This application is based on and incorporates herein by reference Japanese Patent Application No. 2021-118160 filed on Jul. 16, 2021.
The present disclosure relates to a supply pump.
In a previously proposed supply pump, fluid is pressurized and delivered by reciprocating a tappet and a plunger in response to revolution of a cam ring.
In order to limit seizure of a sliding portion between the tappet and the cam ring, a tappet sliding surface of the tappet may be provided with a recess that is not in contact with a cam ring sliding surface of the cam ring, so that a contact surface pressure of the tappet sliding surface is dispersed to achieve a uniform contact surface pressure.
This section provides a general summary of the disclosure, and is not a comprehensive disclosure of its full scope or all of its features.
According to the present disclosure, there is provided a supply pump that includes:
a camshaft that is configured to be rotated;
a cam that is eccentric to the camshaft and is configured to rotate integrally with the camshaft;
a cam ring that is configured to revolve around the camshaft without rotating while the cam ring slides along an outer periphery of the cam;
a tappet that is configured to reciprocate in a direction perpendicular to the camshaft in response to revolution of the cam ring such that the tappet slides along a cam ring sliding surface which is an outer peripheral surface of the cam ring that extends in a direction parallel with the camshaft; and
a plunger that is configured to reciprocate together with the tappet to pressurize and deliver fluid.
The tappet has a tappet recess formed at a tappet sliding surface which is opposed to the cam ring sliding surface.
The cam ring sliding surface may be shaped in a convex form while a contour line of the convex form is a closed curve that is other than a circle, and a height of an inside of the cam ring sliding surface is higher than a height of a periphery of the cam ring sliding surface.
Alternatively or additionally, the tappet may have a resiliently deformable portion that enables resilient deformation of the tappet such that a contact surface area between the tappet sliding surface and the cam ring sliding surface is increased when a load is applied to the tappet toward the cam ring.
Further alternatively or additionally, the cam ring may have a stress relaxation groove formed at a cam ring non-sliding surface which extends in the direction parallel with the camshaft and is perpendicular to the cam ring sliding surface.
Further alternatively or additionally, the cam ring may have a cooling recess that is formed in at least one of two opposite end portions of the cam ring sliding surface which are opposite to each other in a sliding direction of the cam ring sliding surface.
The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.
In a previously proposed supply pump, fluid is pressurized and delivered by reciprocating a tappet and a plunger in response to revolution of a cam ring.
In order to limit seizure of a sliding portion between the tappet and the cam ring, a tappet sliding surface of the tappet may be provided with a recess that is not in contact with a cam ring sliding surface of the cam ring, so that a contact surface pressure of the tappet sliding surface is dispersed to achieve a uniform contact surface pressure.
In general, the supply pump pumps fuel as the fluid to an internal combustion engine. In recent years, there has been an increasing need to increase an injection pressure of the fuel injected in the internal combustion engine in order to reduce fuel consumption and comply with exhaust regulations. In addition, robustness with respect to fuel properties is required in cold regions and emerging countries, and a further improvement in the seizure resistance is an issue in particular.
The present disclosure includes a supply pump of first to fourth aspects. Common to all of these four aspects, the supply pump includes a camshaft, a cam, a cam ring, a tappet and a plunger. The cam is eccentric to the camshaft and is configured to rotate integrally with the camshaft. The cam ring is configured to revolve around the camshaft without rotating while the cam ring slides along an outer periphery of the cam.
The tappet is configured to reciprocate in a direction perpendicular to the camshaft in response to revolution of the cam ring such that the tappet slides along a cam ring sliding surface which is an outer peripheral surface of the cam ring that extends in a direction parallel with the camshaft. The plunger is configured to reciprocate together with the tappet to pressurize and deliver fluid. The tappet has a tappet recess formed at a tappet sliding surface which is opposed to the cam ring sliding surface, and the tappet recess is out of contact with the cam ring sliding surface.
