JP2016065544A - Engine device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent accuracy in engine control from being decreased due to a difference in fixing position of a new gas temperature sensor when a temperature of new gas supplied to an intake manifold of an engine is detected by the new gas temperature sensor.SOLUTION: An engine device 1 has an intake manifold 6 and an exhaust manifold 7 that are installed and divided at a right side and a left side; a cooling fan and a flywheel housing that are installed and divided at a front side and a rear side; an exhaust emission control system; EGR device 26; a turbosupercharger 32; and a breather chamber 38. An intake pipe 35 for supplying new gas to the intake manifold 6 and the breather chamber 38 are connected via a blow-by gas return pipe 37. A new gas temperature sensor 120 for detecting a temperature of new gas fed into an intake pipe 35 is fixed to the intake pipe 35.SELECTED DRAWING: Figure 15

Description

  The present invention relates to an engine device.

  Conventionally, the temperature of fresh air supplied to an intake manifold of a diesel engine (hereinafter simply referred to as an engine) is detected by a fresh air temperature sensor. This type of fresh air temperature sensor is disposed in the intake path of the engine (see, for example, Patent Document 1).

JP 2010-180794 A

  However, in the prior art, a fresh air temperature sensor is installed in the intake path on the side of the work machine on which the engine is mounted. May vary from destination to destination. As a result, the detected fresh air temperature naturally changes depending on the mounting position of the fresh air temperature sensor, so that the accuracy of engine control decreases. In order to avoid this, for example, the detection result may be corrected for each attachment position (layout) of the fresh air temperature sensor. However, in this aspect, there is a problem that engine control becomes complicated.

  This invention makes it a technical subject to provide the exhaust-gas purification apparatus which examined and improved the above present condition.

  The present invention relates to an exhaust gas purification device for purifying exhaust gas from the exhaust manifold, wherein the intake manifold and the exhaust manifold are arranged to be divided into left and right, and the cooling fan and the flywheel housing are arranged in the front and rear. An EGR device that mixes EGR gas and fresh air from the exhaust manifold and supplies them to the intake manifold, a turbocharger that compresses fresh air by exhaust from the exhaust manifold, and a head cover that covers the upper surface side of the cylinder head An engine device including a breather chamber for separating lubricating oil disposed therein, wherein the intake pipe communicating with an intake inlet side of a compressor case of the turbine supercharger and the breather chamber include a blow-by gas return pipe. The temperature of fresh air introduced into the intake pipe is detected. Fresh air temperature sensor than it said connecting portion between the blow-by gas return tube in the intake pipe is that is attached to the position where the intake upstream side.

  In the engine device, the EGR device and the turbine supercharger are arranged separately on the left and right sides of the cylinder head, the breather chamber is arranged on the flywheel housing side of the head cover, and the compressor of the turbine supercharger While the intake inlet of the case faces the cooling fan side, the exhaust outlet of the turbine case of the turbine supercharger faces the flywheel housing side, and the connection portion between the intake pipe and the blow-by gas return pipe is It is good also as what is provided in the said cooling fan side rather than the intake outlet of the said compressor case.

  In the engine apparatus, fresh air that is compressed by being connected to an intake outlet side of the compressor case may be installed such that the EGR apparatus supercharging pipe straddles the cylinder head.

  According to the present invention, since the fresh air temperature sensor for detecting the temperature of fresh air introduced into the intake pipe is attached to the intake pipe, the mounting position (layout) of the fresh air temperature sensor with respect to the engine can always be constant. The fresh air temperature can always be measured under the same conditions (position) with respect to the engine. For this reason, correction for the detection result is unnecessary, and the accuracy of engine control can be maintained with a simple configuration. The structure for detecting the fresh air temperature can be configured at low cost.

  According to the present invention, the fresh air temperature sensor is located upstream of the connection with the blow-by gas return pipe in the intake pipe, so that the fresh air temperature can be detected before the blow-by gas is mixed with the fresh air. . It is possible to prevent the fresh air temperature sensor from being damaged by the lubricating oil in the blow-by gas.

  According to the present invention, a sensor mounting base is integrally formed on the upper surface side of the intake pipe, and a fresh air temperature sensor is detachably bolted to the sensor mounting base. Since the connection direction of the wiring connector is set along the longitudinal direction of the intake pipe, the harness connected to the fresh air wiring connector can be along the intake pipe, and the presence of the harness does not get in the way.

It is the perspective view which looked at the engine from diagonally forward. It is a left view of an engine. It is a right view of an engine. It is a top view of an engine. It is a front view of an engine. It is a rear view of an engine. It is the external appearance perspective view which looked at DPF from the purification inlet pipe side. It is the external appearance perspective view which looked at DPF from the purification outlet pipe side. It is a section explanatory view of DPF. It is a separation side view of a clamping flange. It is an external appearance perspective view of DPF which shows the positional relationship of a hanging body and a hanging metal fitting. It is a bottom view of DPF. It is an external appearance perspective view of DPF in the state where the connection flange body was separated. It is an expanded sectional view of a purification inlet pipe. It is an expansion perspective view of an engine explaining the attachment position of a fresh air temperature sensor.

  DESCRIPTION OF EMBODIMENTS Embodiments embodying the present invention will be described below with reference to the drawings.

(1). General Structure of Engine First, a general structure of a common rail engine 1 will be described with reference to FIGS. In the following description, both sides parallel to the crank axis (the sides on both sides of the crank axis) are left and right, the cooling fan 9 arrangement side is the front side, the flywheel housing 10 arrangement side is the rear side, and the exhaust manifold 7 The arrangement side is referred to as the left side, and the intake manifold 6 arrangement side is referred to as the right side.

  As shown in FIGS. 1 to 6, an engine 1 as a prime mover mounted on a work machine such as an agricultural machine or a construction / civil engineering machine is a continuously regenerative exhaust gas purification device 2 (diesel particulate filter, hereinafter referred to as DPF). ). The particulate matter (PM) in the exhaust gas discharged from the engine 1 is removed by the DPF 2 and carbon monoxide (CO) and hydrocarbons (HC) in the exhaust gas are reduced.

  The engine 1 includes a cylinder block 4 that incorporates a crankshaft 3 that is an engine output shaft and a piston (not shown). A cylinder head 5 is mounted on the cylinder block 4. An intake manifold 6 is disposed on the right side surface of the cylinder head 5, and an exhaust manifold 7 is disposed on the left side surface of the cylinder head 5. The upper surface side of the cylinder head 5 is covered with a head cover 8. The front and rear end sides of the crankshaft 3 are projected from both front and rear side surfaces of the cylinder block 4. A cooling fan 9 is provided on the front side of the engine 1. Rotational power is transmitted from the front end side of the crankshaft 3 to the cooling fan 9 via the cooling fan V-belt 22.

