EP1779973A1 - Meule diamant rotative - Google Patents

Meule diamant rotative Download PDF

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Publication number
EP1779973A1
EP1779973A1 EP05770599A EP05770599A EP1779973A1 EP 1779973 A1 EP1779973 A1 EP 1779973A1 EP 05770599 A EP05770599 A EP 05770599A EP 05770599 A EP05770599 A EP 05770599A EP 1779973 A1 EP1779973 A1 EP 1779973A1
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EP
European Patent Office
Prior art keywords
dressing body
diamond grains
groove
circular
octahedral
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP05770599A
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German (de)
English (en)
Other versions
EP1779973A4 (fr
Inventor
Tomoyasu Toyoda Van Moppes Ltd. IMAI
Toshihisa Toyoda Van Moppes Ltd. NOGIMORI
Masashi Toyoda Van Moppes Ltd. YANAGISAWA
Noboru Toyoda Van Moppes Ltd. HIRAIWA
Shinji c/o JTEKT Corporation SOMA
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Toyoda Van Moppes Ltd
JTEKT Corp
Original Assignee
Toyoda Van Moppes Ltd
JTEKT Corp
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Publication date
Application filed by Toyoda Van Moppes Ltd, JTEKT Corp filed Critical Toyoda Van Moppes Ltd
Publication of EP1779973A1 publication Critical patent/EP1779973A1/fr
Publication of EP1779973A4 publication Critical patent/EP1779973A4/fr
Withdrawn legal-status Critical Current

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
    • B24DTOOLS FOR GRINDING, BUFFING OR SHARPENING
    • B24D3/00Physical features of abrasive bodies, or sheets, e.g. abrasive surfaces of special nature; Abrasive bodies or sheets characterised by their constituents
    • B24D3/02Physical features of abrasive bodies, or sheets, e.g. abrasive surfaces of special nature; Abrasive bodies or sheets characterised by their constituents the constituent being used as bonding agent
    • B24D3/04Physical features of abrasive bodies, or sheets, e.g. abrasive surfaces of special nature; Abrasive bodies or sheets characterised by their constituents the constituent being used as bonding agent and being essentially inorganic
    • B24D3/06Physical features of abrasive bodies, or sheets, e.g. abrasive surfaces of special nature; Abrasive bodies or sheets characterised by their constituents the constituent being used as bonding agent and being essentially inorganic metallic or mixture of metals with ceramic materials, e.g. hard metals, "cermets", cements
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
    • B24BMACHINES, DEVICES, OR PROCESSES FOR GRINDING OR POLISHING; DRESSING OR CONDITIONING OF ABRADING SURFACES; FEEDING OF GRINDING, POLISHING, OR LAPPING AGENTS
    • B24B53/00Devices or means for dressing or conditioning abrasive surfaces
    • B24B53/12Dressing tools; Holders therefor
    • B24B53/14Dressing tools equipped with rotary rollers or cutters; Holders therefor
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
    • B24DTOOLS FOR GRINDING, BUFFING OR SHARPENING
    • B24D5/00Bonded abrasive wheels, or wheels with inserted abrasive blocks, designed for acting only by their periphery; Bushings or mountings therefor
    • B24D5/02Wheels in one piece

Definitions

  • the present invention relates to rotary diamond dressers for dressing grinding surfaces of grinding wheels.
  • diamond grains 45 having octahedral grain shapes are set in an annular band part 44 of the dresser 40, which includes both the junction point C between the straight part 41 and the arcuate part 42 of the dresser 40 and the area around the junction point C, and has the center on a rotary axis 43, such that one crystal surface 46 of each diamond grain 45 is exposed outside parallel to the circumference of the dresser 40.
  • a plurality of V-grooves 211 are formed, as shown in FIG. 1 and FIG. 2 of the official gazette, on the front end of a metal shank 2 such that the surfaces of each of the V-grooves 211 are divergent from each other at an opening angle of about 110 degrees, which is equal to the angle defined between two oriented crystal surfaces (1,1,1) of an octahedral diamond grain 1.
  • a plurality of octahedral diamond grains 1 are sequentially set in the V-grooves 211 such that the two oriented crystal surfaces (1,1,1) of each octahedral diamond grain 1 are soldered to the V-grooves 211 using solder made of an alloy of titanium (Ti), copper (Cu), silver (Ag), etc.
  • each of the octahedral diamond grains is bonded to a female frame 50 at the oriented crystal surfaces (1,1,1) and is integrated with the female frame 50 by injecting molten nickel silver, added with fine powder, such as tungsten powder, between the female frame 50 and a core 51.
