JP5350142B2 - engine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an engine which makes it to connect electric component products mounted on the engine body to harnesses, and subsequently mount them on the engine body previously, in a process to be performed before loading the engine on a working machine, and simplifies connection work necessary when the engine body and the electric component products mounted on the engine body are inspected. <P>SOLUTION: The engine 100 includes: a rail pressure sensor 85; injection actuators 83, 83, ...; a differential pressure sensor 78; an exhaust gas temperature sensor 79; and an ECU 600 which is connected to these sensors and actuators through harnesses, respectively, and controls the engine 100. In the engine, all the plurality of harnesses are connected to the ECU 600 via a relay connector panel 400 mounted on the engine 100. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

The present invention relates to an engine , and more particularly to a connection structure between an electrical component attached to an engine body and an engine control unit.

  2. Description of the Related Art Conventionally, electronically controlled engines that control the fuel injection amount, injection timing, and injection pressure by an engine control unit (hereinafter referred to as “ECU”) and thereby control the operating state of the engine are widely known. Yes. And the technique which attaches the said ECU to the exterior frame of the working machine which mounts an engine is known. For example, as shown in Patent Document 1.

  However, in the technique disclosed in Patent Document 1, the distance between an electrical product (various sensors, various actuators, etc.) attached to the engine body and the ECU differs depending on the type of the working machine on which the engine is mounted. However, a dedicated harness for connecting the electrical product and the ECU must be designed for each type of work implement. This has contributed to an increase in manufacturing cost.

  Moreover, in the technique disclosed in Patent Document 1, it is necessary to connect the electrical product attached to the engine body and the ECU with a harness after the engine is mounted on the work machine. Therefore, a manufacturer that manufactures the engine separately from the work machine (hereinafter referred to as “engine manufacturer”) is responsible for quality assurance of the harness that connects the electrical product and the ECU before the engine is shipped. The ECU is stored in advance with a control program reflecting the inspection results for quality assurance in the ECU, and the electrical equipment and the ECU are connected with a harness in advance. It was difficult to handle it as a single product.

  Furthermore, the engine manufacturer uses the electrical equipment and the inspection device for inspection when performing an inspection for quality assurance of the engine body and the electrical equipment attached to the engine body before the engine is shipped. It was necessary to connect with a harness. And when this inspection was completed, it was necessary to remove the inspection device and the harness from the engine. In particular, since many electrical products are installed in a common rail type engine, the wiring work between the electrical product and the inspection device, which is necessary for inspection for quality assurance, is very large. It has become complicated.

JP 2004-332629 A

  The present invention has been made in view of the situation as described above. In the process before mounting the engine on the work machine, the electrical product attached to the engine body is connected to the harness and then assembled to the engine body in advance. It is an object of the present invention to propose an engine that can be simplified and that can simplify the wiring work required when inspecting the engine body and the electrical components attached to the engine body.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

The invention according to claim 1 is a rail pressure sensor (85) for detecting a pressure in a common rail (84) for accumulating high-pressure fuel, an injection actuator (83) for operating an injector (81) for injecting fuel, A differential pressure sensor (78) for detecting the differential pressure before and after the filter in the exhaust purification device (70), an exhaust temperature sensor (79) for detecting the temperature of the exhaust gas in the exhaust purification device (70), and a crankshaft The crankshaft rotation sensor (8) for detecting the rotation speed of (3), the camshaft rotation sensor (5) for detecting the rotation speed of the camshaft, and the supply amount of fresh air to the intake manifold (30) are adjusted. A throttle actuator (55) for operating the intake throttle and a valve actuator for operating an EGR valve for adjusting the supply amount of exhaust gas to the intake manifold (30) (56), an EGR sensor (59) for detecting the proportion of exhaust gas in the mixed gas of fresh air and exhaust gas supplied to the intake manifold (30), and fuel supplied to the common rail (84) An engine comprising a metering actuator (98) for actuating a metering valve for adjusting the amount, and a control device (600) connected to these sensors and actuators via harnesses to control the engine, All of the plurality of harnesses are connected to the control device (600) via a relay connector board (400) attached to the engine, and the relay connector board (400) includes a first connector (410), The differential pressure sensor (78) has a second connector (420), a third connector (430), and a fourth connector (440). The exhaust temperature sensor (79) and the EGR sensor (59) are each connected to the first connector (410), and the throttle actuator (55) and the valve actuator (56) are respectively connected to the second connector (420). The injection actuator (83) and the metering actuator (98) are respectively connected to the third connector (430), the rail pressure sensor (85), the crankshaft rotation sensor (8), and the camshaft. The rotation sensors (5) are each connected to the fourth connector (440), and the middle portions of the respective harnesses connecting the sensor and actuator and the relay connector panel (400) are bundled together. The wiring is routed around the common rail (84) and along the outer periphery of the EGR valve member (54). The relay connector board (400) is attached to the cylinder block (1) below the common rail (84) and the EGR valve member (54) via an attachment stay (16) .

Since the present invention is configured as described in claim 1, it is possible to connect the electrical product attached to the engine body and the harness and then assemble it to the engine body in advance before the engine is mounted on the work machine. It is possible, and there is an effect that it is possible to simplify the wiring work required when inspecting the engine main body and the electrical equipment attached to the engine main body.

It is a top view which shows one Embodiment of the engine which concerns on this invention. It is a top view which shows one Embodiment of the engine which concerns on this invention, and the left side head cover is abbreviate | omitted. 1 is a left side view showing an embodiment of an engine according to the present invention, in which a left head cover and an ECU are omitted. 1 is a right side view showing an embodiment of an engine according to the present invention, in which a left head cover and an ECU are omitted. It is a figure which shows the attaching part of ECU with which the engine which concerns on this invention is equipped. It is a mimetic diagram showing the common rail system with which the engine concerning the present invention is equipped. It is a block diagram which shows the connection structure of ECU, the electrical equipment attached to the engine main body, and the electrical equipment attached to the working machine. It is a schematic diagram which shows the outline | summary of the manufacturing line which manufactures an engine. It is a flowchart which shows one Embodiment of the inspection method of the engine which concerns on this invention. It is a block diagram which shows the connection structure of the electrical equipment attached to the engine main body, and an inspection apparatus in one Embodiment of the inspection method of the engine which concerns on this invention. It is a schematic diagram which shows the outline | summary of another embodiment of the manufacturing line which manufactures an engine. It is a flowchart which shows another embodiment of the inspection method of an engine. It is a block diagram which shows the connection structure of the electrical equipment attached to the engine main body, ECU, and an inspection apparatus in another embodiment of the inspection method of an engine. It is a schematic diagram which shows the outline | summary of the manufacturing line which manufactures the engine in the past.

  Hereinafter, a configuration of a diesel engine (hereinafter referred to as “engine”) 100 which is an embodiment of the engine according to the present invention will be described with reference to FIGS. 1 to 7. In the following, the axial direction of the crankshaft 3 (see FIGS. 3 and 4) is defined as the front-rear direction, the side on which the flywheel housing 7 is disposed is the front, and the side on which the cooling fan 6 is disposed is the rear. The description will be made based on these directions.

  The engine 100 is a general-purpose diesel engine, and is mounted on, for example, agricultural / construction vehicles, ships, or working machines (hereinafter referred to as “working machines”) such as generators and pumps. . The engine 100 generates a driving force necessary for operating the work machine. The engine 100 of the present embodiment includes an engine 100 main body, electrical products (various sensors and various actuators) attached to the engine 100 main body, a harness (wire harness 300, etc.), a relay connector panel 400, and an ECU 600.

  A cylinder block 1 is located at the center of the engine 100, and a cylinder head 2 is placed and fixed on the upper side of the cylinder block 1. An intake manifold 30 is disposed on the left side surface of the cylinder head 2, and an exhaust manifold 40 is disposed on the right side surface of the cylinder head 2.

  A crankshaft 3 and a piston are housed in the cylinder block 1, and front end portions (front end portion and rear end portion) of the crankshaft 3 protrude from front and rear end faces of the cylinder block 1. A crank gear that rotates integrally with the crankshaft 3 is fixed to the rear end portion of the crankshaft 3, and this crank gear is fixed to the rear end face of the cylinder block 1 (see FIGS. 3 and 4). Decorated in.

  A cam gear that meshes with the crank gear is housed in the gear case 4. The cam gear is fixed to the rear end portion of the cam shaft and rotates integrally with the cam shaft. The gear case 4 is provided with a cam shaft rotation sensor 5 (see FIG. 3) for detecting the rotation speed of the cam shaft. The camshaft rotation sensor 5 is one of electrical products attached to the main body of the engine 100, and is an embodiment of the camshaft rotation sensor 5 according to the present invention.

