The disclosure of Japanese Patent Application No. 2015-235285 filed on Dec. 2, 2015 including the specification, drawings and abstract, is incorporated herein by reference in its entirety.
1. Field of the Invention
The present invention relates to a cam grinding device and a cam grinding method. Specifically, the present invention relates to a grinding device for a composite cam in which two cams having different cam lift amounts and different phase angles are arranged adjacently in the axial direction and a cam grinding method thereof.
2. Description of the Related Art
Suction into and discharge from cylinders of an internal combustion engine are performed by valve-opening operation of valves. This valve-opening operation of valves is performed by operation of cams that rotate.
In the valve-opening operation of valves, from a viewpoint of improving output of the internal combustion engine, for example, valve-opening operation control is performed differently between at a low-speed rotation and at a high-speed rotation of the internal combustion engine.
In one of such control methods, a first cam for low speed and a second cam for high speed are provided as cams that actuate each valve, and valve-opening control is performed by appropriately selecting the first cam and the second cam in accordance with the rotational speed of the internal combustion engine. In this case, selective switching between the first cam and the second cam is performed by relative movement of a tappet of the valve between the first cam and the second cam in the axial direction while the tappet is in contact with the cams.
As depicted in
Cam grinding of the composite cam 110 including the first cam 112 for low speed and the second cam 114 for high speed is generally performed with a grinding wheel T (see
For example, the case depicted in
In the grinding of the composite cam 110 with the grinding wheel T performed by the cam grinding device described above, as depicted in
When the unground portion F exists at the boundary portion between the first cam 112 and the second cam 114 in the range of the common-base circular portion C, relative movement of the tappet between the first cam 112 and the second cam 114 requires the tappet to get over this unground portion F. This makes it difficult to perform this movement smoothly, thereby affecting the valve-opening control of the valve. Thus, the grinding wheel T needs to be trued frequently.
The following specifically describes the problem that the unground portion F is generated. In general, as depicted in
In view of this, herein, as depicted in
Subsequently, after the grinding of the first cam 112 is completed, as depicted in
An object of the present invention is to provide a cam grinding device that can remove an unground portion that is generated at a boundary portion in a common-base circular portion between a first cam and a second cam of a composite cam having different cam lift heights, by generating an imaginary intermediate cam containing profiles of the first cam and the second cam and grinding this intermediate cam.
A composite cam to be ground by a cam grinding device according to one aspect of the present invention includes: a first cam having a first base circular portion in which lift height from a shaft center to an outer peripheral surface is formed by a first radius that is constant and a first cam portion in which the lift height from the shaft center to the outer peripheral surface changes; and a second cam having a second base circular portion in which lift height from the shaft center to an outer peripheral surface is formed by the first radius that is constant and a second cam portion in which the lift height from the shaft center to the outer peripheral surface changes. The first cam and the second cam are arranged adjacently in an axial direction so as to be coaxial, and have shapes that respectively correspond to first cam lift data and second cam lift data that are different from each other. Furthermore, at least part of the outer peripheral surface of the first base circular portion and at least part of the outer peripheral surface of the second base circular portion form a common-base circular portion on an identical surface.
The cam grinding device includes: a bed serving as a base; a spindle device mounted on the bed and including a workpiece rotating device configured to support the composite cam rotatably about the shaft center; a grinding-wheel device mounted on the bed and including a grinding wheel configure to rotate; a traverse-moving device that is capable of reciprocating the grinding wheel relatively to the composite cam in the axial direction; a plunge-moving device that is capable of moving the grinding wheel relatively to the composite cam in a direction crossing the axial direction; and a control device configured to control the workpiece rotating device, the traverse-moving device, and the plunge-moving device.