  • molten nickel silver added with fine powder, such as tungsten powder
  • the oriented crystal surfaces (1,1,1) of the octahedral diamond grains are set in the inner surface of the female frame, so that the abrasion-resistant oriented crystal surfaces (1,1,1) of the octahedral diamond grains are not exposed outside the circumferential surface of the rotary diamond dresser. Further, the oriented crystal surfaces (1,1,1) of the octahedral diamond grains are cleavage surfaces, so that the oriented crystal surfaces (1,1,0) or the oriented crystal surfaces (1,0,0) of the octahedral diamond grains are preferably exposed outside the circumferential surface of the rotary diamond dresser so as to take part in dressing work.
  • the two oriented crystal surfaces (1,1,1) of the octahedral diamond grains 1 are seated in and soldered to the V-grooves 211 having an opening angle of about 110 degrees, and the oriented crystal surfaces (1,0,0) of the octahedral diamond grains 1 dress a grinding wheel.
  • the diamond dresser in the Japanese Patent Publication No. 3450085 in which the diamond grains 1 are soldered to the front end of the shank 2, is not a rotary diamond dresser, and thus the number of the diamond grains 1 that take part in dressing work is reduced and thus the diamond grains are heavily abraded.
  • an error in the size of the front end of the diamond dresser may be generated, so that the diamond dresser may fail to dress the grinding surface of a grinding wheel to form a desired shape. Further, because the diamond dresser uses only expensive octahedral diamond grains, the diamond dresser increases the cost of dressing the grinding surface of a grinding wheel.
  • a conventional conical-type diamond dresser in which a plurality of octahedral diamond grains are set in the dresser such that the octahedral diamond grains protrude outwards from the middle part of the circumference of a circular double-sided truncated conical dressing body in a direction perpendicular to the rotary axis of the dressing body, has been proposed.
  • the plurality of octahedral diamond grains are sintered to the middle part of the circumference of the circular double-sided truncated conical dressing body such that portions of the octahedral diamond grains other than the outside vertices of the octahedral diamond grains, are set in sintered metal and two opposite surfaces of four oriented crystal surfaces (1,1,1) of each octahedral diamond grain, which form vertices on the oriented crystal surfaces (1,0,0), are oriented in the rotating direction of the dressing body.
  • the sintered metal cannot strongly hold the octahedral diamond grains on the dressing body, and furthermore, increases the production cost of the dresser.
  • the angle of the conical middle part of the circumference of the circular double-sided truncated conical diamond dresser is formed as an acute angle of less than about 70 degrees, defined between the two opposite surfaces of the four oriented crystal surfaces (1,1,1) of each octahedral diamond grain, the side surfaces of the octahedral diamond grains are exposed outside the sintered metal, and thus the octahedral diamond grains may be easily removed from the dressing body. Therefore, sintering cannot desirably secure the octahedral diamond grains to the dressing body.
  • the present invention has been made in view of the above problems, and it is an object of the present invention to provide a rotary diamond dresser, which is easily produced, has excellent abrasion resistance, and is low-priced.
  • the present invention provides a rotary diamond dresser comprising a circular dressing body rotated around a rotary axis, with a plurality of diamond grains set into the circumference of the circular dressing body, thus dressing a grinding wheel, wherein a V-groove is formed along a high load part of the circular dressing body such that two surfaces of the V-groove are oriented in a rotating direction of the circular dressing body and are divergent from each other at an opening angle equal to an angle defined between two oriented crystal surfaces (1,1,1) that meet each other to form a ridge on a oriented crystal surface (1,1,0) of an octahedral diamond grain, the high load part being defined along the circumference of the circular dressing body and being heavily loaded during dressing, thus highly abrading the diamond grains; a plurality of octahedral diamond grains are set along the V-groove such that the two oriented crystal surfaces (1,1,1) of each of the octahedral diamond grains
  • the plurality of octahedral diamond grains are set in the circular dressing body such that the two oriented crystal surfaces (1,1,1) of each octahedral diamond grain, which define a ridge on the oriented crystal surface (1,1,0), are bonded to the surfaces of the V-groove, which is formed along the high load part of the circular dressing body. Further, the plurality of small-sized diamond grains are secured to the surface of the circumference of the dressing body at portions other than the high load part.
  • the octahedral diamond grains contact the grinding wheel at the oriented crystal surfaces (1,1,0), and dress the grinding wheel while relatively moving in the direction parallel to the ridge, which has high abrasion resistance.
  • the present invention provides a rotary diamond dresser, which reduces the abrasion of diamond grains, dresses the grinding surface of the grinding wheel to form a desired shape with high precision, and is easily produced at a low cost.
