KR20030083247A - Grinding whet stone and production method of it - Google Patents

Abstract

PURPOSE: A grinding stone and a manufacturing method thereof are provided to improve stability against impact at high speed by lowering the stress on the tangent line with centrifugal force in rotating by forming a reinforcing part with silicon carbide abrasive. CONSTITUTION: A sheet of glass fiber is placed in a grinding stone(1), and an iron ring is recessed in a bore(3) of the grinding stone. A reinforcing part(5) is formed in the bore of the grinding stone to improve impact resistance and rigidity against stress in grinding with rotating. A grinding part(6) of the grinding stone is formed by mixing fused alumina abrasive or fused zirconia abrasive and silicon carbide abrasive at the rate of one to one. The reinforcing part of the grinding stone is formed by mixing a glass chop of 1-3 wt% coated by thermosetting resin and silicon carbide abrasive of 97-99wt%. The reinforcing part is formed by using an auxiliary ring for forming the reinforcing part, and the grinding part is formed around the reinforcing part.

Description

Grinding whet stone and production method of it

The present invention relates to a large grinding wheel used in the pretreatment process of the casting process and a manufacturing method thereof, and more specifically, to the inside of the grinding wheel to reduce the tangential direction by the centrifugal force during rotation of the grinding wheel. use portion fused alumina constituting the (grinding _{part) (Fused alumina (Al 2 O} 3)) based abrasive grains (3.96g / cm ³⁾ of silicon carbide is lower than the specific gravity (silicon carbide (SiC)) based abrasive grains (3.22g / cm ³ ) To provide a grinding wheel that can be used at high speed (main speed 4000m / min or more) by forming a reinforcement part so that the rotational breakdown strength can be improved by centrifugal force during rotation.

In general, in the case of a large grinding wheel used in the pretreatment process of the casting process, as shown in FIG. 1, the grinding wheel 20 is formed of molten alumina abrasive grains 21 without reinforcing parts, and glass fibers (Glass Fiber) on both sides ( 22) by attaching to prevent the grinding wheel 20 to be damaged, but the conventional grinding wheel 20 has a problem that the impact strength and rotational breakdown strength falls.

In order to supplement this, as shown in FIG. 2, when forming the grinding wheel 20 with the molten alumina abrasive grains 21, at least one glass fiber 22 is placed inside the grinding wheel 20 and the inner diameter of the center ( On the 20a) side, the steel ring 23 is recessed to obtain a considerable effect in impact strength or breaking strength, but the grinding wheel 20 receives the tangential stress due to the centrifugal force when the main circumferential speed, that is, the rotation is rapid. There was a problem that the inside and outside of the same is easily broken, the situation is urgently required to develop a grinding wheel of a novel configuration that can solve this problem.

In the present invention, as a research and development to eliminate the problems of the conventional large grinding wheel as described above,

In the present invention, the molten alumina (Fused Alumina (Al ₂ O ₃ )) abrasive grains or fused zirconia (Fuesd Zirconia (AZ)) and silicon carbide abrasive grains to reduce the tangential stress due to the centrifugal force during the rotation of the grinding wheel The present invention provides a grinding wheel and a method for manufacturing the same, which can be used safely and at high speed by forming a reinforcing part on the inner side of the center of the grindstone using a raw material having a lower specific gravity than the grinding part composed of the blended compound. The present invention has been completed with a problem.

1 and 2 is a conventional grinding wheel cross section configuration diagram

3 is a plan view of a grinding wheel showing an embodiment of the present invention

4 is a cross-sectional configuration of the present invention

Figure 5 is a cross-sectional view showing another embodiment of the present invention

Figure 6 is a process chart for manufacturing the grinding wheel of Figure 3 according to the invention

7 is a process chart for manufacturing the grinding wheel of Figure 4 according to the present invention

8 is a graph comparing the strength of the reinforcing part of the grinding wheel and the conventional grinding wheel according to the present invention

☞ Explanation of symbols used in the main part of the drawing ☜

1: grinding wheel 2: glass fiber

3: inner diameter 4: steel ring

5: reinforcing part 5a: compound

6: grinding part 7: mold

8: Auxiliary ring for forming reinforcement part

Figure 3 is a cross-sectional plan view showing a preferred embodiment of the present invention, Figure 4 is a cross-sectional view of the configuration of the present invention, will be described below the configuration of the present invention.

In the present invention, when forming a grinding wheel (1) composed of a blend of fused alumina (Al ₂ O ₃ ) -based abrasive grains or Fusd Zirconia (AZ) abrasive grains and silicon carbide-based abrasive grains. In the grinding wheel (1), at least one glass fiber (2) is placed inside the inner diameter (3) side of the grinding wheel (1) in which the iron ring (4) is recessed, the rotation to the inner diameter (3) side The reinforcement part 5 is formed to improve the impact resistance and the breaking strength due to the stress generated during grinding.

