EP0209005B1 - Air lock for loading and unloading a treatment apparatus working under air-free conditions - Google Patents

Abstract

A lock for loading and unloading a treatment apparatus with bulk goods characterized by at least one U-shaped lock chamber fillable with inert fluid and chargeable with inert gas. To transport the goods through the ascending portion of the U-shaped lock, the lock has a vibratory conveyor comprising a helically ascending conveyor track which can be either a separate track in a chamber or can be formed by a floor of a helically ascending lock chamber. To form the vibratory conveyor, either the helically ascending lock chamber or the helically ascending conveyor is connected to a vibrator preferably through a central column.

Description

The invention relates to a sluice for loading and / or unloading a treatment device for bulk goods working in the absence of air, in particular a device for the electrodeposition of aluminum from aprotic, oxygen-free and water-free, organoaluminum electrolytes, with at least one fillable with inert liquid and pressurized with inert gas U-shaped lock chamber and with means of conveyance for passing the bulk goods along a defined conveying path.

Aluminum deposited from aprotic, oxygen and water-free, organoaluminum electrolytes is characterized by its ductility, low pore density, corrosion resistance and anodizing ability. Since the entry of air through reaction with atmospheric oxygen and air humidity causes a considerable reduction in the conductivity and the service life of these electrolytes, the electroplating must be carried out in an air-tight treatment facility. Pretreatment baths required for surface pretreatment of the aluminized material and aftertreatment baths required to remove electrolyte residues and / or hydrolysis products from the aluminized material are also held in air-operated treatment facilities. Further application examples for such airtight closable treatment devices are electroplating, polishing or cleaning processes, in which the corresponding baths develop, for example, toxic, explosive or other gases or vapors which impair the environment. So that the entry of air or the escape of gases or vapors can be prevented even when loading and unloading these air-tight treatment facilities, import and export locks are required, which are designed as gas locks, as liquid locks or as combined gas-liquid locks and with Subsidies are equipped to pass through the material to be treated.

From EP-PS 00 13 874 an air-tight device for the electrodeposition of aluminum from aprotic, oxygen and water-free, organoaluminum electrolytes is known, in which the aluminum material is introduced via a liquid lock into the electroplating tank containing the electrolyte and also via this liquid lock is removed again. The liquid lock consists of a U-shaped lock chamber which is filled with an inert liquid and which is preceded by a prechamber provided with a gas-tight lockable door and containing an inert gas. To load the device, the goods racks carrying the electroplated goods are brought into the pre-chamber via the gas-tight door and attached to a conveyor device with two endless conveyor chains. The goods racks then pass through the antechamber, the lock chamber filled with inert liquid and an inert gas space arranged above the electrolyte level in the electroplating trough, whereupon they are immersed in the electrolyte. After aluminizing, the removal takes place in the opposite direction.

The lock of this known device is equipped with complex and complicated conveying means, which also only allow goods racks to pass through.

However, goods racks are uneconomical for aluminizing bulk goods such as bolts, nuts, screws, spacer bushings and the like. because the clamping of such an aluminum product would be very labor-intensive and therefore very expensive.

From EP-PS 00 70 011 another air-working device for the electrodeposition of aluminum from aprotic, oxygen- and water-free, organoaluminum electrolytes is known, in which pourable aluminum material is introduced into an electroplating drum rotatably arranged in the electroplating trough via an inlet lock designed as a liquid lock introduced and after passing through the electroplating drum provided on the inner wall with a helical rib as a means of conveyance, it is conveyed out again via an export lock also designed as a liquid lock. The aluminized material is introduced into the entry lock via an introduction funnel and then transported to the front end of the electroplating drum via a conveyor belt beginning below the inert liquid level and a funnel connected to it. At the rear end of the electroplating drum is a conveyor belt starting below the electrolyte level, the other end of which is led out of the electrolyte. From the upper end of this conveyor belt, the aluminizing material passes via a funnel-shaped component onto a part of another conveyor belt which is immersed in the inert liquid and which ends above the inert liquid level above a funnel-shaped outlet nozzle. This known device has the advantage that pourable goods can be aluminized in a continuous process without having to be clamped onto goods racks. However, the funding for the passage of the aluminized material through the import lock and the export lock are also relatively complicated. In addition, the use of conveyor belts requires sealing the drive shafts led out of the lock, such a sealing of rotating parts being problematic given the high demands made here.

