WO2009113734A1 - Cutter and cutting machine - Google Patents

Cutter and cutting machine Download PDF

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Publication number
WO2009113734A1
WO2009113734A1 PCT/JP2009/055542 JP2009055542W WO2009113734A1 WO 2009113734 A1 WO2009113734 A1 WO 2009113734A1 JP 2009055542 W JP2009055542 W JP 2009055542W WO 2009113734 A1 WO2009113734 A1 WO 2009113734A1
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WO
WIPO (PCT)
Prior art keywords
base plate
abrasive grain
grain layer
layer
chip
Prior art date
Application number
PCT/JP2009/055542
Other languages
English (en)
French (fr)
Inventor
Satsuo Satou
Shinki Ohtsu
Toshihiro Ichijyou
Junichi Kamimura
Naoki Omata
Original Assignee
Hitachi Koki Co., Ltd.
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Hitachi Koki Co., Ltd. filed Critical Hitachi Koki Co., Ltd.
Publication of WO2009113734A1 publication Critical patent/WO2009113734A1/en

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Classifications

    • 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
    • B24D5/06Bonded abrasive wheels, or wheels with inserted abrasive blocks, designed for acting only by their periphery; Bushings or mountings therefor with inserted abrasive blocks, e.g. segmental
    • 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
    • B24D5/12Cut-off wheels
    • B24D5/123Cut-off wheels having different cutting segments

Definitions

  • the present invention relates to a cutter having cutting abrasive grains, and a cutting machine including the cutter.
  • Cutters that include abrasive grains and metallic particles are used as blades of cutting machines that cut work materials such as concrete, mortar, ceramic, stone materials, etc.
  • Cutters are constituted by a base plate that rotates as energized by an electric motor, and a chip joined to the outer circumference of the base plate.
  • the center portion of the base plate is rotatably mounted on the cutting machine.
  • the chip is formed as a result of sintering an annular abrasive grain layer and an annular joining layer provided on the inner circumference of the abrasive grain layer.
  • the abrasive grain layer includes abrasive grains, mainly diamond, that are bonded to bond (bonding agent) that contains particles of metals such as W, Cu, Ni, Co, Sn, Ag, etc., and serves as a cutting member.
  • the joining layer joins the base plate and the abrasive grain layer together.
  • the joining layer of the cutter disclosed in Patent Literature 1 is made of a complex alloy that contains titanium. This composition increases the joining strength between the base plate and the chip, and as result, improves the cutting performance of the cutter.
  • the cutting performance of a cutter depends on the thickness and shape of the cutting blade, the grain size and content of the cutting abrasive grains, and the wear characteristic and strength characteristic of the bond that immobilizes the cutting abrasive grains.
  • cutter users demand cutters that can cut work materials efficiently in a short time. To meet this demand, cutters that include a thin chip and cut a small area are under development.
  • Patent Literature 1 Unexamined Japanese Patent Application KOKAI Publication No. H10-166275
  • the present invention was made in view of the above circumstances, and an object of the present invention is to provide a cutter having a high cutting performance by including a thin chip that has endurance against breakage and a high joining strength for itself to be joined with a base plate, and a cutting machine including the cutter.
  • Another object of the present invention is to provide a cutter including a chip in which an abrasive grain layer and a joining layer are joined firmly, and a cutting machine including the cutter.
  • a cutter comprises: a base plate; and a cutting member that is fixed on a circumferential surface of the base plate, and cuts a work material by rotating together with the base plate, characterized in that the cutting member comprises: an abrasive grain layer that contains abrasive grains and bits the work material; a joining layer that joins the circumferential surface of the base plate to the abrasive grain layer; and a reinforcing member that is provided over an interior of the joining layer and an interior of the abrasive grain layer to reinforce binding inside the abrasive grain layer and binding inside the joining layer.
  • a cutting machine comprises: a body; a drive source; and a cutter including a base plate that is rotatably driven by the drive source, and a cutting member that is fixed on a circumferential surface of the base plate and cuts a work material, characterized in that the cutting member comprises: an abrasive grain layer that contains abrasive grains and hits the work material; a joining layer that joins the circumferential surface of the base plate to the abrasive grain layer; and a reinforcing member that is arranged over an interior of the joining layer and an interior of the abrasive grain layer to reinforce binding inside the abrasive grain layer and binding inside the joining layer.