In the supply pump of the first aspect, the cam ring sliding surface is shaped in a convex form while a contour line of the convex form is a closed curve that is other than a circle, and a height of an inside of the cam ring sliding surface is higher than a height of a periphery of the cam ring sliding surface. Here, it should be noted that the contour line is also referred to as an isoline and is a line of constant height, i.e., a line joining points of equal height (or elevation) of the convex form.
Preferably, an ellipsoidal surface portion is formed at the cam ring sliding surface such that an axial direction of a major axis of the ellipsoidal surface portion is set to coincide with one of a sliding direction of the cam ring sliding surface and a direction perpendicular to the sliding direction, and an axial direction of a minor axis of the ellipsoidal surface portion is set to coincide with another one of the sliding direction and the direction perpendicular to the sliding direction.
When a working pressure of the supply pump is increased, an urging force of the tappet against the cam ring sliding surface is increased to cause an increase in a contact surface pressure between the tappet and the cam ring sliding surface. Thus, a risk of the seizure between the tappet and the cam ring sliding surface increases. Therefore, in the first aspect of the present disclosure, the contour line of the convex form of the cam ring sliding surface is set to be the closed curve, such as an ellipse, which is other than the circle, and thereby the concentration of the contact surface pressure at a center portion of the cam ring sliding surface is avoided, and the contact surface pressure is spread over the wide range. In this way, the maximum contact surface pressure can be reduced, and the seizure resistance can be improved.
Furthermore, it is preferable that an apex of the ellipsoidal surface portion is eccentrically displaced from the center of the cam ring sliding surface. In the structure where the plunger axis, which is the sliding center of the tappet, is eccentrically displaced from the center of the camshaft, by eccentrically displacing the apex of the ellipsoidal surface portion from the center of the cam ring sliding surface, it is effective in terms of both the oil film formability and the contact surface pressure dispersion.
In the supply pump of the second aspect, the tappet has a resiliently deformable portion that enables resilient deformation of the tappet such that a contact surface area between the tappet sliding surface and the cam ring sliding surface is increased when a load is applied to the tappet toward the cam ring. For example, the tappet has an annular groove which serves as the resiliently deformable portion and is formed at a tappet upper surface, which is a surface of the tappet opposite to the tappet sliding surface.
By providing the resiliently deformable portion at the tappet, it is possible to obtain the advantage of dispersing the contact surface pressure at the time of applying the load to the tappet. In the case where a depth of the tappet recess is set small, it is difficult to obtain the processing accuracy. According to the second aspect of the present disclosure, even when the depth of the tappet recess is set large, the deformation of the tappet can be absorbed. Thus, the processability is improved.
In the supply pump of the third aspect, the cam ring has a stress relaxation groove formed at a cam ring non-sliding surface of the cam ring. The cam ring non-sliding surface extends in the direction parallel with the camshaft and is perpendicular to the cam ring sliding surface. The stress relaxation groove extends in a direction that crosses an axial direction of the plunger, and the stress relaxation groove is configured to relax transmission of a stress applied in the axial direction of the plunger.
When the direction of the reciprocating motion of the tappet is reversed, the contact surface pressure of an edge portion of the cam ring sliding surface is increased, and thereby the edge portion tends to be deformed and bulged. In view of the above point, according to the third aspect of the present disclosure, the stress relaxation groove is formed at the cam ring non-sliding surface. Therefore, it is possible to disperse the stress, which is generated by the contact surface pressure, by allowing the deformation of the edge portion upon application of the load to the edge portion. Furthermore, in a case of a cam ring that is used in a two-cylinder pump and has a relatively small lift amount, at the time of press-fitting a bush into the cam ring, there is a concern that the non-sliding surface is bulged, and the sliding surface is recessed. Therefore, particularly, there is a concern that the contact surface pressure is increased at the time when the tappet passes over the edge portion. Thus, the effect of the third aspect of the present disclosure is advantageous.