The invention has for its object to provide a lock for loading and unloading a working device in the absence of air for pourable goods, in which the for the conveying means used do not require the sealing of rotating parts and ensure gentle conveyance of the pourable goods.

This object is achieved in a lock of the generic type in that the pourable material can be transported by means of an oscillating conveyor with a conveyor track leading upwards through the upwardly extending leg of the U-shaped lock chamber. Vibratory conveyors are conveyors that transport bulk goods using the mass forces along a defined conveying path in a horizontal and / or inclined direction. As a rule, oblique vibrators or inclined handlebars serve to drive the conveyor track in such a way that the material mostly carries out micro-throwing movements and, if necessary, it is transported in the direction of conveyance at a profit. The use of vibratory conveyors with helical conveyor tracks in air-operated treatment facilities is known from FR-A-2 318 945, DE-A-2 914 868 or US-A-3 868 213.

The invention is based on the finding that vibratory conveyors of this type used in sluices as conveying means do not pose any problems with regard to the sealing and, in addition, enable extremely gentle conveying of pourable material, whereby there is no fear of jamming of the conveying material. On the conveying path through the inert liquid, the vibration of the vibratory conveyor reliably precludes the introduction of gases or vapors into the treatment device via the pourable material. In addition, inert liquid drops still adhering to the pourable material are flung away above the inert liquid level, so that there is only an extremely small carryover of the inert liquid.

The conveyor track is preferably designed as a vibrating trough, which ensures reliable guidance of the goods to be passed through with little effort.

According to a particularly preferred embodiment of the invention, the conveyor track is formed by the bottom of the lock chamber leading helically upwards. The conveyor track thus forms an integral part of the lock chamber, which preferably has a rectangular cross section. Since practically only one vibration exciter is required for the lock chamber to convey the bulk goods, the lock can be realized with a minimum of effort. The problem of sealing drive parts of the conveyor is completely eliminated.

When conveying the pourable material with the helically upward conveying path, it may also be advantageous if an inert liquid flow acting in the conveying direction on the pourable material can be generated in the area of the lock chamber that can be filled with inert liquid. In this case, a damping of the delivery by the inert liquid is counteracted and a support of the delivery by the inert liquid flow is achieved.

If the lock chamber is fastened to a centrally arranged support column, this support column can then serve both as a supporting structure of the lock chamber leading helically upwards and for transmitting the vibrations. The vibration excitation is then brought about in a simple manner in that the support column is arranged on a vibrator or carries a vibrator. The vibrator is then expediently equipped with an unbalance drive. If the unbalance drive has at least one flywheel with adjustable eccentricity, the parameters of the conveyance can be easily optimized and adapted to the particular characteristics of the pourable material.

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 if a gravity conveyor is arranged downstream of the vibratory conveyor when viewed in the conveying direction. In both cases, it is particularly favorable with regard to the sealing of the lock if the gravity conveyor is formed by a downpipe. The gravity conveyor is then included in the lock area, i.e. it is used as a downward leg of a U-shaped liquid lock.

Furthermore, it is expedient if the gravity conveyor can be closed gas-tight on the inlet or outlet side by a cover. If at least the area of the gravity conveyor located below or above the cover can then be flooded with inert gas, this area can easily assume the function of a chamber upstream or downstream of the liquid lock. In order to obtain a balance between stationary parts of the lock and parts of the lock that are mounted so that they can vibrate and to avoid the risk of permanent breaks, it is also expedient if the gravity conveyor comprises an upstream, downstream or intermediate compensator. In the case of an intermediate compensator, part of the gravity conveyor is arranged in a stationary manner, while the other part is excited by the vibrations required for conveying the pourable material.

A further improvement in the conveyance can also be achieved if the conveying path of the vibratory conveyor has a roughened, profiled or friction-coated surface at least in the end region of the associated conveying path. These measures increase the static friction between the conveyor track and the goods to be conveyed to such an extent that safe conveying and complete emptying of the lock is guaranteed in any case.

When using volatile inert liquids such as toluene and the like, it is also advantageous if, as seen in the conveying direction, at least one cooling zone follows the lock zone which can be filled with inert liquid, this cooling zone preferably being formed by cooling tubes. The fact that vapors rising from the inert liquid then condense in the area of the cooling zone and are returned as condensate means that the loss of inert liquid can be kept particularly low.

