NL8005076A - BELT SANDING DEVICE EQUIPPED WITH A PNEUMATIC BELT CONTROL. - Google Patents

Description

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Hw / Mv / vd.Lind? -i-

Belt sander equipped with a pneumatic belt control

The invention relates to a device for sanding workpieces, provided with an endless sanding belt spread over two or more rollers, wherein one of the rollers is driven by a motor oscillating about an axis perpendicular to the roller axis, which motor is controlled by a pneumatic control system provided with at least one pair of spray nozzles mounted on either side of the tire.

The action of the pneumatic control systems is such that the spray nozzles may or may not be covered by the edge of the sanding belt, which oscillates back and forth as a result of the oscillating movement of one roller. As a result of covering the spray nozzles, the pressure in the piping system necessary to control the motor of a booster will change because the varying pressure at the spray nozzles is too low to operate the motor directly.

The object of the invention is to improve the pneumatic control system in such a way that such a strengthening device is no longer necessary.

The device according to the invention is distinguished in that the spray nozzles of each pair are arranged vertically relative to each other and a vane pivotable about a horizontal axis for the higher spray nozzle is suspended.

Thanks to the use of the hinged vane, the higher spray nozzle can be fed at a relatively high pressure, since the lower spray nozzle easily presses and closes the vane due to the leverage effect.

The high steering pressure can be used for any mechanical, hydraulic or other steering systems for any servomotor.

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In the preferred embodiment, however, the oscillating roller actuator is an air cylinder, and its air supply conduit is directly connected to the upper spray nozzle supply conduit, so that the high pressure directly controls the actuator. This greatly simplifies the pneumatic system.

Such a pneumatic control system can also be used for the protection of the hand run, that is to say that the belt does not run out of a predetermined limit value.

For such a safety system, the invention proposes that the supply line of the upper spray nozzle of another pair be in direct communication with the supply line of a pneumatic control cylinder for the belt drive motor brake.

Such a protection system can be provided with two such pairs of spray nozzles, each of which belongs to an edge of the sanding belt.

A simple embodiment has been proposed by the invention by a third vane having one spray nozzle, which vane is in contact with the vane of the other pair of spray nozzles by a tumbler. This brings the entire pneumatic control to one side of the edge of the sanding belt.

It is preferred here that the tumbler has arms of unequal length, with the longest facing the third vane to compensate for the difference in response pressure.

The invention is further elucidated with reference to the figure description below of some exemplary embodiments. In the drawing: Fig. 1 shows a schematic perspective view of a belt sander provided with a pneumatic control system for the oscillating movement.

Fig. 2 shows a side view of the vane control in the device of Fig. 1.

Fig. 3 and Fig. 4 show a top and front view, respectively, of a vane control fitted with three vanes.

8005076 «r. 4 -3- fig. 5 a diagram of a pneumatic control and safety system provided with three vanes according to fig. 3 and fig. 4.

The belt sander according to fig. 1 -5 mainly consists of a frame 1, with a roller track 2 arranged in the lower part thereof for supporting the product to be sanded. Above the roller track a driven pressure roller 3 is provided, which on either side the frame 1 is mounted and driven via the right-angle transmission 4 10 by the motor 5.

A second roller 6 is mounted some distance above the roller and is mounted in a holder 7, which holder is attached to a spindle 8. The spindle is perpendicular to the axis of rotation of the roller 6, and is furthermore mounted in a bridge-shaped part of the frame 1, such that the roller 6 can undergo a pivoting movement around the spindle 8. A sanding belt 9 is wrapped around the roller 6 and the roller 3, which is driven in the direction of the arrow P 1 as a result of the drive of the motor 5.

20 On one side of the holder 7 a hinge piece 10 for a piston rod 11 of a cylinder 12 is coupled, which cylinder 12 is supported by a vertical post 13 of the frame I. The cylinder 12 is fed by an air supply pipe 14, which via a restriction 1 5 is directly connected to the pressure source 16 specified in more detail. The cylinder 12 is single-acting, that is to say, by applying pressure on one side of the piston, the piston rod moves out, while a built-in compression spring moves the piston rod back when the pressure is released. It is thus possible to move the coupling piece 10 back and forth in the direction of the arrow P 1, whereby the holder 7 is brought in an oscillating movement around the spindle 8, as a result of which movement the belt in the direction of the arrow P 3 will move back and forth.

According to the invention, a pneumatic control system 17 is provided near the edge of the belt 9, which consists of a vane 18 which is pivotally mounted about a horizontal axis XX on a bracket 19 of the frame 1.

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Two spray nozzles 20 and 21, respectively, are directed to the vane 18, the spray nozzle 20 being lower than the nozzle 21. The higher spray nozzle 21 is fed by a pipe 22 which is in direct connection with the air supply pipe to the cylinder 12, namely after the restriction 15.

The spray nozzle 20 is permanently supplied with compressed air from, for example, the pressure source 16.

The position of the vane control is such that when the sanding belt 9 is moved to the left in Fig. 1, the spray nozzle 20 is shielded, so that the pressure of the air jet no longer acts on the vane 18.

