The present invention relates to a device and a method for abrading, i.e. sanding, a wooden barrel.
Traditionally, in barrel works, wooden barrels are sanded entirely manually: an operative loads the barrel onto a lathe, removes a first bilge hoop (a metal ring situated in the largest diameter region, known as the “bilge”) with a hammer and a drift, sands a first half of the barrel with a belt sander, replaces the first bilge hoop, removes the second bilge hoop, sands the second half of the barrel, replaces the second bilge hoop, and finally unloads the barrel from the lathe.
Apart from the fact that these operations are physically very tiring, the operative must work in a very dusty atmosphere.
Moreover, it takes a relatively long time to sand a barrel using the traditional technique.
An object of the present invention is to provide a device and a method that overcome these drawbacks.
That object of the invention is achieved with a device for sanding a wooden barrel, characterized in that it consists of a robot comprising:
means for loading said barrel,
means for gripping and rotating said barrel around the axis thereof,
means for removing and replacing the two bilge hoops of said barrel,
means for sanding said barrel, and
means for removing said barrel.
Clearly, the device of the invention robotizes tasks that were previously difficult and lengthy, and thereby achieves the required improvement.
According to other features of the device of the invention:
The method of the invention, applied to the above device, is characterized in that it comprises the steps of:
According to other features of the method of the invention:
Other features and advantages of the invention will become apparent in the light of the following description and on examining the appended drawings, in which:
Doors P1 and P2 separate the entry airlock 3 from the main chamber 4 and the main chamber from the exit airlock 5, respectively.
A pair of parallel rails with a slight inclination known as a track 7 terminates in the entry airlock 3 and conveys thereto a barrel 9 to be processed.
A sequencer device 11 immobilizes the barrel 9 to be processed in the entry airlock 3 until the processing of the preceding barrel 13 has been completed.
The sequencer device 11 may comprise rollers 15a, 15b rotatably mounted at the two ends of a deformable parallelogram 17 mounted pendulum-fashion on a support 19 and actuated by a cylinder 21.
A track 23 links the entry airlock 3 to the main chamber 4.
The main chamber 4 contains means for immobilizing and lifting the barrel 13 before it is processed.
As is apparent in
The main chamber 4 further contains means for gripping the barrel 13 and rotating it about its axis A.
As may be seen in
The term “extendable” means that the jaws 33a, 33b can be moved in the direction of the axis A of the barrel 13 by pneumatic cylinders 35a, 35b visible in
A high-power electric motor 37 is adapted to drive rotation of the chuck 31b.
The main chamber 4 further contains means for removing and replacing the two bilge hoops 39a, 39b of the barrel 13.
As can be seen in
The hoop removing and replacing means comprise a plurality of arms, preferably four arms 43a to 43d as shown in
These arms are therefore mobile between an open position, represented in thicker line in
The arms 43a to 43d are actuated in these two positions by cylinders 47a to 47d disposed between the arms and the carriage 45.
As can be seen in
The clamping shoes are conformed so that they are able to cooperate firmly with either of the bilge hoops 39a, 39b.
Pressure sensors known in the art (not shown) are preferably provided so that the arms 43a to 43d do not apply too high or too low a pressure to the bilge hoops 39a, 39b after their removal.
The carriage 45 is mounted to be slid along the axis A of the barrel 13 by appropriate conventional means, for example rails 51a and 51b and a lead screw 52 extending along the axis A.
The main chamber 4 further contains means for sanding the barrel 13.
As is apparent in
The sanding head is suspended from a frame 60 mounted to be slid along the axis A of the barrel 13 by appropriate conventional means, for example rails 59a and 59b and a lead screw 61 extending along the axis A.
Means are provided for varying the distance of the sanding head 53 from the axis A of the barrel 13.
As can be seen in
Means are also provided for varying the inclination of the sanding head 53 to the axis A of the barrel 13.
As can be seen in
Means known in the art and not shown ensure that the sanding belt 55 applies a constant pressure to the barrel 13.
As can be seen in
Means known in the art are also provided for marking the position of the bunghole 41. Those means may comprise a photoelectric cell, for example (not shown).
All of the moving parts of the device of the invention are controlled by an electronic circuit connected to a man/machine interface (not shown) enabling an operative to fix set points associated with each type of barrel to be processed.
