This application claims priority to Japanese Patent Application No. 2010-168011 filed on Jul. 27, 2010 the disclosure of which, including the specification, drawings and abstract, is incorporated herein by reference in its entirety.
1. Field of the Invention
The invention relates to a grinding operation control and, more particularly to a grinding method and grinding machine with which a change in the outside diameter of a grinding wheel during grinding is measured to control a grinding operation.
2. Discussion of Background
During grinding, the outside diameter of a grinding wheel changes due to wear of the grinding wheel caused by grinding or a repair of a grinding layer of the grinding wheel. Detecting the amount of change in the outside diameter to control a grinding operation based on the detected change amount is indispensable for improving grinding accuracy and grinding efficiency. Japanese Patent Application Publication No. 11-277428 (JP-A-11-277428) describes a technique of calculating the outside diameter of a grinding wheel by measuring a surface position of a grinding portion of the grinding wheel using a touch probe, as a method of measuring the outside diameter of a grinding wheel. In addition, Japanese Patent Application Publication No. 5-104407 (JP-A-5-104407) describes a technique of measuring wear of a grinding wheel by an ultrasonic measuring method.
According to the technique described in JP-A-11-277428, the outside diameter of the grinding wheel is calculated through a grinding wheel measuring process that includes grinding a transfer pin and measuring the surface position of the transfer pin using a touch probe held by an arm made of a low thermal expansion material. Therefore, a measuring process is required and, as a result, the rate of operation of a grinding machine decreases. In the technique described in JP-A-5-104407, the amount of wear of the grinding wheel is measured on the basis of a change in the distance between the surface of the grinding wheel and an ultrasonic sensor head. Therefore, a change in the distance between the installation position of the ultrasonic sensor head and the rotation center position of the grinding wheel is also incorporated in change in the amount of wear. As a result, an error may be caused. Particularly, it is difficult to suppress a change in the distance due to the thermal expansion of a component resulting from a temperature change. In principle, a change in the distance may be suppressed by using a low thermal expansion material to form a component or keeping an ambient temperature constant. However, an expensive material or a temperature controller is required.
The invention is made in light of the above-described circumstances, and it is an object of the invention to provide a grinding method and a grinding machine that make it possible to measure the outside diameter of a grinding wheel in a short period of time with a simple configuration even during grinding or truing, thereby improving the rate of operation of the grinding machine at low cost.
According to a feature of an example of the invention, in a grinding method for grinding a workpiece using a grinding wheel that has a grinding layer on an outer periphery of a core of the grinding wheel, a grinding operation and a truing operation are controlled on the basis of an outside diameter of the grinding wheel, which is obtained by calculating an outside diameter of the core and a thickness of the grinding layer; calculating a time difference in arrival at an ultrasonic sensor between a reflected wave from a surface of the grinding layer and a reflected wave from a surface of the outer periphery of the core; and calculating the outside diameter of the grinding wheel.
A reduction amount of the grinding wheel diameter is measured on the basis of a sonic velocity in the grinding layer and a difference between an arrival time difference between a reflected wave from a surface of the grinding layer before the grinding wheel diameter is reduced and a reflected wave from a surface of the outer periphery of the core and an arrival time difference between a reflected wave from a surface of the grinding layer after the grinding wheel diameter is reduced and a reflected wave from the surface of the outer periphery of the core, so it is possible to measure an accurate grinding wheel outside diameter that is not influenced by changes in distance between an ultrasonic head and a grinding wheel. In addition, the grinding wheel outside diameter may be measured in a state where grinding fluid adheres to the surface of the grinding wheel, so the outside diameter of the grinding wheel may be measured even during truing or immediately after truing. Therefore, a time required to measure the outside diameter of a grinding wheel is reduced to thereby make it possible to reduce a decrease in the rate of operation of the grinding machine.
According to another feature of an example of the invention, the predetermined reduction amount is calculated on condition that the component sonic velocity is the fastest among sonic velocities in components that constitute the grinding layer and the decrease in time difference is the smallest among the decreases in time differences measured at a plurality of points.
According to a further feature of an example of the invention, the predetermined reduction amount is calculated on condition that the component sonic velocity is the slowest among sonic velocities in components that constitute the grinding layer and the decrease in time difference is the largest among the decreases in time differences measured at a plurality of points.
A removed component that constitutes the grinding layer is determined, and the removal amount may be accurately calculated using the sonic velocity in the removed component, so it is possible to measure an accurate grinding wheel outside diameter.
According to another feature of the invention, by way of example, the outside diameter of the grinding wheel is measured while the workpiece is being ground, and the grinding operation is controlled using an amount of change in the outside diameter of the grinding wheel as an amount of wear of the grinding wheel due to grinding. The outside diameter of the grinding wheel is measured in a short period of time during grinding, and the measured outside diameter of the grinding wheel is used to change a grinding start position of the grinding wheel or to evaluate the amount of wear of the grinding wheel to thereby determine whether to carry out truing. Thus, it is possible to reduce an idle grinding time or carry out truing after a grinding wheel is used until its service life limit, so it is possible to improve efficiency and reduce grinding cost.
