exhaust gas outlet pipe 34 is attenuated.

  As shown in FIGS. 1 and 5, the filter side outlet flange 40 is welded to the exhaust gas movement downstream side (right side) end of the filter inner case 20 and the filter outer case 21. The silencer flange 41 is welded to the exhaust gas movement upstream side (left side) of the silencer outer case 32. The filter side outlet flange 40 and the silencer side flange 41 are detachably fastened by bolts 42 and nuts 43. A sensor connection plug 44 is fixed to the filter inner case 20 and the filter outer case 21. The sensor connection plug 44 is connected to an unillustrated outlet side exhaust gas pressure sensor, an outlet side exhaust gas temperature sensor (thermistor) and the like.

  As shown in FIGS. 1, 2, 5 to 7, a diesel oxidation catalyst 2 or soot filter 3 as a gas purification filter for purifying exhaust gas discharged from the diesel engine 70, and a diesel oxidation catalyst 2 or soot filter 3 are provided. Exhaust gas comprising a catalyst inner case 4 or filter inner case 20 as an inner case to be installed inside, and a catalyst outer case 5 or filter outer case 21 as an outer case in which the catalyst inner case 4 or filter inner case 20 is installed. The gas purification apparatus includes a silencer 39 as an exhaust sound attenuator that attenuates the exhaust sound of the exhaust gas discharged from the diesel engine 70, and the silencer at the exhaust gas outlet side end of the catalyst outer case 5 or the filter outer case 21. 39 is arranged, so that the diesel oxidation catalyst 2 or the soot filter 3 While maintaining the gas-gas purification function, without changing the structure of the diesel oxidation catalyst 2 or the soot filter 3 can be easily added to mute the exhaust gas. For example, an exhaust structure in which a tail pipe is directly connected to the outer case, an exhaust structure that further improves the silencing function of an existing silencer, and the like can be easily configured. In addition, it is possible to easily execute high frequency reduction measures for exhaust gas, which has been difficult to implement in the diesel oxidation catalyst 2 or the soot filter 3 part. For example, a silencing structure (silencing material 39) formed by punch holes and a fibrous mat can be easily installed.

  Since the silencer 30 having the silencer 39 is provided as shown in FIGS. 5 to 7 and the silencer 30 is detachably connected to the exhaust gas outlet side end of the filter outer case 21, By attaching / detaching the silencer 30, the exhaust gas silencing function in the diesel oxidation catalyst 2 or the soot filter 3 can be easily changed.

  As shown in FIG. 5 to FIG. 7, a silencer 30 having a silencer 39 is provided, and the catalyst outer case 5 or the filter outer case 21 and the silencer 30 are formed in a cylindrical shape having substantially the same outer diameter, respectively. A filter-side outlet flange 40 as a ring-shaped flange body is provided at an end portion of the exhaust gas outlet side of 21, and a silencer 39 is attached to an end portion of the exhaust gas outlet side of the filter outer case 21 via the filter-side outlet flange 40. Since the silencer 30 having substantially the same outer diameter is connected to the filter outer case 21 by the filter-side outlet flange 40, the catalyst outer case is arranged in the exhaust gas moving direction. 5 or the filter outer case 21 can be assembled in a compact manner simply by lengthening the mounting dimension of the filter outer case 21. For example, the catalyst outer case 5 or the filter outer case 21 can be easily installed close to the side surface of the exhaust gas discharge part of the diesel engine 70. Moreover, the high frequency reduction measures of exhaust gas can be easily implemented by installing the silencer 39 while improving the gas purification function of the diesel oxidation catalyst 2 or the soot filter 3 by maintaining the temperature of the exhaust gas.

