DE29808174U1 - Device for reducing detergent and fresh water consumption in bottle washers - Google Patents

Description

Reference number 298 08 174.1 .*: I . ' ·;*'; -■ -

Device for reducing detergent and fresh water consumption in bottle cleaning machines

Description

The invention relates to cleaning machines for bottles in the beverage industry.

Cleaning machines for cleaning bottles in the beverage industry are among the largest consumers of cleaning agents and fresh water. The majority of the loss of cleaning agents in bottle cleaning machines (FRM) results from carryover from the main cleaning bath into the subsequent spray zones. The reason for this carryover is the residual liquid adhering to the bottles and the corresponding conveyor systems.

The fresh water consumption results from the requirement for both residue-free rinsing and sufficient cooling of the bottles before leaving the FRM.

After leaving the main cleaning bath, the containers pass through a series of consecutive spray zones within the FRM. The last spray zone, as seen in the direction of bottle transport, is fed exclusively with fresh water supplied to the FRM. The water dripping from this spray zone is fed to the storage tank of the spray zone upstream in the direction of bottle transport (cold water spray zone). From this storage tank, the required water is fed to the spray bar of this cold water spray zone via a pump. The water dripping in this spray zone returns to this same storage tank. The excess water that collects in the storage tank is fed via an overflow to the spray zone upstream in the direction of bottle transport (warm water spray zone). The overflow from the warm water spray zone goes analogously into the spray zone upstream, etc. The overflow from the first spray zone after the main cleaning bath, seen in the direction of transport of the bottles, goes into the pre-soak area upstream of the cleaning baths, the overflow from which leaves the FRM and is generally drained into the sewage system. This means that any cleaning agents carried over end up in the wastewater via the pre-soak area. However, it is also common to use the

VLB Berlin 1/6

The first spray zone after the main cleaning bath, viewed in the direction of transport of the bottles, is not to be fully included in the water cascade described above, so that an overall higher cleaning agent concentration and a higher temperature can be achieved in this first spray. In this case, the overflow from the second spray zone downstream of this spray zone behind the main cleaning bath already flows to the pre-soak. So far, only one process is known for recovering the carried-over cleaning agents (A). However, this process also concentrates the dissolved and undissolved contaminants contained in the carried-over volume. The process DE 196 25 A 1 from Wabag is known for treating process water from a FRM. This involves treating process water obtained from the first spray zone after the main cleaning bath, viewed in the direction of transport of the bottles, using reverse osmosis (RO). The permeate is returned to one of the spray zones, while the concentrate flows to the pre-soak.

Another method with the aim of reducing fresh water consumption is the process according to DE 42 29 269 A 1 from KHS. Here, water is taken from the spray zone area, treated - preferably with microfiltration (MF) or bag filtration - and then used again in the spray area. The process DE 195 17 473 A1 from Henkel Ecolab aims to obtain water of drinking water quality from waste water. The treatment here includes in particular ultrafiltration (UF) in connection with two RO stages. The following two utility model-protected processes are also intended to reduce the fresh water consumption of FRM. The first, DE 297 16 444 from WPT, involves treating a partial flow of the water dripping off in the fresh water spray by means of filtration, preferably microfiltration, and subsequent disinfection. The treated water is fed back into the first part of the fresh water spray in the direction of bottle transport.

The second process, DE 295 19 181 or DE 93 21 162 by Nörpel, reprocesses this water flow using an ion exchanger, an activated carbon filter and UV disinfection.

VLB Berlin 2/6

The invention is based on the overflow water (3) flowing into the pre-soak from the spray zones (2). This water is first pre-filtered if necessary and then passed through a nanofiltration (NF) (6), if necessary in multiple stages. The aim here is to retain as many of the undesirable components (= contaminants) dissolved or undissolved in the water as possible in the concentrate without hindering the passage of the cleaning agent(s) used through the NF. The NF therefore represents a cleaning stage. The concentrate (7) is fed into the pre-soak (8). The permeate (9) obtained is subjected to reverse osmosis (RO) (10), if necessary in multiple stages. The aim here is to retain the cleaning agent(s) as completely as possible on the concentrate side. The concentrate obtained (11) is returned in whole or in part to the main cleaning bath (4). The permeate (12) obtained from the RO is cooled. Here, it is possible to use a heat exchanger that heats the pre-soaks in countercurrent, or to use an external cold source. The cooled permeate is fed to the fresh water spray zone of the FRM, if necessary after a further oxidative treatment stage, pH adjustment and disinfection.

The innovations of the invention presented consist essentially of

• in the recovery of carried-over cleaning agents from the overflow water flowing into the pre-soak from the spray zones by using RO.

• in the previous cleaning of the overflow water using NF.

• in the combination of the recovery of cleaning agents with the recovery of water of drinking water quality for reuse in the FRM.

Sources

(A) Tedden.E.

A technical possibility to reduce water consumption while simultaneously improving the composition of wastewater at

Cleaning machines

Daily newspaper for brewery,70,34/35,178-182,1973

VLB Bertin 3/6

List of reference symbols

1 = Bottle transport direction

2 = Spray zones

3 = Overflow water

4 = Main cleaning bath

5 = Inlet to the pre-switch without invention

6 = Nanofiltration

7 = Concentrate Nanofiltration

8 = Pre-soak

9 = Permeate Nanofiltration

10 = Reverse osmosis

11 = Concentrate Reverse Osmosis 12 = Permeate Reverse Osmosis

13 = Fresh water

14 = Bottle cleaning machine

VLB-Berlin 6/6

Claims (6)

Protection claims 1. Device for reducing detergent and fresh water consumption in bottle cleaning machines, characterized in that • that the overflow water flowing into the pre-soak from the spray zones is subjected to nanofiltration. • that the concentrate is fed to the nanofiltration pre-soak. • that the permeate of the nanofiltration is subjected to further treatment in the form of reverse osmosis. • that the reverse osmosis concentrate is fed completely or partially into the main cleaning bath. • that the permeate from the reverse osmosis is reused in the spray zone of the bottle cleaning machine. 2. Device according to claim 1, characterized in that the overflow water is subjected to prefiltration before nanofiltration. 3. Device according to claim 1, characterized in that the nanofiltration is carried out in several stages. 4. Device according to claim 1, characterized in that the reverse osmosis is carried out in several stages. 5. Device according to claim 1, characterized in that the permeate of the reverse osmosis is cooled • by using a cooling source external to the machine. • by using a heat exchanger that heats the pre-soaks of the bottle cleaning machine accordingly in countercurrent. 6. Device according to claim 1 and 5, characterized in that the permeate of the reverse osmosis is brought to drinking water quality by the further treatment steps of neutralization, oxidative post-treatment and disinfection and is then reused in the fresh water spray. VLB Berlin 4/6