JPH10175165A - Centerless grinding method using metal bond grinding wheel, and its device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a centerless grinding method and its device which can carry out a field grinding effectively by carrying out the form correction of a high strength metal bond super abrasive grain grinding wheel at a high accuracy and efficiently. SOLUTION: This standard centerless grinding device is provided with an electrode 1 provided opposing to a grinding wheel 12; a cutting giving means to advance the electrode 1 a specific amount to the grinding wheel 12; an electrode 12 provided opposing to the grinding wheel 12; a power source 16 to apply a voltage between the grinding wheel 12 and the electrode 1 or the electrode 11; and a grinding liquid feeding means 17 to feed a conductive grinding liquid between the grinding wheel 12 and the electrode 11 for dressing. A discharge is generated between the electrode 1 for truing and the grinding wheel 12, so as to correct the form of the grinding operation surface of the metal bond grinding wheel 12. A work is grinding processed while dressing the grinding wheel 12 by the electrolytic operation.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a centerless grinding method using a high-hardness metal bond grindstone and an apparatus therefor.

[0002]

2. Description of the Related Art It has been known that high-strength metal-bonded superabrasive grindstones such as cast iron fiber-bonded diamond grindstones are suitable for ultraprecision machining of hard-hard materials such as ceramics. Electrolytic in-process dressing (hereinafter referred to as “ELID”) grinding has been developed as a highly efficient grinding method using this high-strength metal-bonded superabrasive grindstone, and has recently attracted attention. The high-strength metal-bonded superabrasive grindstone has high strength and is suitable for ultra-precision processing of the hard-hard material, but because of its high strength, its dressing (sharpening) is not easy and is conventionally used. In the case of mechanical dressing using a rotary diamond or the like, the dressing operation not only takes a long time, but also the rotary diamond itself is severely worn, making the operation extremely difficult. Then, the ELID grinding method was developed.
In brief, the grinding method involves dressing a grindstone by electrolytic action (in-process) while performing a grinding process.

FIG. 5 shows an apparatus as one specific example for carrying out this ELID grinding method. As shown in FIG. 1, the ELID grinding apparatus includes a metal bond grindstone 12 supported by a support rotating means (not shown) and rotating in a certain direction.
A blade 15 rotatably supporting the workpiece W,
An adjusting wheel 14 that rotates in the same direction as the metal bond grindstone 12 and presses the workpiece W against the metal bond grindstone 12.
An ELID grinding method is applied to a centerless grinding device provided with: a dressing electrode 1 provided opposite to a grinding action surface of a metal bond grinding wheel 12 as an ELID device.
1 and a power source 16 having an anode connected to the rotating shaft 13 of the metal bond grindstone 12 and a cathode connected to the dressing electrode 11.
And a grinding fluid supply means 17 for supplying a conductive grinding fluid between the metal bond grindstone 12 and the dressing electrode 11.

The metal bond grindstone (hereinafter simply referred to as “grindstone”) 12 holds superabrasive grains such as diamond and CBN with a conductive binder (metal bond) such as cast iron. When a predetermined voltage is applied between the rotating shaft 13 of the grindstone 12 and the dressing electrode 21, the surface of the metal bond grindstone becomes an anode due to the conductivity of the metal bond, and the dressing electrode 11 becomes a cathode.
When a conductive grinding liquid (preferably a weakly conductive grinding liquid) is supplied thereto from the grinding liquid supply means 17, for example, when the metal bond is cast iron, as shown in FIG. Iron ions (Fe ²⁺ ) are eluted from the metal bond portion 18 on the surface of the grindstone 12 by electrolysis, and the abrasive grains 19 are exposed on the surface of the grindstone 12 to perform dressing. Then, a certain percentage of the iron ions (Fe ²⁺ ) change to iron hydroxide, and finally change to hard iron oxide, and
The iron oxide film 20 adheres to the surface and is as shown in FIG.
Is formed on the surface of the grindstone 12. Since the iron oxide is electrically insulating, when the iron oxide film 20 is sufficiently formed,
Elution of iron ions (Fe ²⁺ ) due to electrolysis is suppressed. Next, when grinding is performed subsequently in this state, as shown in FIG.
The iron oxide film 20 starts to be released from the surface of the grindstone 12 due to friction with the workpiece W, and as this proceeds, the iron oxide film 20 covering the surface of the grindstone 12 becomes insufficient as shown in FIG. The conductivity is restored again, and the above-described series of processes from FIG. 6A to FIG. 6D are repeated.