  As shown in FIGS. 5 to 7, the silencer inner case 31 and the silencer outer case 32 as silencer casings in which the silencer 39 is incorporated, the one end side is closed, and the other end side is communicated with a tail pipe (not shown). An exhaust gas outlet pipe 34, and the silencer inner case 31 and the silencer outer case 32 are passed through the exhaust hole 36 forming portion of the exhaust gas outlet pipe 34, and the filter side outlet of the filter outer case 21 is connected to the filter side outlet. Since the silencer inner case 31 and the silencer outer case 32 are detachably connected via the flange 40, the diesel oxidation catalyst 2 or the soot filter can be removed by attaching and detaching the silencer inner case 31 and the silencer outer case 32. It is possible to easily change the exhaust gas silencing function in the third section. For example, by installing a silencer (not shown) separately from the silencer inner case 31 and the silencer outer case 32, an exhaust structure that further improves the exhaust gas silencer function can be easily configured. On the other hand, the exhaust structure in which the tail pipe (not shown) is directly connected to the filter outer case 21 can be easily configured by the arrangement of the silencer inner case 31 and the silencer outer case 32 in which the silencer 39 is not incorporated. Further, as a countermeasure for reducing the high frequency of exhaust gas, which has been difficult to implement in the diesel oxidation catalyst 2 or the soot filter 3 part, a silencer 39 (punch hole and fibrous mat, etc.) is provided in the silencer inner case 31 and the silencer outer case 32. ) The muffler structure can be configured easily.

  As shown in FIGS. 5 to 7, the silencer casing has a cylindrical silencer inner case 31 and a cylindrical silencer outer case 32, and the silencer inner case 31 is arranged in the silencer outer case 32, and the silencer inner case is arranged. Since the silencer 39 is filled between the silencer 31 and the silencer outer case 32 and a number of silencer holes 37 are formed in the silencer inner case 31, the catalyst inner case 4 in which the diesel oxidation catalyst 2 or the soot filter 3 is installed. Alternatively, the silencer casing (the silencer inner case 31 and the silencer outer case 32) can be configured by approximating an exhaust gas purification structure including the filter inner case 20, the catalyst outer case 5, or the filter outer case 21. The silencer casing is silenced by using the same material (pipe or the like) as the catalyst inner case 4 or the filter inner case 20, the catalyst outer case 5 or the filter outer case 21 for installing the diesel oxidation catalyst 2 or the soot filter 3. The inner case 31 and the silencer outer case 32 can be formed. The manufacturing cost of the silencer casing can be easily reduced.

  A modified structure of the exhaust gas inlet 12 will be described with reference to FIGS. 10 to 14. In the above embodiment, as shown in FIG. 9, the exhaust gas inlet 12 is formed by opening substantially elliptical through holes in the catalyst inner case 4 and the catalyst outer case 5. As shown in FIG. 10, the exhaust gas inlet 12 can be formed by opening substantially rectangular through holes in the catalyst inner case 4 and the catalyst outer case 5. Further, as shown in FIG. 11, the exhaust gas inlet 12 can be formed by opening a substantially oval through hole in the catalyst inner case 4 and the catalyst outer case 5. In addition, as shown in FIG. 12, the exhaust gas inlet 12 can be formed by opening substantially polygonal through holes in the catalyst inner case 4 and the catalyst outer case 5. Further, as shown in FIG. 13, the exhaust gas inlet 12 can be formed by opening substantially hexagonal through holes in the catalyst inner case 4 and the catalyst outer case 5. Further, as shown in FIG. 14, the exhaust gas inlet 12 can be formed by opening an indeterminate through hole in the catalyst inner case 4 and the catalyst outer case 5.

  With reference to FIG. 15 thru | or FIG. 18, the structure which provided the said DPF1 in the diesel engine 70 is demonstrated. As shown in FIGS. 15 to 18, an exhaust manifold 71 and an intake manifold 73 are arranged on the left and right side surfaces of the cylinder head 72 of the diesel engine 70. The cylinder head 72 is mounted on a cylinder block 75 having an engine output shaft 74 (crankshaft) and a piston (not shown). The front end and the rear end of the engine output shaft 74 are projected from the front and rear surfaces of the cylinder block 75. A cooling fan 76 is provided on the front surface of the cylinder block 75. The rotational force is transmitted from the front end side of the engine output shaft 74 to the cooling fan 76 via the V belt 77.

