EP1160019A1 - Bottle washing machine - Google Patents

Abstract

The counter (56) determines the number of bottles passing through the machine in a given interval. The quantity of clean water delivered in the final spray zone (32) is regulated by a controller (58), as a function of the bottle rate determined by the counter. An Independent claim is included for the corresponding method.

Description

• eine Vorweichstation zum Vorreinigen der Teile,
• ein Laugenbad zum Intensivreinigen der Teile, und
• eine Spülstation zum Endreinigen der Teile, wobei die Spülstation in mehrere Spritzzonen aufgeteilt ist, die die zu reinigenden Teile nacheinander durchlaufen, und wobei der zuletzt durchlaufenen Spritzzone Frischwasser zugeführt wird,

wobei der Wasserfluß durch die Maschine von der Frischwasserspritzzone über die weitere(n) Spritzzone(n) zur Vorweichstation und von dort zum Abwasser verläuft. Weiterhin betrifft die Erfindung ein Verfahren zur Reinigung von Behältern, insbesondere Glas- und Kunststoffflaschen.The invention relates to a washing machine, in particular a bottle washing machine, with a housing and a conveyor device rotating inside the housing, which leads the parts to be cleaned one after the other through at least the following treatment stations:

• a pre-soaking station for pre-cleaning the parts,
• a lye bath for intensive cleaning of the parts, and
• a rinsing station for final cleaning of the parts, the rinsing station being divided into a plurality of spray zones which pass through the parts to be cleaned one after the other, and fresh water being supplied to the last spray zone to be passed through,

wherein the water flow through the machine runs from the fresh water spray zone over the further spray zone (s) to the pre-soaking station and from there to the waste water. The invention further relates to a method for cleaning containers, in particular glass and plastic bottles.

A common bottle washing machine of the type mentioned above for cleaning reusable glass bottles or reusable plastic bottles in the The beverage industry is, for example, from the German utility model DE 29716444 known and has the structure shown in Figure 1. After entry The bottles to be cleaned are first placed in the machine Residual emptying station 20 emptied. In a pre-soaking station 22 Pre-cleaned bottles. A subsequent hot bath 24 is used for Intensive cleaning of the bottles. The bottles pass through a rinsing station 26 then three spray zones 28, 30, 32 for final cleaning or cooling the Bottles. Cascade rinsing of the bottles and in takes place in the rinsing station 26 Viewed in the transport direction of the bottles, a takes place in the first spray zone 28 Hot water spraying, in the second spray zone 30 a cold water spray and in the third and last zone a fresh water spray. Subsequent to the The cleaned bottles are fresh water sprayed Bottle washing machine issued. The one shown in Figure 1 Bottle washing machine is designed as a single-end machine, i.e. Bottle feeding and bottle dispensing are on one side of the machine, in an alternative design, however, a double-ended machine is also possible, where the feed area and the output area are on opposite sides Sides of the machine.

The fresh water spray zone 32 becomes fresh water partly direct fed from the water supply network, and the fresh water receives from there also the required pressure. The water in the cold water spray zone 30 comes from the overflow of the fresh water spray zone 32 and the water in the Hot water spray zone 28 comes from the overflow from the cold water spray zone 30, the water in the cold water spray zone and in the hot water spray zone is brought to the required spray pressure in each case by means of circulation pumps.

From the catch basin of the hot water spray zone, the water of the Pre-soaking station 22 is supplied and from there the water is sent to the waste water fed.

By procrastination, i.e. Transfer from to the bottles and to Water sticking to the bottle holders is transferred by Contamination or lye in the main water flow described above opposite direction instead, i.e. from the pre-soak to the lye bath and from the lye bath to the rinsing station or the individual spray zones of the Rinsing station.

The amount of water required to operate the Bottle washing machines are usually specified and set up by the manufacturer the required water capacity to remove dirt and microbiological load from the bottles, for cooling the bottles and for Remove the alkalinity (lye residues carried off from the lye bath) from the Bottles. As a rule, the amounts of water required are approx. 100 to approx. 400 ml per bottle.