  A flywheel housing 10 is provided on the rear side of the engine 1. A flywheel 11 is accommodated in the flywheel housing 10 in a state of being supported on the rear end side of the crankshaft 3. The rotational power of the engine 1 is transmitted from the crankshaft 3 to the operating part of the work machine via the flywheel 11. An oil pan 12 that stores lubricating oil is disposed on the lower surface of the cylinder block 4. The lubricating oil in the oil pan 12 is supplied to each lubricating portion of the engine 1 through the oil filter 13 and the like disposed on the right side surface of the cylinder block 4, and then returns to the oil pan 12.

  A fuel supply pump 14 is provided on the right side of the cylinder block 4 above the oil filter 13 (below the intake manifold 6). The engine 1 includes an injector 15 for four cylinders having an electromagnetic opening / closing control type fuel injection valve (not shown). Each injector 15 is connected to a fuel tank (not shown) mounted on the work machine via a fuel supply pump 14, a cylindrical common rail 16 (pressure accumulation chamber), and a fuel filter 17. Fuel in the fuel tank is pumped from the fuel supply pump 14 to the common rail 16 via the fuel filter 17, and high-pressure fuel is stored in the common rail 16. By controlling opening and closing of the fuel injection valve of each injector 15, high-pressure fuel in the common rail 16 is injected from each injector 15 to each cylinder of the engine 1.

  On the front side of the cylinder block 4, a cooling water pump 21 for lubricating lubricating water is arranged coaxially with the fan shaft of the cooling fan 9. The cooling water pump 21 is driven together with the cooling fan 9 via the cooling fan V-belt 22 by the rotational power of the crankshaft 3. Cooling water in a radiator (not shown) mounted on the work machine is supplied to the cylinder block 4 and the cylinder head 5 by driving the cooling water pump 21 to cool the engine 1. The cooling water that has contributed to the cooling of the engine 1 is returned to the radiator. An alternator 23 is arranged on the left side of the cooling water pump 21.

  Engine leg mounting portions 24 are respectively provided on the left and right side surfaces of the cylinder block 4. Each engine leg mounting portion 24 is bolted to an engine leg (not shown) having vibration-proof rubber. The engine 1 is supported in a vibration-proof manner on a work machine (specifically, an engine mounting chassis) through each engine leg.

  As shown in FIGS. 2 and 4, the inlet portion of the intake manifold 6 is connected to an air cleaner (not shown) via an EGR device 26 (exhaust gas recirculation device). The fresh air (external air) sucked into the air cleaner is dust-removed and purified by the air cleaner, then sent to the intake manifold 6 via the EGR device 26 and supplied to each cylinder of the engine 1.

  The EGR device 26 mixes a part of the exhaust gas of the engine 1 (EGR gas from the exhaust manifold 7) and fresh air (external air from the air cleaner) and supplies them to the intake manifold 6; The EGR body case 27 is connected to the recirculation exhaust gas pipe 30, the recirculation exhaust gas pipe 30 connected to the exhaust manifold 7 via the EGR cooler 29, and the recirculation exhaust gas pipe 30. EGR valve member 31 is provided.

  An intake throttle member 28 is connected to the intake manifold 6 via an EGR main body case 27. The intake throttle member 28 is bolted to one end of the EGR main body case 27 in the longitudinal direction. The left and right inwardly opening end portions of the EGR main body case 27 are bolted to the inlet portion of the intake manifold 6. An outlet side of the recirculated exhaust gas pipe 30 is connected to the EGR main body case 27 via an EGR valve member 31. The inlet side of the recirculated exhaust gas pipe 30 is connected to the lower surface side of the exhaust manifold 7 via the EGR cooler 29. The amount of EGR gas supplied to the EGR main body case 27 is adjusted by adjusting the opening of an EGR valve (not shown) in the EGR valve member 31.

  In the above configuration, fresh air (external air) is supplied from the air cleaner through the intake throttle member 28 into the EGR main body case 27, while EGR is supplied from the exhaust manifold 7 through the EGR valve member 31 into the EGR main body case 27. Gas (a part of the exhaust gas discharged from the exhaust manifold 7) is supplied. After fresh air from the air cleaner and EGR gas from the exhaust manifold 7 are mixed in the EGR main body case 27, the mixed gas in the EGR main body case 27 is supplied to the intake manifold 6. In this way, a part of the exhaust gas discharged from the exhaust manifold 7 is recirculated to the engine 1 via the intake manifold 6, thereby lowering the maximum combustion temperature during high load operation and reducing NOx (nitrogen oxidation from the engine 1. Waste) is reduced.

  As shown in FIGS. 1 to 5, a turbocharger 32 is disposed on the right side of the cylinder head 5 and above the exhaust manifold 7. The turbocharger 32 includes a turbine case 33 with a built-in turbine wheel (not shown) and a compressor case 34 with a blower foil (not shown). The exhaust inlet side of the turbine case 33 is connected to the outlet portion of the exhaust manifold 7. The exhaust outlet side of the turbine case 33 is connected to a tail pipe (not shown) via the DPF 2. Exhaust gas discharged from each cylinder of the engine 1 to the exhaust manifold 7 is discharged to the outside through the turbine case 33 of the turbocharger 32, the DPF 2, and the like.

  An intake inlet side of the compressor case 34 is connected to an air cleaner via an intake pipe 35. An intake outlet side of the compressor case 34 is connected to an intake throttle member 28 via a supercharging pipe 36. The fresh air removed by the air cleaner is sent from the compressor case 34 to the intake manifold 6 via the intake throttle member 28 and the EGR main body case 27 and supplied to each cylinder of the engine 1. The intake pipe 35 is connected to a breather chamber 38 in the head cover 8 via a blow-by gas return pipe 37 (see FIG. 7). The blow-by gas from which the lubricating oil is separated and removed in the breather chamber 38 is returned to the intake pipe 35 through the blow-by gas return pipe 37, is returned to the intake manifold 6, and is supplied again to each cylinder of the engine 1.

  As shown in detail in FIG. 15, a fresh air temperature sensor 120 that detects the temperature of fresh air introduced into the intake pipe 35 is attached to the intake pipe 35. A mixed gas temperature sensor 121 that detects the temperature of the mixed gas is attached to the intake manifold 6. Further, an EGR gas temperature sensor 122 that detects the temperature of EGR gas from the exhaust manifold 7 is attached to the EGR valve member 31. These temperature sensors 120 to 122 attached to the engine side are used for obtaining the EGR rate of the mixed gas. Here, the EGR rate means a value obtained by dividing the EGR gas amount by the sum of the EGR gas amount and the fresh air amount (= EGR gas amount / (EGR gas amount + new air amount)).

