EP0211239A1 - Apparatus for the treatment of bulk goods - Google Patents

Abstract

1. Treatment apparatus for bulk goods, having a treatment bath which is accommodated in a tank and through which the bulk goods can be transported with the aid of at least one vibrating conveyor having a conveying track spiralling upwards, a device (FR2, FR20, We) for the returning of the treated goods (G) into the starting area of the vibrating conveyor (Sf), returning the treated goods (G) into the treatment bath (Bb) and carrying the goods out of the treatment apparatus, according to choice.

Description

The invention relates to a treatment device for pourable goods, in particular for activating, pickling, degreasing, rinsing and cleaning pourable goods in electroplating, with a treatment bath accommodated in a tub, through which the pourable goods with the help of at least one vibratory conveyor with a helical upward leading conveyor track is transportable.

From the magazine "Galvanotechnik" D-7968 Saulgau, 75 (1984) No. 11, p. 1399 it is known to carry out the galvanic metal deposition in radial vibrators during the bulk galvanization of pourable material. The vibration of the goods results in a thorough mixing and an improved electrolyte exchange with gentle handling of the goods and also a particularly uniform metal deposition. It is also pointed out that the movement of goods by vibration also offers advantages in washing processes. The disadvantages of treating bulk material in radial vibrators are the low productivity in large series and the higher processing costs.

From US-A-3 216 431 a treatment device of the type mentioned is known, in which an automatic conveyance of the pourable material with simultaneous vibration of the material is achieved through the use of an oscillating conveyor. However, the helical conveyor track of the vibratory conveyor, which is attached to a central support column and suspended from above in the treatment bath, can only be realized with a limited length for constructional reasons and for reasons of strength. For this The reason is that the dwell times of the pourable goods in the treatment bath are too short in many applications.

From EP-OS 007 0011 air treatment devices for pourable material are known, which are used for the galvanic deposition of aluminum from aprotic, oxygen and water-free, organoaluminum electrolytes. Such galvanic aluminum deposits are characterized by their ductility, low pore density, corrosion resistance and anodizing ability. Since the entry of air through reaction with atmospheric oxygen and air humidity would bring about a considerable reduction in the conductivity and the service life of these electrolytes, the electroplating must be carried out in treatment facilities in which the tub receiving the electrolyte is sealed gas-tight and the space above the electrolyte level is sealed with an inert gas is applied. So that the access of air can be prevented even when loading and unloading these air-tight treatment facilities, import and export locks are also required, which are designed as gas locks, as liquid locks or as combined gas-liquid locks and with means of conveyance for passing through the electroplated material are equipped.

The invention has for its object to improve a treatment device of the type mentioned so that the residence times can be adapted to the respective requirements at a sufficiently high throughput and thereby a simple removal of the finished galvanized material from the treatment bath is guaranteed.

This object is achieved in that the pourable good optionally at the end of the Vibratory conveyor connectable feedback device in the initial region of the vibratory conveyor is traceable. With the recirculation device connected, the product can be subjected to the respective treatment in circulation mode until the desired result has been achieved with very good mixing. The return device is then uncoupled so that the finished material can be discharged in the normal way. These advantages result from treatment facilities for pourable goods with any treatment baths. Activator baths, pickling baths, degreasing baths, rinsing baths, cleaning baths, baths containing desiccants, galvanic baths and also baths for electroless metal deposition are only to be mentioned as examples of a large number of treatment baths.

The changeover between circulation and discharge is particularly easy to accomplish if the return device can be connected to the end of the vibratory conveyor via a switch. If the return device is designed as a gravity conveyor, then additional funds for the return can be dispensed with. The gravity conveyor is then preferably formed by a downpipe. When operating under the exclusion of air treatment devices such drop tube can particularly easy to import a subsequent lock device are connected, thereby gf ^g. As a downward leading leg of a U-shaped fluid lock are used.

According to a preferred embodiment of the invention, the conveyor track of the vibratory conveyor is provided with a perforation at least in some areas. Such a perforation further increases the exchange of the treatment liquid and the uniformity of the surface treatment.