  The engine 100 is started by operating a cell motor 25 (see FIG. 4) provided on a side surface (right side surface) of the cylinder block 1 on the exhaust manifold 40 side. The started engine 100 compresses the air in each cylinder of the engine 100 as the crankshaft 3 rotates, and injects fuel into each cylinder from injectors 81, 81. A driving force is generated by burning fuel in each cylinder.

  A cooling fan 6 is disposed on the rear side of the cylinder block 1 (more precisely, on the rear side of the gear case 4). The driving force of the crankshaft 3 is transmitted to the cooling fan 6 from the rear end side of the crankshaft 3 via the V belt.

  A flywheel housing 7 is fixed on the front side of the cylinder block 1. The flywheel housing 7 includes a flywheel. The flywheel is fixed to the front end portion of the crankshaft 3 and rotates integrally with the crankshaft 3. The driving force generated in the engine 100 is taken out through the flywheel to the working part of the work machine on which the engine 100 is mounted.

  The flywheel housing 7 is provided with a crankshaft rotation sensor 8 (see FIG. 3) for detecting the rotation speed of the crankshaft 3 (in other words, detecting the engine rotation speed). The crankshaft rotation sensor 8 is one of the electrical products attached to the main body of the engine 100, and is an embodiment of the crankshaft rotation sensor according to the present invention.

  As shown in FIGS. 3 and 4, an oil pan 10 is fixed to the lower side of the cylinder block 1 via a spacer 9. .. Are provided on the side surface of the cylinder block 1 and the side surface of the flywheel housing 7. The engine leg mounting portions 11, 11... Are provided at four locations, the left side surface of the cylinder block 1, the right side surface of the cylinder block 1, the left side surface of the flywheel housing 7, and the right side surface of the flywheel housing 7. These engine leg mounting portions 11, 11... Are set so that their positions (heights) in the vertical direction are substantially constant.

  An engine leg is attached to each engine leg attachment portion 11 with a bolt. The engine 100 is stably supported by an engine support chassis 990 (see FIGS. 3 and 4) of the work machine via the engine legs. The portion of the side surface of the cylinder block 1 corresponding to the height substantially the same as the position where the engine leg mounting portions 11 and 11 are arranged is formed so as to have a thickness that allows a bolt to be screwed in from the side. Is done.

  As shown in FIGS. 1 and 2, the inlet side of the intake manifold 30 is connected to an air cleaner via a collector 51 of an EGR device 50 (exhaust gas recirculation device), an intercooler, and a compressor of a turbocharger 60 described later. The The fresh air (external air) sucked into the air cleaner is dedusted and purified by the air cleaner, compressed by the compressor of the turbocharger 60, cooled by the intercooler, and then sent to the intake manifold 30 via the collector 51. And supplied to each cylinder of the engine 100.

  The EGR device 50 includes a collector 51 as a relay line that mixes recirculation gas (EGR gas from the exhaust manifold 40) of the engine 100 and fresh air (external air from the air cleaner) and supplies the mixed gas to the intake manifold 30; An intake throttle member 52 for communicating the collector 51 with the air cleaner, a recirculation exhaust gas pipe 53 as a reflux pipe connected to the exhaust manifold 40, an EGR valve member 54 for communicating the collector 51 with the recirculation exhaust gas pipe 53, Have.

  The intake throttle member 52 adjusts the amount of fresh air supplied to the collector 51 (intake manifold 30) as appropriate by adjusting the opening of the intake throttle inside. The intake throttle member 52 is provided with a throttle actuator 55 for adjusting the opening of the intake throttle. The throttle actuator 55 is one of electrical products attached to the main body of the engine 100, and is an embodiment of the throttle actuator according to the present invention.

  The EGR valve member 54 adjusts the amount of exhaust gas (a part of the exhaust gas discharged from the exhaust manifold 40) to the collector 51 (intake manifold 30) by adjusting the opening degree of the EGR valve in the EGR valve member 54. It is adjusted appropriately. The EGR valve member 54 is provided with a valve actuator 56 (see FIG. 3) for adjusting the opening degree of the EGR valve. The valve actuator 56 is one of electrical products attached to the main body of the engine 100, and is an embodiment of the valve actuator according to the present invention. Fresh air is supplied into the collector 51, and EGR gas is supplied from the exhaust manifold 40 via the EGR valve member 54.

  As shown in FIGS. 1 and 2, a turbocharger 60 is disposed above the exhaust manifold 40. The turbocharger 60 includes a turbine case 61 with a turbine wheel and a compressor case 62 with a blower wheel. As shown in FIG. 4, the outlet side of the exhaust manifold 40 is connected to the exhaust gas intake side of the turbine case 61. An exhaust gas exhaust pipe 64 provided on the exhaust gas exhaust side of the turbine case 61 is connected to an inlet side of an exhaust gas purification device (Diesel Particulate Filter) 70. Exhaust gas discharged from each cylinder of the engine 100 to the exhaust manifold 40 is discharged to the outside from the tail pipe 71 (see FIGS. 3 and 4) via the turbocharger 60, the exhaust purification device 70, and the like. .

  The intake side of the air cleaner is connected to the intake side of the compressor case 62. The intake side of the intake throttle member 52 is connected to the intake / exhaust side of the compressor case 62 via a supercharging pipe 66 (see FIGS. 1 and 2). The fresh air removed and purified by the air cleaner is sent from the compressor case 62 to the intake manifold 30 via the intake throttle member 52, the collector 51 and the intercooler, and is supplied to each cylinder of the engine 100.

  As shown in FIGS. 1 and 2, the exhaust purification device 70 is for collecting particulate matter (Particulate Matter) in the exhaust gas, and is a substantially cylindrical device extending in the left-right direction. The exhaust purification device 70 is fixed above the flywheel housing 7 via an attachment stay 72 (see FIGS. 3 and 4). The exhaust gas intake side of the exhaust purification device 70 is connected to the exhaust gas exhaust pipe 64 of the turbine case 61. The exhaust gas discharge side of the exhaust purification device 70 is connected to a tail pipe 71.

  The exhaust purification device 70 has a structure in which a diesel oxidation catalyst such as platinum and a soot filter having a honeycomb structure are accommodated in series in a substantially cylindrical inner case housed in a casing made of a refractory metal material.

  The casing is provided with an inlet side sensing body 73 and an outlet side sensing body 74 for detecting a pressure difference between the upstream side and the downstream side across the soot filter in the exhaust purification device 70. In other words, the inlet side sensor 73 and the outlet side sensor 74 are sensors that detect a differential pressure before and after the soot filter (filter) in the exhaust purification device 70. The inlet side sensor 73 and the outlet side sensor 74 are connected to the differential pressure detection main body 77 via a harness 75 and a harness 76, respectively. A combination of the inlet side sensor 73, the outlet side sensor 74, and the differential pressure detection main body 77 constitutes a differential pressure sensor 78. The differential pressure sensor 78 is one of electrical products attached to the main body of the engine 100, and is an embodiment of the differential pressure sensor according to the present invention. Based on the pressure difference detected by the differential pressure sensor 78, the accumulated amount of particulate matter in the soot filter can be converted to grasp the clogged state of the soot filter.

  Further, an exhaust gas temperature sensor 79 is provided at a portion near the exhaust gas discharge side of the exhaust gas purification device 70 (casing) of the present embodiment. The exhaust gas temperature sensor 79 detects the temperature of the exhaust gas in the exhaust gas purification device 70. The exhaust temperature sensor 79 is one of the electrical products attached to the main body of the engine 100, and is an embodiment of the exhaust temperature sensor according to the present invention.

  Hereinafter, the common rail system 80 provided in the engine 100 will be described. The injectors 81, 81,... Are devices that inject fuel into each cylinder of the engine 100, and are disposed at the top of each cylinder (see FIG. 2). As shown in FIG. 6, the injectors 81, 81... For four cylinders are connected to a fuel tank 95 via a common rail 84 and a supply pump 90. Each injector 81 has a fuel injection valve 82, which is operated by an injection actuator 83 (see FIG. 2). The injection actuators 83, 83,... Are one of electrical products attached to the main body of the engine 100, and are an embodiment of the injection actuator according to the present invention.

Common rail system 80 includes a common rail (蓄 chamber) 84 for pressurizing 蓄 high pressure fuel. The common rail 84 is a member formed in a cylindrical shape, and includes a rail pressure sensor 85 (see FIG. 6) for detecting the pressure (rail pressure) in the common rail 84. The rail pressure sensor 85 is one of electrical products attached to the main body of the engine 100, and is an embodiment of the rail pressure sensor according to the present invention.

  As shown in FIGS. 3 and 6, a fuel tank 95 is connected to the suction side of the supply pump 90 via a fuel filter 96 and a low pressure pipe 97. The fuel in the fuel tank 95 is sucked into the supply pump 90 through the fuel filter 96 and the low pressure pipe 97. A common rail 84 is connected to the discharge side of the supply pump 90 via a high-pressure pipe 91. .. Are connected to the common rail 84 via four fuel injection pipes 86.