  • the present invention provides a rotary diamond dresser comprising a circular dressing body rotated around a rotary axis, with a plurality of diamond grains set into the circumference of the circular dressing body, thus dressing a grinding wheel, wherein a V-groove is formed along a high load part of the circular dressing body such that two surfaces of the V-groove are oriented in a rotating direction of the circular dressing body or in a direction perpendicular to the rotating direction and contact two opposite surfaces of four oriented crystal surfaces (1,1,1) of an octahedral diamond grain, which form vertices on oriented crystal surfaces (1,0,0), the high load part being defined along the circumference of the circular dressing body and being heavily loaded during dressing, thus highly abrading the diamond grains; a plurality of octahedral diamond grains are set along the V-groove such that the two oriented crystal surfaces (1,1,1) of each of the octahedral diamond grains are bonded to the two respective surfaces of the V
  • the plurality of octahedral diamond grains are set to the circular dressing body such that two opposite surfaces of the four oriented crystal surfaces (1,1,1) of each octahedral diamond grain, which form vertices on the oriented crystal surfaces (1,0,0), are bonded to the two respective surfaces of the V-groove that is formed along the high load part of the circular dressing body in the rotating direction or in a direction perpendicular to the rotating direction. Further, the plurality of small-sized diamond grains are secured to the surface of the circumference of the circular dressing body at places other than the high load part.
  • the octahedral diamond grains contact the grinding wheel with the oriented crystal surfaces (1,0,0), and dress the grinding wheel while moving in a direction having high abrasion resistance.
  • the present invention provides a rotary diamond dresser, which reduces the abrasion of diamond grains, dresses the grinding surface of the grinding wheel to form a desired shape with high precision, and is easily produced at a low cost.
  • the V-groove may be continuously and circumferentially formed along the high load part, which is a junction part between a circumferential straight part and a side arcuate part of the circumference of the circular dressing body.
  • the V-groove in which the two oriented crystal surfaces (1,1,1) of each of the plurality of octahedral diamond grains are secured using the bonding material, is circumferentially and continuously formed along the high load part of the circular dressing body, so that the octahedral diamond grains can be easily set in the high load part with high precision such that the octahedral diamond grains can contact the grinding wheel and can move in a direction having high abrasion resistance.
  • the present invention provides a rotary diamond dresser, which is easily produced at a low cost.
  • the present invention provides a cup-type rotary diamond dresser comprising a circular truncated conical dressing body rotated around a rotary axis, with a plurality of diamond grains inclinedly protruding outwards from the circumference of a large-diameter part of the circular truncated conical dressing body at a predetermined inclination angle relative to the rotary axis of the dressing body, or a conical-type rotary diamond dresser comprising a circular double-sided truncated conical dressing body rotated around a rotary axis, with a plurality of diamond grains protruding outwards from a middle part of the circumference of the circular double-sided truncated conical dressing body in a direction perpendicular to the rotary axis of the dressing body, wherein a V-groove having two surfaces, which contact two opposite surfaces of four oriented crystal surfaces (1,1,1) of an octahedral diamond grain that form vertices
  • the plurality of octahedral diamond grains are set in the dressing body such that two opposite surfaces of the four oriented crystal surfaces (1,1,1) that form the vertices on the oriented crystal surfaces (1,0,0) of each octahedral diamond grain are bonded using the bonding material to the two respective surfaces of the V-groove, which is formed around the circumference of the large-diameter part of the circular truncated conical dressing body or is formed around the middle part of the circumference of the circular double-sided truncated conical dressing body.
  • the octahedral diamond grains are strongly secured to the dressing body.
  • the present invention provides a cup-type or conical-type rotary diamond dresser, which reduces the abrasion of diamond grains, dresses the grinding surface of the grinding wheel to form a desired shape with high precision, and is easily produced at a low cost.
  • the present invention provides a cup-type rotary diamond dresser comprising a circular truncated conical dressing body rotated around a rotary axis, with a plurality of diamond grains inclinedly protruding outwards from the circumference of a large-diameter part of the circular truncated conical dressing body at a predetermined inclination angle relative to the rotary axis of the dressing body, or a conical-type rotary diamond dresser comprising a circular double-sided truncated conical dressing body rotated around a rotary axis, with a plurality of diamond grains protruding outwards from a middle part of the circumference of the circular double-sided truncated conical dressing body in a direction perpendicular to the rotary axis of the dressing body, wherein a V-groove having two surfaces, which are divergent from each other at an opening angle equal to an angle defined between two oriented crystal surfaces (1,1,1) that meet each other to form a
  • the plurality of octahedral diamond grains are set in the dressing body such that the two oriented crystal surfaces (1,1,1) that meet each other to form a ridge on the oriented crystal surface (1,1,0) of each octahedral diamond grain are bonded, using the bonding material, to the two respective surfaces of the V-groove, which is formed around the circumference of the large-diameter part of the circular truncated conical dressing body or is formed around the middle part of the circumference of the circular double-sided truncated conical dressing body.
  • the octahedral diamond grains are strongly secured to the dressing body.
