DE202004020280U1 - Device for removing gas samples from hollow vessels and feeding to analysis device used in drinks industry comprises blasting nozzles displaced in transport direction arranged in front of suction channel - Google Patents

Abstract

A device for removing gas samples from hollow vessels and feeding to an analysis device comprises blasting nozzles (13, 3) displaced in the transport direction (F) arranged in front of the suction channel (7). The first nozzle (13) has a higher blasting speed than the second blasting nozzle (3). The blasting nozzles are at a distance of 10 cm in the transport direction of the hollow vessel. The blasting nozzles and the suction channel are arranged stationary over the conveying path of the hollow vessel. The second blasting nozzle and the suction channel are embedded or integrated into a plate (2) which is heated in the region of the nozzles and/or the suction channel.

Description

The The invention relates to a device for taking gas samples from hollow vessels like bottles or the like. Container according to the preamble of Claim 1.

A Device of this kind is known from WO 93/24825 A1. Becoming in the beverage bottling industry such devices used to return from the consumer To inspect empties. The aim is the detection of bottles, the foreign or flavoring substances contain, for example, to exclude from further use or to fill again with a beverage having the same flavor. To For this purpose, the bottles are unlocked before washing and filling with her open mouth under a stationary Sampling unit passed. This has a tuyere and a downstream in the transport direction suction channel. When the bottle mouth under the tuyere is part of the air in the bottle interior expelled, collected by the suction and an analysis device fed. The disadvantage is often foreign body or liquid droplets the interior discharged and dragged into the analysis device. the reason for this Among other things, that in this device is a relatively sharp Blowing air needed is enough To bring air from a bottle to the analyzer.

to Prevention of this problem has already been proposed, the air blast and the inlet opening embed or integrate the suction channel in a flat plate (DE 20 2004 008 202.0). In contrast to the previously known state of Technique with freestanding, single arrangement of the tuyere and the Suction channel can provide a sufficient air sample with little blowing air Be brought analysis unit. The now lower amount of blowing air can through a relatively soft Air jet with low flow velocity be applied. This advantageously reduces the risk that disturbing foreign body or liquid residues the interior of the bottles swirled and in the analysis device be worn even when stuffed Bottles pass the device. Volatile substances are on this Way easily detectable. More critical is the expulsion of more volatile Substances from the floor space of largely empty bottles.

Of the The invention is therefore based on the object improved in this regard Specify sampling unit, solved The object is achieved by the characterizing features of the claim 1.

By the measure, seen in the transport direction in front of the suction channel for the gas sample to be recorded at least one first and second tuyeres spaced one behind the other are arranged offset, provide, as seen in the transport direction first tuyere with a higher blowing pressure compared to the second blowing nozzle downstream be operated without disturbing Foreign body or liquid residues enter into the analysis device because because of the spatial Separation or spacing to the suction channel by the higher injection pressure possibly raised drops or the like can not be sucked. Heavy volatile substances be through the higher Blowing pressure reliable whirled up from the floor space and then passing the second, with only a small blowing pressure working tuyere from the expelled to be examined hollow vessel and over supplied to the subsequent suction channel of an analysis device. These solution combines the advantages of the previously known devices, but without to accept their disadvantages.

Prefers has the first tuyere a distance of at least 8 to 10 cm to the second tuyere.

Further advantageous embodiments of the innovation are the subject of the remaining Dependent claims.

following becomes a preferred embodiment explained with reference to the figures. It shows:

1a a sampling unit of a foreign matter inspection machine viewed in a schematic side view transversely to the transport direction,

1b a part of the sampling after 1a in a perspective view, a plan view, a vertical section along the drawn in plan view section line and a magnified imaged detail of the vertical section and

2 a plate of the sampling unit after 1b in a perspective view, a plan view and three different vertical sections along the drawn in plan view section lines.

The entire sampling unit according to 1a consists essentially of a transport direction F of bottles 11 seen first tuyere 13 , which forms a Voreinblasung, and a distance behind it arranged actual sampling unit E, which has a suction channel 7 having. At a distance of 10 to 12 mm in front of this suction channel is a second tuyere 3 arranged, in turn, about 10 cm behind the first tuyere 13 positivist is tioniert. The units mentioned are arranged stationarily above the travel path of the open bottle mouths, for example by means of a continuously drivable conveyor belt 12 and / or a strap pair (not shown) engaging the bottle sidewall is defined. From the first tuyere 13 occurs a relatively sharp jet of air vertically downwards into a passing bottle mouth, which is so dimensioned that the jet flowing axially downward in the bottle with sufficient energy hits the bottom of the bottle and there possibly reliably stirred up in only a small amount of adhering substances, especially hardly volatile substances. As a result, these substances are distributed during the further transport of the bottle 11 to the second tuyere 3 in the entire interior of the bottle, the only one soft, ie much weaker air flow than the first tuyere 13 perpendicular down into the open mouth of the bottle. Through the immediately following suction channel 7 a part of the air emerging from the bottle mouth is taken up and fed to a gas analyzer, not shown.

The with different flow speed from the tuyeres 3 . 13 exiting air jets are generated, for example, by supplying the blowing nozzles from compressed air sources with different pressures or only one compressed air source with an intermediate throttle to the second blowing nozzle. The air volumes emitted by the two tuyeres may also differ from each other. Preferably, the first tuyere gives 13 a larger amount of air per bottle than the second tuyere 3 , The air supply of the blowing nozzles can be permanent or pulsating on not shown, controllable valves.