  • the cutter and the cutting machine according to the present invention include a reinforcing member that is provided to straddle both the joining layer and the abrasive grain layer. Therefore, the joining layer and the abrasive grain layer are firmly joined and crack development can be stopped. Further, the cutter and the cutting machine according to the present invention can use a thin chip with a smaller cutting resistance, thereby can achieve a high-speed cutting performance.
  • Fig. 1 is a front elevation of a cutting machine according to an embodiment.
  • Fig. 2 is a front elevation of a cutter according to an embodiment.
  • Fig. 3 is a cross sectional view of a chip including a metal sheet according to a first embodiment, taken along a line A-A shown in Fig. 2.
  • Fig. 4 is a cross sectional view of the chip including the metal sheet according to the first embodiment, taken along a line B-B shown in Fig. 3.
  • Fig. 5 is an exemplary cross sectional view for explaining a relationship between exposure pores of the metal sheet and the cutting edge.
  • Fig. 6A is a diagram showing the shape of the metal sheet according to the first embodiment
  • Fig. 6B is a diagram showing the shape of a metal sheet according to a second embodiment.
  • Fig. 7 is a cross sectional view of a chip including a metal mesh according to a third embodiment.
  • Figs. 8A to 8D are cross sectional views of chips including metal meshes according to the third embodiment, taken along the line A-A shown in Fig. 2.
  • Fig. 9 is a diagram showing a cutter that comprises a base plate of a different type from the base plate shown in Fig. 2.
  • a cutter and a cutting machine according to an embodiment of the present invention will be explained below with reference to the attached drawings.
  • a cutting machine 40 according to the present embodiment is used for cutting and grinding a work material 50, which may be concrete, mortar, ceramic, stone materials, etc.
  • the cutting machine 40 is constituted mainly by an electric motor (drive source) 41, a body 42 in which the electric motor 41 is housed, and a cutter 1 supported by the body 42 and connected to an output shaft 44 of the electric motor 41.
  • a handle 46 grabbed by a worker is formed on a portion of the body 42.
  • the body 42 has a switch 48 near the handle 46.
  • the electric motor 41 is supplied with power from an electric outlet, a battery, or the like.
  • the switch 48 is connected to the power supply path leading to an electric outlet, a battery, or the like, and when operated, switches on/off the power supply to the electric motor 41.
  • the cutter 1 having a metal sheet 9 according to a first embodiment will be explained with reference to Fig. 2 to Fig. 4 and Fig. 6A.
  • the cutter 1 is constituted by a disk-like base plate 2 that rotates by motive energy of the electric motor 41 (see Fig. 1), and a chip (cutting member) 4 joined to the outer circumference of the base plate 2.
  • the base plate 2 is made of steel or the like that is heat-treated.
  • An attachment hole 3 that can fit the output shaft 44 of the electric motor 41 is formed in the center of the base plate 2.
  • the chip 4 is constituted by an abrasive grain layer 5, which contains abrasive grains 10 immobilized by bond (bonding agent) to form an annular- shaped layer, a joining layer 6 provided on the inner circumference of the abrasive grain layer 5 and having an annular shape, and a metal sheet (reinforcing member) 9 provided in the thickness- wise direction of the abrasive grain layer 5 and the joining layer 6.
  • the abrasive grain layer 5 is made of hard abrasive grains 10, which are mainly diamond, and bond, which contains metal particles of W, Cu, Ni, Co, Sn, Ag, etc., where the grains and the bond are bonded together and sintered.
  • the joining layer 6 is made of a metal that can suitably be welded to the base plate 2, and welded to the outer circumference of the base plate 2 by laser or the like. A joint 7 is produced as the result of the welding.
  • the abrasive grain layer 5 and the joining layer 6 are joined together and sintered and formed into shape.
  • the metal sheet (reinforcing member) 9 improves the binding forces inside the abrasive grain layer 5 and inside the joining layer 6 respectively.
