AT402617B - SYSTEM FOR AUTOMATED, HERMETIC SYSTEM FOR AUTOMATED, HERMETIC LOCKING OF HOUSINGS LOCKING OF HOUSINGS - Google Patents

Description

AT 402 617 B

The invention relates to a system for the automated, hermetic sealing of housings, preferably metal housings, in which electronic components, in particular in an oxygen and steam-free atmosphere, are arranged, a welding chamber operated with nitrogen overpressure or underpressure being provided, which has at least one welding chamber that can be moved with respect to one another Has electrodes formed welding head and corresponding feed and discharge devices for the housing to and from the welding head.

Such systems are mainly used in the manufacture of electronic components.

So-called glove boxes " built-in. These are chambers that are purged with pure nitrogen and operated with a slight internal pressure to prevent the ingress of the environmental atmosphere in the event of any leaks. Service work had to be carried out with rubber gloves from the outside. If such maintenance is not possible, the box or chamber had to be opened. In order to restore a clean atmosphere for the weld, the chamber had to be purged with pure nitrogen for a long time, possibly longer than a day.

Time-consuming business interruptions naturally have an extremely disadvantageous effect in industrial mass production.

In addition, the electrodes were moved either by large-volume pneumatic cylinders or by eccentric drives. However, each of these drives also has disadvantages. Although the pneumatic drive is flexible in the opening travel and pressure setting, the opening and closing times are extremely long. The eccentric drive has a high closing speed, but is extremely inflexible in its movement.

The object of the invention is to provide a system which avoids the disadvantages mentioned above and which also ensures a higher quality in production. A quality standard for such systems is that a hermetic sealing of the housing is possible, the interior of the housing should be absolutely free of oxygen and water vapor.

The system according to the invention cited at the beginning is characterized in that the welding chamber can be evacuated and the welding head has at least one electrode which can be moved via a servo drive. With the invention, it is possible for the first time to carry out service work, such as regularly changing the electrodes, in the shortest possible time. In addition, thanks to its short closing times, the servo drive allows a high cycle frequency in the production line. Another advantage of the invention is the fact that the system can be built in a compact design, so that the lowest possible evacuation volume occurs.

After the service or maintenance work, the welding chamber is sealed and evacuated, with this evacuation being carried out in an average of 15 minutes. All atmospheric gases are extracted and then the welding chamber is filled with inert gas. The system is ready for operation again in no time.

According to a special feature of the invention, the welding chamber is connected to a gas drying circuit. This gas drying circuit essentially consists of two drying cartridges which contain a gas drying agent and each drying cartridge is connected separately to the welding chamber. A cartridge dries the inert gas from the welding chamber in operation. In the other cartridge, the moisture absorbed is extracted from the drying agent via vacuum and temperature. Through this alternating procedure, the operability of the system is always guaranteed.

According to a further embodiment of the invention, the welding space located in the welding head, which surrounds the housing provided for welding, can be evacuated when the electrodes are closed. In order to obtain an even greater freedom from gas in the interior of the housing to be closed, evacuation takes place shortly before welding in the welding head with the electrodes closed. Vacuum values of the order of 10 torr can be achieved.

According to a special embodiment of the invention, at least one electrode of the welding head has a channel for evacuation and a sealing ring for sealing off the second electrode. The procedure in the welding head is as follows: After inserting the housing into an electrode, the second electrode is closed until the O-ring seals. After a few seconds of evacuation, the electrodes are closed on the welding position. After the welding process, the electrodes are opened and the housing is removed using the ejector. The simple evacuation facility has resulted in a significant improvement in quality.

