ABRASIVE BELT
The invention relates to the abrasion of objects using coated abrasive sheet material more
particularly belts. Coated abrasive belts are widely used in industrial applications for
grinding, stock removal and finishing and surface abrasion of workpieces and materials, e.g.
wood, particle board, metal, plastic veneers, glass, ceramics; seeds, aggregate and precious
stones; and the like.
In use, the abrasive belt is normally run on a machine having two or more rollers which
tension the abrasive belt and also drive it, in some cases up to very high surface speeds.
The material to be abraded, e.g. ground or finished is then applied to the moving belt or
vice versa, either by hand or through an automatic feed device. The action of the workpiece
on the belt, belt wear (stretching), belt heating from grinding, or liquid coolants can cause
the belt to run over to one side of the machine and commonly the belt will progressively
track off the machine which can cause catastrophic damage to the belt and the machine
itself.
Various devices are conventionally used to control this effect, ranging from simple 'cut-out'
devices which automatically switch off the machine if the belt tracks too far to one side or
the other, to highly sophisticated systems which automatically monitor the position of the
moving belt and make continuous small adjustments to track the belt in a tight or
predetermined oscillating range of positions. In order to monitor the lateral position of the
belt on the machine a variety of devices are employed; these include pneumatic sensors,
optical sensors and mechanical devices. All of these devices have limitations caused by the
environment in which they have to operate, e.g. in a cloud of wood or metal dust, in a
coolant spray of oil, water or oil/water mixture.
It is an object of the invention to provide means for the purpose specified in which lateral
deviation of the belt is reduced or eliminated and/or corrected.
In one aspect this invention provides an abrading or polishing machine having a moving
abrasive sheet the sheet having magnetised particles therein, characterised by a sensor
arranged to generate an output signal in dependence upon the magnetism of the particles.
Preferably the sheet has zones having non-uniform magnetisation along its direction of
travel and the sensor is arranged to generate an output signal which varies according to the
magnetisation of the zone passing the sensor.
In one embodiment the magnetisable particles are magnetised in bands having spaced apart
zones of the same or alternating polarity.
The magnetisable particles may be selected from a wide range of materials. Preferably the
magnetised particles comprise any one or more of barium ferrite, chromium dioxide, cobalt
doped iron oxide, ferric oxide, magnetite, strontium ferrite; or the like.
Preferably the particles are present in a concentration of from about 50 grams per square
metre to about 500 grams per square metre of the sheet.
The support may, for example, be woven cloth; paper, fibre, plastic film; or the like.
In one embodiment the sheet comprises an adhesive layer on a support, an abrasive layer
being disposed on the adhesive layer and the magnetised particles being incorporated in the
adhesive layer.
In the manufacture of the above abrasive sheet, one or more adhesive layers can be applied
in known manner to a flexible support backing and the coated abrasive material
incorporating the magnetisable paniculate material can be applied.
For example, a first layer of adhesive (base or maker coat) can be applied to the backing,
abrasive grains deposited on to the adhesive layer followed by drying/curing to anchor the
abrasive grains. A second layer of adhesive (sizing coat) can be applied over the abrasive
grains followed by a further drying/curing operation. A third layer of adhesive containing
grinding aids, lubricants or other additives can optionally be applied over the sizing coat
followed again by drying/curing.
The magnetisable material can be magnetised by passage against single or multiple
electromagnet or permanent magnets to provide a track containing alternating North and
South poles or spaced apart poles of one type only. Preferably in use the sheet (normally in
the form of a belt) generates a pulse signal as it moves past the sensing device.
In another aspect, the invention provides an abrasive sheet having its ends joined together to
form a belt, the belt having zones of magnetisation distributed along its direction of travel,
e.g. at its margins.
The belt may be used in any sanding or abrading machine such as a wide belt sander; or an
automatic narrow belt machine; or the like.
As explained, the magnetised portion of the coated abrasive sheet or belt, for example, can
be continuous and of the same polarity or in discrete bands or strips or other configurations
of the same or alternating polarity. Preferably a sheet of this invention has, by virtue of its
structure, a substantially uniform thickness. This helps the belt run true. The magnetisable
particles may, for example, extend across the belt or they may be confined to specific areas,
e.g. the longitudinal margins.
