DE2411859A1 - GRINDING WHEEL - Google Patents

Description

The invention relates to grinding wheels with a middle Core for diamond soles dry grinding at relative high temperatures and loads, the inventive Cores represent a combination of metal particles in resin and have high thermal conductivity, high heat resistance and make it easy to dress.

Cores for diamond discs for dry grinding have so far mainly contained a large proportion of aluminum powder, a medium proportion of plastic and a small proportion of graphite powder, the latter to facilitate the Dressing on the core is used.

From the IJS-PS 2 150 886 is a core or assembly part for Diamond soles known, which is a shaped body involves relatively large proportions of aluminum powder and relatively small proportions of synthetic resin. With these well-known

409838/0846

Products, no graphite was provided to facilitate the dressing of the mounting part, since its shape requires dressing made not necessary.

From GB-PS 1 099 703 a core for diamond and other grinding wheels is known, which is composed of a relatively large amount of copper powder and a relatively small amount of synthetic resin, also without graphite for a possible dressing, as the shape of the core made dressing unnecessary.

US Pat. No. 2,243,105 can be a combination of one Abrasive part j shaped to remove a metal support, wherein the abrasive part of copper powder, tin powder and a resinous one Binder comprised and mixed with diamond powder. However, no combination of metals and resin can be found, without abrasive grain being available for the production of cores for grinding wheels.

The invention now relates to cores for grinding wheels, which are made up of up to 90 vol .- $ aluminum and / or copper powder, so that the core has a relatively high thermal conductivity and down to 5 vol .- ^ resin as a binder and 2 to 35 YoI .- ^ tin and / _o the tin alloy as an additional binder. This achieves relatively high strength at relatively high temperatures in the core and also the possibility of dressing. Finally, 2 to 10 vol .- ^ solid lubricants are provided to improve the dressability in the form of graphite, hexagonal boron nitride and / or polytetrafluoroethylene.

The grinding wheels according to the invention are characterized by high thermal conductivity and relatively high strength relatively high temperature and good dressability of the core. The cores according to the invention increase the performance of grinding wheels while reducing power consumption.

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. . In the accompanying Pig. a cup grinding wheel with a core according to the invention is shown in side view. The Hopf grinding wheel 10 comprises the core 12 which a Diamantsohleifteil 14 is provided on the circumference. ^ he Core has a conical side wall 16 and a flat rear wall 18 with a central bore 22, with the help of which the grinding wheel can be fixed to the drive shaft. 24 denotes the area of the side wall 16 in the immediate vicinity of the diamond cutting part 14, which from time to time with progressive wear of the diamond part must be dressed to the appropriate distance between core 12 and the workpiece to be processed. The easiest dressing is done with a manual or assembled Dressing tool, less easy with a manual a Dressing stone.

The core according to the invention should be composed of 40 to 90 volume aluminum and / or copper powder, 35 to 2 V0I.-56 tin and / or tin alloy and 30 to 5 vol .- $ plastic powder, with still 0 to 15 V0I.-7S of a solid lubricant may be in the form of graphite, hexagonal boron nitride and / or polytetrafluoroethylene. The preferred proportions depend on the manufacturing method of the grinding wheel. There are two basic methods for doing this.

According to the first method, the core is first formed and then the material mixture for the grinding part into one Circumferential design of the core introduced and molded around the core. For this purpose, a corresponding core mold is filled with a dry mixture of the metal components, the resin and the solid lubricant, the core is cold under a pressure of about

ρ
530 kg / cm pressed, demolded and incorporated the corresponding recess in the wall 16 for the sole part 14 on the circumference.

The grinding part 14 can, for example, consist of a mixture consist of diamond and resin as a binder, which the

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The cavity is filled when the core is returned to the porm. UNJ to achieve an integral connection between the grinding member and core, the abrasive part 20 rain at 16O ⁰ C under a pressure of 70-420 kg / ca, ifteils, hot-pressed, depending on the size and composition of the sole. "

After the removal is 12 to 38 h post-cured at 160 to 22O ⁰ C, depending on the temperature and time are fixed in the usual manner from the area of application of the grinding wheel.

A modification is that first the core at 16O ⁰ C for 20 minutes under a pressure of 280 kg / cm hot pressed, aisgeformt incorporated the recesses for the sliding parts 14 in the wall 16, the core re-inserted into the IORM, the remaining Filled cavity with the mass for the grinding part and this is then - as described above - shaped and hardened, on the assumption that the grinding part here also consists of a mixture of abrasive grain and resin.

The composition for the core material for manufacture According to the first method, there is preferably 58 to 80 YoI .- $ aluminum and / or copper powder, 16 to 8 YoI .- $ Tin and / or tin alloy, 16 to 8 yol .- $ resin and 2 to 10 YoI .- # solid lubricant.

If no solid lubricant is used and the mass is to be processed according to the first method, then contains they preferably 84 to 68 vol.jS aluminum and / or copper powder, 8 to 16 vol .- $ tin and / or tin alloy, 8 to 16 YoI .- # resin, this modified composition is not quite as desirable as the above as it is a little more difficult is to be trained.

