The invention relates to a soldering device comprising:

- a chamber;

- heating means for heating the objects for soldering present in the chamber; - a transporting device present in the chamber for transporting the objects for soldering;

- a cleaning device for cleaning the gases present in the chamber, which cleaning device is connected to the chamber with a feed line and a discharge line; and - a fan arranged in one of the lines.

Such a soldering device is known from US-A-4951401. The filter used in this known soldering device serves to remove waste products from the gases present in the soldering chamber. These waste products occur as a consequence of the soldering process taking place in the soldering chamber, for instance as a result of the reflow-soldering process, wherein the solder paste comprises substances which evaporate on heating. Waste products can further occur for instance due to evaporation of the fluxes used during the normal soldering using a solder wave.

These waste products are present in the soldering chamber mainly in gaseous form. When these gases are passed through the filter they will scarcely be restrained by the filter, so that the greater part of these waste products is fed back again to the soldering chamber and the filter has hardly any effect.

The object of the present invention is to provide such a soldering device wherein the filter is effective.

This object is achieved in that a cooling device is arranged in one of the lines. As a result of this step the gases flowing through the filter have a lower temperature so that condensation of the harmful substances can occur and these remain behind in the

filter. The effectiveness of the filter is thus increased.

According to a preferred embodiment the cooling device is combined with the cleaning device into one unit.

It will be apparent that, when cooling and cleaning take place inside the same unit, the effectiveness of the cleaning is greatest; precisely at the position where they are removed the harmful substances are cooled in order to cause condensation. Condensation therefore occurs at the location where the separation of the liquid substances takes place most effectively. According to a second preferred embodiment the unit is adapted for stepwise alternating cooling of the gas and cleaning thereof by means of filters. This step also results in an improved effectiveness of the cleaning process.

The invention will subsequently be elucidated with reference to the annexed figures, in which: fig. 1 shows a schematic sectional view of a first embodiment of a device according to the invention; fig. 2 shows a partly broken away perspective view of a second embodiment of the device according to the invention; and fig. 3 is a sectional view of a combination of a filter and a cooling unit for use with an embodiment according to the invention.

The soldering device 1 shown in fig. 1 comprises a soldering chamber 2 in which are arranged heating elements 3 in the form of infrared radiators. However, it is also possible to employ other heating elements.

A conveyor belt 4 is arranged in the soldering chamber for transporting the printed circuit boards for soldering, while at both the inlet side and the outlet side the soldering chamber is closed off by means of the respective doors 5, 6. Located downstream of door 5 is a first lock chamber 7 which is closed off from the outside environment by means of a door 8. Located upstream of door 6 is a lock chamber 9 which is separated from the outside environment by a door 10. Further arranged in the lock chambers are respective conveyor belts 11 and 12.

The operation of this soldering device is such that the printed circuit boards for soldering supplied from outside are carried through the opened door 8 to the lock chamber 7, whereafter the door 8 closes, the door 5 is opened and the printed circuit board for soldering is carried by the conveyor belt 11 to soldering chamber 2 where it is transported by the conveyor belt present therein. While they are moving through soldering chamber 2 on conveyor belt 4 the objects for soldering are heated by the heating devices 3. The heating devices 3 are controlled herein such that a certain heating profile results. After ending of the soldering process the printed circuit board for soldering is transported through the door 6 to the lock chamber 7, whereafter the door 6 is closed, door 10 opened and the printed circuit board discharged. During soldering chemical processes take place on the printed circuit board caused by the high temperatures required for the soldering process, whereby reaction products are created which can contaminate the interior of the soldering chamber. Thi has an adverse effect on the good operation of the components present in the soldering chamber, including the heating devices and the transporting device.

To obviate this problem a filter unit 13 is arranged which in the present embodiment is placed under the soldering device.

Arranged for feed of the gas is a feed line 14 which draws in contaminated gas in the part of the soldering chamber located furthest downstream. The filter unit is further connected by means of a discharge line 15 to a part of the soldering chamber located downstream. A fan 16 is arranged in the discharge line 15. Shown in fig. 2 is a soldering machine 18 through which extends a conveyor belt 19 for the printed circuit boards for soldering. Incorporated in the soldering machine 18 is a fluxer 20, in addition to a pre-heating device 21 and a soldering devi 22. Placed beneath the soldering device is a combination unit 23 of a filter and a cooling device according to the present

invention. This unit is connected by means of a feed line 24 to a part of the soldering machine located downstream, while the unit is connected by means of a line 25 to a part of the soldering machine located downstream. The soldering machine can be formed by a normal soldering device operating with ambient air, but it will be apparent that the best cleaning results are obtained with a soldering machine which operates with gas substantially excluding oxygen and which, like the embodiment shown in fig. 1, is connected by locks to the outside air in order to prevent as far as possible the entry of ambient air, and therefore oxygen.

The construction of the cooling and filtering unit will now be described with reference to fig. 3. The cooling and soldering unit 23 depicted in fig. 3 is formed by a substantially cylindrical housing 27, one side of which is closable by means of a cover 28. Arranged on the other side of cylindrical housing 27 is a fixed cover 29, in the centre of which is arranged an opening 30. Two cylinder jacket-like cooling elements 31 and 32 are arranged in the housing, both fixed to the end wall 29. Further, a first guide cylinder 33 is fixed to the removable cover and more to the centre a second guide cylinder 34 is arranged which extends between the first cooling element 31 and the second cooling element 32. This second guide cylinder 34 is supported by means of spacers not shown in the drawing. This cylinder is further provided with a fixed cover 35.

Arranged further on the end wall of the first cooling element is a coarse filter 36 followed more toward the inside by an annular first fine filter 37. The second annular filter 38 is further arranged between both cooling elements 31, 32 and the end wall 29 and the second guide cylinder, while in the interior of the second cooling element are fixed two fine filters 39, 40.

Both cooling elements 31, 32 are connected by means of connecting lines 41 to a cooling machine 42.

The operation of this combined filtering and cooling unit will now be described. The gases for cleaning are supplied via

feed lines 43, whereafter they are distributed tangentially over the periphery of the combination device, wherein the gases are guided between the cylindrical housing 27 and the first guide cylinder. When the thus guided gases have reached the end wall 2 they reverse direction and are guided between the first guide cylinder 33 and the first cooling element 31, wherein a cooling of the gases takes place. On reaching the cover 28 the gases pas through the coarse filter 36, wherein coarse impurities and dust are collected, and the first condensed droplets are collected. The gases then pass through the annular fine filter 37, are guided between the first cooling element 31 and the second guide cylinder 34 and thus further cooled. When reaching the filter 38 the gases reverse direction, wherein droplets condensing during the further cooling are collected, and the gases are further guided between the second guide cylinder 34 and the second cooling element 32 in the direction of the cover 35 where they reverse direction and are subsequently guided through the interior of the second cooling element 32 through filters 39, 40 to a collection space 44 and are discharged via outlet duct 45.