  The supply pump 90 adjusts the fuel pressure when the fuel in the fuel tank 95 is pumped to the common rail 84. The high-pressure fuel supplied from the fuel tank 95 is stored in the common rail 84. The high pressure fuel stored in the common rail 84 is transferred from the injectors 81, 81... To each cylinder of the engine 100 by adjusting the opening / closing time of the fuel injection valves 82, 82. Is injected into. By appropriately controlling the injection actuators 83, 83, etc., it is possible to adjust the injection amount and injection timing of the fuel injected from the injectors 81, 81,.

  An intake manifold 30 is attached to the left side surface of the cylinder head 2 to open an intake port directed to each cylinder of the engine 100 and distribute a mixture of fresh air and EGR gas to the intake port. The intake manifold 30 is a box-shaped member whose longitudinal direction is the front-rear direction, and is fixed to the cylinder head 2 in a state of communicating with each cylinder via an intake port group. The rear portion of the left side surface of the intake manifold 30 communicates with the collector 51. As shown in FIG. 3, the common rail 84 is fixed in a state of being suspended along the longitudinal direction (front-rear direction) of the intake manifold 30 and suspended downward from the intake manifold 30.

  Above the collector 51, the EGR valve member 54 is disposed in a posture extending along the longitudinal direction (front-rear direction) of the intake manifold 30. The EGR discharge side opening portion opened downward in the EGR valve member 54 is fixed to the collector 51, and the EGR valve member 54 and the collector 51 communicate with each other.

  As shown in FIG. 2, from the portion of the upper surface of the cylinder head 2 near the intake manifold 30, the upper portions of the injectors 81, 81,... For four cylinders are lined up in the front-rear direction at a predetermined interval. Protruding. As shown in FIG. 1, a left head cover 35 is attached to a portion of the upper surface of the cylinder head 2 near the intake manifold 30 to cover the injectors 81, 81. A right head cover 45 is attached to a portion of the upper surface of the cylinder head 2 near the exhaust manifold 40.

  As shown in FIGS. 1 and 2, the recirculation exhaust gas pipe 53 and the EGR valve member 54 are connected via a relay joint 57. The relay joint 57 is a cylindrical member curved in a substantially S shape, and an EGR gas temperature sensor 58 is provided in the middle thereof. The EGR gas temperature sensor 58 detects the temperature of the EGR gas that has flowed into the intermediate joint 57. The EGR gas temperature sensor 58 is one of electrical components attached to the engine 100 main body.

  As shown in FIG. 3, a fresh air temperature sensor 31 that detects the fresh air temperature is provided at a portion of the collector 51 near the intake throttle member 52. The fresh air temperature sensor 31 is one of electrical components attached to the engine 100 main body.

  The EGR gas supplied from the recirculation exhaust gas pipe 53 to the collector 51 and the fresh air supplied from the intake throttle member 52 to the collector 51 are mixed in the collector 51. The mixed gas generated in the collector 51 in this way is supplied to the intake manifold 30. A portion of the collector 51 near the air supply manifold 30 is provided with a mixed gas temperature sensor 32 for detecting the temperature of the mixed gas. The mixed gas temperature sensor 32 is one of electrical components attached to the engine 100 main body.

  A combination of the EGR gas temperature sensor 58, the fresh air temperature sensor 31, and the mixed gas temperature sensor 32 constitutes an EGR sensor 59. The EGR sensor 59 is an embodiment of the EGR sensor according to the present invention. The EGR sensor 59 detects an EGR rate in the mixed gas. In other words, the ratio of exhaust gas in the mixed gas of fresh air and exhaust gas supplied to the intake manifold 30 is detected.

  As shown in FIG. 3, the supply pump 90 is fixed to the side surface (left side surface) of the cylinder block 1 on the intake manifold 30 side. More specifically, the supply pump 90 is attached to a position below the intake manifold 30 and closer to the cooling fan 6 side (rear side). The fuel in the fuel tank 95 is sent to a supply pump 90 from a feed pump (not shown). The supply pump 90 has a metering valve for adjusting the amount of fuel sucked, and a plunger for pressurizing the fuel passing through the metering valve and feeding it to the common rail 84.

  The metering valve is provided with a metering actuator 98 for adjusting the opening degree. By operating the metering actuator 98, it is possible to adjust the amount of fuel pumped to the common rail 84, and thus to adjust the fuel pressure. The metering actuator 98 is one of electrical products attached to the main body of the engine 100, and is an embodiment of the metering actuator according to the present invention.

  As the crankshaft 3 rotates, the supply pump 90 operates, and the fuel in the fuel tank 95 is sucked into the supply pump 90 via the feed pump and the fuel filter 96. The driving force (rotational force) of the crankshaft 3 is converted into the reciprocating motion of the plunger of the supply pump 90 via the crank gear, the cam gear, and the camshaft, and the fuel is pressurized by the reciprocating motion of the plunger and is pumped to the common rail 84. Is done.

  As shown in FIGS. 1 to 3, a water pump 20 is fixed at a position facing the cooling fan 6 on the rear end surface of the cylinder head 2. The cooling water is fed into water jackets formed in the cylinder block 1 and the cylinder head 2 by driving the water pump 20 and circulates inside the engine 100. By constituting in this way, heat exchange between engine 100 and cooling water is aimed at, and the temperature rise of engine 100 is controlled. The water pump 20 is provided with a cooling water temperature sensor 21 for detecting the temperature of the cooling water circulating inside the engine 100. The cooling water temperature sensor 21 is one of electrical components attached to the engine 100 main body.

Among the “electrical products attached to the main body of the engine 100”, the camshaft rotation sensor 5, the crankshaft rotation sensor 8, the differential pressure sensor 78 (the inlet side sensor 73, the outlet side sensor 74, and the differential pressure sensor body 77) The exhaust gas temperature sensor 79, the rail pressure sensor 85, the EGR sensor 59 (the EGR gas temperature sensor 58, the fresh air temperature sensor 31, and the mixed gas temperature sensor 32), and the cooling water temperature sensor 21. Corresponds to “various sensors”.
Among the “electrical products attached to the main body of the engine 100”, the throttle actuator 55, the valve actuator 56, the injection actuators 83, 83,.

  The engine 100 main body of this embodiment includes a throttle actuator 55, a valve actuator 56, injection actuators 83, 83..., A metering actuator 98, a camshaft rotation sensor 5, a crankshaft rotation sensor 8, a differential pressure sensor 78, Although the exhaust temperature sensor 79, the rail pressure sensor 85, the EGR sensor 59, and the cooling water temperature sensor 21 are provided as electrical products, the engine according to the present invention is not limited to this. For example, in addition to these electrical products, a hydraulic switch for confirming that the oil pressure of the lubricating oil is kept below a certain value, a boost pressure sensor for detecting the boost pressure in the turbocharger, etc. It is good also as a structure comprised as an electrical equipment (various sensors and various actuators) attached to the engine main body.

  Hereinafter, a connection structure between ECU 600 and an electrical product attached to engine 100 main body and an electrical product attached to the work machine will be described with reference to FIGS. 1 to 4 and FIG. 7.

  The electrical products (various sensors and various actuators) attached to the main body of the engine 100 are connected to the ECU 600 via the wire harness 300, the relay connector panel 400, and the like. ECU 600 controls the operating state of engine 100, and is an embodiment of a control device according to the present invention. The relay connector board 400 is a connector attached to the engine 100 and is an embodiment of the relay connector board according to the present invention.

  ECU 600 includes a CPU, a storage device (ROM, RAM, etc.), and the storage device stores a control program, a map, and the like. ECU 600 can receive detection signals detected by various sensors attached to engine 100 main body. ECU 600 can output command signals created based on the input detection signal, control program, map, and the like to various actuators attached to engine 100. By configuring in this way, the engine 100 is based on various factors such as the engine speed (the number of revolutions of the crankshaft 3), the EGR rate, and the temperature of the engine 100 body (cooling water temperature). The ECU 600 is controlled by the ECU 600 so that the fuel injection amount, the injection timing, and the injection pressure suitable for the situation are calculated and realized.

  ECU 600 is connected to relay connector panel 400 via a wire harness 590 and the like which will be described later. Further, ECU 600 is connected to “an electrical product attached to the work machine” via wire harness 910, 920, 930, 940 or the like.

  The “wire harness” in the present specification refers to a bundle of a plurality of harnesses (wirings) bundled in a bundle with the axial directions aligned in substantially the same direction. Specific examples include a bundle of multiple harnesses bundled by a spiral tube, a bundle of multiple harnesses bundled by a binding band, a bundle of multiple harnesses stored in a corrugated tube, etc. Is mentioned.