Embodiments of the invention are shown in the drawing and are described in more detail below.

• Fig. 1 eine mit einer wendelförmigen Schwingrinne ausgerüstete Einfuhrschleuse einer Einrichtung zum galvanischen Abscheiden von Aluminium,
• Fig. 2 eine mit einer wendelförmigen Schleusenkammer ausgerüstete Einfuhrschleuse einer Einrichtung zum galvanischen Abscheiden von Aluminium,
• Fig. 3 eine mit einer wendelförmigen Schleusenkammer ausgerüstetet Ausfuhrschleuse einer Einrichtung zum galvanischen Abscheiden von Aluminium, und
• Fig. 4 Einzelheiten des in der Ausfuhrschleuse gemäß Fig. 3 verwendeten Vibrators.

They show in a highly simplified schematic representation

• 1 shows an entry lock equipped with a helical vibrating trough of a device for the galvanic deposition of aluminum,
• 2 shows an entry lock of a device for the galvanic deposition of aluminum equipped with a helical lock chamber,
• Fig. 3 is equipped with a helical lock chamber export lock of a device for the galvanic deposition of aluminum, and
• Fig. 4 details of the vibrator used in the export lock according to FIG. 3.

Fig. 1 shows an overall designated S2 lock, which serves as an import lock or an export lock of a device, not shown in the drawing, for the galvanic deposition of aluminum from aprotic, oxygen and water-free, organoaluminum electrolytes. The pourable material G to be aluminized, which is, for example, bolts, nuts, spacer bushings and the like, is introduced on the lock entry side into a downpipe Fr1 which can be closed gas-tight by a cover D1, the lower end of which is inclined in the lower region, partially with a Inert liquid, such as. B. toluene, filled lock chamber Sk2 opens. Since the downpipe Fr1 and the cylindrical lock chamber Sk2 are communicating tubes, the principle of a U-shaped liquid lock is realized. Within this liquid lock, an inert liquid flow directed essentially in the direction of conveyance of the pourable material G is generated with the aid of a circulation pump, not shown in the drawing, the supply of the inert liquid into the downpipe Fr1 and the discharge of the inert liquid from the lock chamber Sk2 being indicated by arrows Ig are. The area of the downpipe Fr1 lying below the cover D1 and above the inert liquid level is mixed with an inert gas, such as, for. B. nitrogen, wherein the supply of the inert gas opening just above the inert liquid level and the discharge of the inert gas from a vertical branch Az1 of the downpipe Fr1 are shown by arrows Ig.

The pourable material G introduced via the downpipe F1 falls onto the lower end of the conveyor track F3 of an oscillating conveyor arranged within the lock chamber Sk2 and designated overall as Sf3. On the conveyor track F3, which is designed as a vibrating trough and spirally upwards in the conveying direction, the pourable material G is transported upward above the inert liquid level and then falls into the funnel-shaped upper end of a downpipe Fr2 leading out of the lock chamber Sk2, the lower end of which is covered by a cover D2 can be closed gas-tight. If the lock S2 is used as an entry lock, the lower end of the downpipe Fr2 opens into the galvanizing device working in the absence of air and the cover D2 can be omitted. The area of the lock chamber Sk2 above the inert liquid level and the downpipe Fr2 are filled with an inert gas, such as. B. Nitrogen, whereby the supply of inert gas opening just above the inert liquid level into the lock chamber Sk, the supply of inert gas opening into the lower region of the downpipe Fr2 and the discharge of the inert gas through the upper end cover Ad of the lock chamber Sk2 are indicated by arrows Ig are. On the section of the conveying path leading through the inert gas zone, the inert liquid drops still adhering to the pourable material G are thrown away by the vibrations of the conveying path F3, so that there is only an extremely small carryover of the inert liquid If from the lock chamber Sk2.