Furthermore, the control device includes: a common-base circular-portion setting unit configured to determine an angular range of the common-base circular portion that is formed on the identical surface by the at least part of the outer peripheral surface of the first base circular portion and the at least part of the outer peripheral surface of the second base circular portion, based on the first cam lift data that contains a lift amount corresponding to a rotational angle in the first cam and the second cam lift data that contains a lift amount corresponding to a rotational angle in the second cam; an intermediate-cam lift-data generating unit configured to generate intermediate-cam lift data of an imaginary intermediate cam that contains a profile of the first cam and a profile of the second cam when viewed from the axial direction, based on the first cam lift data and the second cam lift data; a first cam grinding unit that controls the plunge-moving device and the traverse-moving device to move the grinding wheel to a position facing the outer peripheral surface of the first cam, and controls the workpiece rotating device and the plunge-moving device based on the first cam lift data to grind the first cam; a second cam grinding unit that, in a state in which the grinding wheel has retreated from the composite cam after the first cam has been ground, controls the traverse-moving device to move the grinding wheel to a position facing the outer peripheral surface of the second cam, and controls the workpiece rotating device and the plunge-moving device based on the second cam lift data to grind the second cam; and an intermediate-cam grinding unit that, in a state in which the grinding wheel has retreated from the composite cam after the second cam has been ground, controls the traverse-moving device to move the grinding wheel to a position corresponding to a boundary between the first cam and the second cam, and controls the workpiece rotating device and the plunge-moving device based on the intermediate-cam lift data to grind the imaginary intermediate cam lying on the boundary between the first cam and the second cam.
When the first cam and the second cam of the composite cam have been ground with the grinding wheel by the first cam grinding unit and the second cam grinding unit, an unground portion remains at the boundary portion in the common-base circular portion between both cams. The cam grinding device of the above aspect removes this unground portion as follows.
To begin with, the lift data of the imaginary intermediate cam containing the profile of the first cam and the profile of the second cam when viewed from the cam axial direction is generated based on the first lift data of the first cam and the second lift data of the second cam. Thus, this lift data of the imaginary intermediate cam contains the angular range of the common-base circular portion of the first cam and the second cam in which the unground portion problematically remains.
After the grinding of the first cam and the second cam has been completed, the imaginary intermediate cam lying on the boundary between the first cam and the second cam is ground based on the lift data of the intermediate cam, whereby the unground portion at the boundary portion is removed.
In the cam grinding device of the aspect, grinding of the first cam and grinding of the second cam respectively performed by the first cam grinding unit and the second cam grinding unit may each include rough grinding, fine grinding, and spark-out.
With the cam grinding device of the aspect, cam grinding time can be shortened, and the cams can be ground accurately.
With the cam grinding device of the aspect, the unground portion generated at the boundary portion in the common-base circular portion between the first cam and the second cam of the composite cam having different cam lift heights can be removed by generating the imaginary intermediate cam containing the profiles of the first cam and the second cam and grinding this intermediate cam.
Furthermore, even if the cam profile of the first cam in the lift-height direction and the cam profile of the second cam in the lift-height direction are offset from each other in the angular direction, and are in a positional relation in which these cams protrude from each other when viewed from the cam axial direction, the unground portion can be reliably ground by grinding the intermediate cam.
The foregoing and further features and advantages of the invention will become apparent from the following description of example embodiments with reference to the accompanying drawings, wherein like numerals are used to represent like elements and wherein:
An embodiment of the present invention will now be described with reference to the drawings. The following describes a composite cam 10 in the present embodiment.
As depicted in
As depicted in
As depicted in
Each valve 20 is vertically moved by oscillating motion of a tappet 22. Each tappet 22 is selectively brought into contact with the corresponding first cam 12 or the corresponding second cam 14, and is caused to oscillate by the cam 12 or 14. Specifically, a tappet roller 23 provided to each tappet 22 is brought into contact with the corresponding cam 12 or 14. The tappet 22 is selectively brought into contact with the cam 12 or 14 by engagement of a pin 26 of an actuator 24 such as an electromagnetic solenoid with a spiral-grooved element 28 that is arranged integrally with a side portion of each composite cam 10. On the outer peripheral surface of each spiral-grooved element 28, an axially spiral groove is formed. Each pin 26 engages with this spiral groove, and the camshaft 18 and the composite cams 10 rotate, whereby the two sets of composite cams 10 are moved in the axial direction. The spiral grooves of the spiral-grooved elements 28 arranged right and left are formed in the same direction. For example, with the spiral groove of one of the spiral-grooved elements 28, the corresponding pin 26 engages, and the composite cams 10 are moved rightward. Furthermore, with the spiral groove of the other of the spiral-grooved elements 28, the corresponding pin 26 engages, whereby the composite cams 10 are moved leftward. Consequently, positions of the cams coming into contact with the tappets 22 are switched. Herein, switching operation by the actuator 24 is performed when the tappet 22 comes into contact with the first cam 12 or the second cam 14 on the common-base circular portion C.
