A method for producing a base body with hard material particles, preferably superabrasives, in which first of all an adhesive is applied with a defined film thickness to the entire or parts of the working surface of the tool to be produced, and that the hard material particles are then applied to the regions of the working surface provided with the adhesive film for lasting adhesion; and devices for implementing the method.
In a generic method according to publication EP-A-1 208 945 for producing abrasive tools (which is incorporated by reference herein), an adhesive in droplet form is first of all applied to a carrier. Hard material particles are then dispersed over the carrier provided with droplets of adhesive, and thereby only the hard material particles which come into contact with an adhesive droplet should remain adhered to the carrier.
It is the object of the present invention to provide a method for coating base bodies of the type mentioned at the start which enables rapid coating of a base body with detached hard material particles and guarantees reliable adhesion of the latter to the base body until they are anchored by a subsequent process by soldering.
According to the invention, this object may be achieved by a method according for producing a base body with hard material particles, preferably superabrasives, in which first of all, an adhesive is applied with a defined film thickness to the entire or parts of the working surface of the tool to be produced, and the hard material particles are then applied to the regions of the working surface provided with the adhesive for lasting adhesion, and further, the hard material particles are applied by an appropriate apparatus and are then transferred to the working surface of the tool to be produced provided with the adhesive on which they remain adhered before the adhesive has hardened.
This object may also be achieved by a device for implementing the method wherein a container in the form of a trough is arranged with horizontal alignment of its contact surface and is positioned height-adjustably on a holder, the hard material particles being distributed regularly in the container. In another device, the contact surface, the conveyor belt and/or the dispersing apparatus is/are arranged such that their position and orientation in relation to the working surface to be coated of the tool to be produced can be changed arbitrarily. In another device, the position of the working surface to be coated of the tool to be produced can be moved, as one wishes, continuously or step by step in relation to the contact surface, the conveyor belt and/or the dispersing apparatus. In another device, an adjusting apparatus holds and moves the base body and is made up of a stand, a chuck fastened to the stand for holding the tool to be produced and a motor, it being possible to couple the motor to the base body such that it executes rotations about its axis of rotation.
The method according to the invention makes provision such that first of all an adhesive film is applied evenly to the entire or to part of the working surface of the tool to be produced.
For the coating of the adhesive surface with detached hard material particles the method according to the invention makes provision such that the hard material particles are first of all distributed evenly over a contact surface or a conveyor belt or a dispersing apparatus (sieve), the tool is placed above or below this, and the latter are positioned a predetermined distance away from one another. Next, these hard material particles are moved from the contact surface onto the working surface of the tool to which the adhesive film has been applied so that the latter remain adhered to the working surface.
By forming zones of partial areas, different coating densities or zone-dependent hard material particle types and/or sizes are also provided, and this can be achieved e.g. by repeating the method described above.
This method according to the invention enables rapid coating of the working surface of the tool with a predeterminable uniform number of detached hard material particles per unit of area.
Exemplary embodiments and further advantageous details of this method and these devices are defined in the dependent claims.
Exemplary embodiments and further advantages of the invention are described in more detail below using drawings. These show as follows:
With the method tools 20 with any surface geometry, such as for example grinding, honing and dressing tools of all types, as shown, for example, in
In the method an adhesive is first of all applied, in a way known in its own right, with a defined film thickness to substantially the entire working surface of the base body.
According to the invention the hard material particles 22 are first of all distributed evenly over a contact surface 15. The base body of the tool 20 to be produced, which has an adhesive film over the zones to be coated or over the entire working surface, is placed over this contact surface 15 so that the base body is positioned a pre-determined distance away from the contact surface 15. Next, the hard material particles 22 are moved up from the contact surface 15 to the working surface 20′ of the base body 20 to which the adhesive film has been applied so that they remain adhered to the adhesive film on the working surface 20′.
According to
This planar trough-like container 14 is arranged with horizontal alignment of its contact surface 15 and is positioned height-adjustably on a holder that has flexible longitudinal elements 19. By means of this mounting the container 14 can be moved up and down, there being provided for this purpose a plunger 18 of the drive 17 engaging with the lower side of the container 14 and which is arranged approximately perpendicular to the container and, with its front end staying in contact with the container, implements by means of the drive 17 an upwards and downwards movement.
With this shaking motion produced on the container 14 and so on these hard material particles 22 lying loosely in the latter the particles are lifted from the contact surface 15 of the container 14 and moved upwards to the working surface 20′ of the tool 20, and remain adhered to the latter. The hard material particles 22 are thereby arranged distributed in a single layer in the container 14 and, if required, are topped up again during coating. The plate-shaped container 14 forming the contact surface can be used by means of movements parallel to the contact surface in order to affect the distribution of the hard material particles 22 lying loosely on the contact surface 15.
In a further inventive step, the tool 20 is moved continuously or step by step above the contact surface 15 so that the part of the working surface 20′ to be provided with the hard material particles 22 is always the same distance away from the contact surface. Such adjustment is required when this working surface 20′ is not designed as a level surface but, as shown for example in
For this purpose, within the framework of the invention this adjusting apparatus 30 holding and moving the base body 20 is provided, comprising a stand 33, a chuck 32 fastened to the latter for holding the tool, and a motor 31, it being possible to couple the motor 31 to the tool to be produced such that the latter executes a rotation about its axis of rotation. Alternatively, the adjusting apparatus could be a robot or manipulator by means of which the positioning of the base body would take place automatically.
For the coating of the working surface 20′ of this cone-shaped tool 20 provided as a grinding, honing or dressing disc 20 with a cylindrical shaft 21 shown in
For the overall control of the device 10 for this coating process, an electric control system (not illustrated) is advantageously provided by means of which this continuous or step by step movement of the tool 20 and the drive for the upwards and downwards movement of the container can be controlled by means of a computer or the like. The predetermined density per area of unit of the hard material particles over the working surface of the tool can thus be more easily controlled by this control system by, for example, the frequency, amplitude, time of the vibration excitation of the contact surface or the rotational speed of the base body being controlled.
In
After the coating of the working surface 20′, hardening of the adhesive then takes place, followed, e.g. by the controlled application of a solder layer 24 to the entire coated working surface. In addition to the solder layer, solder matrix reinforcement, consisting of substantially smaller hard material particles and binders, can be applied to the working surface of the tool coated with hard material particles and anchored securely to the base body by means of subsequent soldering for definitive firmly bonded anchoring of the hard material particles 22 by means of the solder 22, possibly with additional solder matrix reinforcement.
According to
According to
Within the framework of the invention the contact surface 15, the conveyor belt 41 and the dispersing apparatus 45 can be set in any position or orientation in relation to the working surface 20′ to be coated of a tool 20 or similar to be produced. Specific coating with hard material particles over the working surface can thus be made possible.
The position of the working surface 20′ to be coated of the tool 20 to be produced can be moved, as one wishes, continuously or step by step in relation to the contact surface 15 or the conveyor belt 41 or the dispersing apparatus 45.
The adhesive could also be understood as meaning a bonding agent which could be made, for example, of a doughy to liquid metal layer in which the grains are then correspondingly embedded.
Number | Date | Country | Kind |
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00492/11 | Mar 2011 | CH | national |