In the supply pump of the fourth aspect, the cam ring has a cooling recess that is formed in at least one of two opposite end portions of the cam ring sliding surface which are opposite to each other in the sliding direction of the cam ring sliding surface. The cooling recess is configured to receive the fluid and cool the cam ring sliding surface.
As one of seizure mechanisms between the cam ring and the tappet, there is a mode in which heat is trapped and stored in the cam ring sliding surface, so that the temperature rises to near the melting point of the base material, and the seizure occurs. With respect to this, in the existing technique, by eccentrically displacing the sliding center (the plunger axis) of the tappet and the center of the cam shaft relative to each other, the tappet is overlapped from the cam ring sliding surface, and thereby the fluid having the low temperature is supplied to the inside of the sliding surface. According to the fourth aspect of the present disclosure, the fluid supply to the inside of the sliding surface can be promoted, and thereby the temperature increase can be limited. Thus, the seizure resistance is improved.
Preferably, the cooling recess is formed on one side of the center of the cam ring sliding surface centered in the sliding direction while the one side is a side, toward which the tappet slides during the time of moving the plunger toward the camshaft, i.e., during a non-delivery time. In contrast, the cooling recess is not formed on the other side of the center of the cam ring sliding surface centered in the sliding direction while the other side is a side, toward which the tappet slides during the time of moving the plunger away from the camshaft, i.e., during a delivery time. Therefore, it is possible to limit the deterioration in the oil film formability in the range where the high load is applied during the delivery time.
Hereinafter, a plurality of embodiments of a supply pump according to the present disclosure will be described with reference to the drawings. In the embodiments, substantially the same structures are indicated by the same reference signs, and redundant description thereof will be omitted. The following embodiments are classified into four groups A to D, which have different solutions to a common objective of “improving the seizure resistance”. Each group contains one to three embodiments. The embodiment(s) of each group may be collectively referred to as “the present embodiment”.
First of all, with reference to
A housing of a supply pump 100 includes a housing main body 11 and a pair of cylinder heads 12. A cam chamber 13, to which the fuel is supplied from a feed pump, is formed in the housing main body 11. Two opposite ends of the cam chamber 13 are respectively closed by the cylinder heads 12. A cam 17 and the cam ring 50 are received in the cam chamber 13.
A camshaft 14 is rotatably supported by the housing main body 11 through a journal 15 and is rotated by the diesel engine (not shown). An oil seal 16 seals between the camshaft 14 and the housing main body 11. The cam 17, which has a circular cross-section, is located at an axial intermediate portion of the camshaft 14 such that the cam 17 is eccentric to the camshaft 14 and is rotated integrally with the camshaft 14. In
The cam ring 50, which revolves around the camshaft 14, is fitted to an outer periphery of the cam 17. The cam ring 50 includes a cam ring main body 51 and a bush 52. The cam ring main body 51 is made of iron-based metal. The bush 52 is shaped in a cylindrical tubular form and is made of metal (e.g., copper, aluminum, iron-based metal) or resin. An outside contour of the cam ring main body 51 is shaped in a quadrangular prism form, and a circular through-hole extends through the cam ring main body 51. The bush 52 is press-fitted into the through-hole of the cam ring main body 51 and is slidable along the outer periphery of the cam 17. Each of upper and lower outer surfaces of the cam ring 50 shown in
A set of a plunger 30 and a tappet 40 made of iron-based metal is provided at each of the upper side and the lower side of the cam ring 50 in
The tappet 40 is urged against the cam ring 50 by a corresponding spring 21 installed in the cam chamber 13, so that rotation of the cam ring 50 is limited. When the cam 17 is rotated, the cam ring 50 revolves around the camshaft 14 without rotating while the cam ring 50 slides along the outer periphery of the cam 17. When the tappet sliding surface 43 of the tappet 40 is slid along the cam ring sliding surface 53, the tappet 40 and the plunger 30 are reciprocated in a direction perpendicular to the camshaft 14 in response to the revolution of the cam ring 50.