  • the present invention provides a cup-type or conical-type rotary diamond dresser, which reduces the abrasion of diamond grains, dresses the grinding surface of a grinding wheel to form a desired shape with high precision, and is easily produced at a low cost.
  • the bonding material for bonding the octahedral diamond grains to the surface of the V-groove may be solder made of an alloy of metal selected from one Group among Group 4A including titanium (Ti), Group 5A including vanadium (V), and Group 6A including chromium (Cr) of the Periodic Table, and metal selected from Group 1B of the Periodic Table.
  • a titanium carbide layer is formed on each of the two oriented crystal surfaces (1,1,1) of the diamond grain.
  • the titanium carbide layer is a half-metallic layer, and thus has excellent integration ability relative to metals included in the solder, so that the diamond grains can be securely fixed to the circular dressing body.
  • the rotary diamond dresser 10 comprises a circular dressing body 11, with a plurality of diamond grains set into the circumference of the circular dressing body 11.
  • the circular dressing body 11, having a center hole, is fitted at the center hole thereof over a rotary shaft 25 of a dressing unit, which is installed on a grinding machine.
  • the circular dressing body 11 is rotated along with the rotary shaft 25, thereby dressing the grinding surface of a grinding wheel 26.
  • a V-groove 14 is formed along a high load part 13 of the circular dressing body 11, which is defined along the circumference 12 of the circular dressing body 11 and is heavily loaded during dressing work, thus highly abrading the diamond grains.
  • the angle between two surfaces of the V-groove 14 is set to an angle of about 110 degrees, which is equal to the angle defined between two oriented crystal surfaces (1,1,1) that meet each other to form a ridge on a oriented crystal surface (1,1,0) of an octahedral diamond grain 15.
  • the high load part 13 is a junction part between a circumferential straight part 16 and a side arcuate part 17 of the circumference 12 of the circular dressing body 11.
  • the V-groove 14 is continuously and circumferentially formed along the high load part 13 such that the two surfaces of the V-groove 14 are oriented in a rotating direction of the dressing body 11.
  • the plurality of octahedral diamond grains 15 are sequentially set along the circumference 12 of the circular dressing body 11 such that two oriented crystal surfaces (1,1,1) of each of the diamond grains 15, which meet each other and define a 110 degree angle therebetween, are bonded to the two respective surfaces of the V-groove 14 using a bonding material 18.
  • the oriented crystal surface (1,1,0) of each of the octahedral diamond grains 15 is formed as a contact surface 19, which contacts a grinding wheel and moves toward the ridge having high abrasion resistance, and dresses the grinding surface of the grinding wheel.
  • the bonding material 18 uses solder made of an alloy of metal selected from one Group among Group 4A including titanium (Ti), Group 5A including vanadium (V), and Group 6A including chromium (Cr) of the Periodic Table, and metal selected from Group 1B including copper (Cu) and silver (Ag) of the Periodic Table.
  • the two oriented crystal surfaces (1,1,1) of each of the diamond grains 15, which meet each other and define a 110 degree angle between them are soldered to the two respective surfaces of the V-groove 14.
  • a titanium carbide layer is formed on each of the two oriented crystal surfaces (1,1,1) of the diamond grain 15.
  • the titanium carbide layer is a half-metallic layer, and thus has excellent integration ability relative to metals included in the solder, so that the diamond grains 15 can be securely fixed to the circular dressing body 11.
  • a plurality of diamond grains 20, having small particle sizes, other than the octahedral diamond grains 15, are secured using the bonding material 18 to the surface of the circumference 12 of the circular dressing body 11 other than the high load part 13.
  • the circumferential surface of each of the small-sized diamond grains 20 is formed as a contact surface 21, which contacts a grinding wheel and dresses the grinding surface of the grinding wheel.
  • the diamond grains 20, having small particle sizes, are securely soldered to the surface of the circumference 12 of the circular dressing body 11 other than the high load part 13, using a bonding material 18 that is a solder made of an alloy of metal selected from one Group among Group 4A including titanium (Ti), Group 5A including vanadium (V), and Group 6A including chromium (Cr) of the Periodic Table, and metal selected from Group 1B including copper (Cu) and silver (Ag) of the Periodic Table.
  • a bonding material 18 that is a solder made of an alloy of metal selected from one Group among Group 4A including titanium (Ti), Group 5A including vanadium (V), and Group 6A including chromium (Cr) of the Periodic Table, and metal selected from Group 1B including copper (Cu) and silver (Ag) of the Periodic Table.
  • a V-groove 14 which has two surfaces that meet each other at a 110 degree angle, is continuously and circumferentially formed along the high load part 13, which is the junction part between the circumferential straight part 16 and the side arcuate part 17 of the circumference 12 of the circular dressing body 11 (First Step).