[0005] As described above, the ELID grinding method can perform the grinding process while performing dressing as needed. The grinding process can be performed with extremely high efficiency, and the dressing is performed electrochemically. Compared to a conventional mechanical dressing using a rotary diamond or the like, the resistance is smaller and the whole device can be made compact.

[0006]

As described above, the EL
The ID grinding method is an epoch-making grinding method, but also in this ELID grinding method, there is a problem to be solved (truing) of a grinding wheel as another problem to be solved.

[0007] As shown in FIG. 7 (a), the grindstone 12 that has just been manufactured is usually covered with a metal bond 18 and the abrasive grains 19 are not exposed on the surface. Therefore, the grinding process cannot be performed unless the metal bond 18 on the surface of the grinding stone 12 is dropped to expose the abrasive grains 19 to the surface. However, conventionally, a rotary diamond similar to that in the above-described dressing is used for this operation. It was.

However, unlike other binders, for example, vitrified or resin, the metal bond is hard and sticky, and it takes an enormous amount of time to remove the metal bond and expose the abrasive grains 19 to the surface of the grinding stone 12. The rotary diamond was severely worn and severe mechanical vibration was caused by poor sharpness due to clogging, which was not suitable for practical use. Further, even if the grinding wheel 12 is trued over a long period of time using a rotary diamond, as a result, as shown in FIG. It becomes exposed and has a disadvantage that its sharpness is poor from the beginning.

Further, as the grinding process proceeds, the grinding wheel 1
It is well known that the shape of No. 2 becomes abnormal, but if processing is performed as it is, the processing accuracy will be deteriorated due to the abnormal shape, so it is necessary to correct this abnormal shape.
In this case, the same problem as described above occurs.

In particular, in centerless grinding, since a relatively wide grindstone is used, it is necessary to improve the efficiency and accuracy of truing, and these are issues that must be achieved without fail.

On the other hand, in the electrolytic dressing in ELID grinding, as described above, iron ions (Fe ²⁺ ) are eluted from the metal bond portion 18 on the surface of the grindstone 12 by electrolysis to form an iron oxide film 20 on the surface of the grindstone 12. Since the operation is relatively slow, it is impossible to correct the shape of the grindstone. Therefore, E
Even in LID grinding, it is a process that must always be performed to correct the shape of the grindstone.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and is a centerless head capable of performing ELID grinding effectively and accurately by efficiently correcting the shape of a high-strength metal-bonded superabrasive grindstone. An object of the present invention is to provide a grinding method and an apparatus therefor.

[0013]

In order to achieve the above object, the present invention provides a method in which a workpiece is rotatably arranged between a metal bond grindstone rotating in a predetermined direction and an adjustment wheel. In the centerless grinding method of performing the grinding of the workpiece by pressing the workpiece against the metal bond grindstone, the truing electrode provided opposite to the grinding action surface of the metal bond grindstone and the metal bond grindstone. By applying a voltage between the truing electrode and the grinding surface of the metal bond grinding wheel to generate and discharge a metal bond on the grinding surface of the grinding wheel. After modifying the shape of the surface,
A voltage is applied between the dressing electrode and the metal bond grindstone provided opposite the grinding action surface of the metal bond grindstone in the same manner as the truing electrode, and between the dressing electrode and the metal bond grindstone. Grinding of a workpiece is performed while supplying a conductive grinding fluid to the electrode and performing electrolytic dressing.