  • the metal sheet 9 is provided inside the chip 4 over the interior of the joining layer 6 and the interior of the abrasive grain layer 5.
  • the metal sheet 9 produces internal binding forces in the abrasive grain layer 5 and the joining layer 6 respectively to bind together the portions of the abrasive grain layer 5 that are on the opposite sides of the metal sheet 9 and the portions of the joining layer 6 that are on the opposite sides of the metal sheet 9, such that the abrasive grain layer 5 and the joining layer 6 adjoin each other in the radial direction.
  • the metal sheet 9 is a smelted material, and preferably provided near the center of the chip 4 in its thickness-wise direction.
  • a surface of the work material 50 (see Fig. 1) that is to be cut needs to have substantially the same coarseness at their portions that contact the abrasive grain layer 5 and at their portions that contact the metal sheet 9. Hence, as shown in Fig.
  • the metal sheet 9 has exposure pores 15 through which the abrasive grains 10 contained in the abrasive grain layer 5 are exposed on the outer circumferential surface 22.
  • the exposure pores (empty holes) 15 penetrate the metal sheet 9 in the thickness- wise direction, are provided in a plural number in the circumferential direction, and have a flat circular shape.
  • These exposure pores 15 serve to connect each of the grain layers 5 and each of the joining layers 6.
  • the grains 10 e.g. diamonds
  • the process for shaping the chip 4 will be explained.
  • the abrasive grain layer 5 and the joining layer 6 are disposed. Then, the metal sheet 9 is placed on the abrasive grain layer 5 and the joining layer 6. On the metal sheet 9, another abrasive grain layer 5 and another joining layer 6 are disposed to fix the metal layer 9 at the center of the chip 4 in its thickness-wise direction. The metal sheet 9, the grain layer 5 and the joining layer 6 are compressed and then sintered, to obtain the chip 4. After this, the joining layer 6 of the chip 4 is welded to the base plate 2, thereby the cutter 1 is formed.
  • a problem of this formation is that the metal sheet 9 will not have a different cubic volume after being compressed, because it is a smelted material. Hence, the portions of the abrasive grain layer 5 that contact the metal sheet 9 will have an increase in density, but the portions of the abrasive grain layer 5 that contact the exposure pores 15 of the metal sheet 9 will have no increase in the density. Accordingly, the chip 4 is formed to have unevenness in the density and cannot have a sufficient strength.
  • the inventor has paid an attention to this point, and to achieve a uniform cutting performance constantly, has arranged the plurality of exposure pores 15 of the metal sheet 9 such that they cross without fail any arbitrary circumferential line that runs along the circumference of the chip 4 about the central axis of the base plate 2, and has placed the abrasive grains 10 at the cross-points. The details will be described later.
  • the cutter 1 cuts the work material 50 mainly by the abrasive grains 10, which protrude from the outer circumferential surface 22 (the abrasive grains 10a that are exposed outside, shown in Fig. 3 and Fig. 4), cutting the work material 50.
  • the cutter 1 should always have some abrasive grains 10 protruding from the outer circumferential surface 22, which is the cutting edge of the cutter 1.
  • the cutter 1 gradually galls and has its outer diameter reduced as a cutting work goes on. For example, consider a case shown in Fig. 4, where the outer circumferential surface 22 has come to the position of a two-dot chain line 21 by galling. In this case, if there are any abrasive grains 10 that cross the two-dot chain line 21, the outer circumferential surface 22 has got some abrasive grains 10 to protrude therefrom and can serve as a cutting portion.
  • Fig. 5 does not show abrasive grains 10 in the exposure pores 15a, but the abrasive grains 10 are actually provided just the same as in Fig. 4. Further, Fig. 5 shows a case that the exposure pores 15a have the shape of a perfect circle.
  • the outer circumferential surface 22 of the metal sheet 9a gradually galls along with the use of the cutter 1.
  • the outer circumferential surface 22 changes its position to two-dot chain lines 21a, 21b, 21c, ... by galling.
  • the exposure pores 15a are exposed on the outer circumferential surface 22.
  • abrasive grains 10 of the grain layer 5 that exist inside the exposure pores 15a are exposed and serve the cutting function.