The following describes a cam grinding device 30 with reference to
The cam grinding device 30 of the present embodiment is a grinding device that rotates and supports the camshaft 18 as a workpiece W including the composite cams 10 to grind the cams with a cylindrical grinding wheel T. As depicted in
The data reading device 36 reads various types of data in accordance with operation of an operator using the input device 32 and the display device 34. In this case, cam lift data for identifying the shape of each composite cam 10 to be ground and the diameter of the grinding wheel T are read. In the present embodiment, cam lift data for two cams having different phases and different cam lift heights depicted in
To the input device 32, pieces of data specifically recited as follows are input by the operator seeing the display device 34. The pieces of input data are:
(a) width E1 of the first cam 12,
(b) width E2 of the second cam 14,
(c) width G and diameter H of the grinding wheel T,
(d) rotational speed m1 of the grinding wheel T, rotational speed n1 of a spindle 74, infeed amount J of the grinding wheel T during idle grinding,
(e) rotational speed m2 of the grinding wheel T, rotational speed n2 of the spindle 74, infeed amount K of the grinding wheel T during rough grinding,
(f) rotational speed m3 of the grinding wheel T, rotational speed n3 of the spindle 74, infeed amount M of the grinding wheel T during fine grinding,
(g) rotational speed m4 of the grinding wheel T, rotational speed n4 of the spindle 74, rotation amount of the spindle 74 during spark-out, and
(h) rotational speed m5 of the grinding wheel T, rotational speed n5 of the spindle 74, rotation amount of the spindle 74 during removal of an unground portion.
The pieces of data (d) to (g) are input for each of a first cam grinding step and a second cam grinding step described later, and the automatic programming device 38 automatically creates a program for the first cam grinding step and a program for the second cam grinding step.
The cam grinding device 30 includes a bed 54 as a base on which various devices are mounted. On this bed 54, a work table 65 that can be moved back and forth in the Z-axis direction by a work-table driving device 66 and a wheel head 70 that can be moved back and forth in the X-axis direction by a wheel-head driving device 68 are mounted. The work-table driving device 66 in the present embodiment corresponds to the traverse-moving device in the present invention, and the wheel-head driving device 68 corresponds to the plunge-moving device.
On the work table 65, a spindle device 56 including a spindle 74 configured to rotate about a spindle rotation axis that is parallel to the Z-axis and passes through the center of a center 72 and the tailstock 58 including a center 73 provided on the spindle rotation axis are mounted. The spindle 74 can be rotated by a spindle driving device 76. This spindle driving device 76 corresponds to the workpiece rotating device of the present invention. The camshaft 18 as the workpiece W including the composite cams 10 is supported between the center 72 and the center 73. In the spindle 74, a positioning pin 78 is formed so as to align the rotation phase of the camshaft 18 as the workpiece W with the rotation phase of the spindle 74. In the camshaft 18 as the workpiece W, a fitting portion (not depicted) into which the positioning pin 78 is fitted is formed. This allows the camshaft 18 to be positioned and supported so that the positioning pin 78 is fitted into the fitting portion.
On the wheel head 70, the grinding wheel T is mounted that is rotated by a grinding-wheel driving device 80 such as a motor. In the present embodiment, these components constitute the grinding-wheel device 50.