[0014] The method comprises the steps of:
A supporting and rotating means for rotatably supporting the metal bond grindstone and rotating the metal bond grindstone in a predetermined direction, a blade for rotatably supporting the workpiece, and a metal bond grindstone for supporting the workpiece supported by the blade; An adjusting wheel pressed against the metal bond grindstone, a truing electrode provided facing the grinding action surface of the metal bond grindstone, and an anode connected to the metal bond grindstone, and a cathode connected to the truing electrode. A truing power supply for applying a voltage between the grindstone and the truing electrode, a notch applying means for advancing the truing electrode by a predetermined amount with respect to the grinding action surface of the metal bond grindstone, and the same as the truing electrode A dressing electrode provided so as to face the grinding action surface of the metal bond grindstone, and an anode in contact with the metal bond grindstone. At the same time, a cathode is connected to the dressing electrode, and a dressing power supply for applying a voltage between the metal bond grindstone and the dressing electrode, and a conductive material between the metal bond grindstone and the dressing electrode. And a grinding fluid supply means for supplying the grinding fluid.

According to the present invention, first, an electric discharge is generated between the truing electrode and the grinding surface of the metal bond grindstone, and the heat generated at this time causes the metal bond on the grinding surface to be melted and eliminated. Truing of the grindstone. As described above, since the metal bond is melted and eliminated by the high thermal energy associated with the discharge, the shape of the metal bond whetstone having a wide width can be easily corrected. Therefore, a special effect is exhibited in a centerless grinding device using a wide grindstone. In addition, since the truing is performed in a non-contact manner with respect to the metal bond grindstone, the resistance at that time is small, and the whole apparatus including the truing means can be made compact.

Thereafter, a voltage is applied between the dressing electrode and the metal bond grindstone provided so as to face the grinding action surface of the metal bond grindstone, and a conductive property is applied between the dress electrode and the metal bond grindstone. ELID grinding for grinding a workpiece while supplying a grinding fluid is performed. In the truing by the above-mentioned electric discharge, the surface of the grindstone is uneven in a crater shape due to the electric discharge, and since the sharpening is insufficient, if the workpiece is ground in this state, the surface roughness of the machined surface is reduced. Not very good. Therefore, by performing ELID grinding accompanied by electrolytic dressing, the crater portion becomes smooth and sufficient dressing is performed, so that the surface roughness of the processed surface of the workpiece can be improved. It is preferable that the grinding fluid has weak conductivity.

Further, if the truing power supply and the dress power supply are constituted by one power supply and the switching means for switching the connection between the power supply and the truing electrode or the dress electrode is provided, the apparatus can be made compact. can do.

Further, there is provided an electrode moving means for moving the truing electrode and / or the dress electrode along the grinding action surface of the metal bond grindstone, wherein the truing electrode and / or the dress electrode are ground by the metal bond grindstone. You may comprise so that it may be moved along a working surface. According to this structure, the truing electrode and / or the dressing electrode can be made as small as possible, and the discharge amount and / or electric power required for electrolysis can be reduced, thereby reducing the capacity of the power supply. be able to.

When a copper-tungsten alloy is used for the truing electrode, the consumption of the electrode can be minimized.

The metal bond whetstone in the present invention is:
Abrasive grains such as diamond and CBN are held by a conductive binder (metal bond) such as cast iron. When the binder is bronze or iron, the strength is particularly high, and the effect of the present invention is exhibited.

[0021]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a specific embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a front view schematically showing an apparatus according to the present embodiment (hereinafter referred to as “the present apparatus”), and FIG. 2 is a perspective view of the apparatus. As shown in FIG. The apparatus is one in which the present invention is applied and embodied to the conventional ELID grinding apparatus shown in FIG. 5 described above, and the truing electrode 1, the changeover switch 2, and the truing electrode 1 are provided in the ELID grinding apparatus. Cutting means (not shown) for advancing a predetermined amount with respect to the grinding surface of the grindstone 12; and electrode moving means (not shown) for moving the truing electrode 1 along the grinding surface of the grindstone 12. The other configuration is the same as that of the conventional ELID grinding device. Therefore, the same components are denoted by the same reference numerals, and detailed description thereof will be omitted.