  The fresh air temperature sensor 120 of the embodiment is located on the intake air upstream side of the connection part 123 with the blow-by gas return pipe 37 in the intake pipe 35. A sensor mounting base 124 is integrally formed on the upper surface side of the intake pipe 35. The fresh air temperature sensor 120 is detachably bolted to the sensor mount 124. The detection part of the fresh air temperature sensor 120 protrudes into the intake pipe 35.

  If comprised in this way, the attachment position (layout) of the fresh air temperature sensor 120 with respect to the engine 1 can always be made constant, and fresh air temperature can always be measured with respect to the engine 1 under the same conditions (position). For this reason, correction for the detection result is unnecessary, and the accuracy of engine control can be maintained with a simple configuration. The structure for detecting the fresh air temperature can be configured at low cost. Further, since the fresh air temperature sensor 120 is positioned on the intake air upstream side of the connection part 123 with the blow-by gas return pipe 37 in the intake pipe 35, the fresh air temperature can be detected before the blow-by gas is mixed with the fresh air. . The fresh air temperature sensor 120 can be prevented from being contaminated by the lubricating oil in the blow-by gas. In addition, since the intake upstream side of the intake pipe 35 is connected to an air cleaner via a rubber hose, vibrations that reach the fresh air temperature sensor 120 can be reduced by the presence of the rubber hose. As a result, the durability of the fresh air temperature sensor 120 can be improved.

  The fresh air temperature sensor 120 is integrally provided with a fresh air wiring connector 125. In the embodiment, the connection direction of the fresh air connector 125 is aligned with the longitudinal direction of the intake pipe 35. If comprised in this way, the harness connected to the wiring connector 125 for fresh air can be made to follow the intake pipe 35, and presence of a harness does not become obstructive.

(2). Next, a schematic structure of the DPF 2 will be described with reference to FIGS. The DPF 2 includes a purification casing 40 made of a heat-resistant metal material having a purification inlet pipe 41 and a purification outlet pipe 42. Inside the purification casing 40 is a diesel oxidation catalyst 43 such as platinum that generates nitrogen dioxide (NO2), and a soot filter with a honeycomb structure that continuously oxidizes and removes the collected particulate matter (PM) at a relatively low temperature. 44 are accommodated in series in the exhaust gas movement direction (see the arrow direction in FIG. 9). A purification inlet pipe 41 and a purification outlet pipe 42 are provided separately on both sides in the longitudinal direction (one end side and the other end side) of the purification casing 40. The purification inlet pipe 41 is connected to the exhaust outlet side of the turbine case 33. The purification outlet pipe 42 is connected to a tail pipe (not shown).

  In the above configuration, the exhaust gas of the engine 1 flows into the purification casing 40 from the exhaust outlet side of the turbine case 33 via the purification inlet pipe 41 and passes through the diesel oxidation catalyst 43 and the soot filter 44 in this order for purification. It is processed. Particulate matter in the exhaust gas is collected without passing through the porous partition wall between the cells in the soot filter 44. Thereafter, exhaust gas that has passed through the diesel oxidation catalyst 43 and the soot filter 44 is discharged toward the tail pipe.

  When the exhaust gas passes through the diesel oxidation catalyst 43 and the soot filter 44, if the exhaust gas temperature exceeds a renewable temperature (for example, about 300 ° C.), the oxidation of the exhaust gas is caused by the action of the diesel oxidation catalyst 43. Nitrogen (NO) is oxidized to unstable nitrogen dioxide. Then, oxygen (O) released when nitrogen dioxide returns to nitric oxide oxidizes and removes the particulate matter deposited on the soot filter 44, so that the particulate matter collecting ability of the soot filter 44 is recovered (soot). The filter 44 self-regenerates).

  In the embodiment, the other end in the longitudinal direction of the purification casing 40 is configured as a silencer 45, and the purification outlet pipe 42 is provided in the silencer 45. The diesel oxidation catalyst 43 and the soot filter 44 correspond to a filter body for exhaust gas purification.

  The purification casing 40 includes a catalyst inner case 46 and a catalyst outer case 47, a filter inner case 48 and a filter outer case 49, and a sound deadening inner case 50 and a sound deadening outer case 51. The combination of each of the inner cases 46, 48, 50 and the outer cases 47, 49, 51 has a double cylinder structure. A diesel oxidation catalyst 43 is accommodated in the catalyst inner case 46. The soot filter 44 is accommodated in the filter inner case 48. Between the outer peripheral side of the catalyst inner case 46 and the inner peripheral side of the catalyst outer case 47, a thin plate support 52 having an L-shaped cross section is disposed. The outer peripheral side of the catalyst inner case 46 and the inner peripheral side of the catalyst outer case 47 are connected via a thin plate support 52.

  The combination of the inner cases 46 and 48 and the outer cases 47 and 49 corresponds to a purification case that is a component of the purification casing 40. The DPF 2 of the embodiment includes the silencer 45, but the silencer 45 itself is not an essential component of the DPF 2. That is, the silencer inner case 50 and the silencer outer case 51 are not essential components of the purification casing 40.

  A catalyst inner lid 53 is welded and fixed to one end side (end portion on the exhaust upstream side) of the catalyst inner case 46 and the catalyst outer case 47. One end sides of the catalyst inner case 46 and the catalyst outer case 47 are closed by a catalyst inner lid 53. A catalyst outer lid body 54 that covers the catalyst inner lid body 53 from the outside is welded and fixed to the outer end face side of the catalyst inner lid body 53. A purification inlet pipe 41 is welded and fixed to the outer peripheral side of the catalyst outer case 47. The purification inlet pipe 41 communicates with the catalyst inner case 46 via an exhaust gas inlet 55 formed in the catalyst inner case 46 and the catalyst outer case 47.

  A thin plate-like catalyst flange 56 protruding from the outer peripheral side (radius outer side) of the catalyst outer case 47 is welded and fixed to the other end side (end portion on the exhaust downstream side) of the catalyst inner case 46. The other end side of the catalyst outer case 47 is welded and fixed to the outer peripheral side of the catalyst flange 56. On the other hand, a thin plate-like filter inlet flange 57 that protrudes from the outer peripheral side of the filter outer case 49 is welded and fixed to a longitudinal middle part of the outer peripheral side of the filter inner case 48. One end side (end portion on the upstream side of the exhaust) of the filter outer case 49 is fixed by welding to the outer peripheral side of the filter inlet flange 57.

  As shown in FIGS. 7 to 9, the catalyst flange 56 and the filter inlet flange 57 are brought into contact with each other via a gasket 58, and both are sandwiched by thick plate-like central clamping flanges 59 and 60 that surround the outer peripheral sides of the outer cases 47 and 49. The flanges 56 and 57 are clamped from both sides in the exhaust gas movement direction, and both the central clamp flanges 59 and 60 are fastened together with both the flanges 56 and 57 with bolts 61 and nuts 62, so that the catalyst outer case 47 and the filter outer case 49 Are concatenated. In a state where the catalyst outer case 47 and the filter outer case 49 are connected, one end side of the filter inner case 46 overlaps (inserts) from the other end side of the catalyst inner case 46 and the catalyst outer case 47. ).