  In the present specification, “an electrical product attached to a work machine” includes an exhaust system lamp group 901, an exhaust system switch group 902, an injection system attached to a work machine (specifically, a tractor or the like) on which the engine 100 is mounted. A system switch group 903 and an injection system lamp group 904 are included. More specifically, the exhaust system lamp group 901 includes, for example, a plurality of accumulation level lamps for displaying the amount (level) of PM (Particulate Matter) accumulated on the soot filter of the exhaust purification device 70. The exhaust system switch group 902 includes, for example, a filter regeneration switch for starting regeneration of the soot filter of the exhaust purification device 70. In the injection system switch group 903, for example, a rotation speed setting switch for setting the rotation speed of the engine 100 (in other words, for controlling the fuel injection amount and injection timing from the injectors 81, 81...). Etc. are included. The injection system lamp group 904 includes alarm lamps for displaying malfunctions or abnormalities of the injectors 81.

  ECU 600 can receive detection signals detected by various operating tools (exhaust system switch group 902, injection system switch group 903, etc.) attached to the work implement. That is, it is possible to input the setting state set by the operator of the work implement using various operating tools to the ECU 600 as a detection signal.

  Note that a female body 612 of an inspection connector 610 that is used when an inspection device 710 described later is connected is connected to the ECU 600 of this embodiment via a harness 620.

  Hereinafter, a connection structure between the electrical component attached to the main body of the engine 100 and the relay connector panel 400 will be described in detail.

  The relay connector panel 400 of the present embodiment includes an exhaust detection system connector 410, an exhaust operation system connector 420, an injection operation system connector 430, and an injection detection system connector 440. Each of these connectors 410, 420, 430, and 440 includes male bodies 411, 421, 431, and 441 and female bodies 412, 422, 432, and 442.

  The male bodies 411, 421, 431, and 441 are connected to the ECU 600 via the wire harness 590 and the like. The female bodies 412, 422, 432, and 442 are attached to the left side surface of the engine 100 (cylinder block 1) via the attachment stay 16 (see FIG. 3).

  As shown in FIG. 3, the mounting stay 16 is a member made of a material having a low thermal conductivity, and projects from the left side surface of the cylinder block 1 toward the side (left side). The mounting stay 16 has a pair of flat surfaces (upper surface and lower surface) perpendicular to the vertical direction. A female body 412 of the exhaust detection system connector 410 and a female body 422 of the exhaust operation system connector 420 are fixed on the upper surface of the mounting stay 16. A female body 432 of the injection operation system connector 430 and a female body 442 of the injection detection system connector 440 are fixed to the lower surface of the mounting stay 16. A vibration isolating member is interposed between the mounting stay 16 and the female body of each connector. When fixed to the mounting stay 16, the connecting portions of the connectors (female bodies 412, 422, 432, and 442) face outward (to the left).

  The exhaust detection system connector 410 is an embodiment of the first connector according to the present invention. The exhaust detection system connector 410 is provided in the middle of the harness connecting the differential pressure sensor 78, the exhaust temperature sensor 79, the EGR sensor 59, the cooling water temperature sensor 21, and the ECU 600. More specifically, among the electrical components attached to the engine 100 main body, the differential pressure sensor 78, the exhaust temperature sensor 79, the EGR sensor 59, and the cooling water temperature sensor 21 are the harness 110, the harness 120, the harness 130, and the harness 140, respectively. To the female body 412 of the exhaust detection system connector 410. That is, various sensors related to the exhaust system of engine 100 (various sensors related to EGR device 50 and exhaust purification device 70) are intensively connected to exhaust detection system connector 410.

  The exhaust operation system connector 420 is an embodiment of the second connector according to the present invention. Exhaust operation system connector 420 is provided in the middle of the harness that connects throttle actuator 55 and valve actuator 56 to ECU 600. More specifically, among the electrical products attached to the main body of engine 100, throttle actuator 55 and valve actuator 56 are connected to female body 422 of exhaust operation system connector 420 via harness 150 and harness 160, respectively. That is, various actuators related to the exhaust system of engine 100 (various actuators related to EGR device 50 and exhaust purification device 70) are intensively connected to exhaust operation system connector 420.

  The injection system connector 430 is an embodiment of the third connector according to the present invention. The injection operation system connector 430 is provided in the middle of the harness that connects the injection actuators 83, 83... And the metering actuator 98 to the ECU 600. More specifically, among the electrical equipment attached to the main body of the engine 100, the injection actuators 83, 83... And the metering actuator 98 are the female body 432 of the injection operation system connector 430 via the harness 170 and the harness 180, respectively. Connected to. In other words, various actuators related to the fuel injection system of engine 100 (common rail system 80 and various actuators related to rotation of engine 100) are intensively connected to injection operation system connector 430.

  The jet detection system connector 440 is an embodiment of the fourth connector according to the present invention. The injection detection system connector 440 is provided in the middle of the harness connecting the camshaft rotation sensor 5, the crankshaft rotation sensor 8, the rail pressure sensor 85, and the ECU 600. More specifically, among the electrical components attached to the main body of the engine 100, the camshaft rotation sensor 5, the crankshaft rotation sensor 8, and the rail pressure sensor 85 detect injection through the harness 190, the harness 210, and the harness 220, respectively. It is connected to the female body 442 of the system connector 440. In other words, various sensors related to the fuel injection system of engine 100 (common rail system 80 and various sensors related to rotation of engine 100) are intensively connected to injection detection system connector 440.

  The harnesses 110, 120, 130, 140, 150, 160, 170, 180, 190, 210, and 220 are bundled together in the middle portion to constitute the wire harness 300.

  Harnesses 130, 140, 160, 170, 180, 190, and 220 are bundled together in a portion closer to the main body of the engine 100 than the wire harness 300 (a portion between the various sensors and actuators and the wire harness 300). Thus, the wire harness 350 (see FIGS. 1 to 3) is configured. The wire harness 350 is formed by connecting the middle part of each harness connecting the rail pressure sensor, the injection actuator, the camshaft rotation sensor, the valve actuator, the EGR sensor, the metering actuator, and the relay connector panel according to the present invention. It is one Embodiment of what was bundled in one.

  As shown in FIG. 1, the wire harness 350 is supported on the upper surface of the left head cover 35 via guide members 36, 36. Each guide member 36 is a substantially U-shaped member when viewed from the front, and a plurality of guide members 36 are arranged on the upper surface of the left head cover 35 at a predetermined interval. When the wire harness 350 is inserted into the guide members 36, 36,..., The wire harness 350 is disposed on the upper surface of the left head cover 35 so as to extend in a substantially horizontal direction (substantially in the front-rear direction in the present embodiment). .

  Further, the harnesses 130, 140, 160, 170, 180, 190, and 220 constituting the wire harness 350 are bundled together with the other harnesses 110, 120, 210, and 150 at the portion near the relay connector board 400 to be wired. The harness 300 is configured and wired so as to pass through the front of the common rail 84 in the left side view (see FIG. 3). By arranging in this way, the wire harness 350, which is the middle part of the wire harness 300, is wired so as to bypass the common rail 84 in a bundle.

  Arranging the wire harness 350 in this way has the following advantages. The wire harness 350 can be supported on the left head cover 35 disposed at the top of the engine 100, and the wire harness 350 can be easily and stably attached to the engine 100. In addition, since the wire harness 350 can be disposed in a substantially horizontal direction along the upper surface of the left head cover 35, the wire harness 350 is rubbed with other members constituting the engine 100 due to vibration of the engine 100, resulting in a short circuit. It is possible to prevent such a situation as much as possible. Further, since the wire harness 350 is routed along the outer periphery of the EGR valve member 54 while bypassing the periphery of the common rail 84, a pipe (high-pressure pipe) connecting the wire harness 350 to the common rail 84 or the EGR valve member 54 is provided. 91 and the fuel injection pipes 86, 86, etc.). Therefore, the wiring work of the wire harness 350 can be easily performed.

  Although the wire harness 350 of the present embodiment is supported on the upper surface of the left head cover 35, the present invention is not limited to this. For example, the wire harness 350 may be fixed to the upper surface of the intake manifold 30 via a guide member. However, from the viewpoint of preventing as much as possible the situation in which the wire harness 350 comes into contact with other members constituting the engine 100 and rubs due to vibrations of the engine 100, the wire harness 350 is placed on the plane of the structure constituting the engine 100. It is desirable to support along.

  As shown in FIG. 7, the male body 411 of the exhaust detection system connector 410 is connected to the ECU 600 via the wire harness 550. The male body 411 can be manually fitted to or removed from the corresponding female body 412. That is, various sensors related to the exhaust system of the engine 100 are connected to the ECU 600 as a whole by setting the exhaust detection system connector 410 to a connected or non-connected state, or are collectively connected to the ECU 600. It is possible to remove from.