The operation and the advantages of the device of the invention are clear from the foregoing description.
The barrel to be processed arrives in the entry airlock 3, rolling along the track 7, and reaches the position 9 represented in
The sequencer 11, which is in the position represented in
When the sanding of the preceding barrel 13 has been finished and that barrel has left the chamber 4, the cylinder 21 pivots the sequencer 11 so that the roller 15a is in the raised position and the roller 15b is in the lowered position.
The door P1 is then opened and the barrel 9 rolls along the track 23 into the chamber 4, until it reaches the position 13 seen in
Driven by the lead screw 53, the buffers 25a, 25b come into contact with the barrel 13 and then lift it until it reaches a position in which its axis A is substantially aligned with the rotation axes of the headstocks 29a and 29b (see
The pneumatic cylinders 35a, 35b then place the jaws 33a, 33b of the chucks 31a, 31b against the two ends of the barrel 13 to hold the barrel firmly.
The electric motor 37 rotates the barrel 13 so that the bunghole 41 moves in front of the photoelectric cell so that it may be identified.
Once this identification has been effected, the barrel 13 continues to turn to a position in which it is certain that the shoes 49a to 49d will be pressed onto areas of the bilge hoops 39a, 39b with no rivets.
In other words, identifying the position of the bunghole 41 indexes the angular position of the barrel 13 in order to optimize the gripping of the bilge hoops 39a, 39b by the arms 43a to 43d.
The carriage 45 then slides on the rails 51a, 51b until the arms 49a to 49d are in line with the bilge hoop 39a.
The cylinders 47a to 47d are then actuated so that the shoes 49a to 49d are pressed onto the bilge hoop 39a and grip it.
The carriage 45 then slides to remove the bilge hoop and then pass it over the head of the barrel 13.
Once it has been extracted, the gripping force applied to the bilge hoop 39a by the arms 43a to 43d is controlled so that the arms do not crush the hoop.
Note that if removing a hoop proves difficult, removing it in several stages may be envisaged, turning the barrel through a certain angle (for example 45°) between attempts.
The barrel 13 is then rotated continuously by the electric motor 37.
The deformable parallelogram 63a, 63b then lowers the sanding head 53 until the sanding belt 55 comes into contact with the head of the barrel 13.
The motor 57 is then started, which drives the sanding belt 55.
While the barrel 13 is turning about its axis, the sanding head 53 slides on the rails 59a, 59b.
The relative speeds of rotation of the barrel 13, on the one hand, and of translation of the head 53, on the other hand, are adapted so that a single excursion of the head 53 between the end and the bilge of the barrel 13 is sufficient to sand half of the barrel.
Once this sanding has been effected, the bilge hoop 39a is replaced by a sequence of operations in the reverse order to that described above: the carriage 45 slides to reposition the hoop 39a on the bilge of the barrel 13, after which the arms 43a to 43d are moved apart to release the hoop.
All of the steps described above are then repeated to remove/replace the other bilge hoop 39b and sand the second half of the barrel 13.
It will be noted that while the sanding head 53 is advancing, its inclination to the axis A of the barrel is adjusted by the cylinder 67 operating on the arm 65.
Thus the sanding belt 55 can at all times be tangential to the generatrices of the barrel 13.
For example,
As is clear in the light of the foregoing description, only one bilge hoop is removed at a time, which means that the staves forming the barrel are held together while the corresponding half of the barrel is sanded, which prevents sawdust penetrating to the interior of the barrel.
Once the whole of the barrel has been sanded, the sanding head 53 is raised by the links 63a, 63b, rotation of the barrel is stopped, the jaws 33a, 33b are opened, the barrel is lowered onto the track 69, the door P2 is opened, and the barrel is evacuated into the exit airlock 5.
The next barrel can then be sanded in its turn.
As is clear in the light of the foregoing description, the device of the invention is able to sand wooden barrels entirely automatically, so that the irksome and lengthy manual operations of the prior art can be dispensed with.
For example, the device of the invention is able to sand a 228-liter barrel in less than two minutes.
Of course, the present invention is not limited to the embodiment described and shown, which is provided by way of illustrative and nonlimiting example.
Number | Date | Country | Kind |
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02 13459 | Oct 2002 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR03/03207 | 10/28/2003 | WO | 4/10/2006 |