  The silencer 45 located on the other longitudinal end side of the purification casing 40 includes a silencer inner case 50 and a silencer outer case 51 having a double cylinder structure. A partition lid 63 is welded and fixed to one end side (end portion on the exhaust upstream side) of the silencer inner case 50. One end side of the silencer inner case 50 is closed by a partition lid 63. A silencer inner lid body 64 is welded and fixed to the other end side (end portion on the exhaust downstream side) of the silencer inner case 50 and the silencer outer case 51. On the outer end face side of the silencer inner lid body 64, a silencer outer lid body 65 that covers the silencer inner lid body 64 from the outside is welded and fixed.

  A pair of communication pipes 66 is provided between the partition lid 63 and the muffler inner lid 64 (only one is shown in FIG. 9). One end side of both communication pipes 66 penetrates the partition lid 63. The other end side of both the communication pipes 66 is closed by a sound deadening inner lid body 64. A number of communication holes 67 are formed in each communication pipe 66. The inside of the silencer inner case 50 partitioned by the partition lid 63 and the silencer inner lid 64 is configured as a resonance chamber that communicates with both the communication pipes 66 through the communication holes 67.

  The sound-absorbing inner case 50 and the sound-absorbing outer case 51 are penetrated by a purification outlet pipe 42 that passes between the two communication pipes 66. A pair of outlet lid bodies 68 are welded and fixed to one end side (upper end side) of the purification outlet pipe 42. One end side of the purification outlet pipe 42 is closed by both outlet lid bodies 68. Both outlet lids 68 are arranged at an appropriate interval in the vertical direction. A number of exhaust holes 69 are formed in a portion of the purification outlet pipe 42 in the silencer inner case 50. Accordingly, both the communication pipes 66 in the silencer inner case 50 communicate with the purification outlet pipe 42 through the communication hole 67, the resonance chamber and the exhaust hole 69. The other end side (lower end side) of the purification outlet pipe 42 is connected to, for example, a tail pipe or an existing silencing member. In the above configuration, the exhaust gas that has entered the both communication pipes 66 of the muffler inner case 46 passes through the purification outlet pipe 42 via the communication hole 67, the resonance chamber and the exhaust hole 69, and is discharged out of the silencer 45. The

  A thin plate-like filter outlet flange 70 protruding from the outer peripheral side of the filter outer case 49 is fixed to the other end side of the filter inner case 48 by welding. The other end side of the filter outer case 49 is fixed to the outer peripheral side of the filter outlet flange 70 by welding. On the other hand, a thin plate-like silencing flange 71 protruding from the outer peripheral side of the silencing outer case 51 is welded and fixed to one end side of the silencing inner case 50. One end side of the silencer outer case 51 is welded and fixed to the outer peripheral side of the silencer flange 71.

  As shown in FIGS. 7 to 9, the filter outlet flange 70 and the silencing flange 71 are brought into contact with each other via a gasket 72, and both are connected by thick plate-like outlet clamping flanges 73 and 74 that surround the outer peripheral sides of the outer cases 49 and 51. The flanges 70 and 71 are clamped from both sides in the exhaust gas movement direction, and both the outlet clamping flanges 73 and 74 are fastened together with both the flanges 70 and 71 by bolts 75 and nuts 76. Are concatenated.

  Each center clamping flange 59 (60) is composed of arcuate bodies 59a, 59b (60a, 60b) divided into a plurality of portions in the circumferential direction of the corresponding outer case 47 (49). Each arc body 59a, 59b (60a, 60b) is formed in an arc shape (substantially semicircular horseshoe shape). In a state where the catalyst outer case 47 and the filter outer case 49 are connected, the ends of both arcs 59a, 59b (60a, 60b) face each other in the circumferential direction, and the catalyst outer case 47 (filter outer case 49). ). Here, the abutting portions of the ends of the arcuate bodies 59a and 59b on the catalyst side and the arcuate bodies 60a and 60b on the filter inlet side are placed at positions shifted from each other (the abutting portions are overlapped in the same phase). Absent). Each of the circular arc bodies 59a, 59b, 60a, 60b constituting the central clamping flanges 59, 60 has the same form.

  Each outlet pinching flange 73 (74) is also composed of arcuate bodies 73a and 73b (74a and 74b) divided into a plurality of portions in the circumferential direction of the corresponding outer case 49 (51), like the central pinching flanges 59 and 60. Yes. The arc bodies 73a and 73b (74a and 74b) have basically the same form as the arc bodies 59a and 59b (60a and 60b) of the center clamping flange 59 (60). The abutting portions between the ends of the arcuate bodies 73a and 73b on the filter outlet side and the arcuate bodies 74a and 74b on the silencing side are also placed at positions that are out of phase with each other.

  A connecting leg 77 for supporting the purification casing 40 on the engine 1 is detachably attached to at least one of the sandwiching flanges 59, 60, 73, 74. In the embodiment, a leg fastening portion 78 with a through hole is formed in one arcuate body 73 a of the outlet pinching flange 73. An attachment boss portion corresponding to the leg fastening portion 78 of the arc member 73a is formed on the connecting leg 77. The connecting leg 77 is detachably attached to the outlet holding flange 73 on the filter outlet side by bolting the mounting boss portion of the connecting leg 77 to the leg fastening portion 78 of the arc member 73a. A fixed leg 79 for supporting the purification casing 40 on the engine 1 is fixed to the outer peripheral side of the purification casing 40 (in the embodiment, the catalyst outer case 47) by welding. The connecting leg 77 and the fixed leg 79 are bolted to a DPF attachment portion 80 formed on the upper surface side of the flywheel housing 10. That is, the DPF 2 is stably connected and supported on the flywheel housing 10, which is a highly rigid member, by the connecting legs 77 and the fixed legs 79.

  As shown in FIGS. 7 and 8, an exhaust gas pressure sensor 81 for detecting the exhaust gas pressure in the purification casing 40 and an exhaust gas for detecting the exhaust gas temperature in the purification casing 40 are disposed on the outer peripheral side of the purification casing 40. And a gas temperature sensor 82. The exhaust gas pressure sensor 81 detects the pressure difference of the exhaust gas between the exhaust upstream side and the exhaust downstream side across the soot filter 44. Based on the pressure difference, the amount of particulate matter deposited on the soot filter 44 is converted, and the clogged state in the DPF 2 is grasped.

