DE3308325A1 - Method and device for the complete or partial destruction of microorganisms - Google Patents

Abstract

The method for the complete or partial destruction of microorganisms is applicable in all fields in which the microorganism count of liquid or gaseous media must be limited or reduced. This is the case, for example, in the fields of pharmaceutical medicine and foodstuffs technology. The problem is solved with an arrangement in which the contaminated liquid or gaseous medium is compressed and immediately relaxed again. The forces liberated thereby lead to a destruction or inactivation of the reproductivity of microorganisms.

Description

Description »3 ·

The fight against harmful or unwanted microorganisms represents an essential task in pharmaceuticals, the food industry, water management, chemistry and biotechnology, for example In the health care system, with regard to hygiene, a limitation or destruction of pathogens or optional pathogenic microorganisms necessary.

Known processes such as heat sterilization, gas sterilization, sterilization by radiation, death by thermal radiation or by exposure to it chemical agents are sometimes extremely complex, cost-intensive or cannot be used for media to be treated accordingly.

With the invention, for example, a liquid or gaseous, Medium contaminated by microorganisms without heat, radiation or chemical agents with little technical and energetic expenditure be continuously or discontinuously reduced in its content of viable microorganisms in whole or in part. The effect the reduction of microorganisms is achieved in the submitted invention that mechanical forces, which in a preceding Pressure increase and immediate relaxation act on the organisms, destroy intact cells, or only inhibit their ability to reproduce.

In the pharmaceutical industry, for example, processed low-germ is used Water circulated in ring lines. It has been shown that running water has a lower growth rate for germs than this is the case in standing water. However, undesirable high levels of germs often occur even with running water.

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For example, such a ring line (1) as in FIG drawn, a certain partial water flow is fed to a pump (3) via the bypass line (10). By the downstream throttle device (5), for example, a pressure difference of, for example, two bar builds up between line (10) and throttle (5), which is caused by change of the throttle valve (5) and can be read on the pressure gauge (4). After passing through, for example, a valve cone in the Throttle device (5), the water is suddenly expanded to the ambient pressure, since the throttle device (5) via a nozzle (6) into an expansion vessel (7) opens and the expansion vessel (7) via a ventilation valve (8) with built-on sterile filter (9) is in constant pressure with the environment. The sudden relaxation causes the destruction of the Microorganisms. In order to supply the water from the expansion vessel (7) back to the line (1), it is necessary that the pressure in the ring line (1) at the entry of the bypass line (10) which leads from the expansion vessel (7) is lower than the ambient pressure. The pressure in the main line can be reduced with the help of the throttle valve (2). The sterile filter (9) is necessary about the treated water in the expansion vessel (7) to recontaminate with microorganisms from the environment. For example, water samples can be taken via the valve (11).

Since the medium can heat up through dissipation, for example in the pump (3) or at the throttle element (5), a cooling device (13), as shown in FIG. 5, must be provided in the bypass line. It is known that the growth of most, found in the water bacteria at about 25-37 ⁰ C at the greatest. With a cooling device it is possible to keep the medium colder.

Unlike in Fig. 1, the return of the water to the Ring line (1) reached from the expansion vessel (7) with the help of another pump (3). The check valve built into the bypass line (10) (12) prevents water from flowing back into the expansion vessel (7) if the pump (3) behind it fails.

ORIGINAL INSPECTED

The bypass system shown in FIGS. 1 and 2 can be used the purchase of only a partial amount of water and thus saves the portion of energy costs that are required for the total amount for the pressure increase would have been needed. A prerequisite with regard to the reduction in microorganisms is that the bypass lines (10) reduce the amount Microorganism count is introduced into the line (1) than in this was before entering the bypass line. The reduction in microorganisms in the overall system depends on the size of the volume flow by the pump (3) and the amount of microorganisms it contains, of the pressure difference occurring between the throttle device (5) and Expansion vessel (7) and the geometry of the throttle device (5) and downstream nozzle (6).

Figure 3, 4 and 6 shows a throttle device (5) in which the point the throttling sits directly on the expansion vessel (7). This results in a more direct expansion of the medium into the expansion vessel.

Figure 6 shows a throttle device in which a throttle gap (1B) thereby is generated that a housing over an opening of the intermediate container (7) (19) is arranged, in which there is a toothed rack (20) with a sharp edge and this for example via a toothed wheel (21) and can be moved here. The sharp-edged throttle gap (18) enables the spontaneous relaxation of the medium in the intermediate container (7).

Due to the bevel of the sharp edge of the rack (20), the medium accelerated again before entering the gap (18), so that in the spontaneous relaxation after passage, even greater forces act on the medium than would be the case without beveling. After the passage of the medium through the gap (18) is the wall of the intermediate container (Π r.o shaped so that the cross-section expands quickly by the relaxation to bring about as quickly as possible.

