JP2018080662A - Oil supply mechanism for engine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an oil supply mechanism for an engine which can promote the temperature rising of oil.SOLUTION: An oil supply mechanism for an engine includes a lower case 130 for returning oil which is pressure-fed from an oil pump and lubricates a crank journal of a crankshaft to an oil pan, and a lower side heat insulation layer 163 which is formed in the lower case 130. The lower case 130 includes an oil receiver 130c for receiving the oil which lubricates the crank journal, and the lower side heat insulation layer 163 includes a receiver side heat insulation layer 163a which is formed on a surface of the oil receiver 130c.SELECTED DRAWING: Figure 8

Description

  The present invention relates to a technique of an oil supply mechanism of an engine for supplying oil to each part of the engine.

  2. Description of the Related Art Conventionally, a technique of an engine oil supply mechanism for supplying oil to each part of an engine is known. For example, as described in Patent Document 1.

  An oil supply mechanism (oil supply device) described in Patent Document 1 includes an oil pan in which oil is stored, an oil pump that pumps the oil, a main oil hole (main gallery) formed in a cylinder block, and the main oil It has a branch road that branches off from the hall. The oil supply mechanism supplies oil pumped from an oil pump to each part of the engine (for example, a crank journal, a VVT (variable valve timing mechanism), a chain tensioner, etc.) via a main oil hole and a branch path. The oil supply mechanism returns the oil supplied to each part of the engine to the oil pan. Thus, the oil supply mechanism circulates oil stored in the oil pan to each part of the engine.

  In the oil supply mechanism described in Patent Document 1, the cylinder block is made of a casting. In this case, the main oil hole and the branch path are formed by, for example, a core when the cylinder block is cast or by being subjected to cutting after casting. The main oil hole and the branch path are generally in a state where the metal surface is exposed.

  Here, the oil circulating through each part of the engine is warmed by taking heat of the engine (for example, combustion heat). However, if the metal surface of the main oil hole and the branch path is exposed, the heat of the heated oil is released to the outside. Thus, when the metal surface is exposed in the oil passage, the oil is circulated downstream of the oil passage while releasing the heat of the oil guided to the oil passage. For this reason, temperature rise of oil cannot be promoted at the time of cold start etc. (oil high viscosity), friction may increase and fuel consumption may deteriorate.

JP 2016-169709 A

  The present invention has been made in view of the above situation, and a problem to be solved is to provide an oil supply mechanism of an engine that can promote the temperature rise of oil.

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

  That is, according to a first aspect of the present invention, a lower case for returning oil lubricated to a crank journal of the crankshaft to the oil pan and a heat insulating layer formed on the lower case are provided, and the lower case closes the oil pan from above. A blocking portion is provided, and the heat insulating layer includes a blocking portion-side heat insulating layer formed on the surface of the blocking portion.

  The lower case includes an oil receiving portion that receives oil that lubricates the crank journal, and the heat insulating layer includes a receiving portion side heat insulating layer formed on a surface of the oil receiving portion. It is.

  According to a third aspect of the present invention, the receiving portion side heat insulating layer is formed over the entire surface of the oil receiving portion.

  According to a fourth aspect of the present invention, the receiving part side heat insulating layer is formed by a heat insulating material coated on the surface of the oil receiving part.

  According to a fifth aspect of the present invention, the closed portion side heat insulating layer is formed over the entire surface of the closed portion.

  In Claim 6, the said obstruction | occlusion part side heat insulation layer is formed with the heat insulating material coated on the surface of the said obstruction | occlusion part.

  As effects of the present invention, the following effects can be obtained.

  In Claim 1, the temperature rise of oil can be accelerated | stimulated.

  In Claim 2, it can suppress that the heat of the oil received by the oil receiving part escapes.

  In Claim 3, it can suppress effectively that the heat | fever of the oil received by the oil receiving part escapes.

  In Claim 4, a receiving part side heat insulation layer can be formed easily.

  In Claim 5, it can suppress effectively that the heat of oil escapes from an oil pan.

  In Claim 6, the obstruction | occlusion part side heat insulation layer can be formed easily.

The schematic diagram which showed the whole structure of the oil supply mechanism. The top view which showed the cylinder block. Similarly, bottom view. X1-X1 sectional drawing. Z1-Z1 sectional drawing. X2-X2 sectional drawing. Z2-Z2 sectional drawing. The top view which showed the lower case. Similarly, bottom view. The rear view which showed the chain case.

  In the following, the directions indicated by arrow U, arrow D, arrow F, arrow B, arrow L and arrow R in the figure are defined as upward, downward, forward, backward, leftward and rightward, respectively. To explain.

  Below, the oil supply mechanism 100 of the engine 10 which concerns on one Embodiment of this invention is demonstrated.

  First, the configuration of the engine 10 provided with the oil supply mechanism 100 will be described with reference to FIGS. 1 to 4.

  The engine 10 is an in-line four-cylinder engine and is mounted on a vehicle such as an automobile, for example. As shown in FIG. 1, the engine 10 includes an oil pan 20, a lower case 130, a cylinder block 30, a cylinder head 40, a chain case 140, and the like.