  • the metal sheet 9 has exposure pores 15 that are so distributed as to be always exposed on the outer circumferential surface 22 until the final use position is reached.
  • the shape of metal sheets 9 and 9b that have exposure pores 15 and 15b that are provided to cross without fail an arbitrary circumferential line that runs along the circumference of the chip 4 about the central axis of the base plate 2 will be explained with reference to Fig. 6A.
  • Fig. 6A is a diagram that shows the metal sheet 9 shown in Fig. 4 in enlargement.
  • the metal sheet 9 has flat-circular exposure pores 15 each formed of two semicircles combined by a straight line.
  • the exposure pores 15 are staggered on the circumferential lines.
  • the length of the longer diameter of one exposure pore 15 is "L"
  • the length over which this exposure pore 15 overlaps the longer diameter of an exposure pore 15 that adjoins this exposure pore 15 is "Ll”.
  • the overlapping length Ll accounts for 25 to 35% of the length L of the longer diameter of the one exposure pore 15. If this rate lowers to less than 25%, a circumferential surface having few exposure pores 15 emerges, and few abrasive grains 10 are exposed from the outer circumferential surface 22, which reduces the cutting performance of the cutter 1.
  • the metal sheet 9b according to a second embodiment has oval exposure pores 15b as shown in Fig. 6B.
  • the exposure pores 15b are distributed on the circumferential lines running about the center of the base plate 2, in a so-called staggered pattern in which the exposure pores 15b meet each other only by about their halves, in a similar manner to the distribution shown in Fig. 6A.
  • the exposure pores 15 and 15b are distributed in a staggered pattern. That is, the exposure pores 15 and 15b formed in the metal sheets 9 and 9b cross without fail an arbitrary circumferential line that runs along the circumference of the chip 4 about the attachment hole 3.
  • an arbitrary circumferential line that runs along the circumference of the chip 4 has any portion at which the circumferential line crosses no exposure pore 15 or 15b, no abrasive grains 10 (see Fig. 4) are exposed from such a portion to lower the cutting performance and fluctuate the cutting speed.
  • adjoining exposure pores 15 or 15b be shaped and distributed to overlap each other on one circumferential line that runs about the attachment hole 3.
  • the exposure pores 15 and 15b have a flat-circular shape and an oval shape respectively.
  • the exposure pores are not limited to these shapes, and may have shapes of various types of circles or a squared shape, or any ones of these shapes in combination.
  • the shape may be determined based on how easy it is to form the shape, or an arbitrary shape that is produced by a shaping method that utilizes corrosion may be used.
  • the exposure pores 15 may have a squared shape, but it is desired that the corners of the squared shape be given a curvature in order not to tear the metal sheet 9 when applied a pressure of a die or a mold for shaping or sintering.
  • the metal sheets 9 and 9b contain Cu as the main component, which accounts for 95% or higher of the whole content, and any of Sn, Ni, P, Mn, and Fe or instead any of them plus an impurity element, which account(s) for 5% or lower of the whole content.
  • a cutter 1 that is mainly used for machining cement primarily uses diamond as the abrasive grains 10.
  • the bond in the chip 4 for bonding such abrasive grains 10 contains mixture particles of metals such as Ni, Cu, Fe, W, Sn, Ag, etc. and is sintered together with the abrasive grains 10 at a temperature of 700 to 900 degrees C.
  • Cu or any Cu alloy mentioned above is the most suitable as the metal to be diffusion-bonded to these metals under such conditions, and such an alloy needs to have a composition that does not cause the alloy to melt. It is possible to achieve a similar effect with a steel sheet mainly made of Fe, which is fully annealed and plated. In this case, it is desired that the plated material peel little and have little unevenness. [0029]
  • the thickness of the metal sheets 9 and 9b is 15 to 30% of the thickness of the chip 4.
  • the material properties of the bond component of the abrasive grain layer 5 become dominant and it becomes harder for the metal sheets 9 and 9b to demonstrate their effect, and because the less effective metal sheets 9 and 9b weaken the binding strength in the bond in the abrasive grain layer 5 to make the layer 5 liable to tear or cannot deter crack development, in a case where, for example, the chip 4 is formed and sintered into a different shape.