  • a viscous granular material 22 is prepared by mixing metal particles, whose metal is selected from one Group among Group 4A including titanium (Ti), Group 5A including vanadium (V), and Group 6A including chromium (Cr) of the Periodic Table, and metal particles, whose metal is selected from Group 1B including copper (Cu) and silver (Ag) of the Periodic Table, with an appropriate organic binder added to the metal particles.
  • Metals laden in the viscous granular material 22 are baked to produce an alloy, and thus provide a solder to be used as the bonding material 18, as will be described later herein.
  • the viscous granular material 22 is coated on the two surfaces of the V-groove 14 to a predetermined thickness using an appropriate device, such as a brush (Second Step). Thereafter, octahedral diamond grains 15, having sizes of 60 ⁇ 80 grains/cts, are sequentially placed in the V-groove 14 at regular intervals of about 1.2 mm.
  • the two oriented crystal surfaces (1,1,1) of each of the diamond grains 15, which meet each other to form a ridge on the oriented crystal surface (1,1,0), are seated on the two respective surfaces of the V-groove 14, with the viscous granular material 22 added to the junction of the contact surfaces (Third Step).
  • the circular dressing body 11 which has the diamond grains 15 seated in the V-groove 14 using the viscous granular material 22, is put in a kiln, and is baked at a calcination temperature of 840 ⁇ 940°C in an inert gas atmosphere, such as an argon gas atmosphere, or in a vacuum atmosphere.
  • a metalized layer such as a titanium carbide (TiC) layer, is formed between the titanium (Ti) and the two oriented crystal surfaces (1,1,1) of each of the diamond grains 15.
  • the metalized layer is easily united with metals of Group 1B, including copper (Cu) and silver (Ag) of the Periodic Table.
  • the diamond grains 15 and the solder have excellent wettability.
  • the two oriented crystal surfaces (1,1,1) of each of the diamond grains 15 are securely soldered to the two respective surfaces of the V-groove 14 of the circular dressing body 11, thus being fixed to the circumference 12 of the circular dressing body 11 (Fourth Step).
  • the viscous granular material 22 is coated on the surfaces of both the circumferential straight part 16 and the side arcuate part 17 of the circumference 12 of the circular dressing body 11, other than the high load part 13, to a predetermined thickness using an appropriate device, such as a brush (Fifth Step).
  • An appropriate device such as a brush (Fifth Step).
  • a plurality of diamond grains 20 that have predetermined small particle sizes, for example, artificial diamond grains having sizes of #20 (average particle size 0.427mm), other than the octahedral diamond grains 15, are placed in the coated viscous granular material 22 with a predetermined concentration and a uniform distribution to form a single layer.
  • the diamond grains 20, having the predetermined small particle sizes are seated in the surfaces of both the circumferential straight part 16 and the side arcuate part 17 of the circumference 12 of the circular dressing body 11 other than the high load part 13 (Sixth Step).
  • the circular dressing body 11 which has the diamond grains 20 having the predetermined small particle sizes and seated in the circumference 12 using the viscous granular material 22, is put in the kiln, and is baked in an inert gas atmosphere, such as an argon gas atmosphere, or in a vacuum atmosphere.
  • an inert gas atmosphere such as an argon gas atmosphere
  • the diamond grains 20 are securely soldered to both the circumferential straight part 16 and the side arcuate part 17 of the circumference 12 of the circular dressing body 11 other than the high load part 13 (Seventh Step).
  • the viscous granular material 22 is coated again using a brush over the entire area of the circumference 12 of the circular dressing body 11 (Eighth Step), which has both the octahedral diamond grains 15 and the small-sized diamond grains 20.
  • CBN abrasive grains (hexagonal boron nitride) 27 of #140/170 (average particle size 0.107mm) are distributed over the entire area of the circumference 12 (Ninth Step).
  • the circular dressing body 11 which has the CBN abrasive grains 27 seated in the circumference 12 using the viscous granular material 22, is put in the kiln, and is baked in an inert gas atmosphere, such as an argon gas atmosphere, or in a vacuum atmosphere (Tenth Step, see FIG. 7).
  • an inert gas atmosphere such as an argon gas atmosphere
  • a vacuum atmosphere such as a vacuum atmosphere
  • each of the diamond grains 20, which have small particle sizes and are soldered to the surface of the circumference 12 of the circular dressing body 11 other than the high load part 13, is formed as the contact surface 21, which contacts the grinding wheel 26 and dresses the grinding surface of the grinding wheel 26 (Eleventh Step, see FIG. 2).
  • the diamond grains 15 and 20 are secured to the circular dressing body 11 such that the contact surfaces 19 and 21 of the diamond grains 15 and 20 protrude from the surface of the circumference 12 by about 0.3 mm.