  At least one of the sandwiching flanges 59, 60, 73, 74 is detachably attached with a sensor bracket 83 having a substantially L-shaped plate that supports the exhaust gas pressure sensor 81 and the exhaust gas temperature sensor 82. In the embodiment, a sensor support portion 86 with a through hole is formed in one arcuate body 74 a of the outlet clamping flange 74 on the silencer side. That is, the sensor support portion 86 is formed in a part of the muffler-side outlet pinching flange 74 farthest from the exhaust gas inlet 55 side. The sensor bracket 83 is detachably attached to the mute-side outlet pinching flange 74 by bolting the vertical plate portion 85 of the sensor bracket 83 to the sensor support portion 86 of the arcuate body 43a.

  As shown in FIGS. 7, 8, and 10, the sensor support portion 86 of the arcuate body 74 a projects to the outer peripheral side (radius outside) of the purification casing 40. For this reason, the horizontal plate portion 84 of the sensor bracket 83 is separated outward from the outer peripheral side of the purification casing 40. The exhaust gas pressure sensor 81 and the exhaust gas temperature sensor 82 are juxtaposed on the horizontal plate portion 84 of the sensor bracket 83. The horizontal plate portion 84 of the sensor bracket 83 is located on the outer peripheral side of the filter outer case 49 so that the sensors 81 and 82 are within the length range of the purification casing 40 in the exhaust gas movement direction. If such a mounting structure is adopted, even if the silencer 45 is not directly attached to the DPF 2, both the sensors 81 and 82 can be accommodated within the length range of the purification casing 40 in the exhaust gas movement direction.

  The exhaust gas pressure sensor 81 is integrally provided with a pressure wiring connector 87. The exhaust gas pressure sensor 81 is connected to the proximal end sides of the upstream and downstream pipe joint bodies 90 and 91 via upstream and downstream sensor pipes 88 and 89, respectively. A pressure boss body 92 is fixed to the catalyst inner case 46 and the filter inner case 48 by welding so as to sandwich the soot filter 44 therebetween. The outward protruding end side of each pressure boss body 92 protrudes radially outward from the opening formed in the corresponding outer case 47, 49. The distal ends of the pipe joint bodies 90 and 91 are fastened to the corresponding pressure boss bodies 92 via pipe joint bolts 93, respectively.

  The exhaust gas temperature sensor 82 includes a temperature wiring connector 94 on the horizontal plate portion 84 of the sensor bracket 83. Three sensor pipes 95 to 97 extend from the exhaust gas temperature sensor 82 (which may be referred to as a temperature wiring connector 94). A temperature boss body 98 is fixed to the catalyst inner case 46 and the filter inner case 48 by welding. Two temperature bosses 98 are provided in the catalyst inner case 46, and one temperature boss body 98 is provided in the filter inner case 48. The outward protruding end side of each temperature boss body 98 protrudes radially outward from the opening formed in the corresponding outer case 47, 49. Detection bolts 95 to 97 extending from the exhaust gas temperature sensor 82 are passed through mounting bolts 99 screwed to the temperature boss bodies 98, and the sensor pipes 95 are connected to the temperature boss bodies 98 via the mounting bolts 99. The detection part at the tip of ~ 97 is fixed. The detection portions at the tips of the sensor pipes 95 to 97 are between the catalyst inner lid 53 and the diesel oxidation catalyst 43, between the diesel oxidation catalyst 43 and the soot filter 44, and between the soot filter 44 and the partition lid body 63. Each rushes in between.

  In the embodiment, the exhaust gas pressure sensor 81 and the exhaust gas temperature sensor 82 are placed on the horizontal plate portion 84 of the sensor bracket 83 with the connection direction of the pressure wiring connector 87 and the temperature wiring connector 94 being in the same direction. It is fixed. For this reason, the connection workability of the wiring with respect to each connector 87,94 can be improved.

  In the embodiment, the suspension body 101 is integrally formed on the other arcuate body 73b of the outlet holding flange 73 on the filter outlet side, and the suspension fitting 102 is bolted to the catalyst outer lid body 54 of the purification casing 40. It is concluded. The suspension body 101 and the suspension fitting 102 are opposed to each other in the exhaust gas movement direction so that the respective opening holes 103 and 104 are located in the diagonal direction of the purification casing 40 (direction intersecting the longitudinal axis A). (See FIG. 11). Not only the outlet clamping flange 73 on the filter outlet side, but also the other clamping flanges 59, 60, 74 correspond to thick plate flanges for connecting the purification case. That is, the suspended body 101 may be integrally formed with the other holding flanges 59, 60, and 74.

  If comprised in this way, in the assembly factory etc. of the engine 1, for example, the suspension body 101 and the suspension metal fitting 102 are locked to the hook (not shown) of the chain block, and the purification casing 40 is moved up and down by the chain block. The purification casing 40 can be assembled to the casing. That is, the purification casing 40 can be smoothly mounted on the engine 1 by using the suspended body 101 and the suspension fitting 102 without the operator lifting the purification casing 40 by himself / herself.

  Further, the purification casing 40, which is a heavy object, can be suspended in a stable posture by the positional relationship in the diagonal direction between the suspended body 101 and the suspended metal fitting 102. For example, the DPF attachment portion 80 of the flywheel housing 10 and the connecting leg body 77 and the fixed leg 79 can be easily aligned. Therefore, the assembly workability of the DPF 2 can be improved.

  By the way, as shown in FIG. 10, each clamping flange 59, 60, 73, 74 corresponding to a thick plate flange is provided with a plurality of bolt fastening portions 105 with through holes at equal intervals along the circumferential direction. . In the embodiment, ten bolt fastening portions 105 are provided for each pair of clamping flanges 59, 60, 73 and 74. When viewed in units of arcs 59a, 59b, 60a, 60b, 73a, 73b, 74a, and 74b, five bolt fastening portions 105 are provided at equal intervals along the circumferential direction. Bolt holes 106 corresponding to the respective bolt fastening portions 105 of the clamping flanges 59, 60, 73, 74 are formed in the flanges 56, 57, 70, 71. For this reason, the mounting phase of the arcuate bodies 59a, 59b, 60a, 60b, 73a, 73b, 74a, 74b of the holding flanges 59, 60, 73, 74 is around the longitudinal axis A in the exhaust gas movement direction of the purification casing 40. It can be changed in multiple stages (along the circumferential direction of the purification casing 40).

  If comprised in this way, without changing the shape (formation position of the suspension body 101) of each clamping flange 59, 60, 73, 74, the connection direction (DPF2 with respect to the engine 1) of the purification inlet pipe 41 or the purification outlet pipe 42 ), The position of the suspended body 101 can be easily changed, which can contribute to further improvement in the assembly workability of the DPF 2.