The conveyor track F3, which leads helically upwards within the lock chamber Sk2 and is designed as a vibrating channel, is fastened to a centrally arranged support column Ts1, the lower end of which is fastened to a vibrator V3 arranged centrally within the support frame Tg of the lock chamber Sk2. The passage of the support column Ts1 through the bottom of the lock chamber Sk2 is sealed by an elastic bellows B3, which is connected on the one hand to a disc placed on the support column Ts1 and on the other hand to the bottom of the lock chamber Sk2. The vibrating conveyor F3 is excited by the vibrator V3 via the support column Ts1 to vibrate with an approximately helical movement. Due to the oblique movement and the accelerations and velocities that occur, an inclined throw is imposed on the pourable material G lying on the helically upward conveying path F3, so that the pourable material G is transported at a height in the direction of conveyance. Since the throwing distance and throwing height are extremely small, this type of conveyance involves micro-throwing, which ensures extremely gentle handling of the material G to be passed through.

2 shows a lock designated overall by S3, which serves as an entry lock for a device E1, only indicated in the drawing, for the galvanic deposition of aluminum from aprotic, oxygen and water-free, organoaluminum electrolytes. To aluminize that de Gut G is introduced on the lock entry side into a downpipe Fr3 which can be closed in a gas-tight manner by a cover D3. B. toluene, filled and helically leading upward lock chamber Sk3 opens. Since the downpipe Fr3 and the lock chamber Sk3 having a rectangular cross section are communicating tubes, the principle of a U-shaped liquid lock is realized. With the aid of a circulation pump Up, an inert liquid flow directed in the conveying direction of the pourable material G is generated within this liquid lock, the circulation of the inert liquid being indicated by arrows lf. The area of the downpipe Fr3 lying below the cover D3 and above the inert liquid level is mixed with an inert gas, such as. B. nitrogen, wherein the supply of the inert gas lying just below the inert liquid level and the derivation of the inert gas from a vertical branch Az2 of the downpipe Fr3 are shown by arrows Ig.

The pourable material G introduced via the downpipe Fr3 thus reaches the lower end of the lock chamber Sk3, the bottom of which simultaneously acts as a helically upward conveying path F4 of an oscillating conveyor designated overall by Sf4. In the lock chamber Sk3, the pourable material G is then transported upwards on the conveyor track F4 above the inert liquid level and then arrives in a downpipe Fr4 directly adjoining the upper end of the lock chamber Sk3, the lower end of which in the one above the electrolyte E1 Inert gas-charged space of the device E1 opens. The area of the lock chamber Sk3 lying above the inert liquid level and the downpipe Fr4 are flushed with an inert gas, such as e.g. B. nitrogen, the supply of which is indicated by an arrow Ig and whose derivation, not shown, is carried out in the area of the device E1. On the section of the conveying path leading through the inert gas zone of the lock chamber Sk3, the inert liquid drops still adhering to the pourable material G are thrown away by the vibrations of the conveying path F4 and run back into the inert liquid zone, i. H. there is extremely little carryover of the inert liquid If into the electrolyte E1. In addition, vapors rising from the inert liquid lf are also condensed in a cooling zone before entering the downpipe Fr4, so that they run back as condensate into the inert liquid lf. This cooling zone is formed by cooling tubes Kr1, which are attached to the floor from the outside in the area of the upper passages of the helical lock chamber Sk3. Vapors rising from the electrolyte E1 into the downpipe Fr4 are condensed there in a second cooling zone, so that they run back into the electrolyte E1 as condensate. This second cooling zone is formed by a cooling pipe Kr2 placed helically around the lower region of the downpipe Fr4.

The helical lock chamber Sk3 leading upwards is fastened to a centrally arranged support column Ts2, the lower end of which is arranged on a vibrator V4. This vibrator V4 then excites the entire lock chamber Sk3 via the support column Ts2 to vibrate with an approximately helical movement, so that the pourable material G is transported upwards on the conveyor track F4 by micro-throwing. Since the areas of the downpipes Fr3 and Fr4 directly adjoining the lock chamber Sk3 are also forced onto the conveying vibrations, they are connected to the fixedly arranged downpipe areas via elastic compensators K1 and K2.