In the treatment devices according to the invention with the conveyor track leading helically upwards, it is also advantageous if the conveyor track of the vibratory conveyor is led beyond the level of the treatment bath. Above the bath level, the liquid drops still adhering to the material are then thrown away by the vibrations, so that there is extremely little carryover of the bath liquid. A spray device for spraying a liquid compatible with the treatment bath can then also be arranged at least in the end region of the conveyor path of the vibratory conveyor. With the help of this spray device, the treated material can then be freed from adhering residues of the bath liquid and cleaned. Since these residues of the bath liquids run back into the treatment bath, the removal of the bath liquid is further reduced or avoided entirely.

A treatment device according to the invention can be operated with relatively little additional effort in the absence of air and can be used, for example, for the treatment of the goods in aprotic, oxygen- and water-free treatment baths. In this case, the tub can be closed gas-tight, while the space above the treatment bath can be charged with an inert gas. In addition to the advantages already mentioned, the use of a vibratory conveyor has the additional advantage that no drive shafts leading out of the tub and the treatment bath have to be sealed. In addition, the parts treated in the absence of air can be transferred directly or via a lock to a subsequent treatment facility, such as e.g. an air-operated aluminizing device, i.e. they do not come into contact with air and reactions such as oxidations, corrosion and the like are avoided.

With a and equipped with a spray device it is also particularly expedient if the treatment device can be operated with the exclusion of air if a condensation device is arranged in the space above the level of the treatment bath, the condensate formed in the condensation device being able to be fed to the spray device. A solvent contained in the treatment bath is therefore used to clean the treated goods, the closed circulation of this solvent allowing a constant solvent concentration in the treatment bath.

The supply of the pourable material to the vibratory conveyor is particularly easy to implement if a gravity conveyor is connected upstream of the vibratory conveyor, as seen in the conveying direction. The same advantages also result in the discharge if a gravity conveyor is arranged downstream of the vibratory conveyor - seen in the direction of conveyance. In both cases, it is particularly favorable if the gravity conveyor is formed by a downpipe. In the case of treatment facilities operated with the exclusion of air, downpipes of this type can also be connected particularly easily to corresponding import or export locks. In the case of an export lock, the downpipe can then already be used as a downward leg of a U-shaped liquid lock. Moreover, when using import and export locks for the passage of the bulk goods _ vibratory conveyors can also be used, which ensure gentle handling of the goods and pose no problems with regard to the sealing of the lock chambers.

An embodiment of the invention is shown in the drawing and will be described in more detail below.

The drawing shows in a highly simplified schematic Representation of a longitudinal section through a tower-shaped treatment device, in which pourable material G, which is, for example, bolts, nuts, screws, spacer bushings and the like, is treated in a treatment bath Bb with the exclusion of air. This treatment bath Bb is located in a circular cylindrical tub W, which can be closed gas-tight with the aid of an upper lid D and is arranged on a frame Ge. The area of the tub W located above the level Sp of the treatment bath Bb is subjected to an inert gas, such as nitrogen. the supply of this inert gas is indicated by an arrow Ig. The treatment bath Bb can be continuously circulated during operation with the aid of a circulation pump Up and, if necessary, can also be heated outside the tub W to the required operating temperature, such circulation of the bath liquid being indicated by arrows Bf.

The material G to be treated is introduced from above into the lower region of the tub W via an inlet lock and a downpipe Frl, the downpipe Frl being filled with the treatment bath Bb up to the level of the mirror Sp and then with inert gas Ig is acted upon. The material G introduced via the downpipe Frl then falls onto the lower end of the conveyor track Fb of an oscillating conveyor arranged inside the tub W and designated overall by Sf. On the conveyor track Fb, which is designed as a vibrating trough and spirally upwards, the material G is transported upward above the mirror Sp of the treatment bath Bb and then falls into the funnel-shaped upper end of a downpipe Fr2 leading out of the tub W, which is in the manner of a Down pipe branches into a downpipe Fr20 and a downpipe Fr21. In the position shown in the drawing of a switch We arranged at the branching point, the good G then becomes via the downpipe Fr20 re-entering the tub W to the bottom aisle of the helical conveyor track Fb. If the switch We, which is designed as a pivotable flap, is adjusted in the direction of the arrow Pf, the finished goods G are passed directly via the downpipe Fr21 or via a lock into a treatment device arranged downstream.