  As shown in detail in FIG. 9, the lid that closes both ends of the purification casing 40 in the exhaust gas movement direction has a double structure of the inner lids 53 and 64 and the outer lids 54 and 65. . And the water which accumulates between the inner cover bodies 53 and 64 and the outer cover bodies 54 and 65 is discharged | emitted to the location located in the lower part in the outer cover bodies 54 and 65 in the state which mounted the purification casing 40 in the engine 1. A first drain hole 107 is formed (see FIGS. 7 to 11). The outer lid bodies 54 and 65 are formed in the substantially same disc shape. The first drain hole 107 is formed in the peripheral edge in the radial direction with respect to the center line (longitudinal axis A) in the exhaust gas movement direction in each of the outer lid bodies 54 and 65. The first drain hole 107 of the embodiment opens at the peripheral edge in the cross direction when viewed from the center line (longitudinal axis A) in the exhaust gas movement direction (four to one outer lid body 54, 65). Some places are open). The inner lid bodies 53 and 64 and the outer lid bodies 54 and 65 communicate with the outside through the first drain holes 107.

  If comprised in this way, although the both ends of the exhaust gas movement direction of the purification | cleaning casing 40 are plugged up with the double structure of the inner cover bodies 53 and 64 and the outer cover bodies 54 and 65, heat insulation is ensured, Water accumulated between the inner lid bodies 53 and 64 and the outer lid bodies 54 and 65 due to condensation, rain water, or the like can be discharged from the first drain hole 107, and the drainage of the DPF 2 is improved. For this reason, the corrosion resistance performance of DPF2 improves. In addition, since both ends of the purification casing 40 in the exhaust gas movement direction are closed by the outer lid bodies 54 and 65 having the same shape, it is possible to reduce the number of components and contribute to cost reduction. Without changing the shape of the outer lid bodies 54 and 65, the direction of attachment around the center line (longitudinal axis A) of the outer lid bodies 54 and 65 is adjusted with respect to each end of the purification casing 40 in the exhaust gas movement direction. Easy to change. As a result, the degree of freedom of the mounting direction of the outer case (for example, the catalyst outer case 47 and the muffler outer case 51) with respect to the engine 1 can be increased.

  As shown in FIG. 12, in a state where the purification casing 40 is mounted on the engine 1, the outer cases 47 and 49 are located at least in the lower part and are collected between the inner cases 46 and 48 and the outer cases 47 and 49. A second drain hole 108 for discharging water is formed. In the embodiment, second drain holes 108 are formed at three locations of the catalyst outer case 47 on both sides of the fixed leg 79 and the filter outer case 49. If comprised in this way, although the purification | cleaning casing 40 is comprised in the double structure of the inner side cases 46 and 48 and the outer side cases 47 and 49, and heat insulation was ensured, the inner case 46, dew, rain water, etc. Water accumulated between the outer case 47 and the outer cases 47 and 49 can be discharged from the second drain hole 108, and the drainage of the DPF 2 is improved. For this reason, it can contribute to the further improvement of the corrosion resistance performance of DPF2.

  As shown in FIGS. 13 and 14, a connection flange body 110 that is fastened to the exhaust outlet side of the turbine case 33 is welded to the distal end side of the purification inlet pipe 41 provided on the outer peripheral side of the catalyst outer case 47. It is fixed. An annular protrusion 111 is integrally formed on the connection flange body 110 by projecting an opening edge formed in the center in the direction of the purification inlet pipe 41. The purification inlet pipe 41 is inserted into the opening at the center of the connection flange body 110, and the annular protrusion 111 of the connection flange body 110 and the tip outer peripheral side of the purification inlet pipe 41 are welded.

  If comprised in this way, since the welding part with the front-end | tip outer peripheral side of the purification inlet pipe 41 will space apart from the flat part of the connection flange body 110, the connection flange body 110 will be fixed to the purification inlet pipe 41 by welding. Nevertheless, the adverse effect of high heat due to welding hardly affects the connection flange body 110, and the flatness of the flat portion of the connection flange body 110 can be maintained. Therefore, it is possible to suppress the possibility that stress that causes damage to the DPF 2 is locally generated in the connection flange body 110.

  As shown in FIGS. 13 and 14, the purification inlet pipe 41 has a double cylinder structure. The purification inlet pipe 41 of the embodiment includes a funnel-like portion 112 having a divergent shape that covers the exhaust gas inlet 55 formed in the catalyst outer case 47 from the outside, and an inner cylindrical portion that is fixedly inserted into the tip opening of the funnel-like portion 112. 113 and an outer cylindrical portion 114 fitted to the inner cylindrical portion 113. The base end side of the funnel-shaped portion 112 is welded and fixed to the outer peripheral side of the catalyst outer case 47. The overlapping part of the front end side of the funnel-shaped part 112 in which the inner cylinder part 113 was inserted, and the base end side of the outer cylinder part 114 is being fixed by welding. The distal end side of the outer cylindrical portion 114 is fixed to the inner cylindrical portion 113 by welding. The front end side of the inner cylinder part 113 protrudes from the outer cylinder part 114, and the connection flange body 110 is fixed to the part by welding. With this configuration, the heat insulation performance is improved not only in the purification casing 40 but also in the purification inlet pipe 41. Therefore, the temperature drop of the exhaust gas in the purification casing 40 can be suppressed. Moreover, the temperature rise in the arrangement | positioning space (for example, hood of a working machine) of the engine 1 can be prevented, and heat balance deterioration can be suppressed.

  As shown in FIG. 9, the purification outlet pipe 42 passes through the purification casing 40. In the embodiment, the purification outlet pipe 42 is passed through the silencer inner case 50 and the silencer outer case 51. One end side (upper end side) which is an end portion on the closed side of the purification outlet pipe 42 is configured in a double wall structure. In this case, a pair of outlet lid bodies 68 are welded and fixed to one end side of the purification outlet pipe 42, and one end side of the purification outlet pipe 42 is closed by both outlet lid bodies 68. Both outlet lids 68 are arranged at an appropriate interval in the vertical direction. The air layer between the two outlet lid bodies 68 contributes as a heat insulating layer. With this configuration, the heat insulation performance is improved not only in the purification casing 40 and the purification inlet pipe 41 but also in the purification outlet pipe 42. Therefore, the temperature drop of the exhaust gas in the purification casing 40 can be further suppressed. Moreover, the temperature rise in the arrangement | positioning space (for example, hood of a working machine) of the engine 1 can be prevented, and a heat balance deterioration can be suppressed more reliably.