• Vorweichstation: 11 bis 12
• Laugenbad: 13,5 bis 14
• Warmwasserspülung: 11 bis 12
• Kaltwasserspülung: 9 bis 10
• Frischwasserspülung: 7,5 bis 8,5

Due to the commonly used lye concentrations in the lye bath and the carryover or dilution effects, the following pH values generally result in the different zones of the bottle washing machine:

• Pre-soaking station: 11 to 12
• Alkali bath: 13.5 to 14
• Warm water rinsing: 11 to 12
• Cold water rinse: 9 to 10
• Fresh water rinsing: 7.5 to 8.5

In some cases, the incoming fresh water is acidified that the above-mentioned pH values for the areas fresh water, Cold water and hot water are lower. The reason can be, for example, Avoid limescale.

The water consumption of the bottle washing machine described above is very high. For ecological and economic reasons therefore tries to increase the consumption of fresh water through suitable measures to reduce.

For this purpose it is from the utility model mentioned at the beginning known, the catch basin 33 of the fresh water spray zone 32 via a line 34 using a pump (not shown) to withdraw water and one after the other a filter device 36, a disinfection device 38 and to supply a cooling device 40. The cleaned, disinfected and cooled Water is returned to the fresh water spray zone 32 via a line 42. Within the fresh water spray zone 32 are two in the transport direction Bottles arranged one behind the other spray bars 44, 46, the Spray bar 44 is connected to line 42 and the spray bar 46, which in Transport direction of the bottles is arranged behind the spray bar 44, with the Fresh water supply line 48.

Such a bottle washing machine enables one Saving water without the use of biological Wastewater treatment processes, precipitation and flocculation plants or the like and thus represents an economical way of saving water. If the Washing machine, however, is only partially busy, which takes to clean the Bottles of water actually required, however, while maintaining a constant Amount of fresh water is fed. The water use efficiency is therefore increasing with only partial utilization of the system.

The invention is therefore based on the object of a washing machine to propose the greatest possible at different degrees of utilization Allows saving water.

• eine Vorweichstation zum Vorreinigen der Teile,
• ein Laugenbad zum Intensivreinigen der Teile, und
• eine Spülstation zum Endreinigen der Teile, wobei die Spülstation in mehrere Spritzzonen aufgeteilt ist, die die zu reinigenden Teile nacheinander durchlaufen, und wobei der zuletzt durchlaufenen Spritzzone Frischwasser zugeführt wird,

   wobei der Wasserfluß durch die Maschine von der Frischwasserspritzzone über die weitere(n) Spritzzone(n) zur Vorweichstation und von dort zum Abwasser verläuft,
   gekennzeichnet durch

• eine Zähleinrichtung zur Ermittlung der in einem gegebenen Zeitraum umlaufenden Teile, und
• eine Frischwasser-Regeleinrichtung zum Regeln der in der zuletzt durchlaufenen Spritzzone abgegebenen Frischwassermenge in Abhängigkeit von der durch die Zähleinrichtung ermittelten Durchlaufmenge.

The object is achieved by a washing machine, in particular a bottle washing machine, with a housing and a conveyor device which rotates within the housing and which successively guides the parts to be cleaned through at least the following treatment stations:

• a pre-soaking station for pre-cleaning the parts,
• a lye bath for intensive cleaning of the parts, and
• a rinsing station for final cleaning of the parts, the rinsing station being divided into a plurality of spray zones which pass through the parts to be cleaned one after the other, and fresh water being supplied to the last spray zone to be passed through,

whereby the water flow through the machine runs from the fresh water spray zone over the further spray zone (s) to the pre-soaking station and from there to the waste water,
marked by

• a counting device for determining the parts rotating in a given period, and
• a fresh water regulating device for regulating the fresh water quantity dispensed in the spray zone last passed as a function of the flow quantity determined by the counting device.

wobei der Wasserfluss von der Frischwasserspritzzone über die weitere(n) Spritzzone(n) zur Vorweichstation läuft,

wobei die Anzahl der umlaufenden Behälter kontinuierlich erfasst wird und die in der Frischwassserspritzzone zugeführte Spritzwassermenge in Abhängigkeit von der erfassten Behälteranzahl geregelt wird.