Further by way of example, according to another aspect of the invention, the outside diameter of the grinding wheel is measured while the grinding wheel is being trued, and the truing operation is controlled using an amount of change in the outside diameter of the grinding wheel as a removal amount of the grinding wheel due to truing. An amount of change in the outside diameter of the grinding wheel may be continuously measured during truing, so it is possible to accurately control truing operation that is based on an actual removal amount of the grinding wheel and that does not require unnecessary removal of grinding wheel, so it is possible to reduce grinding cost.
Features, advantages, and technical and industrial significance of exemplary embodiments of the invention will be described below with reference to the accompanying drawings, in which like numerals denote like elements, and wherein:
Hereinafter, a grinding process and a truing process that include a grinding wheel diameter measuring process performed using an ultrasonic measuring device according to an embodiment of the invention will be described on the basis of an example embodiment of an external cylindrical grinding machine with reference to
As shown in
The grinding machine 1 includes a controller 30. The controller 30 executes predetermined programs to carry out an automated grinding process, a truing process and a grinding wheel diameter measuring process. The functional configuration of the controller 30 includes X-axis control means 31, Z-axis control means 32, truing control means 33, ultrasonic measuring device control means 34, grinding wheel spindle control means 35, etc. The X-axis control means 31 controls the feed motion of the grinding wheel head 3. The Z-axis control means 32 controls the feed motion of the table 4. The truing control means 33 controls the truing device 10. The ultrasonic measuring device control means 34 controls the ultrasonic measuring device 12. The grinding wheel spindle control means 35 controls the rotation of the grinding wheel 7.
A method of measuring the outside diameter of the grinding wheel 7 in the grinding machine 1 will be described below with reference to
The principle of measuring the outside diameter of the grinding wheel 7 will be described below. As shown in
The thickness Wt of the grinding layer 72 is measured as follows. As shown in
As shown in
In order to solve the above problem, ultrasonic measurement is conducted as follows. Multiple ultrasonic measurement points at a grinding layer are set to predetermined positions, the initial grinding layer thickness Wt0 is measured at each point and the time difference ΔT0 in arrival at the ultrasonic sensor 14 between an ultrasonic wave reflected from the surface of the grinding layer 72 and an ultrasonic wave reflected from the outer peripheral surface of the core 71 is measured at each point, and then each initial grinding layer thickness Wt0 and each arrival time difference ΔT0 are stored in the controller. Specifically, the initial grinding layer thickness at the point 1 is Wt10, the arrival time difference at the point 1 is ΔT10, the initial grinding layer thickness at the point n is Wtn0 and the arrival time difference at the point n is ΔTn0.
As an example, a method of measuring a change in the thickness of the grinding layer at the predetermined point 1 will be described. A first change ΔWt11 in the thickness of the grinding layer 7 at the predetermined point 1 after the grinding layer is reduced is a half of the product of the difference ΔT10-ΔT11 between the initial value ΔT10 of the arrival time difference between two reflected waves at the predetermined point 1 and the arrival time difference ΔT11 at the time of measurement, and the sonic velocity V in the material removed from the surface layer at the predetermined point 1 at which actual measurement is performed. That is, ΔWt11=(ΔT10−ΔT11)×V/2, so the thickness Wt11 of the grinding layer 72 at the time of the first measurement at the predetermined point 1 may be expressed by Wt11=Wt10−ΔWt11=Wt10−(ΔT10−ΔT11)×V/2. Similarly, the thickness Wt12 of the grinding layer 72 at the time of the second measurement at the predetermined point 1 may be expressed by Wt12=Wt11−(ΔT11−ΔT12)×V/2. Hereinafter, it is possible to measure the current grinding layer thickness by sequentially subtracting the amount of change in the thickness from the immediately preceding grinding layer thickness.
The above description is tenable if the sonic velocity in a removed portion of the grinding layer 72 is constant; however, as is already described above, the grinding layer 72 is a composite material made of a plurality of materials with different sonic velocities. Therefore, as removal of the grinding layer 72 progresses, different materials are removed, so the sonic velocity at that point changes. For this reason, the above described continuity is interrupted, and the calculation in which the amount of change in the thickness is subtracted from the immediately preceding grinding layer thickness is untenable. Then, the amount of change in the thickness is subtracted from the above described grinding layer thickness at a plurality of points, and only the data at a point, at which only one type of material is removed and the sonic velocity in the removed material is identified, is used for subtraction to thereby ensure the continuity.