The reinforcing portion 5 is a silicon carbide (Silicone Carbide) having a specific gravity smaller than the blend of the molten alumina-based abrasive grains or the molten zirconia-based abrasive grains and the silicon carbide-based abrasive grains constituting the grinding portion 6 of the grinding wheel 1 SiC)) is composed of a compound (5a) compounded by mixing 1 ~ 3wt% of the glass chip (Glass Chop) coated with a thermosetting resin to increase the bonding strength with the abrasive grains 97 ~ 99wt%.

The glass fiber 2 may be used in combination with the reinforcement part 5 as shown in FIG. 5 or in combination with the grinding part 6 as shown in FIG. 4, and the inner diameter 3 side. In the case of the iron ring (4) which is recessed in, one or two or more may be used as shown.

Hereinafter, the manufacturing method for manufacturing the grinding wheel 1 of the present invention based on the accompanying drawings.

FIG. 6 shows a process diagram of a method of manufacturing the grinding wheel 1 shown in FIG. 4.

In manufacturing the grinding wheel 1, the auxiliary ring for forming the reinforcement part 8 is placed in the center of the mold 7 for forming the normal grinding wheel 1, as shown, and the auxiliary ring for forming the reinforcing part 8 ) Inside the silicon carbide-based abrasive grains, 97 ~ 99wt%, 1 ~ 3wt% of glass chips coated with a thermosetting resin were added, and the mixture 5a, glass fiber 2, and iron ring 4 were sequentially added and pressed. And the alumina-based abrasive grains or the molten zirconia-based abrasive grains and silicon carbide, which are the materials constituting the grinding portion 6 outside the reinforcement portion 5 formed by pressing and separating the auxiliary ring 8 for forming the reinforcement portion. Grinding stone (1) is completed through the process of pressing and then adding a compound containing a 1: 1 ratio of system abrasive grains.

In order to mold the reinforcing part 5, the compound 5a containing the glass chips coated with the thermosetting resin in the silicon carbide abrasive grains is divided into four equal parts, and then one quarter of the compound 5a is molded into the reinforcing part 5a. The glass fiber 2 is placed in the auxiliary ring 8 inside, and 1/4 of the compound 5a is introduced into the upper portion of the auxiliary ring 8, and the iron ring 4 is inserted therein, and then in the compound 5a. Put 1/4 and place the glass fiber (2) and then the first pressing in the state of the remaining compound (5a), the first pressing is pressurized by 20-30% of the second pressing It is preferable to.

7 shows a process diagram of a method of manufacturing the grinding wheel 1 shown in FIG.

In the manufacture of the grinding wheel (1), the auxiliary ring for forming the reinforcement part 8 is placed in the center of the mold (7) for forming the normal grinding wheel (1), and into the auxiliary ring (8) for forming the reinforcement part. In the process of pressing by pressing 1/2 of the compound (5a) and the iron ring (4) of the compound (1) by adding 3 ~ 3wt% of the glass chip coated with a thermosetting resin to 97 ~ 99wt% of silicon carbide abrasive grains, 6) A mixture 1/2 containing a mixture of molten alumina abrasive grains or molten zirconia abrasive grains and silicon carbide abrasive grains in a 1: 1 ratio is added, and the glass fiber 2 is ground in the reinforcement portion 5. (6) the process of pressing and then pressing, the rest of the compound (5a) in which the auxiliary ring for forming the reinforcing part (8) is placed in the center of the molding, and the glass chips coated with the thermosetting resin are mixed with silicon carbide abrasive grains. Pressing process 2 and the iron ring (4) and pressing, the grinding portion (6) In the remaining one-half of the components blended in the molten alumina-based abrasive grains or molten zirconia abrasive grains and silicon carbide-based abrasive grains which after formulation and completion of the grinding wheel 1 via a process of pressing

Reference numeral 9 in the drawings shows a pressing member used when pressing the reinforcing portion (5).

According to the grinding wheel 1 of the present invention, which is constructed and manufactured as described above, the grinding wheel 1 consists of a grinding part 6 for processing an actual workpiece and a reinforcing part 5 which is a non-use part for supporting the same. As shown in Equation 1 below, the stress applied to the tangential direction at the time of tangential rotation is reduced as the specific gravity is lower as the specific gravity is lowered.

αｔ: tangential stress, R ₁ : inner diameter / 2,

R ₂ : outer diameter / 2 ρ: specific gravity, w ² : angular velocity.