(3). Summary As is clear from the above configuration, a purification casing comprising a plurality of filter bodies 43, 44 for purifying the exhaust gas discharged from the engine 1 and a plurality of purification cases 46-49 incorporating the filter bodies 43, 44. 40, an exhaust gas pressure sensor 81 for detecting the exhaust gas pressure in the purification casing 40, and an exhaust gas temperature sensor 82 for detecting the exhaust gas temperature in the purification casing 40. Since the sensors 81 and 82 are disposed on the outer peripheral side of the purification casing 40 so as to be within the length range of the purification casing 40 in the exhaust gas movement direction, In addition, it is not necessary to evaluate the suitability of the initial setting (adjustment) of each of the sensors 81 and 82, and the number of evaluation man-hours for designing and testing can be reduced. The components related to the exhaust gas purification device 2 can be standardized. Since the mounting positions of the sensors 81 and 82 are within the length range of the purification casing 40 in the exhaust gas movement direction, the purification casing 40 (the exhaust gas purification device 2) has a total length in the exhaust gas movement direction. The influence of both the sensors 81 and 82 can be eliminated. As a result, the exhaust gas purification device 2 including both the sensors 81 and 82 can be compactly arranged in the arrangement space of the engine 1.

  In addition, a sensor bracket 83 is detachably attached to a sensor support portion 86 provided on a part of the flanges 59, 60, 73, 74 of the purification cases 46 to 49, and both sensors are attached to the sensor bracket 83. Since 81 and 82 are provided, both the sensors 81 and 82 are supported by the highly rigid flanges 59, 60, 73 and 74, and vibrations transmitted to both the sensors 81 and 82 can be reduced. For this reason, an adverse effect on the detection accuracy of the sensors 81 and 82 can be suppressed. The sensors 81 and 82 can be prevented from falling off.

  Further, the sensor support portion 86 is formed in a part of the flange 74 farthest from the exhaust gas inlet 55 side in the purification cases 46 to 49, and the horizontal plate portion 84 of the sensor bracket 83 is the purification casing 40. Since the both sensors 81 and 82 are arranged in parallel on the horizontal plate portion 84, the heat generated by the exhaust gas purifying device 2 is the two sensors 81 and 82. It is hard to be transmitted to. For this reason, although both said sensors 81 and 82 are assembled | attached to the said exhaust gas purification apparatus 2, the failure of both said sensors 81 and 82 by overheating can be suppressed. In addition, since the exhaust gas purification device 2 and the sensors 81 and 82 are close to each other, the lengths of the sensor pipes 88, 89, and 95 to 97 that connect the exhaust gas purification device 2 and the sensors 81 and 82 are long. The length can be set short, and the assembly workability can be improved and the cost can be reduced.

  As apparent from the above description and FIGS. 7, 8, and 11, a plurality of filter bodies 43, 44 that purify the exhaust gas discharged from the engine 1, and a plurality of purification bodies that incorporate the filter bodies 43, 44. In the exhaust gas purifying apparatus 2 including the purification casing 40 including the cases 47, 49, 51, the purification cases 47, 49, 51 are arranged in the exhaust gas moving direction on the thick plate flanges 59, 60, 73, 74. The purification casing 40 is configured by connecting the suspension plate 101 and the suspension body 101 is integrally formed with the thick plate flange 73. For example, in the assembly factory of the engine 1, for example, the hook of the chain block The suspension body 101 and the suspension fitting 102 are locked to (not shown), and the purification casing is secured by the chain block. To lift 40 can be assembled the purification casing 40 to the engine 1. That is, the purification casing 40 can be smoothly mounted on the engine 1 using the suspension body 101 and the suspension fitting 102 without the operator lifting the purification casing 40 by himself.

  As is clear from the above description and FIG. 11, the suspension body 101 is disposed on one end side of the purification casing 40 in the exhaust gas movement direction, and is suspended on the other end side of the purification casing 40 in the exhaust gas movement direction. A metal fitting 102 is arranged, and the suspension body 101 and the metal fitting 102 are arranged so that the respective opening holes 103 and 104 are located in the direction intersecting the longitudinal axis A of the purification casing 40 in the exhaust gas movement direction. Are separated from each other in the exhaust gas movement direction and face each other, so that the purification casing 40, which is a heavy object, has a stable posture according to the positional relationship in the diagonal direction between the suspension body 101 and the suspension fitting 102. For example, alignment of the DPF mounting portion 80 of the flywheel housing 10 with the connecting leg 77 and the fixed leg 79 is possible. Easily performed. Therefore, the assembly workability of the exhaust gas purification device 2 can be improved.

  As apparent from the above description and FIGS. 10 and 11, the attachment angle of the thick plate flanges 59, 60, 73, 74 can be changed around the longitudinal axis A in the exhaust gas movement direction of the purification casing 40. Therefore, the connecting direction of the purification inlet pipe 41 and the purification outlet pipe 42 (the engine 1) without changing the shape of the thick plate flanges 59, 60, 73, 74 (the position where the suspended body 101 is formed). The position of the suspended body 101 can be easily changed with respect to the mounting specification of the exhaust gas purification device 2), and it is possible to contribute to further improvement of the assembly workability of the exhaust gas purification device 2.

  As apparent from the above description and FIGS. 7 to 12, a plurality of filter bodies 43, 44 that purify the exhaust gas exhausted by the engine 1, and a plurality of inner cases 46 that house the filter bodies 43, 44. 48, 50 and a plurality of outer cases 47, 49, 51 containing the respective inner cases 46, 48, 50, and the outer cases 47, 49, 51 arranged side by side in the exhaust gas movement direction. Thus, in the exhaust gas purification apparatus constituting the purification casing 40, the lids that close both ends of the purification casing 40 in the exhaust gas movement direction are the inner lid bodies 53, 64 and the outer lid bodies 54, 65. The inner lid body is configured in a double structure and is located at least at the lower part of the outer lid bodies 54 and 65 with the purification casing 40 mounted on the engine 1. 3 and 64 and the outer lid bodies 54 and 56 are formed with first drain holes 107 for discharging water accumulated therein, both ends of the purification casing 40 in the exhaust gas movement direction are connected to the inner lid. The inner lid bodies 53 and 64 and the outer lid bodies 54 and 65 are sealed by a double structure of the bodies 53 and 64 and the outer lid bodies 54 and 65 so as to ensure heat insulation. Can be discharged from the first drain hole 107, so that the drainage of the exhaust gas purification device 2 is improved. For this reason, the corrosion resistance performance of the exhaust gas purification device 2 is improved.

  Further, since the first drain hole 107 is formed at a radial position with respect to the center line (longitudinal axis A) in the exhaust gas movement direction in the outer lid bodies 54 and 65, the purification casing 40. It is possible to close both ends in the exhaust gas movement direction with the outer lid bodies 54 and 65 having the same shape. For this reason, it can contribute to cost reduction by reducing the number of components. Moreover, the center line (longitudinal axis A) of the outer lid bodies 54 and 65 with respect to each end of the purification casing 40 in the exhaust gas movement direction without changing the shape of the outer lid bodies 54 and 65. You can easily change the direction of mounting around. As a result, the degree of freedom of the mounting direction of the outer case (for example, the catalyst outer case 47 and the silencer outer case 51) with respect to the engine 1 can be increased.