  The oil pan 20 is for storing oil inside. The oil stored in the oil pan 20 is supplied to the cylinder block 30 and the like by an oil supply mechanism 100 described later. The oil pan 20 is formed in a substantially box shape whose upper side is opened (not shown).

  The lower case 130 is disposed above the oil pan 20 and supports the crank journal 31 of the crankshaft. The configuration of the lower case 130 will be described later.

  The cylinder block 30 is for sliding a piston (not shown). As shown in FIGS. 2 to 4, the cylinder block 30 includes a cylinder bore 30 a and a support portion 30 b.

  The cylinder bore 30 a is a hole having a substantially circular shape in plan view formed so as to extend downward from the upper surface of the cylinder block 30. Four cylinder bores 30a according to the present embodiment are formed at intervals. The piston is slidably provided in the cylinder bore 30a.

  The support portion 30 b is a substantially semicircular recess in front view formed at the lower end portion of the cylinder block 30. The support part 30 b supports the crank journal 31. A plurality of support portions 30b are provided at intervals in the axial direction of the crankshaft (the front-rear direction in the present embodiment). The support portions 30b are formed so as to correspond to the number of crank journals 31 (one support portion 30b is formed for one crank journal 31).

  As shown in FIG. 1, the oil pan 20 is attached to the cylinder block 30 configured in this way from below via a lower case 130. The cylinder block 30 is provided with a piston jet 32 and the like for injecting oil to the piston.

  The cylinder head 40 includes a valve operating mechanism (not shown) that opens and closes an intake valve and an exhaust valve by rotating a camshaft, and is attached to the cylinder block 30 from above via bolts or the like. The cylinder head 40 is provided with an OCV (oil control valve) 41, a VVT (valve timing changing mechanism) 42, an intake lash adjuster 43, an exhaust lash adjuster 44, and the like. The OCV 41 controls the supply and discharge of oil to the VVT 42. The VVT 42 changes the opening / closing timing of the intake valve. The intake side lash adjuster 43 suppresses the occurrence of intake side valve clearance. The exhaust side lash adjuster 44 suppresses the occurrence of exhaust side valve clearance. The VVT 42, the intake lash adjuster 43, and the exhaust lash adjuster 44 operate when oil is supplied.

  The chain case 140 is disposed so as to face the cylinder block 30 and the cylinder head 40. The chain case 140 covers a timing chain (not shown) that transmits the rotation of the crankshaft to the camshaft, a chain tensioner 51 for applying tension to the timing chain, and the like. The chain tensioner 51 operates when oil is supplied. The configuration of the chain case 140 will be described later.

  Next, the configuration of the oil supply mechanism 100 will be described with reference to FIGS.

  The oil supply mechanism 100 shown in FIG. 1 is for supplying oil stored in the oil pan 20 to each part of the engine 10. The oil supply mechanism 100 includes an oil pump 110, an oil filter 120, a lower case 130, a chain case 140, a supply oil passage 150, a heat insulating layer group 160, and the like.

  The oil pump 110 sucks oil stored in the oil pan 20 and pumps the oil downstream. The oil pump 110 is driven by the engine 10 and is driven at a rotational speed corresponding to the rotational speed of the engine 10.

  The oil filter 120 is disposed on the downstream side of the oil pump 110, and removes foreign matters contained in the oil pumped from the oil pump 110.

  The lower case 130 is for returning the oil supplied to the cylinder block 30 or the like (oil falling from the cylinder block 30 or the like) to the oil pan 20. The lower case 130 shown in FIGS. 8 and 9 is formed in a substantially box shape opened up and down. The upper portion of the lower case 130 opens from the front end portion to the rear end portion. Further, the lower case 130 has a lower portion that opens from the front end portion to the front / rear halfway portion. The lower case 130 includes a rear side wall portion 130a, a front side wall portion 130b, an oil receiving portion 130c, a mounting portion 130d, a closing portion 130e, and a through hole 130f.

  The rear side wall portion 130a is a wall that forms the rear portion of the bottom surface of the lower case 130 (the surface with the plate surface facing up and down), and is formed from the rear end portion of the lower case 130 to the front and rear intermediate portions. The rear side wall part 130 a is formed in the upper and lower middle part of the lower case 130.

  The front side wall part 130b is a wall that forms the front part of the bottom surface of the lower case 130, and is formed from the front and rear midway part to the front end part of the lower case 130. The front side wall part 130b is formed to be continuous with the front side of the rear side wall part 130a, and divides the internal space of the lower case 130 vertically.

  The oil receiving portion 130c is a portion that receives oil supplied to the cylinder block 30 and the like. The oil receiving portion 130 c is formed by the upper inner surface of the lower case 130. More specifically, the oil receiving portion 130c is formed by the upper surfaces of the rear side wall portion 130a and the front side wall portion 130b (see the hatched area indicated by the dotted line in FIG. 8) and the side walls of the lower case 130 (from the upper end portion to the upper and lower middle portions). It is formed.

  The attachment portion 130d is a portion formed at the lower end portion of the lower case 130. The attachment portion 130d is formed in a substantially rectangular ring shape when viewed from the bottom. The oil pan 20 is attached to the attachment portion 130d via a bolt or the like.