  • the reason for which the thickness of the metal sheets 9 and 9b is 30% or lower of the thickness of the chip 4 is to suppress the above-described density difference between the portions of the abrasive grain layer 5 that contact the metal sheets 9 and 9b and the portions of the abrasive grain layer 5 that contact the exposure pores 15 and 15b.
  • Another reason is that if Cu layer, which is the main component of the metal sheets 9 and 9b, emerges in a greater amount to the outer circumferential surface 22, it generates heat by friction with the work material 50 to cause the metal sheets 9 and 9b to plastically flow and coat nearby abrasive grains 10, which worsens the cutting ability of the cutter 1. This phenomenon tends to occur in a cutting work that is particularly hard and heavy.
  • the rate at which the exposure pores 15 and 15b cross a circumferential line that runs along the circumference of the chip 4 about the attachment hole 3 of the base plate 2 (hereinafter, this rate will be referred to as porosity) is 35 to 80% of the circumferential line.
  • the porosity is set to 35% or higher in order to securely expose the abrasive grains 10 from the outer circumferential surface 22 that serves as the cutting edge.
  • the abrasive grains 10 in the abrasive grain layer 5 are exposed in the exposure pores 15 and 15b while the chip 4 is shaped.
  • a region of the metal sheets 9 and 9b that adjoins the outer circumferential surface 22 of the chip 4 best contributes to cutting.
  • the porosity is lower than 35%, the exposure pores 15 and 15b can only have a small area to let the abrasive grains 10 in. As a result, fewer abrasive grains 10 are exposed from the outer circumferential surface 22 and the cutting performance of the chip 4 is reduced.
  • the porosity is over 80%, space occupation of the metal sheets 9 and 9b is very small. Then, if a crack occurs in the bond in the abrasive grain layer 5, the metal sheets 9 and 9b can hardly stop the development of the crack. Further, the metal sheets 9 and 9b have a reduced strength and are liable to tear during shaping and sintering.
  • the probability that the chip may break during shaping is high with such a highly porous metal sheet, which is not desirable.
  • An appropriate range of the porosity varies according to the material and hardness of the metal sheets 9 and 9b and the work material 50 machined.
  • the cutter 1 is for cutting concrete and the chip 4 of the cutter 1 includes the metal sheet 9b, whose thickness is 0.2 to 0.3 mm and whose main component is Cu, and which includes oval exposure pores 15b
  • the appropriate range of the porosity was 48 to 72%.
  • a chip 4 whose cross sectional shape is not uniform, and which includes a metal sheet 9 or 9b made of an Fe-based steel material, tends to get the metal sheet 9 or 9b detached from the bond in the chip 4 due to a spring back of the metal sheet 9 or 9b during shaping of the chip 4.
  • this chip 4 cannot have intermetallic diffusion occur between the metals contained therein during sintering of the chip 4 and thus cannot have a strong cohesiveness, and as a result cannot have a sufficient strength.
  • a cutter includes a base plate 2 that is partially surrounded by the layers of the chip 4 and as the base plate 2 is thicker.
  • the inventor also discovered that surface treatment such as plating is required as a measure to remedy these phenomena, which would lead to an increase of the cost.
  • surface treatment such as plating is required as a measure to remedy these phenomena, which would lead to an increase of the cost.
  • the density of the part of the grain layer 5 in the neighborhood of the exposure pores 15 is not likely to be high as compared to the part that abuts to the metal sheet 9, 9. Therefore, a difference of density is caused between the part on which the exposure pores 15 are formed and the part on which the exposure pores are not formed. This results in the difficulty to obtain a sufficient thickness of the chip 4.
  • the metal sheets 9 and 9b are given the alloy composition that contains Cu as the main material, which accounts for 95% or higher of the whole content, and any of Sn, Ni, P, Mn, and Fe or instead any of them plus an impurity element, which account(s) for 5% or lower of the whole content.
  • the metal sheets 9 and 9b having such a composition have a rich elasticity and easily deform, and can therefore be prevented from being detached from the abrasive grain layers 5 and the joining layers 6 due to a spring back of the metal sheet 9 or 9b during shaping of the chip 4.