The truing electrode 1 is provided so as to be opposed to the grinding surface of the grinding stone 12 with a slight gap therebetween.
6 are connected to the cathode. The truing electrode 1 may be made of various conductive metals such as copper and stainless steel.
The use of a copper-tungsten alloy is preferable because the consumption of the electrode is suppressed.

The dressing electrode 11 is also connected to the switch 2.
Is connected to the cathode of the power supply 16 through the switch. By switching the switch 2, a voltage is applied between the surface of the grindstone 12 and the electrode 11 for dressing or between the surface of the grindstone 12 and the electrode 1 for truing. Can be applied.

Although not particularly shown, the incision applying means and the electrode moving means are capable of moving the truing electrode 1 along a trajectory shown by a dashed line in FIG. 2 by the operation of these means. For example, a combination of a ball screw and a servomotor can be employed.

According to the present apparatus having the above-described configuration, first, the grindstone 12 is mounted on the apparatus, and the switch 2 is switched to apply a predetermined voltage between the surface of the grindstone 12 and the truing electrode 1. Next, the truing electrode 1 is moved so as to approach the grinding action surface of the grindstone 12 by driving the notch applying means (not shown).
Is adjusted so that the gap with the grinding action surface becomes a predetermined gap (5 to 20 μm). Thereby, the truing electrode 1
A discharge is generated between the grinding wheel 12 and the grinding surface of the grinding wheel 12, and the heat generated at this time melts and eliminates the metal bond on the grinding surface. And an electrode moving means (not shown)
Is driven to move (traverse) the truing electrode 1 along the grinding action surface of the grindstone 12, the discharge action position moves with the traverse of the truing electrode 1, and as a result, the grinding of the grindstone 12 is performed. The metal bond on the entire working surface is melted and eliminated one after another.

As described above, the surface of the whetstone 12 is covered with a metal bond in a new state, and the abrasive grains 19 are not exposed on the surface (FIG. 3A). By repeating, the abrasive grains 19 are exposed on the grinding surface of the grindstone 12 as shown in FIG. Then, in this state, the grindstone 12 can be ground for the first time.

Next, the switch 2 is switched so that the grindstone 12 is
A voltage is applied between the surface and the dressing electrode 11 to perform the ELID grinding described in the section of the related art. In the truing by the electric discharge, the metal bond portion on the surface of the grindstone 12 is formed into a crater-like unevenness by the electric discharge and the sharpening is insufficient. Does not have very good surface roughness. Therefore, by performing electrolytic dressing to smooth the crater portion and performing sufficient sharpening, the surface roughness of the processed surface of the workpiece W can be improved. Thus, discharge truing is the most preferred truing method used in combination with ELID grinding.

Thereafter, if ELID grinding is continuously performed for a certain period of time, the shape of the grindstone 12 becomes abnormal due to wear. In this case, the truing by the above-described discharge is performed again to correct the shape of the grindstone 12. FIG. 4 shows a series of these processing systems.

As described above, according to the present apparatus, the metal bond is melted and eliminated by the high thermal energy associated with the discharge, so that the grindstone 12 can be easily dressed, and the shape of the grindstone 12 is deformed by wear. In this case, the correction can be easily performed, and the wide grinding stone can be easily trued. Further, since the truing is performed without contacting the grindstone 12, the resistance at that time is small, and there is an effect that the whole apparatus can be downsized. Further, since the truing electrode 1 is configured to be traversed, the truing electrode 1 can be reduced as much as possible, and the discharge amount accompanying the truing electrode 1 can be reduced.
Also has the effect of reducing the capacity of the device.

The dressing electrode 11 may be similarly traversed along the grinding surface of the grindstone 12. With this configuration, the dressing electrode 1 is formed.
Can be reduced as much as possible, and the power required for electrolysis can be reduced, so that the capacity of the power supply 16 can be reduced.