The vane 18 is moved toward the leading edge of the tire due to the pressure from the spray nozzle 21, allowing the supply air to the cylinder 12 to escape through the spray nozzle 21 and the pressure in the system after the friction 15 decreases. The piston will therefore retract into the cylinder. The holder 7 is pivoted such that the tape will consequently move to the right, releasing the spray nozzle 20, releasing the air jet from the vane 18, and closing the upper spray nozzle 21. The pressure in the line 22 increases, and therefore in the line 14, whereby the cylinder 12 is energized and the piston rod moves out.

Fig. 2 shows in detail that the air jet from the spray nozzle 20 presses against the underside of the vane 18, taking into account the arm 1, i.e. the distance between the spray nozzle 20 and the pivot point X of the can exert a great compressive force on the spray nozzle 21 thereon. It will be clear that at a high pressure in the spray nozzle 21, the vane 18 can still be closed against the spray nozzle 21.

Figures 3 and 4 show such a vane control, however, carried out with three vanes. Each vane 18 is again freely pivotable about the horizontal pivot axis XX, with a lower spray nozzle 20 'for the middle vane 18', 2011 for the left vane 18, at the two left vanes in Figs. 3 and 4, and 20 ,,, in front of the right van 181 * '. The two left vanes 18 'and 18' 'also have an upper spray nozzle 21' and 21 '' respectively.

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The triple vane control makes it possible not only to control the oscillating movement of the sanding belt 9, but also to monitor the extreme limit of the runway by means of the outer vanes 18 * * and 18 ''.

All this will also be explained with reference to Fig. 5.

The diagram in fig. 5 again shows a pressure source which, via a hydraulic control system 17 known per se, on the one hand controls the cylinder 12 of the oscillating roller 10 6, and on the other hand a pneumatic cylinder 25 for operating a brake 26 of the drive motor 5 of the sanding belt. For this purpose, the piston rod 27 of the cylinder 25 is connected to a control arm 28, which, on the one hand, the block brake 26 and, on the other hand, a switch 29 for switching off the electrical voltage of the drive motor 5.

The supply line 30 of cylinder. 25, after the friction 31, is directly connected to the spray nozzle 21'1 of the vane 18, r. This vane 18 '' is normally irradiated by the spray nozzle 20 '', thereby closing the spray 20 nozzle 18 '', as a result of which the pressure in the system is maintained and the brake 26 is released.

The belt 9 can therefore be driven without any problem.

Each time the belt oscillates along the spray nozzle 20 ', whereby the cylinder 12 is controlled as described above. The tape therefore undergoes normal oscillating action. However, should the belt deviate too far from the prescribed path, for example, the spray nozzle 20 '' is shielded, releasing the spray nozzle 21 '' 30, as a result of which the pressure in the system drops, the brake 26 is energized and the engine is switched off. due to switch changeover 29.

If the belt 9 on the other side runs too far out of the path, the spray nozzle 20 '' 'is released 35 which then irradiates the vane 18' '', which is rotatable around the point 33 the vane 18 'via a rocker arm 32' * pressed away and therefore releases the spray nozzle 21 ''. In the same manner as described above, the pressure in the system drops and the belt drive is switched off.

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In order to be able to overcome the air pressure of the spray nozzle 2011 when the vane 18 '' is lifted as a result of the rotation of the tumbler 32, this tumbler has arms of unequal length, the largest arm 5 of which faces the vane 18 ' * f points.

In combination with this, the distance of the spray nozzles 20 from the horizontal axis X-X of the tumblers can also be changed in order to be able to exert a greater steering torque on the vanes. It is clear from Fig. 4 10 that the distance from the spray nozzle 20111 to the axis X-X is greater than that of the spray nozzle 2011.

The invention is not limited to the above-described embodiments. For example, the pneumatic cylinders 12 and 25 may have been replaced by any other suitable propellant which is controlled by the pneumatic system.

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Claims (6)

1. Device for sanding workpieces, provided with an endless sanding belt, spread over two or more rollers, in which one of the rollers is driven by a motor about an axis perpendicularly to the roller axis, which motor is controlled by a pneumatic system provided with at least one pair of spray nozzles arranged on either side of the belt, characterized in that the spray nozzles of each pair are arranged vertically relative to each other and a vane pivotable about a horizontal axis for the higher nozzle piece is hung. 2. Device according to claim 1, characterized in that the motor is an air cylinder and the air supply pipe of the higher spray nozzle of a pair and directly connected to the supply pipe of the air cylinder. 3. Device according to claims 1 and 2, characterized in that the air supply line of the higher spray nozzle of another pair is in direct connection with the supply line of a pneumatic control cylinder for the brake of the drive motor of the sanding belt. 4. Device as claimed in claims 1-3, characterized in that a third vane is provided with one associated spray nozzle, which vane contacts the vane of the other pair of spray nozzles via a tumbler. 5. Device as claimed in claim 4, characterized in that the tumbler has arms of unequal length, the longest arm pointing towards the third vane. 6. Device according to claim 4, characterized in that the distance of the lower-lying nozzles associated with the third vane or the vane of the other pair differs from the horizontal hinge axis 35 of the vanes. 8005076