  • the rotary diamond dresser 10 which has been produced through the above-mentioned process, is fitted over the rotary shaft 25, which is installed in the dressing unit of a grinding machine parallel to the rotary axis of the grinding wheel 26.
  • the rotary diamond dresser 10 can be rotated along with the rotary shaft 25 by a motor.
  • the rotary diamond dresser 10 moves relative to the grinding wheel 26 according to the shape of the grinding surface of the grinding wheel 26.
  • the high load part 13 which is at the junction of the circumferential straight part 16 and the side arcuate part 17, acts as a leading edge and dresses the straight part of the circumferential grinding surface of the grinding wheel 26.
  • the high load part 13 is heavily loaded.
  • the octahedral diamond grains 15, fixed to the high load part 13 contact the grinding wheel 26 with the oriented crystal surface (1,1,0), move relatively in the direction parallel to the ridge having high abrasion resistance, and dress the grinding surface of the grinding wheel 26.
  • the rotary diamond dresser 10 is not partially abraded at the high load part 13, but dresses the grinding surface of the grinding wheel 26 to form a desired shape with high precision.
  • octahedral diamond grains 15, having sizes of 60 ⁇ 80 grains per carat are sequentially placed in the V-groove 14 at a regular pitch of about 1.2 mm such that the ridges of the neighboring diamond grains 15 come into close contact with each other.
  • octahedral diamond grains, having sizes of 150 ⁇ 200 grains per carat may be sequentially and closely placed in the V-groove 14 at a regular pitch of about 0.75 mm (see FIG. 8).
  • the octahedral diamond grains 15 can be sequentially set in the V-groove 14 such that the ridges of the neighboring diamond grains 15 come into close contact with each other, as described above, the number of octahedral diamond grains 15 set in the V-groove 14 can be increased, and thus increase the abrasion resistance of the high load part 13.
  • the pitch of the octahedral diamond grains 15, which are placed in the V-groove 14 is preferably set to 0.5 ⁇ 10 mm to provide high abrasion resistance.
  • one V-groove 14 is formed on the high load part 13 of the rotary diamond dresser 10.
  • a plurality of V-grooves for example, two V-grooves 14, may be formed around the circular dressing body 11, as shown in FIG. 9.
  • a plurality of octahedral diamond grains 15 may be securely set in the two V-grooves 14 of the rotary diamond dresser 10 such that a phase difference is defined between the trains of diamond grains 15 set in the two grooves 14 along the circumference, and such that the summed lengths of the contact surfaces 19 of the diamond grains 15 in the generating line direction become almost equal to each other.
  • artificial diamond grains having sizes of #140/170 are distributed on and soldered to the entire area of the circumference 12 of the circular dressing body 11, which has both the octahedral diamond grains 15 and the small-sized diamond grains 20, so that the abrasion resistance of the solder surface can be increased.
  • the eighth through tenth steps may be omitted from the process.
  • the V-groove 14 is continuously formed around the circumference 12 of the rotary diamond dresser 10, and thus the machining process for forming the V-groove 14 can be easily executed.
  • the V-groove 14 may be formed through indenting such that a plurality of V-grooves are intermittently formed along the high load part 13, which is present on the circumference 12 of the circular dressing body 11 and is highly loaded during dressing, thus heavily abrading the diamond grains.
  • the second embodiment of the present invention will be described.
  • the second embodiment is characterized in that two opposite surfaces of four oriented crystal surfaces (1,1,1) of each octahedral diamond grain, which form vertices on oriented crystal surfaces (1,0,0), are secured to the two respective surfaces of a V-groove 24.
  • the second embodiment is the same as the first embodiment in the other respects and in the process of manufacturing the diamond dresser. Therefore, in the drawings, the same elements as those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and a description thereof is omitted.
  • the V-groove 24 is formed along the high load part 13, which is present on the circumference 12 of the circular dressing body 11 and is highly loaded during dressing, thus heavily abrading the diamond grains, such that the two surfaces of the V-groove 24 are oriented in the rotating direction of the dressing body 11.
  • the angle between the two surfaces of the V-groove 24 is set to an angle of about 70 degrees, which is equal to the angle defined between the two opposite surfaces of the four oriented crystal surfaces (1,1,1) that form vertices on the oriented crystal surfaces (1,0,0) of each octahedral diamond grain 15.
  • the high load part 13 is a junction part between a circumferential straight part 16 and a side arcuate part 17 of the circumference 12 of the circular dressing body 11.
  • the V-groove 24 is continuously and circumferentially formed along the high load part 13.
  • the plurality of octahedral diamond grains 15 are set along the circumference 12 of the circular dressing body 11 such that the two oppositely situated crystal surfaces (1,1,1) of each of the diamond grains 15, which define a 70 degree angle therebetween, are bonded to the two respective surfaces of the V-groove 24 using a bonding material 18.