In the above-described discharge truing, it is preferable to perform two-step truing in which rough truing is performed by increasing the applied voltage, and then finishing truing is performed by applying a voltage lower than the applied voltage. Thereby, truing can be performed efficiently, and craters generated on the grindstone surface can be minimized by performing finishing truing.

If the truing electrode 1 is provided rotatably about the axis and is appropriately rotated by a driving means, the truing electrode 1 accompanying the discharge can be effectively prevented from being consumed. .

If the electric capacity of the power supply 16 is not limited, the truing electrode 1 has a length corresponding to the entire width of the grinding action surface of the grindstone 12, and the truing electrode 1 is configured to perform discharge truing without traversing. Is also good.

[0035]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which the grinding wheel 12 is actually trued using the present apparatus will be described below.

(Example 1) SD800S75MEL (outer diameter 15) using a bronze-iron metal bond for the grindstone 12
0 mm, width 50 mm, inner diameter 63.5 mm), a DC power supply having a capacity of 150 V and 75 A as the power supply 16, and a copper-tungsten alloy (outer diameter 50 m) for the truing electrode 1.
m, width 5 mm), the discharge truing of the grindstone 12 was performed by the above-described apparatus. The truing electrode 1 was rotated about its axis at a rotational speed of 3090 rpm, the cut amount was 5 μm, and the truing electrode 1 was reciprocated (traverse) along the grinding action surface of the grindstone at a speed of 100 mm / min. . Truing was performed in two stages, rough truing and finish truing. A voltage of 150 V was applied in rough truing, and a voltage of 120 V was applied in finish truing. The rotation speed of the grindstone 12 was 4060 rpm.

(Comparative Example 1) A true stone rotary diamond (outer diameter 50 mm, width 1 mm, 80 pieces embedded) was used as a truer.
This was rotated at a rotation speed of 3090 rpm, and the same metal bond grindstone as in Example 1 was trued.

(Comparative Example 2) Bond rotary diamond (outer diameter 50 mm, width 5 mm, SD # 80, 100)
M), this was rotated at a rotation speed of 3090 rpm, and the same metal bond grindstone as in Example 1 was trued.

In the above Example 1 and Comparative Examples 1 and 2, the "run-out" and "straightness" of the truing whetstone 12 were measured. The results are shown in Table 1 below. In addition, "run-out"
Means the run-out of the grinding action surface of the grinding wheel 12, and "straightness"
Means the parallelism with the axis of the grindstone 12.

[0040]

[Table 1]

As shown in Table 1, the discharge truing according to the present invention of Example 1 has a "run-out" and "straightness" of the grindstone as compared with Comparative Examples 1 and 2, which are truing using a conventional rotary diamond. It is clear that both of the examples have remarkably excellent characteristics, and the ability to correct the shape of the discharge truing is high. In addition, as shown in Table 1, in Comparative Examples 1 and 2, the "run-out" of the grindstone was worsened by performing truing, and measurement was impossible.

(Embodiment 2) Using the grindstone 12 for which truing was completed in Embodiment 1 above, the ELID
Grinding was performed. The conditions for ELID grinding are as follows: dress electrode 11
A voltage of 90 V is applied between the grinding wheel 12 and the grinding wheel 12, the rotation speed of the grinding wheel 12 is set to 4060 rpm, and the rotation speed of the adjusting wheel is set to 45 r.
pm, a feed rate of 0.5 mm / min, a cutting depth of 20 μm, and a zirconia-based ceramic workpiece W (outer diameter 2.5 mm,
(Length 12.5 mm) was ground.

(Comparative Example 3) Example 2 except that the ELID apparatus of the present apparatus was not used, that is, ELID grinding was not performed.
Under the same conditions as above, a workpiece W (outer diameter 2.5 mm, length 12.5 mm) of zirconia ceramics was ground.

The surface roughness of the workpiece W processed in Example 2 and Comparative Example 3 was measured. The results are shown in Table 2 below.