  “Connecting the exhaust detection system connector 410” means that the male body 411 of the exhaust detection system connector 410 is fitted to the female body 412 and the corresponding harnesses (110, 120, 130, 140, and 550) are electrically connected. Shall be connected to each other. Further, “disconnecting the exhaust detection system connector 410 (disconnecting)” means that the male body 411 of the exhaust detection system connector 410 is removed from the female body 412 and the corresponding harnesses (110, 120, 130). 140 and 550) shall be in a state where they are not electrically connected. The connection / non-connection of the other connectors 420, 430, and 440 is also expressed in the same manner, and the following description will be given.

  The male body 421 of the exhaust operation system connector 420 is connected to the ECU 600 via the wire harness 560. The male body 421 can be manually inserted into or removed from the corresponding female body 422. That is, various actuators related to the exhaust system of the engine 100 are connected to the ECU 600 as a whole by setting the exhaust operation system connector 420 to either the connected state or the non-connected state. It is possible to remove from.

  The male body 431 of the injection operation system connector 430 is connected to the ECU 600 via the wire harness 570. The male body 431 can be manually fitted to or removed from the corresponding female body 432. That is, various actuators related to the fuel injection system of the engine 100 can be connected to the ECU 600 together or collectively as a result of setting the injection operating system connector 430 to either connected or disconnected state. It is possible to remove from ECU600.

  The male body 441 of the injection detection system connector 440 is connected to the ECU 600 via the wire harness 580. The male body 441 can be manually fitted to or removed from the corresponding female body 442. That is, various sensors related to the combustion injection system of the engine 100 can be connected to the ECU 600 together or collectively as a result of setting the injection detection system connector 440 to either connected or disconnected state. It is possible to remove from ECU600.

  Since the connecting portions of the female bodies 412, 422, 432, and 442 of each connector face the outside (left side) of the engine 100, the operator can easily operate the relay connector panel 400 from the left side of the engine 100. Each connector 410, 420, 430, 440 can be connected to or disconnected from the connector.

  The wire harness 550, the wire harness 560, the wire harness 570, and the wire harness 580 are bundled together in the middle portion to constitute the wire harness 590. The wire harness 590 of this embodiment can be supported on the upper surface of the flywheel housing 7 via a plurality of guide members. With this configuration, the wire harness 300 is disposed so as to extend in a substantially horizontal direction (left-right direction) along the upper surface of the flywheel housing 7. The end (right end) of the wire harness 590 connected to the ECU 600 reaches the right side of the cylinder block 1.

  The right end portion of the wire harness 590 is connected to the ECU 600 via a connector provided in the ECU 600. An operator can connect or disconnect the relay connector board 400 and the ECU 600 via the wire harness 590.

  As shown in FIGS. 4 and 5, the ECU 600 according to this embodiment is attached to a position on the right side surface of the cylinder block 1 and below the cell motor 25. More specifically, the ECU 600 is connected to the engine 100 via a bracket 26 fixed so as to straddle a region from the cylinder block 1 to the oil pan 10 through the spacer 9 on the right side surface of the engine 100. Attached to.

  The bracket 26 is a member made of a material having a low thermal conductivity, and is fixed at a position substantially the same height as the engine leg mounting portion 11 in the cylinder block 1. The portion to which the bracket 26 is attached corresponds to a portion formed thick on the side surface of the cylinder block 1 as described above. Therefore, it is possible to stably fix the bracket 26 to the engine 100 (cylinder block 1) by screwing a bolt from the right side of the cylinder block 1. In this way, the ECU 600 is stably attached to the highly rigid cylinder block 1.

  Mounting the ECU 600 at the position as described above in the engine 100 has the following advantages. It is known that when the ambient temperature rises, the cell motor 25 is deteriorated in function due to a decrease in rotational force, malfunction of the pinion, and the like. For this reason, the cell motor 25 is conventionally disposed at a position where the ambient temperature does not increase (desirably a position where the ambient temperature is always less than 80 ° C.). In the present embodiment, by attaching the ECU 600 in the vicinity of the cell motor 25, it is possible to keep the ECU 600 at a relatively low temperature with almost no modification to the configuration of the conventional engine. Therefore, it is possible to prevent a situation in which a control circuit built in ECU 600 is burned in or ECU 600 is thermally runaway. In addition, the position where the bracket 26 of the present embodiment is fixed is sufficiently separated from the position where the water pump 20, the water jacket, the lubricating oil pump, or the like is disposed. Therefore, the ECU 600 that is an electrical product is less likely to come into contact with water or lubricating oil, and the ECU 600 can be prevented from malfunctioning.

  It is desirable that a vibration isolating member is interposed between the bracket 26 and the ECU 600. With this configuration, vibration transmitted from engine 100 to ECU 600 can be reduced as much as possible, and failure, breakage, or the like of ECU 600 due to vibration of engine 100 can be prevented.

  Note that the bracket 26 of the present embodiment is fixed so as to straddle the region from the cylinder block 1 to the oil pan 10 through the spacer 9 on the right side surface of the engine 100. The invention is not limited to this. For example, a bracket may be fixed to the right side surface of the cylinder block 1. That is, the position of the bracket may be set so that the ECU 600 can be disposed in the vicinity of the cell motor 25.

  In the engine 100 configured as described above, various sensors and actuators (electrical products attached to the main body of the engine 100) and the ECU 600 are connected to the connectors 410, 420, 430, and 440 of the relay connector panel 400. By setting to any state of non-connection, it is possible to easily connect or disconnect.

  In the relay connector panel 400 of the present embodiment, the harnesses 110, 120, 130, 140, 150, 160, 170, 180, 190, 210, and 220 connected to various sensors and actuators are highly relevant. Since things are grouped together (because they are grouped into four groups), connection / disconnection can be set for each connector (group). For example, when maintenance of the operation system of the common rail system 80 is required, the electrical equipment related to the operation of the common rail system 80 (the injection actuators 83, 83... And the injection operation system connector 430 is disconnected). Only the connection between the metering actuator 98) and the ECU 600 can be removed. Therefore, the trouble of removing other harnesses not related to the operating system of the common rail system 80 can be saved and workability can be improved.

  In addition, before the engine 100 is shipped (before the engine 100 is mounted on the work machine), the engine manufacturer connects the electrical equipment (various sensors and various actuators) attached to the main body of the engine 100 and the ECU 600 in advance with a harness ( These are connected by the wire harness 300) and can be handled as an aggregate (one product combined with the main body of the engine 100). In this case, since the distance between the electrical product attached to the main body of the engine 100 and the ECU 600 is uniquely determined, a dedicated connection for connecting the electrical product and the ECU 600 for each type of work machine on which the engine 100 is mounted. There is no need to design a harness.

  Conventionally, an engine manufacturer is a customer (for example, in a factory of a manufacturer of a working machine that purchased the engine 100), and after mounting the engine 100 on the working machine, The wiring work which connects with the electrical equipment attached to the working machine via ECU600 was performed. In this regard, in the engine 100 according to the present invention, the ECU 600 and the harness (such as the wire harness 300) can be pre-assembled into the engine 100 main body and handled as an assembly as described above, so that the connection work at the customer can be performed. It can be easily performed. That is, at the customer, the electrical equipment (exhaust system lamp group 901, exhaust system switch group 902, injection system switch group 903, and injection system lamp group 904) attached to the work machine and ECU 600 are connected to wire harness 910. It is only necessary to connect by 920, 930, 940, etc., and such a connection work can be easily performed by connecting connectors (four connectors in this embodiment) (see FIG. 7).

  Further, by configuring in this way, before the engine 100 is shipped, the engine manufacturer can supply the engine 100 main body, the electrical products (various sensors and various actuators) attached to the engine 100 main body, and the wire harness 300 for connecting them. It is possible to perform inspections for quality assurance, and it is possible to guarantee quality in the state of the aggregate. Therefore, after assembly of engine 100 to the work implement, it is possible to prevent a situation in which malfunctions or abnormalities of various sensors and actuators are detected, or disconnection of wire harness 300 is detected.

  Below, the manufacturing line 1000 which is one Embodiment of the manufacturing line which manufactures the engine 100 is demonstrated with reference to FIGS. 8-10. As shown in FIG. 8, the production line 1000 of the engine 100 includes a component manufacturing process S1100, an assembly process S1200, an inspection process S1300, and a final assembly process S1400.

  The component manufacturing step S1100 is a step of manufacturing main components constituting the main body of the engine 100, and is a step of manufacturing the cylinder block 1, the cylinder head 2, and the like, for example. Each component manufactured in the component manufacturing process S1100 is set on a conveyor. When the component manufacturing process S1100 is completed, the process proceeds to an assembly process S1200.

  The assembly process S1200 is a process in which each component is assembled to the main body including the cylinder block 1 and the cylinder head 2. At this time, a piston, various gears, a pre-assembled subassembly, various electrical components (various sensors and various actuators), a wire harness 300, and the like are assembled to the engine 100 main body. When the assembly process S1200 is completed, the process proceeds to the inspection process S1300.