Fig. 3 shows an overall designated S4 lock, which serves as an export lock of a device E2 only indicated in the drawing, wherein this device E2 is either a device for the electrodeposition of aluminum from aprotic, oxygen and water-free, organoaluminum electrolytes or an aftertreatment device for the aluminized material G which works in the absence of air. The material G aluminized or aftertreated in the device E2 is introduced inside the device E2 into the funnel-shaped upper end of a downpipe Fr5 which can be closed in a gas-tight manner by a cover D4. This down pipe Fr5, which is led to the outside and equipped with an intermediate compensator K3, opens into the lower end of a pipe partially filled with an inert liquid, such as, for. B. toluene, filled and helically upward leading lock chamber Sk4. Since the downpipe Fr5 and the lock chamber Sk4, which has a rectangular cross section, are communicating tubes, the principle of a U-shaped liquid lock is also implemented here. An inert liquid flow directed in the conveying direction of the pourable material G is generated within this liquid lock with the aid of a circulation pump, the supply of the inert liquid into the downpipe Fr5 and the exit of the inert liquid from the lock chamber Sk4 being indicated by arrows lf. The area of the downpipe Fr5 lying above the inert liquid level is in an inert gas, such as. B. nitrogen, acted upon, the supply of the inert gas lying just above the inert liquid level being indicated by an arrow Ig.

The pourable material G introduced via the downpipe Fr5 thus reaches the lower end of the lock chamber Sk4, the bottom of which acts at the same time as a helically upward conveying path F5 of an oscillating conveyor generally designated Sf5. The lock chamber Sk4 is fastened to a centrally arranged support column Ts3, the lower end of which is arranged on a vibrator V5. By means of this vibrator V5, the entire lock chamber Sk4 is set in vibration via the support column Ts3 in such a way that the pourable material G is transported upwards above the inert liquid level by micro-throwing and into a directly adjacent to the upper one The downpipe Fr6 reaches the end of the lock chamber Sk4. The lower end of the downpipe Fr6 equipped with an intermediate compensator K4 can be closed gas-tight by a cover D5. In order to prevent the entry of air into the lock S4 when the bulk material G is removed with the lid D5 open, the area of the lock chamber Sk4 and the downpipe Fr6 lying above the inert liquid level are filled with an inert gas such as e.g. B. nitrogen, the supply of the inert gas into the lock chamber Sk4 and the discharge of the inert gas from the downpipe Fr6 are shown by arrows Ig. The inert gas zone of the lock chamber Sk4 acts here again as a drying zone due to the vibrations transmitted to the pourable material G, in which adhering drops of inert liquid are thrown away. In addition, in the area of the upper passages of the lock chamber Sk4, cooling tubes Kr3 are provided from the outside, which form a cooling zone for the condensation of vapors rising from the inert liquid lf.

FIG. 4 shows, using the example of the vibrator V5 used in the lock S4, the functional principle of the vibration excitation by means of an unbalance drive designated overall by Ua. The vibration excitation of the gravity conveyor Sf5 takes place via the support column Ts3 carrying the lock chamber Sk4, which is fixedly connected via a flange F1 to a support body Tk of the vibrator V5 which widens conically towards the bottom. The support body Tk is supported on a bearing L such that it can vibrate, the bearing L being formed, for example, by a plurality of springs, as indicated by the spring Fd at one point. The unbalance drive Ua, whose motor M drives flywheels Ss1 and Ss2 with adjustable eccentricity e, is arranged within the conical support body Tk. The drive axis Aa of the motor M is inclined at an angle β of, for example, 45 ° to the horizontal. The entire oscillatable system is then caused to vibrate by the unbalance of the flywheels Ss1 and Ss2 in such a way that the acceleration forces exerted on the pourable material G cause micro-throwing along the conveyor path F5 leading helically upwards in a clockwise rotation, as indicated by the arrow Pf is indicated. The setting of the eccentricity e, which can be carried out, for example, by means of double eccentrics, enables an optimization of the micro-throwing of the pourable material G. The angle of increase of the helical upward conveying path F5 is chosen so that the pourable material G no longer slides downwards or at least the promotion of the subsequent micro throwing movement is greater than when slipping down and there is still a useful promotion. It has been observed that useful conveying in the area of the upper turns of the conveying path F5 can also come to a standstill if there is no longer any good G to be pushed from below. In order to rule out this danger from the outset, the static friction between the material G to be conveyed and the conveyor track F5 can be increased in this upper region, which is indicated in FIG. 4 by a conveyor track F5 profiled here by means of knobs N.

The locks shown in FIGS. 1, 2 and 3 with a helically upward conveying path have the particular advantage that they can be designed as U-shaped liquid locks in a space-saving and compact design. Numerous variations are possible for the arrangement and design of the conveyor track and for the vibration excitation of the conveyor track. For example, in the embodiment shown in FIG. 1, the helical conveyor track can also be arranged in a framework with a ring-shaped plan, with a replaceable conveyor track segment being attached to radially oriented bars of this rack with a view to possible wear. The frame is in turn connected to a support plate which is mounted in the lock chamber so that it can vibrate, for example, which is excited by a vibrator which is likewise arranged within the lock chamber. The problem of sealing drive parts of the conveyor is completely eliminated.