[0045]

[Table 2]

As shown in Table 2, the case where the ELID grinding was performed after the discharge truing (Example 2) was compared with the case where the grinding was performed using the grindstone 12 which only performed the discharge truing (Comparative Example 3). Thus, the surface roughness of the workpiece W became excellent. From this, discharge truing and E
It can be seen that good surface roughness can be obtained by using in combination with the LID grinding method.

[Brief description of the drawings]

FIG. 1 is a front view schematically showing the present apparatus.

FIG. 2 is a perspective view of FIG.

FIG. 3 is an explanatory diagram for explaining the principle of discharge truing in the present invention.

FIG. 4 is a process diagram showing a grinding system in the present apparatus.

FIG. 5 is a front view schematically showing a conventional ELID grinding device.

FIG. 6 is an explanatory diagram for explaining the principle of the ELID grinding method.

FIG. 7 is an explanatory diagram for explaining an operation of truing using a conventional rotary diagram.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Truing electrode 2 Switch 11 Dress electrode 12 Metal bond grindstone (grindstone) 13 Rotation axis 14 Adjusting wheel 15 Blade 16 Power supply 17 Grinding fluid supply means

Claims (7)

[Claims] 1. A work piece is rotatably arranged between a metal bond grindstone rotating in a predetermined direction and an adjustment wheel, and the work piece is pressed against the metal bond grindstone by the adjustment wheel to grind the work piece. In a centerless grinding method for performing processing, a voltage is applied between the metal bond grindstone and a truing electrode provided so as to face a grinding action surface of the metal bond grindstone, and a grinding action of the truing electrode and the metal bond grindstone is performed. By causing a discharge between the surface and the metal bond on the grinding wheel grinding action surface to be melted and eliminated, the shape of the grinding action surface of the metal bond grindstone is modified, and then the metal is fixed in the same manner as the truing electrode. A voltage is applied between the dressing electrode and the metal bond grindstone provided opposite to the grinding action surface of the bond grindstone, and the dressing electrode and the metal bond grindstone are applied. Centerless grinding method using a metal bonded grinding wheel and performing grinding of a conductive grinding fluid workpiece while electrolytic dressing by supplying between. 2. The centerless grinding method using a metal bond grinding wheel according to claim 1, wherein the truing electrode and / or the dress electrode are moved along the grinding action surface of the metal bond grinding wheel. 3. A metal bond grindstone, a support rotating means for rotatably supporting the metal bond grindstone and rotating the metal bond grindstone in a predetermined direction, a blade for rotatably supporting a workpiece, and a blade supported by the blade. An adjusting wheel that presses the workpiece to be processed against the metal bond grindstone; a truing electrode provided so as to face a grinding surface of the metal bond grindstone; an anode connected to the metal bond grindstone; A truing power source that is connected to the electrode for grinding and applies a voltage between the metal bond grinding wheel and the truing electrode; and a notch for advancing the truing electrode by a predetermined amount with respect to the grinding action surface of the metal bond grinding wheel. Application means, for a dress provided opposite to the grinding action surface of the metal bond grindstone similarly to the truing electrode A pole, an anode connected to the metal bond grindstone, a cathode connected to the dress electrode, and a dress power supply for applying a voltage between the metal bond grindstone and the dress electrode; A centerless grinding apparatus using a metal bond grinding wheel, comprising a grinding fluid supply means for supplying a conductive grinding fluid between the grinding wheel and the dressing electrode. 4. The metal bond grinding wheel according to claim 3, wherein said truing power supply and said dress power supply are constituted by one power supply, and a switching means for switching connection between said power supply and said truing electrode or dress electrode is provided. Centerless grinding machine 5. A centerless grinding apparatus using a metal bond grinding wheel according to claim 3, further comprising an electrode moving means for moving the truing electrode and / or the dress electrode along a grinding action surface of the metal bond grinding wheel. . 6. The centerless grinding apparatus according to claim 3, wherein the truing electrode is made of a copper-tungsten alloy. 7. A centerless grinding apparatus using a metal bond grinding wheel according to claim 3, wherein the binder of the metal bond grinding wheel is bronze and iron.