  • the oriented crystal surface (1,0,0) of each of the octahedral diamond grains 15 is formed as a contact surface 23, which contacts a grinding wheel 26 and dresses the grinding surface of the grinding wheel 26.
  • each of the octahedral diamond grains 15 contacts the grinding wheel 26 with the oriented crystal surface (1,0,0), moves relatively in a direction that is perpendicular to the oriented crystal surface (1,0,0), and has high abrasion resistance.
  • the octahedral diamond grains 15 in the above state dress the grinding surface of the grinding wheel 26, so that the rotary diamond dresser 10 is not partially abraded at the high load part 13, but dresses the grinding surface of the grinding wheel 26 to form a desired shape with high precision.
  • the third embodiment of the present invention will be described. Unlike the first and second embodiments, in which a plurality of octahedral diamond grains 15 are secured using a bonding material 18 to a V-groove 14 or 24 that is formed along the high load part 13 of the circumference 12 of a circular dressing body 11, and a plurality of diamond grains 20, having small particle sizes, other than the octahedral diamond grains 15, are secured using the bonding material 18 to the surface of the circumference 12 of the circular dressing body 11 other than the high load part 13, the third embodiment provides a cup-type rotary diamond dresser, in which only a plurality of diamond grains are bonded using a bonding material to a V-groove that is formed around the circumference of a large-diameter part of a circular truncated conical dressing body.
  • the V-groove 33 is continuously formed around the circumference 32 of the large-diameter part 31 of the circular truncated conical dressing body 30, which is rotated around a rotary axis.
  • the center line of the V-groove 33 is inclined outwards relative to the rotary axis of the dressing body 30.
  • the angle between two surfaces of the V-groove 33 is set to an angle of about 70 degrees, which is equal to the angle defined between two opposite surfaces of the four oriented crystal surfaces (1,1,1) that form vertices on the oriented crystal surfaces (1,0,0) of each of the octahedral diamond grains 15.
  • the plurality of octahedral diamond grains 15 are set along the V-groove 33 such that the two opposite oriented crystal surfaces (1,1,1) of each diamond grain 15, which define a 70 degree angle therebetween, are bonded to the two respective surfaces of the V-groove 33 using a bonding material 18.
  • each of the diamond grains 15 inclinedly protrudes outwards from the circumference 32 of the large-diameter part 31 of the circular truncated conical dressing body 30 at a predetermined inclination angle relative to the rotary axis of the dressing body 30.
  • each diamond grain 15 which protrudes from the V-groove 33, is an acute angle, and the oriented crystal surface (1,0,0) of the octahedral diamond grain 15 is formed as a contact surface, which contacts a grinding wheel 26 and dresses the grinding surface of the grinding wheel 26.
  • the cup-type rotary diamond dresser 34 is fitted over a rotary shaft 35, which is installed on a dressing unit of a grinding machine at a predetermined inclination angle relative to the rotary axis of the grinding wheel 26.
  • the dresser 34 is rotated along with the rotary shaft 35 by a motor.
  • the cup-type rotary diamond dresser 34 and the grinding wheel 26 are moved relative to each other according to the shape of the grinding surface of the grinding wheel 26.
  • the fourth embodiment comprises a circular double-sided truncated conical dressing body.
  • a V-groove 43 is continuously formed around the middle part 42 of the circumference of the circular double-sided truncated conical dressing body 40, which is rotated around a rotary axis, such that the center line of the V-groove 43 is perpendicular to the rotary axis of the dressing body 40.
  • the two surfaces of the V-groove 43 define an angle of about 70 degrees.
  • a plurality of octahedral diamond grains 15 are set along the V-groove 43 such that two opposite oriented crystal surfaces (1,1,1) of each diamond grain 15, which define a 70 degree angle therebetween, are bonded to the two respective surfaces of the V-groove 43 using a bonding material 18.
  • each of the diamond grains 15 protrudes outwards from the middle part 42 of the circumference of the circular double-sided truncated conical dressing body 40 in a direction perpendicular to the rotary axis of the dressing body 40.
  • each diamond grain 15 protruding from the V-groove 43 is an acute angle
  • the oriented crystal surface (1,0,0) of the octahedral diamond grain 15 is formed as a contact surface, which contacts a grinding wheel 26 and dresses the grinding surface of the grinding wheel 26.
  • the dresser 44 when the conical-type rotary diamond dresser 44 is used for dressing both side surfaces of a grinding wheel 26, the dresser 44 is located such that the rotary axis of the dressing body 40 is inclined relative to the rotary axis of the grinding wheel 26 and thus part of the circumference of the dressing body 40, which is near to the rotary axis of the grinding wheel 26 approaches the side surface of the grinding wheel 26. Meanwhile, when the conical-type rotary diamond dresser 44 is used for linearly dressing the circumference of the grinding wheel 26, the dresser 44 is located such that the rotary axis of the dressing body 40 is parallel to the rotary axis of the grinding wheel 26.