According to a special feature of the invention, the drying chamber is preceded by a drying oven and, if appropriate, a subsequent prechamber for the intermediate storage of the housings to be closed, the entry opening into the welding chamber being closable via a lock flap. The lock flap ensures that the welding chamber operates properly. The from the 2nd

AT 402 617 B

Housings coming into the drying oven must no longer come into contact with the environmental atmosphere. This means that housings that are delivered from the drying oven can also be stored in the welding chamber for service work. In addition, only the welding chamber has to be evacuated through the lock flap after the service work, s According to a further feature of the invention, an output lock chamber is built, which can be both evacuated and flushed with inert gas, and whose inlet and outlet openings each have one Lock valve is lockable. In order to prevent contamination of the inert gas atmosphere in the welding chamber when the housings are being brought out, the exit lock chamber 8 with its two lock flaps is of particular advantage. According to a special embodiment of the invention, helium gas is added to the nitrogen for operating the welding chamber. This added helium gas is an indicator of the welding quality. If a housing is leaky after the welding process, the gas flows out and is detected by a sensor. A quick method for quality control is preferably provided for random samples.

According to a special feature of the invention, the servo drive consists of an electronically controlled electric motor which drives a spindle, preferably a ball screw. This simple drive for closing and opening the electrode has proven its worth. The cycle frequency of production can be increased enormously, above all by the ability to adjust the speed and also the acceleration process.

According to a further embodiment of the invention, the electrode is supported vertically via a suspension, preferably a spring assembly. The purpose of this resilient support is that the flanging of the housing becomes practically zero during the actual welding process, and the electrode has to be retracted minimally in order to enable an optimal closure.

According to a further feature of the invention, the sealing necessary for the evacuation takes place on the rotating spindle part. Such a seal can be carried out with conventional machine components, a high level of operational safety being guaranteed.

The invention is explained in more detail with reference to exemplary embodiments which are shown in the drawing. 1 shows the schematic structure of the overall system, FIG. 2 the welding head with the servo drive, FIG. 3 an evacuable electrode and FIG. 4 the movement sequence during welding.

1, the system for closing the metal housing consists of several chambers. 30 The heart of this system is the welding chamber 1, in which the welding head 2 is also arranged.

Since electronic components are provided in the metal housings, these metal housings must be sealed in an atmosphere free of oxygen and water vapor. So that this atmosphere is present, the welding chamber 1 is operated in operation with a nitrogen overpressure, possibly also with a negative pressure. The welding head 2, which will be described in more detail later, consists of 35 movable electrodes. Since these electrodes have to be serviced at regular intervals, the welding chamber 1 must be opened. In order to achieve a clean atmosphere in the welding chamber 1 for welding again after this maintenance work, the latter can be evacuated. This means that the welding chamber is tightly sealed and evacuated after service or maintenance work. The atmospheric gases are extracted and then the welding chamber 1 is optionally filled with 40 inert gas, so that it is ready for operation again in the shortest possible time.

The welding chamber 1 is pre-built with a drying oven 3 and an antechamber 4. In addition, the welding chamber 1 also has an exit lock chamber 5. It is certainly extremely important in this system that at least the openings of the welding chamber 1, that is to say the inlet opening from the prechamber 4 into the welding chamber 1, and also the opening from the welding chamber 1 into the 45 outlet lock chamber 5 can be closed via lock flaps 6, 7. The exit sluice chamber 5 is also provided on the exit side with a sluice flap 8. In addition, the connection opening from drying oven 3 to prechamber 4 is provided with a connecting lock 9.

The metal housings provided with the electronic components are dried in the drying oven 3, temporarily stored in the prechamber 4, sealed in the welding chamber 1 and discharged via the exit 50 lock chamber 5.

In order to always have an optimal atmosphere for sealing in the welding chamber 1, the welding chamber 1 is connected to a gas drying circuit.

According to FIG. 2, the welding head 2 has a servo drive 11 for moving the electrode 10. The spindle 14 is mounted in the housing 12 of the welding head 2 via a spindle bearing 13. Outside 55 of the housing 12, the servo drive 11 is connected to the spindle 14 via a drive belt 15. Of course, both the spindle bearing 13 and the shaft of the servo drive 11 are vacuum sealed.