The object is further achieved by a method for cleaning packaging containers, in particular glass and plastic bottles, the containers to be cleaned successively passing through a pre-soaking station for pre-cleaning the containers, an alkali bath for intensive cleaning of the containers, and a rinsing station for final cleaning of the containers Rinsing station is divided into several spray zones and water is supplied to the last spray zone that was passed through,

whereby the water flow runs from the fresh water spray zone over the further spray zone (s) to the pre-soaking station,

wherein the number of rotating containers is continuously recorded and the amount of spray water supplied in the fresh water spray zone is regulated as a function of the number of containers detected.

Measuring the flow of bottles through the washing machine and corresponding regulation of the amount of water in the fresh water spray zone enables optimal adjustment of the required spray water quantity the current load on the washing machine. So with partial utilization fresh water can be saved in the system considerably.

The fresh water supply to the fresh water spray zone is preferably regulated so that even in the event of a failure of the processing device Continued operation of the washing machine is guaranteed. That means it will be with one Failure of the fresh water treatment device correspondingly more Fresh water regulated from the "line", so that the system without Interruption can continue to work. The total amount of water is in Regulated depending on the number of bottles passing through. So is ensures that the processing device is interrupted, for example due to a filter change or the like, not to one costly business interruption of the entire plant.

The invention also allows water consumption Bottle washing machine in combination with a downstream rinser thereby be significantly reduced in that the running water of the rinser is processed that the bottle washer prepared with this Water is fed. The combination bottle washer with rinser used for example in the cleaning of PET bottles where shown did that cleaning results with the same amount of water that usually used for glass bottles, may be insufficient.

According to the invention, there may also be an additional one Cooling device provided in order to remove the from the fresh water spray zone, to cool treated or treated water. In breweries can Cooling especially beer or fermentation carbon dioxide can be used.

Furthermore, in a preferred embodiment of the invention, it may be expedient to provide an additional neutralization device in order to neutralize the alkalinity carried over from the alkali bath into the rinsing station. In a preferred development, the invention therefore comprises a device for removing water, in particular from the spray zone immediately adjacent to the lye bath, for neutralizing this water and for returning the neutralized water to this spray zone. The neutralization device preferably comprises a pH-controlled CO ₂ metering device.

The invention can be used in a large part of those on the market Bottle washing machines can be retrofitted and used economically as Reference sizes for normal operating conditions are 10 cubic meters per Hour of fresh water demand, water or wastewater costs of DM 5, - each Cubic meters, machine running time 2000 hours a year.

Figur 1 eine vertikale Schnittansicht einer Flaschenwaschmaschine nach dem Stand der Technik, und

Figur 2 eine erfindungsgemäße Flaschenwaschmaschine.

In the following an embodiment of the invention will be explained with reference to the drawing. The drawing shows in a schematic representation:

Figure 1 is a vertical sectional view of a bottle washing machine according to the prior art, and

Figure 2 shows a bottle washing machine according to the invention.

With regard to the basic structure of the bottle washing machine, reference is made to the Explanations to Figure 1 referenced.

Figure 2 shows schematically a bottle washing machine according to the present inventions. Elements corresponding to those shown in Figure 1 are identified by the same reference numerals and are therefore not repeated explained.

Compared to the bottle washing machine shown in Figure 1 the bottle washing machine according to the invention additionally a Bottle counter 56, preferably as an inductive Flow measuring device is formed. The counter 56 determines the Bottle flow, for example the number of running through the system cleaning bottles per second. In the embodiment shown in Figure 2 the counting device 56 is arranged in front of the hot water spray zone 28. Each different arrangement inside or outside the bottle washer, the one Determination of the bottle throughput allowed, but is also possible. The The fresh water control device receives the measurement result from the counter device 56 58 fed, which due to the bottle throughput the required amount of Fresh water calculated by the spray bars 44 and 46 in the Fresh water spray zone 32 is injected for bottle cleaning. The total amount of fresh water is made up of fresh water from the tap, recycled, treated fresh water from the disinfection device 38 and cooling device 40 and reused fresh water from the Bottle rinsing device 60. The control device 58 ensures that the total amount of fresh water injected is always that for the measured bottle throughput corresponds to the required and optimal amount. In the case when, for example, the processing of the fresh water from the Fresh water spray zone 32 itself or from the rinser 60 is defective or only one delivers smaller amount of water, the control device 58 keeps the Total amount of water always constant, so that the operation of the Bottle washing machine is avoided. This increases operational safety and economy of the bottle washing machine according to the invention considerably.