  Further, in a state where the purification casing 40 is mounted on the engine 1, it accumulates between the inner cases 46 and 48 and the outer cases 47 and 49 at a position located at least in the lower case 47 and 49. Since the second drain hole 108 for discharging water is formed, the purification casing 40 is configured in a double structure of the inner cases 46 and 48 and the outer cases 47 and 49 to ensure heat insulation. However, water accumulated between the inner cases 46 and 48 and the outer cases 47 and 49 due to condensation, rain water, or the like can be discharged from the second drain hole 108, and the exhaust gas purifier 2 can be drained. Sexuality improves. For this reason, it can contribute to the further improvement of the corrosion resistance performance of the exhaust gas purification device 2.

  As is clear from the above description and FIGS. 13 and 14, a plurality of filter bodies 43, 44 that purify the exhaust gas discharged from the engine 1, and a plurality of purification cases 46-that incorporate the filter bodies 43, 44. 51, and the purification casing 40 includes a purification inlet pipe 41 and a purification outlet pipe 42. In the exhaust gas purification apparatus 2, the connection flange body attached to the purification inlet pipe 41 is provided. By projecting the opening edge of 110 in the direction of the purification inlet pipe 41, an annular protrusion 111 is formed on the connection flange body 110, and the annular protrusion 111 of the connection flange body 110 is formed on the purification inlet. Since it is welded and fixed to the pipe 41, welding from the flat part of the connection flange body 110 to the outer peripheral side of the distal end of the purification inlet pipe 41 So that the minute apart. For this reason, although the connection flange body 110 is fixed to the purification inlet pipe 41 by welding, the adverse effect of high heat due to welding is unlikely to reach the connection flange body 110, and the flatness of the flat portion of the connection flange body 110 Can be maintained. Accordingly, it is possible to suppress the possibility that stress that causes damage to the exhaust gas purification device 2 is locally generated in the connection flange body 110.

  As is clear from the above description and FIGS. 13 and 14, each of the purification cases 46 to 51 includes a plurality of inner cases 46, 48, and 50 containing the filter bodies 43 and 44, and the inner cases 46. , 48, 50 and a plurality of outer cases 47, 49, 51, and the purification inlet pipe 41 has a double cylinder structure, so that not only the purification casing 40 but also the purification inlet Also in the pipe 41, the heat insulation performance is improved. Therefore, it is possible to suppress the temperature drop of the exhaust gas in the purification casing 40. Moreover, the temperature rise in the arrangement | positioning space (for example, hood of a working machine) of the said engine 1 can be prevented, and heat balance deterioration can be suppressed.

  As shown in the above description and FIG. 9, the purification outlet pipe 42 penetrates the purification casing 40, and the closed side end of the purification outlet pipe 40 is configured in a double wall structure. The heat insulation performance is improved not only in the purification casing 40 and the purification inlet pipe 41 but also in the purification outlet pipe 42. Therefore, the temperature drop of the exhaust gas in the purification casing 40 can be further suppressed. Moreover, the temperature rise in the arrangement | positioning space (for example, hood of a working machine) of the said engine 1 can be prevented, and a heat balance deterioration can be suppressed more reliably.

  As apparent from the above description and FIG. 15, the intake pipe 35 for supplying fresh air to the intake manifold 6, and the breather chamber for separating lubricating oil disposed in the head cover 8 covering the upper surface side of the cylinder head 5. 38 is an engine device connected via a blow-by gas return pipe 37, and a fresh air temperature sensor 120 for detecting the temperature of fresh air introduced into the intake pipe 35 is attached to the intake pipe 35. Therefore, the mounting position (layout) of the fresh air temperature sensor 120 with respect to the engine 1 can always be made constant, and the fresh air temperature can always be measured with respect to the engine 1 under the same conditions (position). For this reason, correction for the detection result is unnecessary, and the accuracy of engine control can be maintained with a simple configuration. The structure for detecting the fresh air temperature can be configured at low cost.

  As is clear from the above description and FIG. 15, the fresh air temperature sensor 120 is located on the intake air upstream side of the connection portion 123 with the blow-by gas return pipe 37 in the intake pipe 35. The fresh air temperature can be detected before mixing the blow-by gas. The fresh air temperature sensor 120 can be prevented from being contaminated by the lubricating oil in the blow-by gas.

  As apparent from the above description and FIG. 15, a sensor mounting base 124 is integrally formed on the upper surface side of the intake pipe 35, and the fresh air temperature sensor 120 is detachably bolted to the sensor mounting base 124. Since the connection direction of the fresh air wiring connector 125 provided in the fresh air temperature sensor 120 is set along the longitudinal direction of the intake pipe 35, the fresh air wiring connector 125 is connected to the fresh air wiring connector 125. Therefore, the presence of the harness does not get in the way.

  In addition, this invention is not limited to the above-mentioned embodiment, It can be embodied in various aspects. The structure of each part in this invention is not limited to embodiment of illustration, A various change is possible in the range which does not deviate from the meaning of this invention.

1 Engine 2 DPF (Exhaust Gas Purifier)
5 Cylinder head 6 Intake manifold 8 Head cover 35 Intake pipe 37 Blow-by gas return pipe 38 Breather chamber 120 Fresh air temperature sensor 121 Mixed gas temperature sensor 122 EGR gas temperature sensor 123 Connection 124 Sensor mounting base 125 Fresh air wiring connector

Claims (3)

An intake manifold and an exhaust manifold are arranged separately on the right and left, and a cooling fan and a flywheel housing are arranged on the front and back, and an exhaust gas purification device that purifies the exhaust gas from the exhaust manifold, and the exhaust manifold Of EGR gas and fresh air are mixed and supplied to the intake manifold, a turbocharger that compresses fresh air by exhaust from the exhaust manifold, and a head cover that covers the upper surface side of the cylinder head. An engine device comprising a breather chamber for separating lubricating oil,
An intake pipe communicating with the intake inlet side of the compressor case of the turbine supercharger and the breather chamber are connected via a blow-by gas return pipe to detect the temperature of fresh air introduced into the intake pipe. An engine apparatus, wherein a fresh air temperature sensor is attached to the intake pipe at a position on the intake upstream side of a connection portion with the blow-by gas return pipe. The EGR device and the turbine supercharger are arranged separately on the left and right sides of the cylinder head, and the breather chamber is arranged on the flywheel housing side of the head cover,
The inlet of the compressor case of the turbine supercharger faces the cooling fan side, while the exhaust outlet of the turbine case of the turbine supercharger faces the flywheel housing,
The engine device according to claim 1, wherein a connection portion between the intake pipe and the blow-by gas return pipe is provided closer to the cooling fan than an intake outlet of the compressor case.   The engine apparatus according to claim 2, wherein fresh air compressed by being connected to an intake outlet side of the compressor case is installed so that the EGR apparatus supercharging pipe straddles the cylinder head.

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