  The closing part 130e is a part that closes the oil pan 20 from above. The closing portion 130e is formed by the lower inner surface of the lower case 130. More specifically, the closing portion 130e includes a lower surface of the front side wall portion 130b (see a portion surrounded by the mounting portion 130d in the bottom view, see a hatched area shown by a dotted line in FIG. 9) and a side wall (from the upper and lower middle portions). To the lower end). As described above, in the lower case 130, the oil pan 20 is closed from above by the closing portion 130 e, thereby forming a relatively small space between the lower case 130 and the oil pan 20. In the front side wall portion 130b, an oil receiving portion 130c is formed on the upper side surface, and a closing portion 130e is formed on the lower side surface.

  The through hole 130f is a hole that allows the lower case 130 and the oil pan 20 to communicate with each other. The through hole 130f vertically penetrates the closing portion 130e (the lower surface of the front side wall portion 130b). A plurality of through holes 130f are formed at intervals.

  The chain case 140 shown in FIG. 10 is a substantially lid-shaped member. The chain case 140 includes a convex portion 140a.

  The convex part 140a is a part protruding from the upper and lower halfway part of the surface (the rear surface in this embodiment) facing the cylinder block 30 and the cylinder head 40 of the chain case 140. The convex part 140a is formed so as to surround a part of the area of the facing surface (see the hatched area indicated by the dotted line in FIG. 10). The convex portion 140a is blocked from the cylinder block 30 side (the front side in the present embodiment) by a predetermined member (not shown).

  A supply oil passage 150 shown in FIG. 1 is an oil passage for guiding oil from which foreign matter has been removed by the oil filter 120 to each part of the engine 10. The supply oil passage 150 includes an oil passage 151, a main oil hole 152, a sub oil hole 153, a chain side oil passage 154, an oil dropping oil passage 155, and an oil return oil passage 156.

  The oil passage 151 is an oil passage that guides oil from which foreign matter has been removed by the oil filter 120 to the cylinder block 30 and the chain case 140. One end of the oil passage 151 is connected to the oil filter 120, and the midway portion branches into two. One end of the oil passage 151 is connected to the cylinder block 30 at one end thereof. Further, the other branch of the oil passage 151 is connected to the chain case 140 at an end thereof.

  The main oil hole 152 is an oil passage through which oil guided to the cylinder block 30 from the oil passage 151 (one branched passage) flows in the axial direction (front-rear direction) of the crankshaft. As shown in FIGS. 2 to 4, the main oil hole 152 is formed on the side of the cylinder bore 30a (right side in the present embodiment). The main oil hole 152 includes a connection part 152a and a supply part 152b.

  The connection part 152a is a part connected to the oil passage 151. The connecting portion 152a is formed in a T-shape in front sectional view such that an end portion extending upward extends to the left and right. The lower end portion of the connection portion 152a is connected to the oil passage 151. Further, the connecting portion 152a is connected to a supply portion 152b, which will be described later, at an end portion extending rightward.

  The supply portion 152b is a portion that guides oil in the axial direction (front-rear direction) of the crankshaft. The supply part 152b is formed in a substantially circular shape when viewed from the front. As shown in FIGS. 4 and 5, the supply portion 152b is formed to extend in the axial direction of the crankshaft from the front end portion to the rear end portion. The supply part 152b is connected to the connection part 152a in the middle part. Moreover, the supply part 152b branches appropriately in the middle part, and is connected with the piston jet 32 (refer FIG. 1).

  The sub oil hole 153 is an oil passage for guiding the oil flowing through the main oil hole 152 to the crank journal 31. As shown in FIGS. 3, 5, and 6, the sub oil hole 153 is formed to extend from the supply part 152 b of the main oil hole 152 toward the support part 30 b, and the extended end part is the support part 30 b. It opens to the outside and is connected to the crank journal 31. The sub oil hole 153 is formed so as to correspond to the crank journal 31 (one sub oil hole 153 is formed for one crank journal 31).

  As shown in FIGS. 1 and 10, the chain side oil passage 154 is an oil passage for guiding the oil guided to the chain case 140 from the oil passage 151 (the other branched passage) to the cylinder head 40 and the like. . The chain-side oil passage 154 is formed by a portion surrounded by the convex portion 140a of the chain case 140 and the convex portion 140a on the rear surface, and a predetermined member that closes the convex portion 140a (see the hatched area shown by the dotted line in FIG. 10). ). The chain-side oil passage 154 has a lower end connected to the oil passage 151 and an upper end connected to the cylinder head 40. Further, the chain-side oil passage 154 is connected to the chain tensioner 51 in the middle.

  The oil dropping oil passage 155 is an oil passage for dropping the oil guided from the chain side oil passage 154 to the cylinder head 40 to the oil receiving portion 130 c of the lower case 130. As shown in FIGS. 2, 6, and 7, the oil dropping oil passage 155 is formed so as to penetrate the cylinder block 30 vertically. The oil dropping oil passage 155 has an upper end connected to the cylinder head 40 and a lower end connected to the oil receiving portion 130c. A plurality of oil dropping oil passages 155 are formed at intervals in the axial direction (front-rear direction) of the crankshaft.