In the case of the embodiment, the bottle washer - overall, at maximum capacity - a fresh water requirement of 14 Cubic meters per hour. Via the horizontal centrifugal pump (not shown) the catch basin 33 of the fresh water spray zone 32 has a water quantity of 7 cubic meters removed per hour; the pump delivers at a pressure of 4.5 bar.

The filter 36 is a switchable double filter that consisting of two filter housings, each with five filter cartridges made of polypropylene with one Filter fineness of 5µ exists. The disinfection device 38 is a UV disinfection system with a given UV-C dose at the end of the Radiation period to restore water sterility. Alternatively, other disinfection techniques could also be used, in particular the dosage of disinfectant chemicals. The reliability of UV disinfection and avoiding the risk of being too high Chemical doses could be detected as traces on the bottles, In this case, you have the choice of UV disinfection.

The cooling device 40 comprises a plate heat exchanger, by means of which the treated water is cooled by approximately 7 ° from approximately 22 ° C. (corresponding to a cooling capacity of 57 kW). In the case of the exemplary embodiment, the cooling medium is the product to be filled with beer (approx. 23 cubic meters per hour are heated from +2 to + 4 ° C.). Alternatively, it is also possible to use the ambient air as a coolant via a chiller (driven by a 25kW compressor), or to extract the cold from the CO ₂ evaporating in the filling system, or to use another coolant, e.g. one nearby flowing stream. The heat dissipation could also be achieved in that the water of the hot water spray zone is cooled in a circulation process. This water, which is usually 60 ° C warm, would then have to be cooled by about 10 ° C, the energy dissipated at the same time being used to heat water for an existing crate washer or for an existing KEG washer.

The water in the rinsing station could be neutralized by a pH-controlled metering of a mineral acid directly after the feed pump (not shown) of the treatment station. In the case of the exemplary embodiment, however, the neutralization is achieved in a particularly advantageous manner by means of a pH-controlled CO ₂ metering in the area of the hot water spray zone 28 in a separate circulation process. For this purpose, hot water is withdrawn from the hot water spray zone 28 via a line 50 in the catch basin 29, this water is neutralized in the neutralization device 52 by pH-controlled CO ₂ metering, and the neutralized water is then returned via line 54 to the catch basin 29 of the hot water spray zone 28. The neutralization takes place via a dosage of approx. 3kg CO ₂ per hour with a circulation rate of approx. 50m ³ per hour. The neutralization in the hot water spray zone has the additional advantage that the spray zones adjoining it, namely the cold water spray zone 30 and the fresh water spray zone 32, also reach the pH-neutral range and thus prevent limescale deposits.

Although the invention has been described above in connection with a Bottle washing machine has been described, it can also be used with others Washing machines can be used with advantage, for example at Crate washers, which have a similar structure to that Bottle washing machines, or dishwashers for the area Commercial kitchens where the last rinse, i.e. the rinse aid usually with Hot water takes place, so that here an additional cooling as in the case of The embodiment described above is not required.