The spindle 14 is provided with a spindle nut 16, which in turn moves the electrode 10 via at least two bolts 17. The bolts 17 have a suspension 19. The suspension 18 can also be a third

Claims (10)

AT 402 617 B spring package. With this simple drive, which is characterized by the ability to adjust the speed and the acceleration process, the cycle frequency of production can be increased enormously. In order to obtain an even greater freedom from gas in the interior of the housing to be closed, evacuation is carried out shortly before welding in the welding head 2 with the electrodes 10 closed. 3, both the upper electrode 10a and the lower electrode 10b each have a channel 19 for suction or evacuation. The metal housing 20 to be welded lies in a corresponding recess in the lower electrodes. The upper electrode 10a has a sealing ring 21 for sealing off the second electrode 10b. After the electrodes 10a, 10b have been closed and before welding, evacuation is carried out; this additional evacuation has brought about a clear improvement in quality. 4, the sequence of movements in the course of the welding process is shown over time. Diagram a shows the build-up of force during the welding process, diagram b the spring travel of the suspension 18, diagram c the movement of the electrode 10a, diagram d the movement sequence of the servo drive and diagram me the summation of the movement sequences or the speed of the overall system. After inserting the housing 20 with the element to be welded into the lower electrode 10b, as can be seen from diagram e, the servo drive is started at maximum speed up to the first point of contact with the element to be welded. Shortly before reaching the touchdown point (diagram e point 30), the brakes are applied and then, at a reduced speed of the servo drive, a force build-up between the two parts to be welded up to a maximum force. During this last phase, the suspension 18 is finally tensioned (diagram b), the electrode 10a having reached the maximum contact force at point 31 (diagram a). The welding process takes place at time 32, the deformation of the elements to be welded being compensated by the suspension 18 (diagram b point 33). After the welding process has been completed, the electrode is returned to the starting position at maximum speed (diagram e position 34). 1. System for automated, hermetic sealing of housings, preferably of metal housings, in which electronic components located in particular in an oxygen and water vapor-free atmosphere are arranged, with a welding chamber operated with nitrogen overpressure or underpressure being provided which has at least one formed with two electrodes which can be moved relative to one another Welding head and corresponding feed and discharge devices for the housing to and from the welding head, characterized in that the welding chamber (1) can be evacuated and the welding head (2) has at least one electrode (10) movable via a servo drive (11). 2. Plant according to claim 1, characterized in that the welding chamber (1) is connected to a gas drying circuit. 3. Plant according to claim 1 or 2, characterized in that the welding chamber located in the welding head (2), which surrounds the housing (12) provided for welding, can be evacuated with closed electrodes (10a, 10b). 4. Plant according to claim 3, characterized in that at least one electrode (10a, 10b) of the welding head (2) has a channel (19) for evacuation and a sealing ring (21) for sealing to the second electrode. 5. Plant according to at least one of claims 1 to 4, characterized in that the welding chamber (1) a drying oven (3) and optionally a subsequent pre-chamber (4) for intermediate storage of the housing to be closed are built, the inlet opening in the welding chamber (1 ) can be closed via a lock flap (6). 6. System according to at least one of claims 1 to 5, characterized in that the welding chamber (1) is an output lock chamber (5) is reproduced, which can be both evacuated and flushed with inert gas, and the inlet and outlet opening with a lock flap each (7, 8) can be closed. 4 AT 402 617 B 7. Plant according to at least one of claims 1 to 6, characterized in that the nitrogen for operating the welding chamber (1) helium gas is added. 8. Plant according to at least one of claims 1 to 7, characterized in that the servo drive (11) consists of an electronically controlled electric motor which drives a spindle (14), preferably a Kugeiumlaufspindel. 9. Plant according to at least one of claims 1 to 8, characterized in that the electrode (10) via a suspension (19), preferably a spring assembly is supported vertically. 10. Plant according to at least one of claims 1 to 9, characterized in that the sealing necessary for evacuation takes place on the rotating spindle part. Including 4 sheets of drawings 5