ν: Poisson ^, s ratio r: arbitrary radius by centrifugal force

Therefore, one of the molten alumina-based abrasive grain (3.96g / cm ³⁾ or the molten zirconia-based abrasive grain (4.30g / cm ³⁾ and silicon carbide-based abrasive grains (3.22g / cm ³⁾ constituting the ground portion 6: 1 ratio The reinforcement part 5 is composed of a blended compound by adding 1 to ³ wt% of glass chips to 97 to 99 wt% of silicon carbide abrasive grains (3.22 g / cm ³ ), which is a raw material having a lower specific gravity than the blended compound. By lowering the stress applied in the tangential direction to increase safety, the present invention can satisfy the grinding conditions of random grinding in a short time, thereby ensuring safety at a working speed of 3800 to 4000 m / min. It is possible to manufacture a high-speed grinding grindstone (1) that is destroyed at a speed of 1.8 times or more, the present invention has the advantage that can be obtained a number of effects compared to the prior art as the grinding wheel used in the pretreatment process of the casting process ( Snaggi ng Wheel) (1) can be utilized at high speed, thus ensuring the safety of users and improving productivity when processing workpieces.

Although the present invention has been described above, there is room for the present invention to be modified in various ways, and such modifications are not to be regarded as a departure from the scope and claims of the invention and all such modifications are common in the art to which the invention pertains. To the knowledgeable person, it is considered to be included in the following claims.

As described above, the present invention provides a silicon carbide (SiC) having a lower specific gravity than the molten alumina-based abrasive grains constituting the grinding portion 6 inside the grinding wheel 1 having the glass fiber 2 and the iron ring 4 embedded therein. By forming the reinforcement part 5 using the abrasive grain, the following effects can be acquired.

1) By using silicon carbide (SiC) abrasive grains, which have a lower specific gravity than molten alumina (Al ₂ O ₃ ) abrasive grains, the stress applied to the tangential direction can be reduced by centrifugal force during rotation, thereby increasing safety.

2) The glass chips are coated with a thermosetting binder and bonded together with the abrasive grains to increase the bonding strength with the abrasive grains, thereby improving safety by impact or centrifugal force.

3) The glass fiber (2) and the iron ring (4) were used to increase the safety strength so that the grinding wheel (1) can endure at high speed, and the impact resistance to withstand the impact was improved.

4) By securing safety at high speed, the user's efficiency and productivity are improved.

Claims (3)

In the grinding wheel (1) in which at least one glass fiber (2) is placed inside and the iron ring (4) is recessed in the inner diameter (3) side of the center, To the inner diameter (3) side to form a reinforcing portion (5) to improve the impact resistance and rotational fracture strength due to the stress generated during the rotation grinding, The reinforcement part 5 mixes silicon carbide (SiC) abrasive grains with molten alumina abrasive grains or molten zirconia abrasive grains constituting the grinding portion 6 of the grinding wheel 1 in a 1: 1 ratio. As a blend (5a), 1 ~ 3wt% of glass chips coated with a thermosetting resin were added to 97 ~ 99wt% of silicon carbide (SiC) -based abrasive grains having a smaller specific gravity than the conventional abrasive grains. Grinding wheel characterized by the construction. In manufacturing the grinding wheel (1), A secondary ring 8 for reinforcement part is placed in the center of a mold 7 for forming a conventional grinding wheel 1 and a silicon carbide (SiC) system is provided inside the auxiliary ring for reinforcement part 8. Pressing 1 ~ 3wt% of glass chip coated with thermosetting resin (Glass Chop) into 97 ~ 99wt% of abrasive grains, and then pressing the mixture 5a, glass fiber (2) and iron ring (4) sequentially. Process, The auxiliary ring 8 for forming the reinforcing part is separated, and molten alumina-based or molten zirconia-based abrasives and silicon carbide-based abrasives, which are materials constituting the grinding part 6, are formed outside the reinforcement part 5 formed by pressing. Method for producing a grinding wheel, characterized in that the manufacturing process by pressing the compounding formulated in a ratio of 1: 1. In manufacturing the grinding wheel (1), A secondary ring 8 for reinforcement part is placed in the center of a mold 7 for forming a conventional grinding wheel 1 and a silicon carbide (SiC) system is provided inside the auxiliary ring for reinforcement part 8. 1 to 3 wt% of glass chips coated with a thermosetting resin (Glass Chop) to 97 to 99 wt% abrasive, and a half of the blended compound (5a) and iron ring (4) were pressed and pressed, After removing the auxiliary ring 8 for forming the reinforcement part, 1/2 of the mixture containing molten alumina-based abrasive grains or molten zirconia-based abrasive grains and silicon carbide abrasive grains, which are materials constituting the grinding portion 6, is added at a ratio of 1: 1. The glass fiber 2 is inserted into the grinding portion 6 from the reinforcement portion 5 and then pressed; The auxiliary ring 8 for forming the reinforcement part is placed in the center of the molding, and the other half of the compound 5a containing the glass chip coated with the thermosetting resin is pressed into the silicon carbide abrasive grain and the iron ring 4 is pressed. Process, Separating the reinforcing part forming auxiliary ring (8) and the remainder of the blended compound of the molten zirconia-based abrasive grains and silicon carbide abrasive grains that are the material constituting the grinding portion (6) outside the reinforcement portion (5) formed by pressing Method for producing a grinding wheel, characterized in that the manufacturing process by pressing after the addition of / 2.