Reference list

20th

Residual emptying station

22

Pre-soaking station

24th

Lye bath

26

Spray station

28

Hot water spray zone

29

Catch basin

30th

Cold water spray zone

31

Catch basin

32

Fresh water spray zone

33

Catch basin

34

management

36

Filter device

38

Disinfection device

40

Cooling device

42

management

44

Spray bars

46

Spray bars

48

Fresh water supply

50

management

52

Neutralization device

54

management

56

Bottle counter

58

Fresh water control device

60

Bottle rinsing device (rinser)

Claims (16)

Washing machine, in particular bottle washing machine, with a housing and a conveyor device rotating inside the housing, which in turn leads the parts to be cleaned through at least the following treatment stations: a pre-soaking station for pre-cleaning the parts, a lye bath for intensive cleaning of the parts, and a rinsing station for final cleaning of the parts, the rinsing station being divided into a plurality of spray zones which pass through the parts to be cleaned one after the other, and fresh water being supplied to the last spray zone to be passed through, whereby the water flow through the machine runs from the fresh water spray zone over the further spray zone (s) to the pre-soaking station and from there to the waste water,
marked by a counting device (56) for determining the parts rotating in a given period, and a fresh water control device (58) for controlling the amount of fresh water dispensed in the spray zone (32) last passed, depending on the flow rate determined by the counting device (56). The washing machine according to claim 1, further comprising a discharge device (34) for discharging part of the water of the fresh water spray zone (32) from the fresh water spray zone, a treatment device (36, 38, 40) for treating the discharged water, and a return device (42) for returning the treated water back to the fresh water spray zone (32), The fresh water control device (58) controls the amount of water injected into the fresh water zone, which is composed of fresh water and treated water coming from the treatment device (36, 38, 40), so that even if the treatment device (36, 38, 40) the amount of water corresponding to the measured flow rate is injected. Washing machine according to claim 1 or 2, wherein the Bottle counting device (56) is designed as an inductive flow meter. Washing machine according to one of claims 1 to 3, further having a rinsing device for rinsing the parts after leaving the Washing machine, the used rinse water collected and then the Fresh water spray zone (32) is supplied. Washing machine according to one of claims 1 to 4, characterized in that the first part of the nozzles is arranged behind the second part of the nozzles as seen in the transport direction of the parts. Washing machine according to one of claims 1 to 5, characterized in that the processing device comprises a cleaning device (36) and a disinfection device (38). Washing machine according to claim 6, characterized in that the disinfection device (38) has a thin-film reactor with a predetermined UV-C radiation dose. Washing machine according to one of the preceding claims, characterized in that the processing device comprises a cooling device (40). Washing machine according to one of the preceding claims, characterized in that the processing device comprises a neutralization device. Washing machine according to one of claims 1 to 9, characterized by a device (50, 52, 54) for removing water from one or the further spray zone (28), for neutralizing this water and for returning the neutralized water to the further spray zone ( 28). Washing machine according to claim 10, characterized in that the neutralization device comprises a preferably pH-controlled CO ₂ metering device (52). Washing machine according to claim 10 or 11, characterized in that the neutralization device (50, 52, 54) is assigned to that spray zone (28) which is adjacent to the alkali bath (24). Bottle washing machine according to one of the preceding claims, characterized in that it comprises three spray zones, namely, seen in the transport direction of the bottles one behind the other, a hot water spray zone (28), a cold water spray zone (30) and the fresh water spray zone (32). Process for cleaning containers, in particular glass and plastic bottles, the containers to be cleaned passing through a pre-soaking station for pre-cleaning the containers, an alkali bath for intensive cleaning of the containers, and a rinsing station for final cleaning of the containers, the rinsing station being divided into several spray zones and fresh water is supplied in the last spray zone passed through, the water flow running from the fresh water spray zone over the further spray zone (s) to the pre-soaking station, and wherein the number of rotating containers is continuously recorded and the amount of spray water supplied in the fresh water spray zone (32) is regulated as a function of the number of containers detected. The method of claim 14, wherein a portion of the in the Fresh water spray zone (32) sprayed water treated and the Fresh water spray zone is supplied again, and the fresh water supply to Fresh water spray zone is regulated so that even if the treatment fails the amount of spray water corresponding to the number of tanks in transit is always supplied to the water cycle. The method of claim 14 or 15, wherein the container after the Wash and before filling, especially with a drink, with Fresh water are rinsed, which after using the Fresh water spray zone (32) is supplied.

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