The plunger 30 and the tappet 40 are coaxially arranged. An axis of the plunger 30 and the tappet 40 will be referred to as a plunger axis Zp. Furthermore, in a cross-section shown in
At the inside of each cylinder head 12, a fuel pressurizing chamber 22, to which the fuel is supplied from the feed pump 25, is formed on a side of the plunger 30 which is opposite to the tappet 40. Furthermore, an inlet check valve 23 and an outlet check valve 24 are installed at the inside of each cylinder head 12. The inlet check valve 23 enables only a flow of the fuel from the feed pump 25 toward the fuel pressurizing chamber 22. The outlet check valve 24 enables only a flow of the fuel from the fuel pressurizing chamber 22 toward the common rail (not shown).
One end of the camshaft 14 is coupled to the feed pump 25 that is of an inner gear type. The feed pump 25 is rotatably received at an inside of a pump cover 26. When the camshaft 14 is rotated, the feed pump 25 pressurizes the fuel suctioned from the fuel tank and discharge the pressurized fuel. The fuel, which is discharged from the feed pump 25, is supplied to the fuel pressurizing chamber 22 through a fuel passage (not shown) and the inlet check valve 23. A metering valve, which is installed in the middle of the fuel passage, adjusts the amount of the fuel supplied to the fuel pressurizing chamber 22 based on an operational state of the engine.
A communication passage 261, which is formed at the pump cover 26, guides the fuel, which is discharged from the feed pump 25, to one end surface of the camshaft 14. An axial lubricant oil passage 141 and a radial lubricant oil passage 142 are formed in the camshaft 14. The axial lubricant oil passage 141 opens at the one end surface of the camshaft 14 and is communicated with the communication passage 261. The radial lubricant oil passage 142 communicates between the axial lubricant oil passage 141 and an outer peripheral surface of the cam 17. A portion of the fuel, which is discharged from the feed pump 25, is supplied to the cam chamber 13 through these paths.
Next, the operation of the supply pump 100 will be described. When the camshaft 14 is rotated, the feed pump 25 suctions the fuel from the fuel tank and pressurizes and discharges the suctioned fuel. Furthermore, the cam 17 is rotated in response to the rotation of the camshaft 14, and the cam ring 50 revolves without rotating in response to the rotation of the cam 17. Each tappet 40 and the corresponding plunger 30 are reciprocated in response to the revolution of the cam ring 50.
When the plunger 30, which is placed at a top dead center, is moved toward a bottom dead center, the fuel, which is discharged from the feed pump 25, flows into the fuel pressurizing chamber 22 through the inlet check valve 23. When the plunger 30, which has reached the bottom dead center, is moved toward the top dead center once again, the inlet check valve 23 is closed. Thereby, the fuel pressure in the fuel pressurizing chamber 22 is increased. When the fuel pressure in the fuel pressurizing chamber 22 is increased, the outlet check valve 24 is opened. Thereby, the high pressure fuel is supplied to the common rail. As described above, the plunger 30 is reciprocated together with the tappet 40 to pressurize and deliver the fuel.
In contrast, a portion of the fuel, which is discharged from the feed pump 25, is guided to a gap between the cam 17 and the bush 52 of the cam ring 50 through the communication passage 261, the axial lubricant oil passage 141 and the radial lubricant oil passage 142 and then flows into the cam chamber 13. In this way, a sliding portion between the cam 17 and the bush 52 is lubricated, and the cam ring sliding surface 53 and the tappet sliding surface 43 are lubricated.