The conveyor track Fb leading upwards in a spiral shape in the tub W is provided with a perforation P indicated only at one point in the drawing and fastened to a centrally arranged support column Ts. The lower end of the support column Ts is fastened on a vibrator V arranged centrally within the frame Ge. The passage of the support column Ts through the bottom of the tub W is sealed by an elastic bellows B, which is connected on the one hand to a disc placed on the support column Ts and on the other hand to the bottom of the tub W. The conveyor track Fb is excited by the vibrator V via the support column Ts to vibrate with an approximately helical movement. Due to the oblique movement and the accelerations and speeds that occur, an oblique throw is forced on the goods G lying on the helically upward conveying path Fb, so that the pourable goods G are transported upwards in the direction of conveyance at a profit. Since the throwing distance and throwing height are extremely small, this type of funding involves micro-throwing, which ensures extremely gentle treatment of the good G. In the example shown, the support column Ts is fixedly connected via a flange Fla to a supporting body Tk of the vibrator V which widens conically towards the bottom. The supporting body Tk is mounted on the foundation so that it can vibrate via several springs Fd. An unbalance drive is arranged within the supporting body Tk, the motor M of which has flywheels Ss arranged on both sides drives with adjustable eccentricity e. The drive axis Aa of the motor M is inclined at an angle of, for example, 45 ° to the horizontal, so that the unbalance of the flywheels Ss generates the vibrations already mentioned with an approximately helical movement.

The pourable material G is transported via the conveyor track Fb through the treatment bath Bb and is subjected to a surface treatment depending on the type of treatment bath. The vibrations of the conveyor track Fb and the good G favor an all-round and uniform treatment of the good G and in particular its mixing and the exchange of the bath liquid. The treatment device is operated in the position of the switch We shown in the drawing until the desired success of the treatment has been achieved. Thereafter, the goods G led beyond the mirror Sp of the treatment bath Bb are freed from the residues of the bath liquid still adhering to them with the aid of a spray device Se arranged in the tub W and discharged via the switch We which is switched in the direction of the arrow Pf and the downpipe Fr21 or a downstream one Treatment facility supplied. The spraying device Se sprays a solvent contained in the treatment bath Bb, which is obtained from the vapors rising from the heated treatment bath Bb as condensate Ko. For this purpose, a condensation device Ke arranged above the mirror Sp of the treatment bath Bb and consisting of a helically wound cooling tube is used, the condensate Ko formed on this condensation device Ke being collected in a gutter Sr arranged underneath and fed to the spraying device Se via a circulation pump (not shown in the drawing) becomes.

Example I:

The treatment facility shown in the drawing is used for activating the pourable material G, the activator bath used as treatment bath Bb consisting, for example, of a suitable non-aqueous acid, such as hydrogen fluoride and an organic solvent, such as alcohol. Depending on the initial state of the good G, the treatment device is operated in circulation until cast or rolled skins, oxide layers, rust or scale have been removed and a metallically pure surface has formed. The material G is then cleaned with the spray device Se and fed to a downstream treatment device via the downpipe Fr21. Since the treated material G does not come into contact with air, the pure metallic surface is no longer deteriorated again by oxidation, corrosion and the like, but is maintained until the end of the entire treatment, for example until an aluminum coating has been electrodeposited. As a result, the adhesive strength and quality of subsequently applied coatings are considerably improved.

Example II:

The treatment device shown in the drawing is used for degreasing the pourable material G, the degreasing bath used as treatment bath Bb by an organic solvent such as e.g. Carbon tetrachloride or trichlorethylene or is formed by a hot degreasing solution. Because the degreasing is carried out in a single pass or in the absence of air, the emission of harmful vapors rising from the degreasing bath to the environment is avoided.