  The oil return oil passage 156 shown in FIGS. 1 and 8 is an oil passage for returning the oil dropped in the oil receiving portion 130 c to the oil pan 20. The oil return oil passage 156 is formed by the oil receiving portion 130c and the through hole 130f.

  The heat insulation layer group 160 shown in FIG. 1 is for making it difficult for the heat of the oil flowing through the supply oil passage 150 to escape from the supply oil passage 150 to the outside. The heat insulating layer group 160 includes a main heat insulating layer 161, a sub heat insulating layer 162, a lower heat insulating layer 163, a chain heat insulating layer 164, and a drop side heat insulating layer 165.

  As shown in FIGS. 4 and 5, the main heat insulating layer 161 is formed in the entire area of the main oil hole 152 (the entire circumference of the portion extending above and to the left and right of the connecting portion 152 a and from one end portion to the other end portion of the supplying portion 152 b. Of the entire circumference). The main-side heat insulating layer 161 is formed by coating the main oil hole 152 with a resin material (for example, PAI (polyamideimide resin)). In FIGS. 4 and 5, a portion where the main heat insulating layer 161 is formed is indicated by a dotted diagonal line.

  As shown in FIG. 6, the sub-side heat insulating layer 162 is formed over the entire area of the sub oil hole 153 (the entire circumference from one end portion to the other end portion of the sub oil hole 153). The sub-side heat insulating layer 162 is formed by coating the sub oil hole 153 with the same resin material as that of the main-side heat insulating layer 161. In addition, in FIG. 6, the location in which the sub side heat insulation layer 162 is formed is shown with the oblique line of a dotted line.

  As shown in FIGS. 8 and 9, the lower heat insulating layer 163 is formed in the lower case 130 (the oil return oil passage 156 and its surroundings). The lower heat insulating layer 163 includes a receiving part heat insulating layer 163a and a closed part heat insulating layer 163b.

  The receiving portion side heat insulating layer 163a is formed over the entire surface of the oil receiving portion 130c (the inner surface on the upper side of the lower case 130). The receiving side heat insulating layer 163a is formed by coating the same resin material as that of the main heat insulating layer 161. In addition, in FIG. 8, the location in which the receiving part side heat insulation layer 163a is formed is shown by the dotted oblique line.

  The blocking portion side heat insulating layer 163b is formed over the entire surface of the blocking portion 130e (the inner surface on the lower side of the lower case 130). The blocking portion side heat insulating layer 163b is formed by coating the same resin material as the resin material of the main side heat insulating layer 161. In addition, in FIG. 9, the location in which the obstruction | occlusion part side heat insulation layer 163b is formed is shown with the oblique line of a dotted line. Further, the closing portion side heat insulating layer 163b and the receiving portion side heat insulating layer 163a are respectively formed on the upper side surface and the lower side surface of the front side wall portion 130b (formed so as to overlap in the vertical direction).

  As shown in FIG. 10, the chain-side heat insulating layer 164 is formed over the entire region of the chain-side oil passage 154. The chain-side heat insulation layer 164 is formed by coating the chain-side oil passage 154 with the same resin material as the resin material of the main-side heat insulation layer 161. In addition, in FIG. 10, the location where the chain side heat insulation layer 164 is formed is shown by the oblique line of a dotted line.

  As shown in FIGS. 6 and 7, the drop-side heat insulating layer 165 is formed over the entire area of the oil drop oil passage 155 (the whole from the upper end to the lower end). The drop-side heat insulation layer 165 is formed by coating the oil drop oil passage 155 with the same resin material as the resin material of the main-side heat insulation layer 161. In FIGS. 6 and 7, a portion where the drop-side heat insulating layer 165 is formed is indicated by a dotted oblique line.

  Next, the operation of the oil supply mechanism 100 will be described with reference to FIG.

  First, the oil pump 110 operates as the engine 10 is driven, and pumps the oil in the oil pan 20 to the oil passage 151 via the oil filter 120. Part of the oil is guided from the middle of the oil passage 151 to the main oil hole 152 (cylinder block 30). Further, the remainder of the oil pumped from the oil pump 110 is guided to the chain side oil passage 154 (chain case 140) from the middle of the oil passage 151.

  The oil guided to the main oil hole 152 flows through the sub oil hole 153 and is guided to the crank journal 31 to lubricate the crank journal 31. The oil that has passed through the sub oil hole 153 flows through a hole formed in the crankshaft and lubricates a crank pin (not shown). Oil that has lubricated the crank journal 31 and the crank pin falls from the crank shaft to the oil return oil passage 156 (oil receiving portion 130c).

  Further, the oil guided to the main oil hole 152 is guided to the piston jet 32 and injected to the piston. The oil falls to the oil return oil passage 156 after lubricating the piston.

  On the other hand, a part of the oil guided from the oil passage 151 to the chain side oil passage 154 is supplied to the chain tensioner 51. The oil falls on the oil return oil passage 156 along the rear surface of the chain case 140 (the portion not surrounded by the convex portion 140a). The remainder of the oil guided to the chain side oil passage 154 is guided to the cylinder head 40 and supplied to the OCV 41 (VVT 42), the exhaust side lash adjuster 44, and the intake side lash adjuster 43. The oil is guided to the oil dropping oil passage 155 along the inner surface of the cylinder block 30 and falls from the oil dropping oil passage 155 to the oil returning oil passage 156.