Next, detailed structures and actions of the cam ring 50 and the tappet 40 in the supply pump 100 of the embodiment(s) of each group will be sequentially described. In the drawings of the following embodiments, only the tappet 40 and the plunger 30 shown on the upper side of
Hereinafter, an external view of the cam ring 50 viewed from the viewing direction of
In the front view shown in each of
The supply pump of the group A will be described with reference to
The cam ring 501 of the first embodiment will be described with reference to
The cam ring sliding surface 53 has an ellipsoidal surface portion 531. A height of an inside of the ellipsoidal surface portion 531 is higher than a height of a periphery of the ellipsoidal surface portion 531. In the ellipsoidal surface portion 531 of the first embodiment, an axial direction of the major axis of the ellipsoidal surface portion 531 is set to coincide with the direction (the Y direction) perpendicular to the sliding direction of the cam ring sliding surface 53, and an axial direction of the minor axis of the ellipsoidal surface portion 531 is set to coincide with the sliding direction (the X direction). Furthermore, an apex of the ellipsoidal surface portion 531 is indicated by Pv.
With reference to
The front view of the cam ring 501, which is shown on the right side of
The side view of the cam ring 501, which is shown on the left side of
In summary, the projection height Hx of the cam ring sliding surface 53 along the plane extending in the sliding direction (the X direction) is higher than the projection height Hy of the cam ring sliding surface 53 along the plane extending in the direction (the Y direction) perpendicular to the sliding direction. Furthermore, a radius of curvature Rx of the ellipsoidal surface of the cam ring sliding surface 53 along the plane in the sliding direction (the X direction) is smaller than a radius of curvature Ry of the ellipsoidal surface of the cam ring sliding surface 53 along the plane in the direction (the Y direction) perpendicular to the sliding direction.
When a working pressure of the supply pump 100 is increased, an urging force of the tappet 40 against the cam ring sliding surface 53 is increased to cause an increase in the contact surface pressure. Therefore, a risk of the seizure between the tappet 40 and the cam ring sliding surface 53 increases. Thus, in the embodiment of the group A, each of the contour lines of the convex form of the cam ring sliding surface 53 is set to be the closed curve, such as the ellipse, which is other than the circle, and thereby the concentration of the contact surface pressure at a center portion of the cam ring sliding surface 53 is avoided, and the contact surface pressure is dispersed over the wide range. In this way, the maximum contact surface pressure can be reduced, and the seizure resistance can be improved.
Specifically, the convex form of the cam ring sliding surface 53 is formed by the ellipsoidal surface portion 531. Particularly, in the ellipsoidal surface portion 531 of the first embodiment, the axial direction of the major axis of the ellipsoidal surface portion 531 is set to coincide with the direction (the Y direction) perpendicular to the sliding direction of the cam ring sliding surface 53. Therefore, the ellipsoidal surface portion 531 can be more easily processed in comparison to a case where the axial direction of the major axis of the ellipsoidal surface portion 531 is set to coincide with the sliding direction (the X direction) of the cam ring sliding surface 53.
The cam ring 502 of the second embodiment will be described with reference to
The cam ring 503 of the third embodiment will be described with reference to
The convex form of the cam ring sliding surface 53 is not limited to the ellipsoidal surface form, in which the axial direction of the major axis is set to coincide with the one of the sliding direction (the X direction) and the direction (the Y direction) perpendicular to the sliding direction, and the axial direction of the minor axis is set to coincide with the other one of the sliding direction (the X direction) and the direction (the Y direction) perpendicular to the sliding direction. For example, the convex form of the cam ring sliding surface 53 may be an ellipsoidal surface form, in which an axial direction of the major axis is set to coincide with an axial direction of an axis that is oblique to the X direction. Furthermore, the convex form of the cam ring sliding surface 53 may be any suitable form where each of the contour lines is a closed curve that is other than the circle, and the range, in which the contact surface pressure is equal to or larger than the predetermined value, is larger than that of the comparative example of
The supply pump of the group B will be described with reference to
As discussed above, the tappet 404 has the tappet recess 41 that is formed at the tappet sliding surface 43 and is out of contact with the cam ring sliding surface 53. Here, the expression of “is out of contact with the cam ring sliding surface 53” refers to a positional relationship in the initial state where the load is not applied to the tappet 404. Furthermore, it is assumed that the cam ring 50, which is used together with the tappet 404, has the cam ring sliding surface 53, a center portion of which is shaped in the convex form, such as the ellipsoidal surface or the spherical surface, like in the embodiments of the group A or the comparative example of the group A.