  • the conical-type rotary diamond dresser 44 and the grinding wheel 26 move relative to each other according to the shape of the grinding surface of the grinding wheel 26.
  • the oriented crystal surface (1,0,0) of each of the octahedral diamond grains 15 which perpendicularly protrudes outwards from the middle part 42 of the circumference of the circular double-sided truncated conical dressing body 40, contacts the grinding wheel 26 and dresses straight, for example, the opposite side surfaces and the circumference of the grinding wheel 26, thus forming a flat grinding surface.
  • the two surfaces of the V-groove 33 or 43 define an angle of about 70 degrees therebetween.
  • the angle between two surfaces of the V-groove may be set to an angle of about 110 degrees, which is equal to the angle defined between two oriented crystal surfaces (1,1,1) that meet each other to form a ridge on an oriented crystal surface (1,1,0) of an octahedral diamond grain.
  • the plurality of octahedral diamond grains 15 are sequentially set along the circumference of the dressing body 30 or 40 such that two oriented crystal surfaces (1,1,1) of each diamond grain 15, which define a 110 degree angle therebetween, are bonded to the two respective surfaces of the V-groove 33 or 43 using a bonding material 18.
  • the V-groove 24, 33, or 43 is continuously formed around the circumference of the dressing body.
  • a plurality of V-grooves 24 may be intermittently formed along the high load part 13, which is present on the circumference of the circular dressing body 11 and is highly loaded during dressing to heavily abrade the diamond grains
  • a plurality of V-grooves 33 may be intermittently formed around the circumference 32 of the large-diameter part of the circular truncated conical dressing body 30
  • a plurality of V-grooves 43 may be intermittently formed around the middle part 42 of the circumference of the circular double-sided truncated conical dressing body 40, such that the two surfaces of each V-groove are oriented in a rotating direction of the dressing body 40 or in a direction perpendicular to the rotating direction of the dressing body.
  • the octahedral diamond grains 15, the small-sized diamond grains 20 and the CBN abrasive grains 27 are soldered to the dressing body using solder as the bonding material 18.
  • the octahedral diamond grains 15, the small-sized diamond grains 20 and the CBN abrasive grains 27 may be fixed to the dressing body through electro-plating or electroless plating.
  • the rotary diamond dresser according to the present invention is preferably used as a rotary diamond dresser, which can dress the grinding surface of a grinding wheel installed in a grinding machine that grinds workpieces using the grinding wheel, so that the dresser can form a grinding surface having a desired shape with high precision.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Chemical & Material Sciences (AREA)
  • Ceramic Engineering (AREA)
  • Inorganic Chemistry (AREA)
  • Polishing Bodies And Polishing Tools (AREA)
  • Grinding-Machine Dressing And Accessory Apparatuses (AREA)
EP05770599A 2004-08-16 2005-08-05 Meule diamant rotative Withdrawn EP1779973A4 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
JP2004236416 2004-08-16
PCT/JP2005/014858 WO2006019062A1 (fr) 2004-08-16 2005-08-05 Meule diamant rotative

Publications (2)

Publication Number Publication Date
EP1779973A1 true EP1779973A1 (fr) 2007-05-02
EP1779973A4 EP1779973A4 (fr) 2010-10-27

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EP05770599A Withdrawn EP1779973A4 (fr) 2004-08-16 2005-08-05 Meule diamant rotative

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US (1) US20080041354A1 (fr)
EP (1) EP1779973A4 (fr)
JP (1) JPWO2006019062A1 (fr)
CN (1) CN101001720A (fr)
WO (1) WO2006019062A1 (fr)

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CN103492126B (zh) * 2011-04-18 2017-03-29 3M创新有限公司 磨削方法和磨料制品
JP6591237B2 (ja) * 2015-09-02 2019-10-16 株式会社ノリタケカンパニーリミテド ダイヤモンドドレッサ
JP2017071026A (ja) * 2015-10-07 2017-04-13 株式会社ディスコ 総型砥石工具
EP3409422B1 (fr) * 2016-02-22 2024-05-22 A.L.M.T. Corp. Outil abrasif
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CN106311868B (zh) * 2016-07-20 2018-11-02 长春理工大学 一种降低金刚石压头纳米印压单侧成孔圆度误差的方法
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Also Published As

Publication number Publication date
WO2006019062A1 (fr) 2006-02-23
EP1779973A4 (fr) 2010-10-27
CN101001720A (zh) 2007-07-18
US20080041354A1 (en) 2008-02-21
JPWO2006019062A1 (ja) 2008-05-08

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