The numerical controller 40 controls various devices by outputting control signals to the various drive units 42, 44, 46, and 48 and drive-controlling the various driving devices 68, 76, 66, and 80. In the present embodiment, the numerical controller 40 controls the advancing/retreating position of the grinding wheel T that is the position of the wheel head 70 in the X-axis direction by outputting a control signal to the drive unit 42 and drive-controlling the wheel-head driving device 68. The numerical controller 40 also controls the spindle rotational angle of the spindle 74 by outputting a control signal to the drive unit 44 and drive-controlling the spindle driving device 76. The numerical controller 40 also controls the position of the work table 65 in Z-axis direction by outputting a control signal to the drive unit 46 and drive-controlling the work-table driving device 66. The numerical controller 40 also controls the rotational speed of the grinding wheel T by outputting a control signal to the drive unit 48 and drive-controlling the grinding-wheel driving device 80.
The drive unit 44 acquires the actual spindle rotational angle of the spindle 74 from a detection signal of an encoder 76E of the spindle driving device 76 to perform feedback control. The drive unit 42 acquires the actual position of the wheel head 70 in the X-axis direction from a detection signal of an encoder 68E of the wheel-head driving device 68 to perform feedback control. The drive unit 46 acquires the actual position of the work table 65 in the Z-axis direction from a detection signal of an encoder 66E of the work-table driving device 66 to perform feedback control.
Specifically, the movement amount of the work table 65 is detected by the encoder 66E and the drive unit 46. The movement amount of the wheel head 70 toward the work table 65 is detected by the encoder 68E and the drive unit 42. When the movement amount based on a control signal that is a command signal matches the actual movement amount detected by the encoder and the drive unit, a completion signal is transmitted to the numerical controller.
As depicted in
In the cam grinding device 30 described in the present embodiment, the spindle rotation axis (aligned with the workpiece rotation axis PW in the example of
The following describes details of control of the control device 64. The control device 64 includes components within a range surrounded by the imaginary line indicated in
As depicted in
The common-base circular-portion setting unit 82 is a functional unit that sets the common-base circular portion C of the first cam 12 and the second cam 14 on the basis of a program for a common-base circular-portion setting step in a control process flow described later.
The intermediate-cam lift-data generating unit 90 is a functional unit that generates and sets intermediate-cam lift data on the basis of a program for an intermediate-cam lift-data generating step in the control process flow described later.
The first cam grinding unit 84 is a functional unit that grinds the first cam 12 on the basis of a program for a first cam grinding step described later. The second cam grinding unit 86 is a functional unit that grinds the second cam 14 on the basis of a program for a second cam grinding step described later.
The intermediate-cam grinding unit 88 is a functional unit that grinds the imaginary intermediate cam set as described above on the basis of a program for an intermediate-cam grinding step described later.
The following describes, with reference to
In the present embodiment, as indicated in the control process flow in
Subsequently, in the common-base circular-portion setting step at step S11, the common-base circular portion C of the first cam 12 and the second cam 14 are determined. This determination is made based on the first cam lift data containing cam lift heights (lift amounts) set for the corresponding phases in the first cam 12 and the second cam lift data containing cam lift heights (lift amounts) set for the corresponding phases in the second cam 14 depicted in
Subsequently, in the intermediate-cam lift-data generating step at step S12, cam lift data of an imaginary intermediate cam 15 (see
Subsequently, in the first cam grinding step at step S13, the first cam 12 is ground.
At the positioning S31, in the traverse direction (right-and-left direction) depicted in
Referring back to
Subsequently, the second cam grinding step at step S15 is performed. At the second cam grinding step S15, the second cam 14 is ground.
The infeed amount J at the idle grinding in the first cam grinding step S13 and the second cam grinding step S15 is as follows. The infeed amount J at the idle grinding is an amount that is larger than the maximum lift amount of the first cam 12 or the second cam 14 and prevents the grinding wheel T from coming into contact with the first cam 12 and the second cam 14 even if the work table 65 is traversed when the wheel head 70 sits at a position before the idle grinding, that is, the maximum lift amount=the maximum value of lift data−the minimum value of lift data. Herein, the minimum value of lift data is the radius of the first base circular portion C1 and the second base circular portion C2.