  The inspection step S1300 is a step of performing inspection for quality assurance of the assembled engine 100. In the inspection, the quality and performance of the engine 100 main body, various sensors and various actuators, and the wire harness 300 are inspected. At this time, the test operation of the engine 100 is performed in the test operation place, and various data are acquired. As a specific example, whether or not a predetermined rotation can be obtained when the engine 100 is idle and when it is loaded, whether or not exhaust gas is within a reference value, and each engine 100 can be operated in conformity with a standard value. Whether or not, etc. are inspected. When a defect is detected by the inspection, the defect is corrected in another process, and the inspection process S1300 is performed again. When the inspection process S1300 is completed, the process proceeds to the final assembly process S1400.

  The final assembly step S1400 is a step of assembling the ECU 600 to the engine 100 that has been inspected for quality assurance. After the correction value of each engine 100 is determined based on the result of the inspection obtained in the inspection step S1300, a control program that reflects this correction value is stored in the ECU 600 of each engine 100. ECU 600 is attached to cylinder block 1 of engine 100 via bracket 26. Relay connector panel 400 and ECU 600 are connected via wire harness 590 (see FIG. 7).

  Hereinafter, an inspection method 700 of the engine 100 performed in the inspection step S1300 will be described with reference to FIGS. Inspection method 700 is an embodiment of an engine inspection method according to the present invention.

  The inspection method 700 of the present embodiment is a method for performing inspection for quality assurance of the engine 100 using an inspection apparatus 710 (see FIGS. 8 and 10). As shown in FIG. 9, the inspection method 700 mainly includes a connection step S7100, an engine operation step S7200, and an inspection execution step S7300.

  Connection step S7100 is a step of connecting engine 100 and inspection device 710 via relay connector panel 400. That is, as shown in FIG. 10, an inspection device 710 is connected to the relay connector panel 400 instead of the ECU 600 via a wire harness 720 (inspection harness). Inspection device 710 is a control device used for inspection for quality assurance of engine 100. The inspection device 710 includes a control circuit and stores various control programs and maps used for inspection. The inspection apparatus 710 includes male bodies 711, 712, 713, and 714 corresponding to the female bodies 412, 422, 432, and 442 of the relay connector board 400. An operator who inspects the engine 100 connects the electrical equipment (various sensors and various actuators) attached to the main body of the engine 100 and the inspection device 710 by connecting the connectors 410, 420, 430, and 440. When the connection step S7100 is completed, the process proceeds to the engine operation step S7200.

  Engine operation step S7200 is a step of experimentally operating engine 100 connected to inspection device 710. That is, engine 100 is started. An operator who inspects the engine 100 operates the cell motor 25 (see FIG. 4) of the engine 100 by operating the key switch 721 provided in the inspection device 710. The engine 100 is started by the operation of the cell motor 25. When the engine operation step S7200 is completed, the process proceeds to the inspection execution step S7300.

  Inspection execution process S7300 is a process of inspecting the quality and performance of engine 100 started in engine operation process S7200. That is, an operation inspection of engine 100 is performed. The operator operates the operation tool 722 (switches) for inspection provided in the inspection apparatus 710 to check the operation of the engine 100 main body and the electrical products (various sensors and various actuators) attached to the engine 100 main body. I do. Alternatively, the inspection apparatus 710 is operated in accordance with the control program, and the inspection is automatically performed, the data is automatically acquired, and it is determined whether or not the value is within the set range. Specifically, for example, inspections are performed to check whether various sensors have malfunctions or whether various actuators operate with high accuracy. When inspection execution process S7300 is completed, the process proceeds to final assembly process S1400 (see FIG. 8).

  Inspecting the engine 100 by the inspection method 700 having the above-described configuration has the following advantages (A) to (C).

  (A) In the connection step S7100, all the “electrical products attached to the engine 100 main body” in this embodiment (connected to the wire harness 300) are connected by connecting the four connectors 410, 420, 430, and 440. All of various sensors and various actuators) can be connected to the inspection apparatus 710. Therefore, as compared with the case of performing inspection for quality assurance by connecting each electrical product and the inspection apparatus in a one-to-one correspondence as in the conventional inspection method (see FIG. 14), the wiring work can be significantly reduced. It is possible to simplify the work in the inspection step S1300.

  (B) Further, in the relay connector panel 400, since the associated harnesses are grouped into the connectors 410, 420, 430, and 440, for example, when a malfunction occurs in the operating system of the common rail system 80 (injection actuators 83 and 83). ), Etc.) by removing the male body 713 of the injection system connector 430 from the female body 432, the electrical equipment related to the operation of the common rail system 80 (injection actuators 83, 83. It is possible to remove only the connection between the quantity actuator 98) and the inspection device 710. Therefore, it is possible to save the trouble of removing other harnesses that are not malfunctioning, and to improve the work efficiency in the inspection.

  (C) Further, in the inspection method 700, in addition to the engine 100 main body and the electrical equipment attached to the engine 100 main body, a harness (wire harness 300) connecting them is also inspected for quality assurance. It is possible. Further, after determining the correction value of each engine 100 based on the result of this inspection, a control program reflecting this correction value can be stored in ECU 600 of each engine 100. Accordingly, the engine manufacturer individually corrects the assembled assembly of the engine 100 main body, various electrical components (various sensors and various actuators), harness (wire harness 300), and ECU 600 through inspection. It can be handled as a single product with a high degree of perfection.

  Below, the manufacturing line 2000 which is another embodiment of the manufacturing line which manufactures the engine 100 is demonstrated with reference to FIGS. As shown in FIG. 11, the production line 2000 of the engine 100 includes a component manufacturing process S2100, an assembly process S2200, and an inspection process S2300. That is, the production line 2000 is different from the production line 1000 in that it does not include a process corresponding to the final assembly process S1400 in the production line 1000.

  The component manufacturing step S2100 is a step of manufacturing main components that constitute the main body of the engine 200. For example, the cylinder block 1 and the cylinder head 2 are manufactured. When the component manufacturing process S2100 is completed, the process proceeds to an assembly process S2200.

  The assembly step S2200 is a step in which each component is assembled to the main body including the cylinder block 1 and the cylinder head 2. At this time, the piston, various gears, a pre-assembled subassembly, various electrical components (various sensors and various actuators), ECU 600, and the like are assembled to the engine 100 body. ECU 600 is assembled to the main body of engine 100 while being connected to various electrical components (various sensors and various actuators) via wire harness 300 and wire harness 590 (see FIG. 7). ECU 600 stores a control program, a map, and the like. When the assembly process S2200 is completed, the process proceeds to the inspection process S2300.

  The inspection step S2300 is a step of performing inspection for quality assurance of the assembled engine 100. In the inspection, the quality and performance of the engine 100 main body, various sensors and various actuators, the wire harness 300, the wire harness 590, and the ECU 600 are inspected. When the inspection process S2300 is completed, the production line 2000 of the engine 100 is completed.

  Hereinafter, the inspection method 750 of the engine 100 performed in the inspection step S2300 will be described with reference to FIGS.

  The inspection method 750 of the present embodiment is a method for performing an inspection for quality assurance of the engine 100 using the inspection device 760 (see FIGS. 11 and 13). As shown in FIG. 12, the inspection method 750 mainly includes a connection step S7600, an engine operation step S7700, and an inspection execution step S7800.

  The connecting step S7600 is a step of connecting the ECU 600 in which the control program, the map, and the like are stored in the assembling step S2200 and the inspection device 760 via the connector 610 and the harness 620 (see FIG. 13). Inspection device 760 is a device used for inspection for quality assurance of engine 100. The inspection device 760 includes an operation tool 762 for inspection (for example, a rotational speed setting switch for setting the rotational speed of the engine 100), a key switch 761, and the like. The inspection device 760 includes a male body 611 corresponding to the female body 612 of the connector 610. An operator who inspects the engine 100 connects the ECU 600 and the inspection device 760 by connecting the inspection connector 610, and in turn, inspects the electrical products (various sensors and various actuators) attached to the main body of the engine 100. Device 760 is connected. When the connection process S7600 is completed, the process proceeds to the engine operation process S7700.

  The engine operation step S7700 is a step of experimentally operating the engine 100 connected to the inspection device 760. That is, engine 100 is started. An operator who inspects the engine 100 operates the cell motor 25 (see FIG. 4) of the engine 100 by operating the key switch 761 provided in the inspection device 760. The engine 100 is started by the operation of the cell motor 25. When the engine operation step S7700 ends, the process proceeds to the inspection execution step S7800.