  • the metal sheets 9 and 9b having such a composition can be firmly integrated with the bond of the chip 4 when they are sintered with the chip 4 that has been shaped. Furthermore, the metal sheets 9 and 9b can stop development of a crack, if it occurs. Still further, in a case where the chip 4 needs to be formed into a shape having a non-uniform cross sectional shape with hard abrasive grains 10 existing in the metal sheet 9 or 9b, the metal sheet 9 or 9b having such a composition can relatively easily deform to conform to the non-uniform cross sectional shape of the chip 4. [0034] The inclusion of metals such as Sn, etc.
  • a chip 4 having a thickness that is smaller than conventional by 30% can be manufactured. And it was confirmed that the chip having this thickness can increase the cutting speed by 50 to 80%.
  • the metal sheets 9 and 9b according to the above embodiment integrally join the chip 4 including the abrasive grain layer 5 and the joining layer 6 to the base plate 2 and can stop development of a crack that might occur in the chip 4.
  • the metal sheets 9 and 9b which are formed to have their exposure pores 15 and 15b cross every arbitrary circumferential line that runs along the circumference of the chip 4 about the center of the base plate 2, can have the abrasive grains 10 exist on the outer circumferential surface 22, which is the cutting edge, all the time through year-to-year uses for cutting works. Hence, the cutter 1 can sustain its cutting performance. [0037]
  • the metal meshes 19 are made of a netted metal material, and cover the surface of the chip 4 or exist right under the surface of the chip 4 or inside the chip 4.
  • the net of the metal meshes 19 serves the same effect as that of the exposure pores 15 and 15b of the metal sheets 9 and 9b.
  • the netted metal material is provided at substantially the center of the chip 4 in its thickness- wise direction, and has a size of 5 to 15 mesh per inch, with a wire diameter of 0.1 to 0.5 mm.
  • the metal mesh 19a shown in Fig. 8 A extends from the joining layer 6 to the end of the abrasive grain layer 5 in the radial direction of the cutter 1, and is arranged substantially all across the chip 4.
  • the metal mesh 19b shown in Fig. 8B does not extend to the end of the abrasive grain layer 5 in the radial direction unlike the metal mesh 19a shown in Fig. 8 A, and is arranged to about 1/2 to 2/3 of the abrasive grain layer 5 from the inner circumferential side. Even with this arrangement, the metal mesh 19b crosses the joint surface between the abrasive grain layer 5 and the joining layer 6 likewise the metal mesh 19a, and can serve to improve their joining strength. In Fig. 8B, the metal mesh 19b is not joined to the base plate 2, but can sufficiently serve the effect of reinforcing the abrasive grain layer 5 and the joining layer 6. [0040]
  • the metal mesh 19c shown in Fig. 8 C is formed thin into a U-letter shape and arranged. The metal mesh 19c is provided near the center of the chip 4 in its thickness-wise direction.
  • the metal mesh 19d shown in Fig. 8D is formed thick into a U-letter shape and arranged more peripherally in the thickness-wise direction of the chip 4. With this arrangement, the chip can have a significantly high rigidity and become suitable for cutting an especially hard work material 50.
  • the third embodiment explained with reference to Figs. 8 has shown the examples of the metal meshes 19a to 19d, which may be applied in place of the metal sheets 9 and 9b.
  • the metal meshes 19c and 19d are U-letter shaped, but two or more metal meshes 19a or 19b shown in Fig. 8A or 8B may be arranged in the thickness- wise direction with a distance between them.
  • Such arrangement of the metal mesh 19 can suppress scattering of debris of the chip 4 in case the chip 4 is broken by a shock during cutting.
  • the use of the metal mesh 19 does not spoil the autogenous action of the abrasive grains 10 made of diamond, etc., i.e., the metal mesh 19 galls together with the abrasive grain layer 5 and does not contribute to reducing the cutting performance.
  • the range across which the metal mesh 19 is arranged includes the joining layer 6 that contains no diamond or abrasive grains 10, which can improve the joining strength between the abrasive grain layer 5 and the joining layer 6 and can prevent a breakage of the abrasive grain layer 5 and the joining layer 6 at their boundary.