ORIGINAL INSPECTED

The geometric shape of the entry point of the medium into the intermediate container (7) is of great importance for the effectiveness of the "killing or growth reduction. As already described, the relaxation be able to follow up quickly after the passage. ■ That is why the drilling for receiving the throttle cone (16) in Figure 4 from the interior of the intermediate container (7) countersunk. The resulting sharp edge of the annular gap (15) between valve cone (16) and housing (17) generates strong shear forces when the medium passes through it, which destroys the Accelerate microorganisms.

The pump (3) also has a destructive effect on the microorganisms. If a pump is used in which strong forces act on the medium, such as centrifugal forces caused by high radial accelerations occur, the microorganisms are severely squeezed and already partially destroyed. For example, centrifugal pumps are suitable for this.

For example, the arrangement shown in FIG. 5 with the throttle valve (2) closed and a device for cooling (13) the bypass flow (10) achieved the killing curve (14) shown in FIG. 7 with the bacteria Pseudomonas cepacia and an initial germ count of 2 χ 10 CFU / ml. The solid curve (14) shows the decrease in CFU of Pseudomonas cepacia over time, at a pressure difference between the throttling means (5) and expansion vessel (7) of two Bar und.einer temperature between 14 and 16 ⁰ C. The dashed curve (13) shows the course of the CFU of a control culture prepared from the same starting material, the same concentration, and the same medium at the same temperature as in the experiment.

It is important in the process described that in empirically to be determined At intervals the throttle device is briefly fully opened and then set back to the old value, in order to possibly weaker in dead spaces Rinse off settling microorganisms. This can be done by hand or with an automatic drive.

ORIGINAL INSPECTED

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The killing of the microorganisms can be increased by the medium to be treated is acted upon by means of ultrasonic waves. These sound waves burst the cells of these organisms, which are then no longer viable.

The arrangement shown in FIG. 8 shows, for example, ultrasonic oscillators (22), which sonicate the medium still in the nozzle (6) and thus destroy germs that have not yet been killed. In principle, one or more transducers can be used, which or which can also be used at any other point of those described Arrangement, both outside and inside the device parts in contact with the medium, are arranged.

If the throttle device (5) or (17) or (19) is acted upon with ultrasound, in addition to the killing effect, this also has the advantage that, as already described, microorganisms settle out are immediately removed again at dead spaces and the flushing process of the throttle device, which is necessary from time to time, is omitted.

ORIGINAL INSPECTS

Claims (11)

Method and device for the complete or partial destruction of microorganisms Expectations π. / Method for reducing microorganisms in liquid or gaseous media, dgd from a container or a main line the liquid or gaseous medium is wholly or partially fed to a bypass line by intrinsic pressure or suction by means of a pressure increasing device and then via a suitable, oiling device directly or with a downstream nozzle is spontaneously relaxed in an intermediate container and then in ^; the tank or the main line (with cooling)! '. is fed back if the temperature of the medium cannot be kept constant. 2. The method according to claim 1, dgd in the case of a line, the return of the liquid or gaseous medium takes place without additional pressure increase if a throttle valve in the main line is set so that there is a lower pressure at the junction of the bypass line behind it than in the Intermediate container is the case. 3. The method according to claim 1 and 2, dgd with a further pressure increasing device the liquid or gaseous medium can flow back into the main line from the intermediate container, wherein the pressure increasing device between the intermediate container and the main line is set so that an inflow of the liquid or gaseous medium takes place from the bypass line into the main line and that the flow in the main line in the same direction shows how in front of the extraction point. ORIGINAL INSPECTED COPY L 33UbJZO . SL. 4. Apparatus for performing the method according to claims 1 to 3, dgd from a container or a main line (1) with a throttle valve (2), a bypass line (10) to a pump (3) and a throttle device (5) with a nozzle (6) is connected downstream, which opens into an intermediate container (7), from which the bypass return line (10), to which a cooler (13) is arranged to keep the temperature constant if necessary, leads into the container or the main line (1) . 5. Device for performing the method according to 1 to 3, dgd of a main line (1) with a throttle valve (2), a bypass line (10) to a pump (3) is branched off and a throttle device is connected downstream the output of which opens directly into an intermediate tank (7), from which the bypass return line (10) into the main line (1) leads. 6. Apparatus according to claim 4 or 5 dgd between the pump (3) and throttle device (5), a pressure gauge (4) is installed for pressure monitoring. 7. Device according to claims 4 or 5 to 6, dgd in the intermediate container (7) a shut-off element (8) with a sterile filter (9) opens. 8. Device according to claims 4 or 5 to 7, dgd on the intermediate container (7) a drain valve (11) is arranged. 9. Device according to claims 4 or 5 to 8, dgd after the intermediate container (7) a pump (3) with a non-return valve (12) is arranged in the bypass line (10). 10. Device according to claims 1 to 9, dgd on the nozzle (6) ultrasound generating devices are arranged. 11. The device according to claim 1 to 9, dgd ultrasound-generating devices on the by-pass line (10), before or after the throttle element (5), in or on the intermediate container (7) are arranged. ORIGINAL INSPECTED