DE971204C - Metal-bonded abrasive body - Google Patents

Description

Metal-bonded grinding wheel The invention relates to grinding wheels, in particular grinding wheels, with metal-bonded abrasive grains and inside the grinding wheel provided cavities that are used for cooling.

The metal bond is the more heavily used grinding wheels Resin bond is preferred because it improves heat dissipation in addition to it Strength is affected to a lesser extent by the frictional heat that occurs although the metallic bond compound tends to become a to form a relatively smooth friction surface.

Have interstice-free, especially metal-bonded grinding wheels the disadvantage that a relatively large amount of heat build-up during the operation appear. The frictional heat that occurs when the machined material is machined becomes higher, the more the abrasive grains become blunt; they can be very hard-bound Abrasive grains are not removed sufficiently quickly even when wet grinding.

When grinding wheels have become smooth, in addition to heat build-up, and the harmful effect on the material to be ground the cutting ability of the Abrasive grains substantially reduced if not canceled as soon as their surface is in the same plane with the solid bonding surface. The consequence of this is that the grinding wheel no longer or only inadequately grips. You can renew the cutting ability by dressing the smooth surface, but this dressing causes considerable wear on the grinding wheel. Around To remedy this problem, grinding wheels of any type of bond have already been made have been, which have a large number of cavities in their interior, optionally can be kept filled with coolant. Such voids are previously either by mixing in thin-walled hollow bodies, such as hollow glass beads, or combustible body into the mass used to make the grindstone or by intermediate mixing of substances capable of developing gas that are within the Abrasive body by developing gas bubbles to form cavities. At the However, loops clog these cavities and cause them to smear Grinding wheel, so that it does not have sufficient cutting ability.

It has also been suggested that the top layer of the metal-bonded abrasive grain of a grinding wheel by adding it of metal or metal alloy particles under the powdered, metallic binder and to be achieved by sintering at a certain temperature and sufficient pressure, whereby these particles are to be melted so far that they become the abrasive grains hold and make the binder more or less porous. Besides that in this way not evenly distributed within the grinding wheel, if possible Small cavities can be formed, this process is very cumbersome. The cavities would also have the disadvantages described above.

It is also known to improve cooling within the Grinding wheel and on their outer surfaces channels or grooves for the passage of coolant to be provided.

The aim of the invention is to provide such grinding bodies or grinding wheels with metallically bound grain and with cooling cavities provided inside improve and correct the deficiencies described above. This is done according to the invention achieved in that porous mineral grains embedded in the metal bond are.

These porous mineral grains do not have an abrasive effect, but only serve to protect the cold rooms or cooling surfaces by embedding them in to create the metal bond. The cooling effect is due to the high permeability these grains are also secured before they break out. Is one in the sanding surface If lying grain has broken out, the full space is free for the cooling effect.

This also prevents the grinding tool from forming a work surface that is too smooth or the grinding wheel, since porous grains are constantly exposed or breaking out. Since the porous grains initially stay in their embedding for a long time and only gradually breaking out and freeing cavities is a disadvantage However, smearing and clogging of the cavities is not easily possible. The grains suitably consist of pumice stone, fired clay or other ceramic mass and can be many times larger than the abrasive grains used. As a result Due to the lower strength of this mineral material, the grains break out, while the surrounding bond is still tight.

It is known in the case of non-metallically bonded grinding tools To provide cell spaces as pores, the size of which is far from that of the embedded abrasive grain surpasses. To create this large-pored grinding wheel structure, this known proposal, however, no mineral, inherently porous body mixed in, but removable substances in spherical or granular form, which can be removed by subsequent Dissolving, melting, evaporation, burning out or the like. The cavities are left behind.

The embedding of the porous mineral grains is a matter of course also advantageous for tools that have diamond chips as abrasive grain, since special attention is paid to low wear on the grinding wheel got to.

To support heat dissipation, you can also use grinding wheels known grooves, incisions, bores or the like in the grinding wheel or in the grinding wheel are provided.

Claims (4)

PATENT CLAIMS: I. Grinding wheel, especially grinding wheel, with metal-bonded abrasive grains and a large number of cold rooms, characterized in that porous mineral grains are embedded in the metal bond. 2. grinding wheel, in particular grinding wheel, according to claim r, characterized in that the porous mineral grains made from pumice stone, baked clay or similar ceramic masses exist. 3. Abrasive body, in particular a grinding wheel, according to claim z, characterized characterized in that the porous grains embedded in the metal bond around a Many times larger than the abrasive grains used. 4. Grinding body, in particular grinding wheel, according to claim z, characterized in that grooves, incisions, bores or the like that promote heat dissipation are provided in a manner known per se. Considered publications: German Patent Nos. 743 122, 661 650, 659 286, 612 g18, 575 458; Austrian Patent No. 152 550; French Patent No. 838 826; British Patent No. 525 095; USA. Patent Nos. 2,307,312, 89o 2 296, 2 136 O22, 1 9 86 85o, 1,986,849.