  The inspection execution step S7800 is a step for inspecting the quality and performance of the engine 100 started in the engine operation step S7700. That is, an operation inspection of engine 100 is performed. The operator operates the operation tool 762 for inspection (rotation speed setting switch, etc.) provided in the inspection device 760 to thereby operate the engine 100 main body and electrical products (various sensors and various actuators) attached to the engine 100 main body. And an operation test of the ECU 600. Alternatively, the inspection device 760 is operated in accordance with the control program, and the inspection is automatically performed, the data is automatically acquired, and it is determined whether or not the value is within the set range. Specifically, for example, inspections are performed on whether the various sensors are not malfunctioning, whether the various actuators operate with high accuracy, and whether the control circuit of the ECU 600 is defective. When the inspection execution process S7800 is completed, the production line 2000 of the engine 100 is completed, and the engine 100 is shipped to the customer.

  Inspecting the engine 100 by the inspection method 750 having the above-described configuration has the following advantages (a) to (c).

  (A) In the connecting step S7600, by connecting the connector 610, the ECU 600 and the inspection device 760 are connected. As a result, all of the “electrical products attached to the main body of the engine 100” in this embodiment (connected to the wire harness 300) All of the various sensors and various actuators that are used can be connected to the inspection device 760. Therefore, as compared with the case of performing inspection for quality assurance by connecting each electrical product and the inspection apparatus in a one-to-one correspondence as in the conventional inspection method (see FIG. 14), the wiring work can be significantly reduced. It is possible to simplify the work in the inspection step S2300.

  (B) Further, in the relay connector panel 400, since the associated harnesses are grouped into the connectors 410, 420, 430, and 440, for example, when a malfunction occurs in the operating system of the common rail system 80 (injection actuators 83 and 83). , Etc.), the male body 611 of the connector 610 is removed from the female body 612, and the male body 431 of the injection operation system connector 430 is removed from the female body 432, so that the necessary minimum (connector) It is possible to perform maintenance by removing only the connection. That is, the other connectors 420, 430, and 440 can be left connected (no need to be set to non-connected), and work efficiency in inspection can be improved.

  (C) Furthermore, in the inspection method 700, in addition to the engine 100 main body and the electrical equipment attached to the engine 100 main body, the wire harness 300, the wire harness 590, and the ECU 600 are also inspected for quality assurance. It is possible. As a result of the inspection, if it becomes necessary to correct the control program of each engine 100, the correction value can be further reflected in the control program stored in the ECU 600 in the assembly step S2200. Therefore, the engine manufacturer can also use the ECU 600 for the assembly including the engine 100 main body, various electrical products (various sensors and various actuators), the harness (the wire harness 300 and the wire harness 590), and the ECU 600. It can be handled as a single product with a high degree of completeness that has been inspected for quality assurance.

As mentioned above, the engine 100 includes a rail pressure sensor 85 for detecting the pressure in the common rail 84 for pressurizing 蓄 high pressure fuel, an ejection actuator 83, 83, ... to operate the injector 81, 81 ... for injecting fuel A differential pressure sensor 78 for detecting a differential pressure before and after the filter (soot filter) in the exhaust purification device 70 (a combination of the inlet side sensing body 73, the outlet side sensing body 74, and the differential pressure sensing body 77); Exhaust temperature sensor 79 for detecting the temperature of the exhaust gas in the purification device 70, these sensors 85, 78, 79 and actuators 83, 83, ..., harness 220, 170, 110, 120 (wire harness 300, etc.), respectively. In the engine 100 including the ECU 600 that is connected via the ECU and controls the engine 100, All harnesses 220, 170, 110, 120 is connected to ECU600 via relay connector board 400 which is attached to the engine 100. With this configuration, electrical components (rail pressure sensor 85, injection actuators 83, 83,..., Differential pressure sensor 78, and the like mounted on the main body of engine 100 in a step before mounting engine 100 on the work machine. The exhaust temperature sensor 79) and the wire harness 300 can be connected and assembled to the engine 100 in advance. In other words, rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78 and exhaust temperature sensor 79 attached to engine 100 main body are all connected to relay connector panel 400. Therefore, the electrical equipment (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78 and exhaust temperature sensor 79) attached to the main body of engine 100 and ECU 600 (or inspection device 710 for quality assurance) When connecting the connectors, it is only necessary to operate the relay connector panel 400 (the connectors 410, 430, and 440 may be connected), and the connection work can be simplified.

  The engine 100 also adjusts the supply amount of fresh air to the crankshaft rotation sensor 8 that detects the rotation speed of the crankshaft 3, the camshaft rotation sensor 5 that detects the rotation speed of the camshaft, and the intake manifold 30. A throttle actuator 55 that operates the intake throttle, a valve actuator 56 that operates an EGR valve that adjusts the supply amount of exhaust gas to the intake manifold 30, and a mixed gas of fresh air and exhaust gas supplied to the intake manifold 30 Of these, an EGR sensor 59 that detects the proportion of exhaust gas and a metering actuator 98 that operates a metering valve that adjusts the amount of fuel supplied to the common rail 84 are provided. Connector 410, exhaust operation system connector 420, injection operation system connector 430, and injection detection And the differential pressure sensor 78, the exhaust temperature sensor 79, and the EGR sensor 59 are respectively connected to the exhaust detection system connector 410, and the throttle actuator 55 and the valve actuator 56 are respectively connected to the exhaust operation system. The injection actuators 83, 83... And the metering actuator 98 are connected to the injection operation system connector 430, and the rail pressure sensor 85, the crankshaft rotation sensor 8, and the camshaft rotation sensor 5 are connected to the connector 420. These are connected to the injection detection system connector 440, respectively. With this configuration, electrical components (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78, attached to the main body of the engine 100 in a step before the engine 100 is mounted on the work machine. The exhaust temperature sensor 79, the crankshaft rotation sensor 8, the camshaft rotation sensor 5, the throttle actuator 55, the valve actuator 56, the EGR sensor 59, and the metering actuator 98) and the wire harness 300 are connected to the engine 100 in advance. It is possible to keep. .., Differential pressure sensor 78 and exhaust temperature sensor 79, crankshaft rotation sensor 8, camshaft rotation sensor 5, throttle actuator 55, valve Actuator 56, EGR sensor 59, and metering actuator 98 are all connected to relay connector board 400. Therefore, electrical components (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78, exhaust temperature sensor 79, crankshaft rotation sensor 8, camshaft rotation sensor 5, throttle actuator attached to the main body of engine 100. 55, the valve actuator 56, the EGR sensor 59, and the metering actuator 98) and the ECU 600 (or the inspection device 710 for quality assurance) may be connected to each other by operating the relay connector panel 400 (each connector 410). It is only necessary to connect 420, 430, and 440), and the wiring work can be simplified. Moreover, it is possible to connect and disconnect the harnesses connected to highly relevant electrical equipment together. Therefore, the connection work required for maintenance or the like is simplified, and the work efficiency is improved.

  Further, in the engine 100, the middle portions of the harnesses 220 and 170 that connect the rail pressure sensor 85, the injection actuators 83, 83, and the relay connector panel 400 are bundled together to surround the common rail 84. Is routed around the engine and supported by the engine 100. With such a configuration, the pipe (the high-pressure pipe 91 and the fuel injection pipes 86, 86, etc.) in which the wire harness 350 is connected to the common rail 84 when the engine 100 is operated or the engine 100 is assembled. There is little possibility of getting tangled, and the wiring does not get in the way. In addition, wiring work can be easily performed, and wiring errors and disconnections can be prevented.

  Further, engine 100 connects rail pressure sensor 85, injection actuators 83, 83..., Cam shaft rotation sensor 5, valve actuator 56, EGR sensor 59, metering actuator 98, and relay connector panel 400. The middle portions of the harnesses 220, 170, 190, 160, 130, and 180 are bundled together and routed around the common rail 84 and wired along the outer periphery of the EGR valve member 54. Is supported by the engine 100. With this configuration, even when the engine 100 vibrates violently, the wire harness 350 is less likely to get entangled with the pipe connected to the common rail 84 or the EGR valve member 54, and thus rubs against other members constituting the engine 100. It is difficult for a situation such as a short circuit to occur. That is, the swing of the wire harness 350 can be remarkably reduced, and disconnection due to the vibration of the engine 100 of the wire harness 350 can be minimized.