Specifically, description will be provided with reference to
When the sonic velocity in the abrasive grains 721 is V1, the sonic velocity in the binder 722 is V2 and the sonic velocity in the aggregate grains 723 is V3, V1>V2>V3. The surface layer is removed by ΔWt11 and the thickness of the grinding layer is reduced from Wt10 to Wt11, so the time difference in arrival at the ultrasonic sensor 14 between an ultrasonic wave reflected from the surface of the grinding layer 72 and an ultrasonic wave reflected from the outer peripheral surface of the core 71 reduces from ΔT10 to ΔT11 at each portion. A decrease in the time difference (ΔT10−ΔT11) is denoted by Δt, and the decreases in the time differences Δt corresponding to the first portion to the fourth portion are respectively denoted by Δt1 to Δt4. At is determined on the basis of the sonic velocity in the removed material and the removal amount ΔWt11. At the first portion, the aggregate grain 723 is removed, so Δt1=ΔWt11/V3. Similarly, at the third portion, the abrasive grain 721 is removed, so Δt3=ΔWt11/N1, and, at the fourth portion, the binder 722 is removed, so Δt4=ΔWt11/V2. At the second portion, both the aggregate grain 723 and the binder 722 are removed, so Δt2 is equal to the sum of decreases in time differences in correspondence with the amounts of removal of the respective materials.
Here, when the decreases in the time differences Δt are compared with one another, because the removal amount is the same among the portions, Δt is inversely proportional to the sonic velocity in the removed material, that is, Δt1=ΔWt11/V3>Δt4=ΔWt11/V2>Δt3=ΔWt11/V1, and the mean sonic velocity Va in the second portion is V2>Va>V3, so Δt1>Δt4>Δt2>Δt3. The portion at which Δt is minimum among the plurality of measured portions is the portion at which only the abrasive grain 721 is removed, and the portion at which Δt is maximum is the portion at which only the aggregate grain 723 is removed. Δt at the portion at which the plurality of materials is removed falls within a range between the maximum value and the minimum value. Therefore, the product of Δtmin that is the minimum value of Δt and V1 that is the maximum value among the sonic velocities in the materials or the product of Δtmax that is the maximum value of Δt and V3 that is the minimum value among the sonic velocities in the materials is the removal amount of the grinding layer. That is, decreases in time differences Δt at multiple portions are measured at the same point at which the amount of removal of the grinding layer is substantially constant, and the product of Δtmin and V1 that is the maximum value among the sonic velocities in the materials or the product of Δtmax and V3 that is the minimum value among the sonic velocities in the materials is obtained to thereby make it possible to calculate the accurate removal amount of the grinding layer.
Measurement at the same point may be performed by arranging the ultrasonic measuring head 14 at a position facing the grinding working surface of the grinding wheel 7, measuring the rotational phase of the grinding wheel 7 using the phase detector provided at the grinding wheel drive motor and then performing measurement at the same rotational phase. The size of the component of a general grinding layer is larger than or equal to 50 μn, and the removal amount of the grinding layer to be measured is smaller than or equal to 10 μm, so the same material is removed at quite a few points among a plurality of measurement points.
A concrete ultrasonic measuring method will be described with reference to the flowchart of
As described above, the removal amount of the grinding layer is calculated by selecting data at the point at which only a single material is removed and using a decrease in the difference in reflection time between ultrasonic waves due to removal and the sonic velocity in that material, so it is possible to accurately measure the thickness of the grinding layer and, as a result, it is possible to accurately measure the outside diameter of the grinding wheel 7. In addition, measurement may be performed in a short period of time, that is, a time period shorter than or equal to several milliseconds, and measurement may be performed irrespective of whether there is grinding fluid, so it is possible to perform measurement during a grinding process or a truing process.
The grinding process in which a workpiece W is subjected to plunge grinding using the grinding wheel 7 in the grinding machine 1 will be described with reference to the flowchart shown in
As described above, by measuring the outside diameter of the grinding wheel, the amount of wear of the grinding working surface of the grinding wheel due to grinding is measured in each grinding process to determine whether to use the grinding wheel. Therefore, in comparison with an existing grinding method in which a predetermined number of workpieces are ground and then truing is conducted, the grinding wheel may be effectively used and, in addition, a defective workpiece due to abnormal wear may be prevented.
Next, a truing process for the grinding wheel 7 using the above described grinding wheel diameter measurement with an ultrasonic wave will be described with reference to
A concrete truing method will be described with reference to the flowchart shown in
As described above, the outside diameter of the grinding wheel may be measured in a short period of time for each grinding wheel removal process during a truing process, so truing for removing a necessary minimum amount of the grinding wheel is possible, and unnecessary wear of the grinding wheel may be prevented.
Number | Date | Country | Kind |
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2010-168011 | Jul 2010 | JP | national |
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Number | Date | Country |
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5-104407 | Apr 1993 | JP |
11-277428 | Oct 1999 | JP |
Number | Date | Country | |
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20120028543 A1 | Feb 2012 | US |