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2Λ11859

For the first processing oil it is obvious the optimal composition 66 YoI.-JiS aluminum and / or Copper powder, 12 vol .- ^ tin and / or tin alloy, 13.3 Vol .- # resin, 0.7 vol .-? £ calf, 4 YoI .- # graphite and 4 vol .- # Polytetrafluoroethylene. The modified cash register then contains 76 vol .- $ aluminum and / or copper powder, 12 vol .- # tin and / or tin alloy and 12 vol-56 resin,

In the second method of manufacturing the grinding wheel, the ring-shaped grinding part with hard-bonded diamond particles is first molded and completely hardened. Then it is placed in the bottom of the core mold, a coating of phenol or epoxy adhesive is applied to the intermediate surface against the grain and then the mold is filled with the dry mixture of metal and resin particles and lubricant. For the integral connection of the annular abrasive part ~ oit the core is this hot pressed at 16Q ⁰ CJ under a pressure of 280 kg / cm * "during 20 min.

A modification of this second method is that the ring-shaped abrasive part is made of resin-bonded diamond particles first molded, but not yet complete is hardened, whereupon the core material around the ring is shaped. Then do the molding, they both become post-cured as mentioned in the first method.

The second processing method contains the core material preferably 70 "to 54 vol .- ^ aluminum and / or Copper powder, 8 to 16 V0I.-3S tin or tin alloy, 14 up to 22 volume # of resin and 2 to 10% by volume of solid lubricant.

In the modified embodiment without lubricant The proportion of aluminum and / or copper powder is then 74 to 58 vol .- $ in addition to 8 to 16 tol.-96 tin and / or tin alloy and 18 to 26 V0I.-9 & Harz. The resulting

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Grinding wheels are less easy to dress.

The optimal modified composition of the core mass for the sv / eite method is 66 vol .- $ aluminum and / or Copper Powder, 12 V0I.-5S Tin or Tin Alloy-and 22 YoI .- ^ Resin.

If one of the above production methods of the invention The core is brought together with the grinding part before its hardening, so there is the resinous core material During the curing process, volatile gases are released, which lead to cracking and swelling of the core. To avoid this, up to 15 wt .- / * of the resin is used in the core material lime, that which forms during the curing of the resin absorbs volatile gases.

The broadest composition of the core material according to the above statements comprises up to 30 % of the core of resin, the equivalent core proportion is up to 1.9 "vol .- ^ of the grain of the resin-replacing lime. The first method contains the core Material up to 16% by volume of the core of resin and the equivalent volume of lime is up to 1% of the core to the lime replacing the resin. For the second method the values are 26% of resin or up to 1.6 vol .- $ £ of the core to the resin-replacing lime.

The optimum composition of the core material for the first processing method is 12 vol .- $ des Core resin and 0.6% by volume resin-replacing lime.

It was found that the grain size of the Meiallomponents is not critical to the core material. Preferably, however, no powders over 1 mm are ended. The maximum particle size the resin should be on the order of 0.5 mm or less. Satisfactory results are achieved

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2Λ11859

with aluminum particles of a maximum of 32 / 4ίβ, tin particles "the same Size range and resin particles of 76 or less

Since aluminum and copper have essentially the same heat -have conductivity, they can replace each other or are used in a mixture. Because copper is three times heavier than Aluminum, a core with copper instead of aluminum has a considerably greater inertia, which is useful in order to achieve this the running speed of the grinding wheel can easily be kept constant with external power input. ·

vBy qde.iL>

A tin alloy can be used in place of the tin, provided that it shows the tin's strength and dressability. To meet this requirement, it should have a melting point of up to 35O ⁰ C. Examples of such tin alloys are 75 i <> tin, 25% zinc or tin 60 fo, fo 30 zinc and 10% cadmium.

The presence of a certain volume of solid lubricant is not absolutely necessary, however, the core material shows less good dressability without lubricant

Whether the dressability of the core material according to the invention can be increased by increasing the volume of tin or Tin alloy at the expense of the volume fraction of aluminum and / or copper powder, so there is an increase in dressability relatively undesirable by increasing the proportion of tin, since this large volume of tin or tin alloy becomes relatively undesirable Working conditions such as large chips flying on the worker during core dressing. The relatively high strength at relatively high temperatures of the core material according to the invention compared to conventional core material is shown in the following table emerge:

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- ο -

Core-
material VoI
of Mixture Flexural strength at
(psi) kg / cm2 150 ⁰ C RT 100 ° 0 comparison
(7 i ° porosity) (4th 000) aluminum 58 , 1 $> (12 400) (9 700) 280 graphite 15th , $ 8> 870 680 Phenolic resin 26th • 1 JO

Erf. according to I.