  Further, the engine 600 is arranged in the vicinity of the cell motor 25 in the region extending from the side surface of the cylinder block 1 or the side surface of the cylinder block 1 to the side surface of the oil pan 10. With this configuration, electrical components (rail pressure sensor 85, injection actuators 83, 83,..., Differential pressure sensor 78, and the like mounted on the main body of engine 100 in a step before mounting engine 100 on the work machine. The exhaust temperature sensor 79 and the like) and the ECU 600 can be connected to the engine 100 main body in advance after being connected via the wire harness 300 and the like. In this case, the distance between the ECU 600 and the electrical equipment (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78, exhaust temperature sensor 79, etc.) attached to the main body of the engine 100 is uniquely determined. Therefore, it is not necessary to design a dedicated harness for connecting the electrical equipment (various sensors and various actuators) and the ECU 600 for each type of work machine on which the engine 100 is mounted. Further, in the wiring work after the engine 100 is mounted on the work machine, the electrical components (exhaust system lamp group 901, exhaust system switch group 902, injection system switch group 903, and injection system lamp group 904 attached to the work machine are used. ) And the ECU 600 need only be connected by the wire harness 910, 920, 930, 940, etc., so that the connection work at the customer can be easily performed. Further, since the ECU 600 is attached to the cylinder block 1 at a position where the ambient temperature is kept at a relatively low temperature, there is less possibility of the ECU 600 being exposed to a high temperature and failing.

The inspection method 700, a rail pressure sensor 85 for detecting the pressure in the common rail 84 for pressurizing 蓄 high pressure fuel, an ejection actuator 83, 83, ... to operate the injector 81, 81 ... for injecting fuel, A differential pressure sensor 78 (a combination of the inlet side sensing body 73, the outlet side sensing body 74, and the differential pressure sensing body 77) that detects the differential pressure before and after the filter (soot filter) in the exhaust purification device 70, and exhaust purification An exhaust temperature sensor 79 for detecting the temperature of exhaust gas in the apparatus 70, these sensors 85, 78, 79 and actuators 83, 83, ..., and harnesses 220, 170, 110, 120 (wire harness 300, etc.), respectively. And a plurality of harnesses 220, 170, and 11 that are connected to each other via the ECU 600 and that controls the engine 100. All of 120 are inspection methods for the engine 100 that are connected to the ECU 600 via the relay connector board 400 attached to the engine 100, and an inspection device 710 is connected to the relay connector board 400 instead of the ECU 600. Connecting step S7100, engine operating step S7200 for starting engine 100 subsequent to connecting step S7100, and inspection for performing operation inspection of sensors 85, 78, 79 and actuators 83, 83... Following engine operating step S7200 Execution step S7300. By using such a method, the inspection of the engine 100 main body and the electrical equipment (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78 and exhaust temperature sensor 79) attached to the engine 100 main body are performed. Therefore, it is possible to simplify the connection work required when performing the inspection, and thus it is possible to simplify the work in the inspection execution process. Further, in addition to the engine 100 main body and electrical products (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78 and exhaust temperature sensor 79) attached to the engine 100 main body, these are connected. The harnesses 220, 170, 110, and 120 to be inspected can be inspected for quality assurance. Therefore, the manufacturer of the engine includes the engine 100 main body, and electrical products (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78 and exhaust temperature sensor 79) attached to the engine 100 main body, It is possible to handle the assembly including the harnesses 220, 170, 110, and 120 that connect the two as one product having a high degree of completion after inspection.

  Further, in the inspection method 700, the engine 100 includes a crankshaft rotation sensor 8 that detects the rotation speed of the crankshaft 3, a camshaft rotation sensor 5 that detects the rotation speed of the camshaft, and fresh air to the intake manifold 30. A throttle actuator 55 that operates an intake throttle that adjusts the supply amount, a valve actuator 56 that operates an EGR valve that adjusts the supply amount of exhaust gas to the intake manifold 30, and fresh air and exhaust gas supplied to the intake manifold 30 An EGR sensor 59 that detects the ratio of exhaust gas in the mixed gas and a metering actuator 98 that operates a metering valve that adjusts the amount of fuel supplied to the common rail 84, and the relay connector panel 400 Are an exhaust detection system connector 410, an exhaust operation system connector 420, and an injection operation system connector. 430, an injection detection system connector 440, and a differential pressure sensor 78, an exhaust temperature sensor 79, and an EGR sensor 59 are respectively connected to the exhaust detection system connector 410, and the throttle actuator 55 and the valve actuator 56 .. And the metering actuator 98 are respectively connected to the injection operation system connector 430, the rail pressure sensor 85, the crankshaft rotation sensor 8, and the cam. The shaft rotation sensor 5 is connected to the injection detection system connector 440, respectively. By using such a method, the engine 100 main body and the electrical equipment attached to the engine 100 main body (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78, exhaust temperature sensor 79, crankshaft Wiring work required for inspection of the rotation sensor 8, the camshaft rotation sensor 5, the throttle actuator 55, the valve actuator 56, the EGR sensor 59, and the metering actuator 98) can be simplified, and as a result, the inspection is performed. Work in the process can be simplified. In addition, the engine 100 main body and electrical products (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78, exhaust temperature sensor 79, crankshaft rotation sensor 8, camshaft rotation attached to the engine 100 main body. In addition to the sensor 5, the throttle actuator 55, the valve actuator 56, the EGR sensor 59, and the metering actuator 98), the harness 220, 170, 110, 120, 210, 190, 150, 160, 130 Also for 180 (wire harness 300), inspection for quality assurance can be performed. Therefore, the engine manufacturer has the engine 100 main body and the electrical equipment (rail pressure sensor 85, injection actuators 83, 83..., Differential pressure sensor 78, exhaust temperature sensor 79, crankshaft rotation attached to the engine 100 main body. Sensor 8, camshaft rotation sensor 5, throttle actuator 55, valve actuator 56, EGR sensor 59, and metering actuator 98), and harnesses 220, 170, 110, 120, 210, 190, 150, 160, connecting them. It becomes possible to handle the assembly including 130 and 180 (wire harness 300) as one product having a high degree of completion after inspection. Moreover, it is possible to connect and disconnect the harnesses connected to highly relevant electrical equipment together. Therefore, the connection work required when performing an inspection for quality assurance of engine 100 is simplified, and the work efficiency is improved.

1 Cylinder block 5 Camshaft rotation sensor (one of the sensors)
8 Crankshaft rotation sensor (one of the sensors)
10 Oil pan 54 EGR valve member 55 Throttle actuator (one of the actuators)
56 Valve actuator (one of the actuators)
59 EGR sensor (one of the sensors)
78 Differential pressure sensor (one of the sensors)
79 Exhaust temperature sensor (one of the sensors)
83 Injection actuator (one of the actuators)
84 Common rail 85 Rail pressure sensor (one of the sensors)
98 Metering actuator (one of the actuators)
DESCRIPTION OF SYMBOLS 100 Engine 300 Wire harness 350 Wire harness (Harness which connects a rail pressure sensor and an injection actuator, and a connector)
400 Relay connector panel 410 Exhaust detection system connector (first connector)
420 Exhaust actuation system connector (second connector)
430 Injection system connector (third connector)
440 Injection detection system connector (fourth connector)
600 ECU (control device)
700 Inspection method (Engine inspection method)
710 Inspection equipment

Claims (1)

A rail pressure sensor (85) for detecting the pressure in the common rail (84) for accumulating high-pressure fuel, an injection actuator (83) for operating the injector (81) for injecting fuel, and a filter in the exhaust purification device (70) A differential pressure sensor (78) for detecting the differential pressure before and after, an exhaust gas temperature sensor (79) for detecting the temperature of the exhaust gas in the exhaust gas purification device (70), and the rotational speed of the crankshaft (3) are detected. A crankshaft rotation sensor (8), a camshaft rotation sensor (5) for detecting the rotation speed of the camshaft, and a throttle actuator (55) for operating an intake throttle for adjusting the amount of fresh air supplied to the intake manifold (30) ), A valve actuator (56) for operating an EGR valve for adjusting the amount of exhaust gas supplied to the intake manifold (30), and the intake manifold An EGR sensor (59) for detecting the ratio of exhaust gas in the mixed gas of fresh air and exhaust gas supplied to the hold (30), and a metering for adjusting the amount of fuel supplied to the common rail (84) In an engine comprising a metering actuator (98) for actuating a valve, and a controller (600) connected to these sensors and actuators via harnesses to control the engine,
All of the plurality of harnesses are connected to the control device (600) via a relay connector panel (400) attached to the engine,
The relay connector board (400) includes a first connector (410), a second connector (420), a third connector (430), and a fourth connector (440).
The differential pressure sensor (78), the exhaust temperature sensor (79), and the EGR sensor (59) are connected to the first connector (410), respectively.
The throttle actuator (55) and the valve actuator (56) are respectively connected to the second connector (420),
The injection actuator (83) and the metering actuator (98) are each connected to the third connector (430),
The rail pressure sensor (85), the crankshaft rotation sensor (8), and the camshaft rotation sensor (5) are connected to the fourth connector (440), respectively.
The middle portions of the harnesses connecting the sensors and actuators to the relay connector panel (400) are bundled together and wired so as to bypass the common rail (84), and an EGR valve member (54) is routed along the outer periphery,
The engine is characterized in that the relay connector board (400) is attached to a cylinder block (1) below a common rail (84) and an EGR valve member (54) via an attachment stay (16) .

Images