  Oil that has fallen into the oil return oil passage 156 (oil lubricated with the crank journal 31, the crankpin and the piston, and oil supplied to the chain tensioner 51, the OCV 41, etc.) passes through the side surface and the bottom surface of the oil receiving portion 130c and passes through the hole. It is guided by 130f and falls into the oil pan 20 from the through hole 130f (see FIG. 8).

  As described above, when the engine 10 is driven, the oil supply mechanism 100 can circulate the oil in the oil pan 20 in the engine 10 to lubricate the lubrication part such as the piston or operate the chain tensioner 51 and the like.

  Here, the oil circulating through the engine 10 is warmed by taking heat of the engine (heat of the piston and combustion heat). In the oil supply mechanism 100 according to the present embodiment, the heat of the heated oil is prevented from escaping by the heat insulating layer group 160.

  Specifically, the oil supply mechanism 100 according to the present embodiment insulates the main oil hole 152 by the main-side heat insulating layer 161 shown in FIGS. 4 and 5. According to this, it is possible to suppress the heat of oil (warmed oil) flowing through the main oil hole 152 from escaping to the outside of the main oil hole 152.

  Further, the oil supply mechanism 100 according to the present embodiment insulates the sub oil hole 153 by the sub side heat insulating layer 162 shown in FIG. According to this, it is possible to suppress the heat of the oil flowing through the sub oil hole 153 from escaping to the outside of the sub oil hole 153.

  Further, the oil supply mechanism 100 according to the present embodiment insulates the oil receiving portion 130c by the receiving portion side heat insulating layer 163a of the lower side heat insulating layer 163 shown in FIG. According to this, it is possible to suppress the heat of the oil received by the oil receiving portion 130c (oil lubricated to the crank journal 31 and the piston, oil supplied to the chain tensioner 51 and OCV 41) from escaping to the outside of the lower case 130. .

  Further, the lower side heat insulating layer 163 insulates the closed portion 130e by the closed portion side heat insulating layer 163b shown in FIG. According to this, it is possible to suppress the heat of the oil stored in the oil pan 20 (oil heated by circulating through the engine 10) from escaping to the outside (upward) of the oil pan 20.

  Further, the oil supply mechanism 100 according to the present embodiment insulates the chain side oil passage 154 by the chain side heat insulating layer 164 shown in FIG. According to this, it is possible to suppress the heat of the oil flowing through the chain side oil passage 154 (oil supplied to the chain tensioner 51, the VVT 42, etc.) from escaping to the outside of the chain side oil passage 154.

  Moreover, the oil supply mechanism 100 according to the present embodiment insulates the oil dropping oil passage 155 by the dropping side heat insulating layer 165 shown in FIGS. 6 and 7. According to this, it is possible to suppress the heat of the oil flowing through the oil dropping oil passage 155 (oil supplied to the OCV 41 and the like) from escaping to the outside of the oil dropping oil passage 155.

  As described above, the oil supply mechanism 100 suppresses the heat of the oil from escaping to the outside by the heat insulating layer group 160 at many locations (locations excluding the cylinder head 40 and the oil passage 151) of the supply oil passage 150. ing. According to this, since the temperature rise of the oil can be promoted, the time for circulating the low temperature (high viscosity) oil is shortened as much as possible at the time of cold start of the engine 10 (warmed oil (low viscosity oil)). Can be quickly lubricated). Thereby, the friction of the lubrication part can be quickly reduced (suppression of the phenomenon that the friction increases), and the deterioration of fuel consumption can be suppressed. Further, the engine 10 can be quickly warmed up by promoting the temperature rise of the oil.

  Moreover, the main side heat insulation layer 161, the sub side heat insulation layer 162, the lower side heat insulation layer 163, the chain side heat insulation layer 164, and the drop side heat insulation layer 165 are formed by coating a resin material. According to this, the main side heat insulation layer 161, the sub side heat insulation layer 162, the lower side heat insulation layer 163, the chain side heat insulation layer 164, and the drop side heat insulation layer 165 can be formed by simple processing.

  As described above, the oil supply mechanism 100 of the engine 10 according to this embodiment is formed in the main oil hole 152 that guides the oil to the crank journal 31 and the piston (the lubricating portion of the engine 10), and the main oil hole 152. A main heat insulating layer 161 (heat insulating layer).

  By configuring in this way, it is possible to prevent the heat of the oil from escaping from the main oil hole 152, so that the temperature rise of the oil can be promoted.

  The main heat insulating layer 161 is formed over the entire main oil hole 152.

  With this configuration, there is no place where heat can easily escape from the main oil hole 152, and therefore it is possible to effectively suppress the heat of oil from escaping from the main oil hole 152.

  The main heat insulating layer 161 is formed of a heat insulating material coated on the main oil hole 152.

  By comprising in this way, the main side heat insulation layer 161 can be formed easily.

  As described above, the oil supply mechanism 100 of the engine 10 according to the present embodiment is formed in the sub oil hole 153 that guides oil from the main oil hole 152 to the crank journal 31 of the crankshaft, and the sub oil hole 153. And the sub-side heat insulating layer 162 (heat insulating layer).