The annular groove 46 is located on an inner side of “a closed curve Tc, which is formed by connecting a plurality of contact points between a peripheral edge of the tappet recess 41 and the cam ring sliding surface 53 in a state where the tappet 404 is resiliently deformed.” In a case where each of the tappet recess 41 and the convex form of the cam ring sliding surface 53 is a spherical surface, ideally the closed curve Tc becomes a circle. For example, one or both of the tappet recess 41 and the convex form of the cam ring sliding surface 53 are the ellipsoidal surface, the closed curve Tc may possibly become an ellipse or another type of closed curve.
In
A contact surface pressure distribution of the embodiment and a contact surface pressure distribution of the comparative example will be compared with reference to
By providing the annular groove 46 at the tappet 404, it is possible to obtain the advantage of dispersing the contact surface pressure at the time of applying the load to the tappet 404. In the case where the depth of the tappet recess 41 is set small (e.g., about 1 μm), it is difficult to obtain the processing accuracy. According to the embodiment of the group B, even when the depth of the tappet recess 41 is set large, the deformation of the tappet 404 can be absorbed. Thus, the processability is improved.
Furthermore, the annular groove 46 is located on the inner side of “the closed curve Tc, which is formed by connecting the plurality of contact points between the peripheral edge of the tappet recess 41 and the cam ring sliding surface 53 in the state where the tappet 404 is resiliently deformed.” Therefore, when the load is applied to the tappet 404 toward the cam ring 50, the resilient deformation of the tappet 404 occurs such that the tappet sliding surface 43 and the cam ring sliding surface 53 contact with each other at the location on the inner side of the closed curve Tc. Therefore, the effect of the resilient deformation can be reliably obtained.
The resiliently deformable portion is not limited to the annular groove 46. Specifically, the resiliently deformable portion needs to be only a portion that enables resilient deformation of the tappet 404 in a manner that increases the contact surface area between the tappet sliding surface 43 and the cam ring sliding surface 53. Furthermore, the resiliently deformable portion is not limited to the annular groove that continuously extends in the circumferential direction. For example, the resiliently deformable portion may be a plurality of recesses that are discontinuous in the circumferential direction.
The supply pump of the group C will be described with reference to
Each of the stress relaxation grooves 555, 556 extends in a direction that intersects the axial direction of the plunger axis Zp and relax the transmission of the stress applied in the axial direction of the plunger axis Zp. In the description of the group C, the cam ring sliding surface 53 is shortened as “sliding surface 53,” and the cam ring non-sliding surface 54 is shortened as “non-sliding surface 54.”
The cam ring 505 has four stress relaxation grooves 555 that are provided at four locations that include an upper end portion and a lower end portion of each of the left non-sliding surface 54 and the right non-sliding surface 54 of the cam ring 505. Each of the stress relaxation grooves 555 extends in the direction parallel with the camshaft 14, i.e., extends in the direction perpendicular to the axial direction of the plunger axis Zp. In the first embodiment, each of the stress relaxation grooves 555 is uniformly formed along an entire extent of the stress relaxation groove 555 in the direction (the Y direction) perpendicular to the sliding direction, so that the stress relaxation groove 555 can be easily processed.
A disadvantage of the cam ring 509 of the comparative example, which does not have the stress relaxation grooves, will be described with reference to
Furthermore, a margin in the height direction (Z direction) from the outer periphery of the bush 52 to the cam ring sliding surface 53 is defined as a margin Mz, and a margin in the sliding direction (the X direction) from the outer periphery of the bush 52 to the cam ring non-sliding surface 54 is defined as a margin Mx. When the margin Mz in the height direction is larger than the margin Mx in the sliding direction, the non-sliding surfaces 54 tend to be largely deformed. For example, in a case of a cam ring that is used in a two-cylinder pump and has a relatively small lift amount, at the time of press-fitting the bush 52 into the cam ring, there is a concern that the non-sliding surfaces 54 are bulged, and the sliding surfaces 53 are recessed. Therefore, particularly, there is a concern that the contact surface pressure is increased at the time when the tappet 40 passes over the edge portions.