The actual sampling unit E is shown in detail in the figure sequences 1b and 2 and will be described below. It consists essentially of a ring body 1 with a stepped cross-section and a plate 2 with a flat bottom 2 ' , which in the installed state with the underside of the ring body 1 flees. The plate 2 is with a total of four screws 5 on the ring body 1 releasably secured, which in turn also with four screws 6 from below on a housing construction, not shown, a mounted in a conventional manner on a bottle conveyor inspection head is attachable.

At the bottom of the flat 2 ' groundbreaking side of the plate 2 is close to the center of an exchangeable tuyere 3 screwed. Its outlet channel is aligned perpendicular to the bottom running.

Furthermore, the plate has 2 a suction connection indicated by dot-dash lines 8th for a suction channel 7 (please refer 2 ) and with a distance from the bottom parallel extending, aligned radially to the center blind hole 9 for receiving an electric heating rod, with a in the enlarged reproduced detail B indicated Allen head screw 4 is definable, up.

The blind hole 9 extends at right angles to the recognizable in the plan view sectional line DD, whose course substantially at the same time corresponds to the Flaschenlaufweg F, while the suction port 8th and the suction channel aligned with it 7 viewed in the vertical projection with the same cutting line an angle α of approximately 40 degrees and at an angle β of about 30 degrees obliquely from above into the center of the flat bottom of the plate 2 opens. This geometry allows a straight, to the bottle running direction predominantly oppositely designed extending suction channel 7 although its confluence with the bottom of the plate is seen in a straight line of the bottle walkway just behind the tuyere 3 is located, for example, at a distance of about 10 to 12 mm.

The course of the suction channel 7 is best from the section AA and the blind hole 9 for an electric heating rod from the section BB of the 2 seen. Section CC shows the receptacle for the replaceable tuyere 3 serving threaded hole in the plate 2 , With the mentioned heating rod in the blind hole 9 is primarily the center of the plate receiving the suction channel and the tuyere 2 heated, to prevent condensation.

From the approximately 2mm diameter diameter opening of the tuyere 3 occurs constantly due to low air velocity uniformly soft sterile air jet, while bottles, especially plastic, with its open mouth edge with a distance of about 6 mm to the flat bottom of the plate 2 approximately centric continuously - preferably on a straight path - first under the tuyere 3 and subsequently the also of a diameter of 2 mm having the mouth of the suction channel 7 be passed.

By means of the sterile air entering a bottle mouth vertically from above in a thin stream, part of the air originally trapped in the interior of the bottle is forced out and expelled through the mouth into the open air, the air stream flowing upwards onto the underside of the plate 2 meets and briefly there forms a small air cloud which extends at least to the mouth of the suction channel, through which a portion of this cloud is sucked into the suction channel substantially opposite to the bottle conveying direction and in the direction of an analysis device, not shown, For example, a mass spectrometer is forwarded. Until the next bottle arrives, the cloud of the previous bottle has already evaporated. The aspiration of the air to be examined is clocked, for example in conjunction with a triggers triggered by the passing bottle mouths photocell, the actual sampling time is approximately 40ms.

Claims (12)

Device for removing gas samples from hollow vessels and forwarding to an analysis device with the aid of a suction channel and a blowing nozzle upstream of the suction channel in the transport direction of the hollow vessels, characterized in that the suction channel ( 7 ) at least a first and second in the transport direction (F) successively staggered tuyere ( 13 . 3 ) are arranged upstream. Apparatus according to claim 1, characterized in that seen in the transport direction first tuyere ( 13 ) has a higher blowing speed than the second blowing nozzle arranged behind it ( 3 ). Apparatus according to claim 1 or 2, characterized in that seen in the transport direction first tuyere ( 13 ) is supplied with a higher pressure than the second blowing nozzle ( 3 ). Device according to one of claims 1 to 3, characterized in that the first ( 13 ) and second tuyere ( 3 ) in the transport direction (F) of the hollow vessels ( 11 ) have a distance of at least 8 cm, preferably 10 cm. Device according to one of claims 1 to 4, characterized in that the pressure for feeding the second blowing nozzle ( 3 ) is selected so that the suction channel ( 7 ) does not receive liquid drops from a filled hollow vessel. Device according to one of claims 1 to 5, characterized in that the blowing nozzles ( 3 . 13 ) and the suction channel ( 7 ) are arranged stationarily above the conveying path of the hollow vessels. Device according to at least one of the preceding claims 1 to 6, characterized in that the at least one blowing nozzle ( 3 ) and the at least one suction channel ( 7 ) into a plate ( 2 ) are embedded or integrated, their side facing the hollow vessels to be examined ( 2 ' ) is formed. Device according to claim 7, characterized in that the plate ( 2 ) is heated, at least in the area of the blowing nozzles and / or the suction channel. Apparatus according to claim 7 or 8, characterized in that the suction channel ( 7 ) starting from its inlet mouth to the plate ( 2 ) at least in sections, the vessel running direction is formed predominantly oppositely extending, preferably with this seen in vertical projection an angle (α) of approximately 40 degrees and transversely to the vessel direction (F) in the plane of the plane side ( 2 ' ) of the plate observes an angle (β) of 30 degrees with the plane side ( 2 ' ) of the disk. Device according to at least one of claims 7 to 9, characterized in that the blowing nozzles and / or the suction channel a diameter of approximately 2 mm. Device according to at least one of claims 7 to 10, characterized in that the Einsaugmündung of the suction channel seen in the direction of vessel travel in about 10 to 12 mm behind the mouth of the second blast nozzle ( 3 ) is positioned. Device according to at least one of the preceding claims 7 to 11, characterized in that the hollow vessels by a transport device ( 12 ) with its open mouth edge at a distance of about 6 mm to the flat side of the plate to this running parallel to the blowing nozzles and the suction channel are continuously fed.