  As shown in FIGS. 15, 16, and 18, a flywheel housing 78 is fixed to the rear surface of the cylinder block 75. A flywheel 79 is installed in the flywheel housing 78. A flywheel 79 is pivotally supported on the rear end side of the engine output shaft 74. The power of the diesel engine 70 is taken out via a flywheel 79 to operating parts such as a backhoe 100 and a forklift 120 described later. An oil pan 81 is arranged on the lower surface of the cylinder block 75. Engine leg mounting portions 82 are provided on the side surface of the cylinder block 75 and the side surface of the flywheel housing 78. An engine leg 83 having anti-vibration rubber is fastened to the engine leg mounting portion 82 with bolts 80. The diesel engine 70 is supported via an engine leg 83 on an engine mounting chassis 84 such as a traveling vehicle (backhoe 100, forklift car 120).

  As shown in FIGS. 15, 17, and 18, one end of the support leg 19 is welded to the catalyst outer case 5 and the muffler outer case 32. The other end sides of the left and right support legs 19 are fastened to the engine leg mounting portions 82 on the left and right side surfaces of the flywheel housing 78 with bolts 80. The above-described DPF 1 is supported by the high-rigidity flywheel housing 78 via the support legs 19. The DPF 1 is disposed below the flywheel housing 78 and behind the oil pan 81 so that the exhaust gas movement direction of the DPF 1 is left and right.

  Further, the exhaust gas inlet pipe 16 is connected to the exhaust manifold 71 of the diesel engine 70 via the front exhaust pipe 85. The exhaust gas moves from the exhaust manifold 71 of the diesel engine 70 to the inside of the DPF 1 through the front exhaust pipe 85 and the exhaust gas inlet pipe 16, and the exhaust gas is purified by the DPF 1, and the tail pipe ( The exhaust gas moves to (not shown), and the exhaust gas is discharged outside the apparatus.

  As shown in FIGS. 15 to 18, in an engine device comprising a diesel engine 70 having an exhaust manifold 71 and a DPF1 (diesel particulate filter) as a gas purification filter for purifying exhaust gas discharged from the diesel engine 70, A support leg 19 is provided as a filter support for supporting the DPF 1, and the support leg 19 is provided below the flywheel housing 78 in the diesel engine 70. The flywheel housing 78 is provided with a plurality of support legs 19. DPF1 is connected. Therefore, as one of the components of the diesel engine 70, the DPF 1 can be disposed with high rigidity on the diesel engine 70, and the exhaust gas countermeasures for each device such as a work vehicle can be made unnecessary, and the versatility of the diesel engine 70 can be improved. That is, the DPF 1 can be supported with high rigidity by using the flywheel housing 78 that is a highly rigid part of the diesel engine 70. Damage to the DPF 1 due to vibration or the like can be prevented. The DPF 1 can be incorporated into the diesel engine 70 and shipped at the production site of the diesel engine 70. This saves labor for shipping application for each work machine equipped with the diesel engine 70. The DPF 1 can be communicated with the exhaust manifold 71 at a close distance, the DPF 1 can be easily maintained at an appropriate temperature, and high exhaust gas purification performance can be maintained. The DPF 1 can be configured in a small size.

  As shown in FIGS. 15 to 18, since the support leg 19 is disposed on the engine leg mounting part 82 for supporting the diesel engine 70 in the flywheel housing 78, the engine leg mounting part of the flywheel housing 78 is arranged. By using 82, the DPF 1 can be supported with high rigidity. Damage to the DPF 1 due to vibration or the like can be prevented.

  As shown in FIGS. 15 to 18, the DPF 1 is provided so as to face one side surface of the oil pan 81 on the lower surface side of the diesel engine 70 and the lower surface of the flywheel housing 78. Therefore, the DPF 1 can be installed at the lower position of the flywheel housing 78 where the wind of the cooling fan 76 does not directly hit the cooling fan 76 of the diesel engine 70. The center of gravity of the diesel engine 70 can be lowered to improve vibration isolation. For example, the DPF 1 can be compactly installed adjacent to the side surface of the oil pan 81, the flywheel housing 78, or the like. By simply configuring the upper surface side of the diesel engine 70, maintenance workability of the diesel engine 70 can be improved.