In view of the above point, in the embodiment of the group C, the stress relaxation grooves 555 are formed at the cam ring non-sliding surfaces 54. Therefore, it is possible to disperse the stress, which is generated by the contact surface pressure, by allowing the deformation of the edge portion upon application of the load to the edge portion. This is particularly effective for the cam ring that has the relatively small lift amount in the two-cylinder pump.
The extending direction of each stress relaxation groove is not limited to the direction perpendicular to the axial direction of the plunger axis Zp. Specifically, the extending direction of each stress relaxation groove may be an intersecting direction that intersects the axial direction of the plunger axis Zp, and this intersecting direction may include a direction that is tilted relative to the axial direction of the plunger axis Zp. It has the advantage of dispersing the contact surface pressure of the tappet 40 except a case where the grooves are formed parallel to the axial direction of the plunger axis Zp.
In the front view of the cam ring, the stress relaxation grooves do not have to be symmetrical with respect to the X direction center line Xr and the Z direction center line Zr of the cam ring. For example, the stress relaxation grooves may be arranged such that the stress relaxation grooves are offset downward at the non-sliding surface 54 on the left side, and the stress relaxation grooves are offset upward at the non-sliding surface 54 on the right side. Even in this configuration, the stress relaxation grooves are respectively formed at the positions that corresponds to the edge portions at the four locations.
The supply pump of the group D will be described with reference to
The cam ring 507 has the cooling recess 577 at the left end portion of the cam ring sliding surface 53 in the sliding direction in
In
In
As one of the seizure mechanisms between the cam ring 507 and the tappet 40, there is a mode in which heat is trapped and stored in the cam ring sliding surface 53, so that the temperature rises to near the melting point of the base material, and the seizure occurs. With respect to this, in the existing technique, by eccentrically displacing the sliding center (the plunger axis Zp) of the tappet 40 and the center Ca of the camshaft 14 relative to each other, the tappet 40 is overlapped from the cam ring sliding surface 53, and thereby the fuel having the low temperature is supplied to the inside of the sliding surface. According to the embodiment of the group D, the fuel supply to the inside of the sliding surface can be promoted, and thereby the temperature increase can be limited. Thus, the seizure resistance is improved.
However, when the size of the cooling recess 577 becomes larger than necessary, the contact surface area between the tappet 40 and the cam ring sliding surface 53 is decreased, and this is disadvantageous in terms of the contact surface pressure reduction and the oil film formability. Therefore, by locally providing the cooling recess 577, the contact surface area between the tappet 40 and the cam ring sliding surface 53 can be maintained to a maximum level. Furthermore, by forming the cooling recess 577 only on the side, toward which the tappet 40 slides during the non-delivery time, it is possible to limit the deterioration in the oil film formability in the range, in which the high load is applied during the delivery time.
From the viewpoint of the cooling performance of the cam ring sliding surface 53, the cooling recess may be formed in both of the two opposite end portions of the cam ring sliding surface 53 which are opposite to each other in the sliding direction. It is preferable that the optimum size and the optimum location of the cooling recesses are determined from the viewpoint of securing the area where the cam ring sliding surface 53 receives the load of the tappet 40 and the viewpoint of cooling performance.
The fluid, which is delivered by the plunger of the supply pump, is not limited to the fuel or the lubricating oil mixed fuel and may be a lubricating oil containing no fuel.
The embodiments of the groups A to D are not limited to those implemented independently, and embodiments of two or more groups may be combined and implemented.
As described above, the present disclosure is not limited to the above embodiments and can be implemented in various forms without departing from the scope of the present disclosure.
Number | Date | Country | Kind |
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2021-118160 | Jul 2021 | JP | national |