Example III

The treatment device shown in the drawing is a device for the galvanic deposition of aluminum from aprotic, oxygen and water-free, subordinate organo-aluminum electrolytes. The inlet-side downpipe Frl is connected to the discharge side of the aluminizing device in such a way that the tub W fills with the organoaluminum electrolyte as treatment bath Bb according to the principle of the communicating tubes. The aprotic solvent evaporating from the heated electrolyte, which is, for example, toluene, is condensed on the cooling device Ke and supplied to the spray device Se. The cleaning carried out with the aid of the spray device Se prevents the electrolyte from being carried away with the product G. Since the goods G are cleaned in one pass, the downpipe Fr20 serving as a return device can be omitted. In order to reliably prevent air from entering the electrolyte or treatment bath Bb, the downpipe Fr21 is followed by an export lock which is preferably designed as a liquid lock.

Reference list for VPA 85 P 1421

• B
• Bb
• Bf
• D
• Col
• Fd
• Fla
• Frl, Fr2, Fr20, Fr21
• G
• Ge
• Ig
• Ke
• Knockout
• M
• P
• Pf
• Se
• Sf
• Sp
• Sr.
• Ss
• Tk
• Ts
• Up
• V
• W
• We
• e
• bellows
• Treatment bath
• Bath liquid
• cover
• Conveyor track
• feather
• flange
• Downpipe
• pourable goods
• frame
• Inert gas
• Condensing device
• condensate
• engine
• perforation
• arrow
• Spraying device
• Vibratory conveyor
• Mirror of the treatment bath
• Collecting trough
• flywheel
• Supporting body
• Support column
• Circulation pump
• vibrator
• Tub
• Switch
• eccentricity

Claims (12)

1. Treatment device for pourable goods, in particular for activating, pickling, degreasing, rinsing and cleaning of pourable goods in electroplating, with a treatment bath accommodated in a tub, through which the pourable goods with the help of at least one vibratory conveyor with a helically leading upward Conveyor track can be transported, characterized in that the pourable material (G) can be returned to the starting area of the vibratory conveyor (Sf) via a return device which can optionally be connected to the end of the vibratory conveyor (Sf). 2. Treatment device according to claim 1, characterized in that the return device can be connected via a switch (We) to the end of the vibratory conveyor (Sf). 3. Treatment device according to claim 1 or 2, characterized in that the return device is designed as a gravity conveyor. 4. Treatment device according to claim 3, characterized in that the gravity conveyor is formed by a downpipe (Fr2, Fr20). 5. Treatment device according to one of the preceding claims, characterized in that the conveyor track (Fb) of the vibratory conveyor is at least partially provided with a perforation (P). 6. Treatment device according to one of the preceding claims, characterized in that the conveyor track (Fb) of the vibratory conveyor (Sf) on the mirror (Sp) of the treatment bath (Bb) is guided. 7. Treatment device according to claim 6, characterized in that at least in the end region of the conveyor track (Fb) of the vibratory conveyor (Sf) a spray device (Se) for spraying a liquid compatible with the treatment bath (Bb) is arranged. 8. Treatment device according to one of the preceding claims, characterized in that the trough (W) can be closed in a gas-tight manner and in that the space above the mirror (Sp) of the treatment bath (Bb) can be acted upon with an inert gas (Ig). 9. Treatment device according to claims 7 and 8, characterized in that a condensation device (Ke) is arranged in the space above the mirror (Sp) of the treatment bath (Bb) and that the condensate (Ko) formed in the condensation device (Ke) Spray device (Se) can be fed. 10. Treatment device according to one of the preceding claims, characterized in that the vibratory conveyor (Sf) - seen in the conveying direction - is preceded by a gravity conveyor. 11. Treatment device according to one of the preceding claims, characterized in that the vibratory conveyor (Sf) - seen in the conveying direction - is followed by a gravity conveyor. 12. Treatment device according to claim 10 or 11, characterized in that the gravity conveyor is formed by a downpipe (Frl, Fr2, Fr21).

Images