  As shown in FIGS. 15 to 18, the exhaust gas inlet (exhaust gas inlet pipe 16) and the exhaust gas outlet (exhaust gas outlet pipe 34) of the DPF 1 are arranged separately on the left and right sides of the flywheel housing 78. Therefore, the DPF 1 can be supported close to the lower surface of the flywheel housing 78. The DPF 1 can be communicated with the exhaust manifold 71 at a close distance, the DPF 1 can be easily maintained at an appropriate temperature, and high exhaust gas purification performance can be maintained.

  A structure in which the diesel engine 70 is mounted on the backhoe 100 will be described with reference to FIGS. 19 and 20. As shown in FIGS. 19 and 20, the backhoe 100 includes a crawler-type traveling device 102 having a pair of left and right traveling crawlers 103, and a turning machine body 104 provided on the traveling device 102. The revolving machine body 104 is configured to be horizontally revolved over 360 ° in all directions by a revolving hydraulic motor (not shown). An earthwork plate 105 for ground work is mounted on the rear part of the traveling device 102 so as to be movable up and down. A steering unit 106 and a diesel engine 70 are mounted on the left side of the revolving machine body 104. A working unit 110 having a boom 111 and a bucket 113 for excavation work is provided on the right side of the revolving machine body 104.

  The control unit 106 is provided with a control seat 108 on which an operator is seated, operation means for operating the diesel engine 70 and the like, and a lever or switch as an operation means for the work unit 110. A boom cylinder 112 and a bucket cylinder 114 are arranged on a boom 111 which is a component of the working unit 110. A bucket 113 as an attachment for excavation is pivotally attached to the tip end portion of the boom 111 so as to be inserted and rotated. The boom cylinder 112 or the bucket cylinder 114 is operated to perform earthwork work (ground work such as grooving) by the bucket 113.

  A structure in which the diesel engine 70 is mounted on the forklift car 120 will be described with reference to FIGS. 21 and 22. As shown in FIGS. 21 and 22, the forklift car 120 includes a traveling machine body 124 having a pair of left and right front wheels 122 and a rear wheel 123. The traveling body 124 is equipped with a control unit 125 and a diesel engine 70. A working portion 127 having a fork 126 for cargo handling work is provided on the front side portion of the traveling machine body 124. In the control unit 125, a control seat 128 on which an operator is seated, a control handle 129, an operation means for operating the diesel engine 70 and the like, a lever or a switch as an operation means for the working unit 127, and the like are disposed. .

  A fork 126 is arranged on the mast 130 that is a component of the working unit 127 so as to be movable up and down. The fork 126 is moved up and down, a pallet (not shown) loaded with a load is placed on the fork 126, the traveling machine body 124 is moved forward and backward, and a cargo handling operation such as transportation of the pallet is performed. Yes.

1 Diesel particulate filter (DPF) (gas purification filter)
16 Exhaust gas inlet pipe (exhaust gas inlet of DPF)
19 Support leg (filter support)
34 Exhaust gas outlet pipe (DPF exhaust gas outlet)
70 Diesel engine 71 Exhaust manifold 78 Flywheel housing 81 Oil pan 82 Engine leg mounting part

Claims (1)

In an engine apparatus comprising an engine (70) having an exhaust manifold (71) and a gas purification filter (1) for purifying exhaust gas discharged from the engine (70),
A cooling fan (76) is provided on one side of the engine (70), and a flywheel housing (78) is provided on a side of the engine (70) opposite to the cooling fan (76),
The gas cleaning filter (1), the lower position of said flywheel housing of the engine (70) (78), said fly with one side of the oil pan (81) on the lower side of the engine (70) Installed to face the lower surface of the wheel housing (78) ,
The exhaust gas inlet (16) of the gas purification filter (1) and the exhaust manifold (71) are arranged on the same side of the engine (1), and an exhaust pipe (85) is provided in the exhaust manifold (71). The exhaust gas inlet (16) through
One end side of the filter support (19) is fixed to the outer peripheral surface of the gas purification filter (1), and the filter support is mounted on the engine leg mounting portion (82) provided on the side surface of the flywheel housing (78). The other end side of (19) is attached,
Engine equipment.

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