In one embodiment the apparatus includes a sensor adapted to derive information, e.g.
digital or analogue signals, from the magnetised particles to keep the belt running true. The
magnetic portion on the coated abrasive belt can be detected for example by a Hall Effect
device, magneto resistor, flux-gate sensor, pick-up coil, or any other magnetic field or
proximity sensitive device. The output from these devices can be processed electronically, to trigger the tracking mechanism and track the coated abrasive belt in normal use.
However, the sensor may be arranged to act in a smart sense, e.g. to react to the information
sensed to adjust speed of the belt or the position according to rate of wear sensed; or the like.
The invention also provides a method of abrading or polishing an object or objects using an
abrading or polishing machine as defined and maintaining the belt in a predetermined path
comprising running a machine as defined and moving the belt into the predetermined path according to the deviation from the predetermined path sensed by the sensor.
In order that the invention may be well understood, a preferred embodiment will now be
described by way of example only with reference to the accompanying diagrammatic
drawings, in which:
Figure 1 is a cross section of part of a belt for use in an embodiment of the
invention;
Figure 2 is a partial plan view of two magnetic pole designs for the belt;
Figure 3 is a plan view of part of an abrasive belt grinding machine in accordance
with the invention;
Figure 4 is a side elevation of an arrangement for magnetising the belt of Figure 1 or
Figure 2; and
Figure 5 is a plot of output voltage : speed of a belt for use in an embodiment of the
invention.
As shown in Figure 1, a belt B comprises a length of sheet material joined end-to-end. The
belt comprises a support 1 of backing material, e.g. paper cloth or plastics. A layer 2 of
adhesive resin containing magnetisable particles M, e.g. barium ferrite has been applied in
known manner, and on top of that a second adhesive layer 3 to anchor the abrasive particles
A to the support. On top of the second adhesive layer is a third adhesive layer 4 as a
supersize. The formed sheet thus comprises four layers, the two uppermost of which have
abrasive grains embedded therein. The sheet is cut to length and two ends are joined
together in known way to form a belt.
Referring to Figure 4, the belt B is passed under an electromagnet E, energised by a pulsed
signal to magnetise the magnetisable particles M into bands made up of zones Z of
magnetic polarity; as shown in Figure 2 these can be spaced apart zones of say North pole
(Figure 2a) or alternating North and South poles (Figure 2b). The belt is then mounted on a
machine such as a wide belt sander for wood, veneer and particle board or for metal
finishing and polishing with water, oil or water/oil coolant; or an automatic narrow belt
machine.
It has also been observed that the magnetised signal from such a belt can penetrate layers of
thin metal (e.g. steel), wood and plastic to such an extent that a strong signal can be
measured even with such materials between the moving abrasive belt and the sensor.
Figure 3 shows an abrasive belt grinding machine in accordance with the invention,
comprising a belt B (as described above) mounted on rollers Rl and R2 and driven by a
motor (not shown). The axis of rotation of roller R2 can be tilted in a horizontal plane by a
tracking actuator T, as indicated at P. Actuator T is controlled by the output of a control
circuit C, which compares the outputs of two magnetic sensors SI and S2 which are located
beneath belt B with the centres of their sensitive regions located slightly outside the centres
of two series of zones of magnetisation Zl and Z2 respectively. When belt B deviates to
the right on roller R2 then the output of sensor S 1 exceeds that of S2 and the resulting difference signal is derived by circuit C to cause actuator T to tilt the axis of roller R2 in the
direction Ql. When the belt deviates to the left, the relative outputs of the sensors SI and
S2 are reversed and the actuator T is caused to tilt the axis of roller R2 in the opposite
direction Q2. In this manner any deviations from true running of the belt are corrected.
8
By incorporating a magnetisable particulate material into the adhesive layers of the coated
abrasive, the lateral position of the abrasive belt on the machine can be sensed without
interference despite the presence of particulate dust and coolants.
EXAMPLE
An abrasive belt 50 mm x 1525 mm was prepared using conventionally manufactured grit
size P80 aluminium oxide resin bonded abrasive cloth where the base coat of adhesive
contained 84g/m addition of barium ferrite. The belt was then magnetised using an
electromagnet to produce magnetised areas approximately 10 mm diameter, spaced at
approximately 100 mm intervals along the length of the belt.
The belt was then run at a range of different surface speeds and the pulse signal measured at
each speed using a pick up coil. The signal voltage measurements are given in Figure 5.
It should be noted that the invention is not limited to the embodiments shown. For
example, in other embodiments the magnetisable material M could be incorporated in the
backing of the belt B or even applied in a coating (e.g. on ink coating) to the rear surface of the backing.