At the idle grinding, the rough grinding, the fine grinding, the spark-out in the first cam grinding step S13 and the second cam grinding step S15, the wheel head 70 is moved forward and backward in accordance with the rotational angle of the spindle 74 on the basis of the first cam lift data or the second cam lift data. This forward and backward movement is performed in conjunction with operation of moving forward in the plunge direction by the infeed amount.
The cam grinding in the first cam grinding step S13 and the second cam grinding step S15 is performed through three steps of the rough grinding, the fine grinding, and the spark-out in this order. This enables the grinding time to be shortened. In other words, the cam grinding can be performed through the fine grinding alone, but it takes more time for the grinding. Herein, the spark-out is grinding that does not involve grinding infeed such as plunge grinding. The purpose of performing this spark-out is to improve grinding accuracy by grinding a workpiece W without grinding infeed by an amount of deflection and deformation that have been generated during machining in the workpiece W ground at the fine grinding, thereby removing the deflection and deformation.
After the plunge grinding of the first cam 12 and the second cam 14 with the grinding wheel T in the first cam grinding step S13 and the second cam grinding step S15, an unground portion F remains at a boundary portion between the first cam 12 and the second cam 14. The unground portion F is illustrated, filled with black. It should be noted that the unground portion F and grinding allowances of the first cam 12 and the second cam 14 that are indicated by imaginary lines are drawn in an exaggerated manner for the purpose of easy understanding.
Subsequently, after the second cam grinding step S15, at the intermediate-cam grinding step S16 depicted in
The grinding wheel T is positioned to a position corresponding to the imaginary set position of the intermediate cam 15 by the work-table driving device 66 controlled by the control device 64. The spindle driving device 76 and the wheel-head driving device 68 are controlled, whereby the wheel head 70 is moved forward in the plunge direction by the infeed amount J, and the wheel head 70 is moved forward and backward according to the rotational angle of the spindle 74 on the basis of the intermediate-cam lift data of the intermediate cam 15. The grinding of the intermediate cam 15 is performed as spark-out grinding. Together with this spark-out grinding, grinding to remove the unground portion F at the boundary portion is performed. The spark-out grinding is grinding to grind part of the first cam 12 and part of the second cam 14, which is performed continuously while the spindle 74 rotates several times, and thus is advantageous in that the unground portion F at the boundary portion between both cams can be reliably removed.
The wheel head 70 is moved forward and backward in accordance with the rotational angle of the spindle 74 on the basis of the intermediate-cam lift data, and simultaneously the wheel head 70 is moved backward in the plunge direction by the infeed amount J, and thus the spark-out grinding of the intermediate cam 15 is completed.
In the present embodiment, the unground portion F generated at the boundary portion between the first cam 12 and the second cam 14 at the first cam grinding step S13 and the second cam grinding step S15 is removed at the intermediate-cam grinding step S16. Thus, when the tappet 22 is relatively moved between the first cam 12 and the second cam 14, unlike the related art, the tappet 22 does not get over the unground portion F, and this movement can be performed smoothly. Consequently, the grinding wheel does not have to be replaced more frequently, and the grinding wheel does not have to be dressed sooner.
In the present embodiment, the cam profile of the first cam 12 in the lift-height direction and the cam profile of the second cam 14 in the lift-height direction are offset from each other in the angular direction, and are in a positional relation in which these cams protrude from each other when viewed from the cam axial direction. Even in this positional relation, according to the present embodiment, the unground portion F can be reliably ground by grinding the intermediate cam 15.
In the foregoing, a specific embodiment of the present invention has been described. However, the present invention may be applied to other various embodiments.
For example, the axial direction widths of the first cam and the second cam are the same in the embodiment above, but may be different. In this case, attention needs to be paid to the fact that the contact pressure applied by the grinding wheel T during plunge grinding is different therebetween.
In the examples described above, description has been made under the assumption that the first cam 12 is a cam for low speed and the second cam 14 is a cam for high speed, but these may be inverted.
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2015-235285 | Dec 2015 | JP | national |
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