  By configuring in this way, it is possible to prevent the heat of the oil from escaping from the sub oil hole 153, so that the temperature rise of the oil can be promoted.

  The sub-side heat insulating layer 162 is formed over the entire sub oil hole 153.

  With this configuration, there is no place where heat can easily escape from the sub oil hole 153, so that it is possible to effectively suppress the oil heat from escaping from the sub oil hole 153.

  The sub-side heat insulating layer 162 is formed of a heat insulating material coated on the sub oil hole 153.

  By comprising in this way, the sub side heat insulation layer 162 can be formed easily.

  Further, as described above, the oil supply mechanism 100 of the engine 10 according to the present embodiment includes the lower case 130 that returns the oil that lubricated the crank journal 31 of the crankshaft to the oil pan 20, and the lower side heat insulation formed in the lower case 130. The lower case 130 includes a closed portion 130e that closes the oil pan 20 from above, and the lower heat insulating layer 163 is formed on the surface of the closed portion 130e. The closed portion side heat insulating layer 163b is provided.

  Here, for example, assuming that there is no blocking portion 130e, the upper portion of the oil pan 20 is greatly opened toward the cylinder block 30 without being blocked by any member. In such a case, since a large space is provided above the oil pan 20, the heat of the oil stored in the oil pan 20 will actively escape upward. Thus, when there is no closed part 130e, the oil stored in the oil pan 20 becomes relatively easy to cool.

  On the other hand, in the present embodiment, as described above, the oil pan 20 is closed from above by the closing portion 130e, so that a relatively small space is formed between the lower case 130 and the oil pan 20. Thus, when the space provided above the oil pan 20 is small, it is possible to prevent the heat of the oil stored in the oil pan 20 from actively escaping upward. Further, in the present embodiment, since the closed portion side heat insulating layer 163b is formed on the surface of the closed portion 130e, the heat of the space between the lower case 130 and the oil pan 20 is passed through the closed portion 130e. It is difficult to be transmitted to the upper part of.

  As described above, in the oil supply mechanism 100 according to the present embodiment, the oil stored in the oil pan 20 is compared by having the closed portion 130e in which the closed portion side heat insulating layer 163b is formed on the surface of the closed portion 130e. Can be difficult to cool. That is, by configuring like the oil supply mechanism 100 of the engine 10 according to the present embodiment, it is possible to suppress the heat of oil from escaping from the oil pan 20 and to promote the temperature rise of the oil.

  The lower case 130 includes an oil receiving portion 130c that receives oil that lubricates the crank journal 31, and the lower heat insulating layer 163 includes a receiving portion heat insulating layer 163a formed on the surface of the oil receiving portion 130c. It comprises.

By comprising in this way, it can suppress that the heat | fever of the oil received by the oil receiving part 130c escapes.
In the present embodiment, as described above, the blocking portion side heat insulating layer 163b and the receiving portion side heat insulating layer 163a are formed so as to overlap in the vertical direction on the front side wall portion 130b. That is, the heat of the space of the oil pan 20 is transferred to the upper part of the lower case 130 through the closing part 130e (the front part of the front side wall part 130b) by the double heat insulating layer formed so as to overlap in the vertical direction. It is even more difficult to communicate. In this way, the oil stored in the oil pan 20 can be made more difficult to cool.

  Moreover, the said receiving part side heat insulation layer 163a is formed in the whole surface of the said oil receiving part 130c.

  With this configuration, there is no place where heat easily escapes in the oil receiving portion 130c, so that it is possible to effectively suppress the heat of the oil received by the oil receiving portion 130c.

  The receiving part-side heat insulating layer 163a is formed of a heat insulating material coated on the surface of the oil receiving part 130c.

  By comprising in this way, the receiving part side heat insulation layer 163a can be formed easily.

  Further, the blocking portion side heat insulating layer 163b is formed over the entire surface of the blocking portion 130e.

  By configuring in this way, there is no place where heat easily escapes in the closed portion 130e, so that it is possible to effectively suppress the escape of oil heat from the oil pan 20.

  Further, the blocking portion side heat insulating layer 163b is formed by a heat insulating material coated on the surface of the blocking portion 130e.

  By comprising in this way, the obstruction | occlusion part side heat insulation layer 163b can be formed easily.

  In addition, the lower side heat insulation layer 163 which concerns on this embodiment is one Embodiment of the heat insulation layer which concerns on this invention.

  Further, as described above, the oil supply mechanism 100 of the engine 10 according to the present embodiment includes the oil dropping oil passage 155 that drops the oil guided from the cylinder head 40 to the cylinder block 30 onto the lower case 130, and the oil dropping oil passage. And a drop-side heat insulating layer 165 (heat insulating layer) formed at 155.

  By configuring in this way, it is possible to suppress the heat of the oil from escaping from the oil dropping oil passage 155, so that the temperature rise of the oil can be promoted.

  The drop-side heat insulation layer 165 is formed over the entire area of the oil drop oil passage 155.

  By configuring in this way, there is no place where heat easily escapes in the oil dropping oil passage 155, so that it is possible to effectively suppress the heat of oil from the oil dropping oil passage 155.