(10 ^ porosity)

Aluminum 68 fo (11,000) (8,000) (6,500) tin 12 g 770 560 455

Phenolic resin 12 $ graphite 4 # polytetrafluoroethylene

Erf. according to I mo
diffused
(12 5 ^ porosity) 76 pounds aluminum $ 12> tin 12 ύ Phenolic resin

(12 100) (11 800) (10 700) 850 830 750

Erf. according to II

modified

(12 9δ porosity)

Aluminum $ 66 (12,300) (11,000) (10,800) Tin 12 % 860 770 760

Phenolic resin 22%

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The thermal conductivity measurements showed that a core manufactured according to the modified 1 * method leads to a conductivity that is 78 $ better than known cores. This improves the life of the grinding wheel by reducing the temperature on the grinding surface. In addition, such a grinding wheel according to the invention requires about 10 $ less drive energy than usual. The G-Y ratio is about 10 fo greater (ratio of the metal removed to the grinding wheel wear).

Instead of the above phenolic resin, other thermosetting resins can be used, such as alkyd, melamine formaldehyde, polyester,! Έ ^ οχγγ silicone resins and infusible polyimide resins. The type of binder used is not critical. In principle, a conventional thermoplastic resin can also be used if a relatively high strength of the core at a relatively high temperature is not critical. Analogously , in addition to diamond, any other abrasive, such as cubic boron nitride, can also be present in the grinding part. The abrasive part in connection with the core according to the invention can contain diamond or other abrasive grain, optionally mixed with metal powders, as a binder and is processed with the core material to form the grinding wheel according to the second method described above. But it is also possible to use the first method with cold pressing of the core. Finally, a glassy bond of the diamond

part ^

t echen ^
or abrasives / with fixation of the abrasive part on the core according to the second method of grinding wheel manufacture.

Claims

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Claims (12)

P a tentan claims 1. ) Soleplate, composed of a core and a grinding part extending over the circumference, the core consisting of resin-bonded metal powder, characterized in that it contains 90 to 40% aluminum and / or copper powder, 2 to 35% * - Contains tin and / or tin alloy with a maximum temperature of 35O ⁰ C and 5 to 30 vol .-% resin. 2. Grinding wheel according to Claim 1, characterized in that up to 15 wt .- / S of the resin in the core are replaced by lime. 3 · Grinding wheel according to claim 1 or 2 _f thereby characterized in that the core 84 to 68 Aluminum and / or copper powder and 8 to 16 vol .- $ tin and / or tin alloy and 8 to 16 volume # of resin. 4. Grinding wheel according to claim 3 »characterized in that the core of the resin is a thermosetting one. 5. Grinding wheel according to claim 3 or 4, characterized in that up to 1 vol .- $ 6 in the core the resin is replaced by lime » 6. Grinding wheel according to claim 1, characterized in that in the core 76 vol .-? & Aluminum and / or copper powder, 12% tin and / or tin alloy and 12 YoI .- # resin are included. 409838/084 7. Grinding wheel according to claim 6, characterized in that the resin is a phenolic resin at the core is. 8. Grinding wheel according to claim 6, characterized that in the core 0.4% by volume of resin has been replaced by lime. 9. A grinding wheel according to claim 1, characterized in that the core bj 74, s 58 vol .- $ aluminum and / or copper powder, 8 to 16 vol .- $ tin and / or tin alloy and 18 to 26 parts by volume resin fo , preferably contains a thermosetting resin and optionally up to 1% by volume of the resin is replaced by lime. 10. Grinding wheel according to claim 1, characterized in that the core is 66 vol .- $ aluminum and / or Copper powder, 12 volumes of tin and / or tin alloy and 22 volumes of resin, in particular contains a phenolic resin. 11. Grinding wheel according to claim 1, characterized in that the core is up to 15 V0I.-5 & solid Contains lubricants in the form of graphite, hexagonal boron nitride and / or polytetrafluoroethylene. 12. Grinding wheel according to claim 11, characterized that in the core up to 15 wt .- $ of the resin is replaced by lime. 13 · Grinding wheel according to claim 11, characterized in that in the core of 80 to 58 vol .- # aluminum and / or copper powder, 8 to 16 parts by volume jS tin and / or tin alloy, 8 to 16 YoI.-fo resin and 2 up to 10 vol. 56 solid lubricant are contained, the resin preferably being a thermosetting agent and optionally up to 1 vol.% of the resin having been replaced by lime. 409838/0846 - 3 - 2Λ11859 14 · Roof grinding wheel according to claim 11, characterized in that the core contains 66 vol .- $ aluminum and / or copper powder, 12 YoI .- ^ tin and / or tin alloy ¹ ^ * tKaXl c, 4-, Vol.-C / tion, 14 vol .- # resin, up to 0.7 "vol .- $ yu-raphit and 4 vol .- J polytetrafluoroethylene are included, the resin preferably being phenolic and optionally up to 0.6 vol . -fo of the resin have been replaced by lime. 15 · grinding wheel according to claim 11, characterized in that in the core _f 70-54 vol .- ^ aluminum and / or copper powder, 8 to 16 vol .- $ tin and / or tin alloy, 14 to 22 YoI.-fo resin and 2 up to 10% by volume of solid lubricant are included, the resin preferably being a thermosetting one and optionally up to 1% by volume of the resin being replaced by lime. 409838/0846