  • the joining layer 6 contains the metal mesh 19 deep to its interface with the base plate 2 where they are welded, which means that the base plate 2 is also welded with the metal mesh 19 and a joining strength can be ensured between the chip 4 and the base plate 2.
  • the metal mesh 19 explained above according to the third embodiment of the present invention can improve the strength of the chip 4 and the joining strength between the chip 4 and the base plate 2. This enables the chip 4 to be formed thin. As a result, fast and precise cutting can be realized and scattering of debris of the chip 4 can be suppressed if the chip 4 is broken.
  • the cutter 1 and the cutting machine 40 include a reinforcing member in the joining layer and the abrasive grain layer, such that the reinforcing member extends across the layers in the radial direction, and can therefore have a firm joint between the base plate and the chip formed of the joining layer and the abrasive grain layer, and can stop development of a crack that might occur in the chip.
  • the cutter 1 according to the embodiments described above can use a thin chip, which reduces the cutting resistance to enable the cutter 1 to perform cutting at a high speed.
  • the reinforcing member which is made of a metal sheet having a plurality of exposure pores, does not influence the distribution of abrasive grains made of diamond, etc. in the abrasive grain layer, and can firmly join the joining layer with the abrasive grain layer, and the joining layer with the base plate.
  • the exposure pores are arranged to cross without fail an arbitrary circumferential line that runs along the chip circumference about the center of the base plate. Therefore, the metal sheet can have the abrasive grains exist at any position thereof via the exposure pores. Hence, the cutting performance can be maintained over the entire thickness of the chip and stable cutting can be performed.
  • the metal sheet is made of Cu, or an alloy whose main component is Cu, and has a thickness that is 15 to 30% of the thickness of the abrasive grain layer.
  • a percentage of 35 to 80% is line portions at which the arbitrary circumferential line is crossed by the exposure pores. Such a rate does not influence the distribution of the abrasive grains made of diamond, etc. in the abrasive grain layer or the cutting performance of the cutter, either.
  • the pores can have shapes of various types of circles or a squared shape, or any ones of these shapes in combination. Therefore, the reinforcing member can be easily manufactured by punching or the like.
  • the reinforcing member may also be a netted metal material, with which a cutter with no less cutting performance can be realized, because the abrasive grains made of diamond, etc. do not lose the autogenous action because of the netted metal material since the netted metal material also galls together with the bond.
  • the netted metal material has a size of 5 to 15 mesh per inch and a wire diameter of 0.1 to 0.5 mm. Therefore, the material can effectively suppress scattering of debris of the chip if the chip breaks due to a shock.
  • Since the reinforcing member is joined to the base plate, a strong joint can be formed between the joining layer and the base plate and between the joining layer and the abrasive grain layer via the reinforcing member.
  • the base plate and the reinforcing member are joined by laser welding, which helps improve the joining strength between the chip and the base plate.
  • the present invention has been explained based on its embodiments, the present invention is not limited to the embodiments described above, but can be modified in various manners within the scope of the spirit of the invention.
  • the embodiments have been explained with a segmented cutter, but the present invention can likewise be applied to a rim cutter that has a continuous cutting blade all along the outer circumference.
  • the present invention can also likewise be applied to a cutter 30 shown in Fig. 9, which, unlike the configuration shown in Fig. 2, has a base plate 2a of another segmentation tape, having a slit 17 between the segments.
  • the chip 4 is joined to the base plate 2 by laser welding, but the joining manner is not limited to welding and other joining manners such as bonding may be employed.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Polishing Bodies And Polishing Tools (AREA)
  • Processing Of Stones Or Stones Resemblance Materials (AREA)
PCT/JP2009/055542 2008-03-14 2009-03-13 Cutter and cutting machine WO2009113734A1 (en)

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Cited By (1)

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CN112518580A (zh) * 2020-11-20 2021-03-19 杭州电子科技大学 一种抛光对磨硬质金属材料的木刀具及其装配方法

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Publication number Priority date Publication date Assignee Title
JP5840270B2 (ja) * 2014-08-27 2016-01-06 株式会社東京精密 切断ブレード
JP6668178B2 (ja) * 2015-06-23 2020-03-18 株式会社ノリタケカンパニーリミテド セグメントチップ

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