  The drop-side heat insulation layer 165 is formed by a heat insulating material coated on the oil drop oil passage 155.

  By comprising in this way, the drop side heat insulation layer 165 can be formed easily.

  As described above, the oil supply mechanism 100 of the engine 10 according to the present embodiment includes the chain case 140 having the chain side oil passage 154 (oil passage) for guiding the oil to the cylinder head 40, and the chain side oil passage 154. And a chain side heat insulating layer 164 (heat insulating layer) formed on the surface.

  By configuring in this way, it is possible to prevent the heat of the oil from escaping from the chain-side oil passage 154, so that the temperature rise of the oil can be promoted.

  The chain-side heat insulating layer 164 is formed over the entire region of the chain-side oil passage 154.

  By configuring in this way, there is no place where heat easily escapes in the chain-side oil passage 154, so that it is possible to effectively suppress the escape of oil heat from the chain-side oil passage 154.

  The chain-side heat insulating layer 164 is formed by a heat insulating material coated on the chain-side oil passage 154.

  By comprising in this way, the chain side heat insulation layer 164 can be formed easily.

  In addition, the oil supply mechanism 100 according to the present embodiment forms a heat insulating layer in the main oil hole 152 and the sub oil hole 153 (the main side heat insulating layer 161 and the sub side heat insulating layer 162 are provided). Accordingly, it is possible to suppress the escape of the heat of the oil that flows from the main oil hole 152 to the sub oil hole 153 and lubricates the crank journal 31. According to this, since it is difficult to cool the oil that lubricates the crank journal 31, low-viscosity oil can be quickly supplied to the crank journal 31, and as a result, deterioration of the friction of the crank journal 31 can be effectively suppressed.

  Further, the oil supply mechanism 100 forms a heat insulating layer not only in the main oil hole 152 and the sub oil hole 153 but also in the oil receiving portion 130c (the main side heat insulating layer 161, the sub side heat insulating layer 162, and the receiving portion side). A heat insulating layer 163a). Accordingly, even when the oil that has lubricated the crank journal 31 returns to the oil pan 20, it is possible to prevent the heat of the oil from escaping. According to this, it is possible to suppress the escape of oil heat in many of the paths (the main oil hole 152, the sub oil hole 153, and the oil return oil path 156) that circulate between the oil pan 20 and the crank journal 31. For this reason, low-viscosity oil can be supplied to the crank journal 31 more quickly, and deterioration of the friction of the crank journal 31 can be effectively suppressed.

  The embodiment of the present invention has been described above, but the present invention is not limited to the above-described configuration, and various modifications can be made within the scope of the invention described in the claims.

  For example, the main side heat insulating layer 161, the sub side heat insulating layer 162, the lower side heat insulating layer 163, the chain side heat insulating layer 164, and the drop side heat insulating layer 165 are formed of PAI. It is not limited to PPS (polyphenylene sulfide), PTFE (polytetrafluoroethylene), a phenol resin, or the like.

  In addition, the main side heat insulating layer 161, the sub side heat insulating layer 162, the lower side heat insulating layer 163, the chain side heat insulating layer 164, and the drop side heat insulating layer 165 are formed of the same resin material, but the present invention is not limited thereto. For example, they may be formed of different resin materials.

  The heat insulating layer group 160 may include a heat insulating layer formed in the oil passage 151. According to this, it is possible to suppress the heat of the oil flowing through the oil passage 151 from escaping from the outside of the oil passage 151.

  The heat insulating layer group 160 may include a heat insulating layer formed on the inner surface of the chain case 140 (a portion not surrounded by the convex portion 140a). According to this, it is possible to suppress the heat of the oil supplied to the chain tensioner 51 (oil transmitted through the inner surface of the chain case 140) from escaping from the outside of the chain case 140.

  The heat insulation layer group 160 includes a heat insulation layer formed on the cylinder head 40 (the portion connecting the OCV 41, the intake side lash adjuster 43 and the exhaust side lash adjuster 44 and the oil dropping oil passage 155). Also good. According to this, it is possible to suppress the heat of the oil guided from the OCV 41 or the like to the oil dropping oil passage 155 from escaping from the outside of the cylinder head 40.

  Further, the main heat insulating layer 161 may be coated with a different resin material depending on the portion of the main oil hole 152. For example, in the main heat insulating layer 161, the connecting portion 152a may be coated with PAI, and the supply portion 152b may be coated with PPS.

  The main-side heat insulating layer 161 may be composed of two or more heat insulating layers. For example, the main-side heat insulation layer 161 may be configured by PAI formed in the main oil hole 152 and PPS laminated on the PAI.

  Further, the main-side heat insulating layer 161 does not necessarily have to be formed in the entire area of the main oil hole 152.

  Moreover, although the main side heat insulation layer 161 shall be formed by coating a resin material, the formation means of the main side heat insulation layer 161 is not limited to this. For example, the main-side heat insulating layer 161 may be formed by inserting a pipe made of a resin material into the main oil hole 152.

  Moreover, although the main oil hole 152 shall be provided with the connection part 152a and the supply part 152b, the structure of the main oil hole 152 is not limited to this. For example, the main oil hole 152 may include only the supply unit 152b.