In the locks shown in FIGS. 1, 2 and 3, the support columns can also be set up on support plates which are mounted in a vibrating manner and can be excited by vibrators arranged at their upper end. In the embodiment of Fig. 1, both the support plate and the vibrator are then included in the lock chamber, so that the bellows shown in the drawing can be omitted.

Claims (17)

1. A lock for charging and/or discharging a treatment device for pourable goods, operating with the exclusion of air, in particular a device for the electrolytic deposition of aluminium from aprotic, oxygen- free and anhydrous organo-aluminium electrolytes, having at least one U-shaped lock chamber which can be filled with inert liquid and subjected to inert gas and having conveying means for passing the pourable goods through the lock along a fixed conveying path, characterised in that the pourable goods G can be transported through the upwardly-leading limb of the U-shaped lock chamber (Sk2 ; Sk3 ; Sk4) by means of a vibrating conveyor (Sf2 ; Sf3 ; Sf4 ; Sf5) having a conveying track (F3 ; F4 ; F5) leading helically upwards.

2. Lock according to Claim 1, characterised in that the conveying track (F3) is designed as a vibrating trough.

3. Lock according to Claim 1 or 2, characterised in that the conveying track (F4 ; F5) is formed as a floor of the lock chamber (Sk3 ; Sk4) which leads helically upwards.

4. Lock according to Claim 3, characterised in that the lock chamber (Sk3 ; Sk4) has a rectangular cross-section.

5. Lock according to one of the preceding Claims, characterised in that a flow of inert liquid acting in the conveying direction on the pourable goods (G) can be generated in the region of the lock chamber (Sk2; Sk3 ; Sk4) which can be filled with inert liquid (If) by means of a circulating pump (Up).

6. Lock according to one of the preceding Claims, characterised in that the lock chamber (Sk3 ; Sk4) is fixed to a centrally-arranged supporting column (Ts2 ; Ts3).

7. Lock according to Claim 6, characterised in that the supporting column (Ts2 ; Ts3) is arranged on a vibrator (V4 ; V5) or carries a vibrator.

8. Lock according to Claim 7, characterised in that the vibrator (V4 ; V5) is equipped with an unbalanced drive (Ua).

9. Lock according to Claim 8, characterised in that the unbalanced drive (Ua) has at least one flywheel disc (Ss1 ; Ss2) with adjustable eccentricity (e).

10. Lock according to one of the preceding Claims, characterised in that a gravity conveyor is arranged upstream of the vibrating conveyor (Sf3 ; Sf4 ; Sf5) in the conveying direction.

11. Lock according to one of the preceding Claims, characterised in that a gravity conveyor is arranged downstream of the vibrating conveyor (Sf3 ; Sf4 ; Sf5) in the conveying direction.

12. Lock according to Claim 10 or 11, characterised in that the gravity conveyor is formed by a downpipe (Fr1, Fr2; Fr3, Fr4; Fr5 ; Fr6).

13. Lock according to one of Claims 10 to 12, characterised in that the gravity conveyor can be sealed by a lid (D1, D2 ; D3 ; D4, D5) at the inlet end or outlet end, and in that at least the region of the gravity conveyor situated below or above the lid (D1, D2 ; D3 ; D4, D5) can be flooded with inert gas (Ig).

14. Lock according to one of Claims 10 to 13, characterised in that the gravity conveyor includes a compensator (K1, K2 ; K3, K4) installed upstream, downstream, or in parallel.

15. Lock according to one of the preceding Claims, characterised in that the conveying track (F3 ; F4 ; F5) of the vibrating conveyor (Sf3 ; Sf4 ; Sf5) has at least in the end region of the associated conveying path, a surface which is roughened, profiled or provided with a friction lining.

16. Lock according to one of the preceding Claims, characterised in that at least one cooling zone follows the lock zone which can be filled with inert liquid (If) in the conveying direction.

17. Lock according to Claim 16, characterised in that the cooling zone is formed by cooling pipes (Kr1, Kr3).

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