  In addition, the sub-side heat insulating layer 162 may be coated with a different resin material depending on the portion of the sub oil hole 153. For example, the sub-side heat insulating layer 162 may be coated with PAI on the top and with PPS on the bottom.

  Moreover, the sub-side heat insulation layer 162 may be composed of two or more heat insulation layers. For example, the sub-side heat insulating layer 162 may be configured by PAI formed in the sub-oil hole 153 and PPS laminated on the PAI.

  Further, the sub-side heat insulating layer 162 does not necessarily have to be formed in the entire region of the sub oil hole 153.

  Moreover, although the sub side heat insulation layer 162 shall be formed by coating a resin material, the formation means of the sub side heat insulation layer 162 is not limited to this. For example, the sub-side heat insulating layer 162 may be formed by inserting a pipe made of a resin material into the sub oil hole 153.

  Further, the lower heat insulating layer 163 may be coated with a different resin material depending on the portion of the oil receiving portion 130c. For example, in the lower heat insulating layer 163, the oil receiving part 130c may be coated with PAI, and the blocking part 130e may be coated with PPS.

  The lower heat insulating layer 163 may be composed of two or more heat insulating layers. For example, the lower heat insulating layer 163 may be configured by a PAI formed on the oil receiving portion 130c and the closing portion 130e and a PPS laminated on the PAI.

  Further, the lower-side heat insulating layer 163 does not necessarily have to be formed in the entire area of the oil receiving portion 130c and the closing portion 130e.

  Moreover, although the lower side heat insulation layer 163 shall be formed by coating a resin material, the formation means of the lower side heat insulation layer 163 is not limited to this. For example, the lower heat insulating layer 163 is formed by fixing a substantially box-shaped resin material having an upper opening to the oil receiving portion 130c and fixing a substantially box-shaped resin material having a lower opening to the closing portion 130e. It may be a thing.

  Further, the lower-side heat insulating layer 163 may be formed on the inner surface of the through hole 130 f of the lower case 130. According to this, the lower heat insulating layer 163 can suppress the heat of the oil transmitted through the through hole 130f from escaping to the outside, and thus can effectively promote the temperature rise of the oil.

  The chain-side heat insulating layer 164 may be coated with a different resin material depending on the part of the chain-side oil passage 154. For example, the chain-side heat insulating layer 164 may be coated with PAI on the top and with PPS on the bottom.

  The chain-side heat insulating layer 164 may be composed of two or more heat insulating layers. For example, the chain-side heat insulation layer 164 may be configured by a PAI formed in the chain-side oil passage 154 and a PPS laminated on the PAI.

  Further, the chain side heat insulating layer 164 does not necessarily have to be formed in the entire region of the chain side oil passage 154.

  Moreover, although the chain side heat insulation layer 164 shall be formed by coating a resin material, the formation means of the chain side heat insulation layer 164 is not limited to this. For example, the chain side heat insulating layer 164 may be formed by inserting a pipe made of a resin material into the chain side oil passage 154.

  The drop-side heat insulation layer 165 may be coated with a different resin material depending on the site of the oil drop oil passage 155. For example, the drop-side heat insulating layer 165 may be coated with PAI on the top and with PPS on the bottom.

  The drop-side heat insulating layer 165 may be composed of two or more heat insulating layers. For example, the drop-side heat insulating layer 165 may be configured by a PAI formed in the oil drop oil passage 155 and a PPS laminated on the PAI.

  Further, the drop-side heat insulation layer 165 does not necessarily have to be formed in the entire area of the oil drop oil passage 155.

  Moreover, although the drop side heat insulation layer 165 shall be formed by coating a resin material, the formation means of the drop side heat insulation layer 165 is not limited to this. For example, the drop-side heat insulation layer 165 may be formed by inserting a pipe made of a resin material into the oil drop oil passage 155.

10 Engine 20 Oil pan 31 Crank journal 100 Oil supply mechanism 130 Lower case 153 Sub oil hole 163 Lower heat insulation layer (heat insulation layer)

Claims (6)

A lower case that returns the oil lubricated to the crank journal of the crankshaft to the oil pan;
A heat insulating layer formed on the lower case;
Comprising
The lower case is
It comprises a blocking part that closes the oil pan from above,
The thermal insulation layer is
Comprising a closed portion side heat insulating layer formed on the surface of the closed portion;
Engine oil supply mechanism. The lower case is
Comprising an oil receiving portion for receiving the oil that lubricated the crank journal;
The thermal insulation layer is
Comprising a receiving part side heat insulating layer formed on the surface of the oil receiving part,
The engine oil supply mechanism according to claim 1. The receiving side heat insulating layer is
Formed over the entire surface of the oil receiver,
The engine oil supply mechanism according to claim 2. The receiving side heat insulating layer is
Formed by a heat insulating material coated on the surface of the oil receiving part,
An oil supply mechanism for an engine according to claim 2 or claim 3. The closed portion side heat insulating layer is
Formed over the entire surface of the closure,
The engine oil supply mechanism according to any one of claims 1 to 4. The closed portion side heat insulating layer is
It is formed by a heat insulating material coated on the surface of the blocking portion,
The engine oil supply mechanism according to any one of claims 1 to 5.

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