WO2016020172A1 - Active container pressure control of a tunnel-type pasteurizer - Google Patents

Abstract

Method for active container pressure control of a tunnel-type pasteurizer for pasteurizing a product which is filled into containers, said method comprising the steps of: providing a model for determining a partial pressure within the container; determining an upper threshold for the partial pressure and/or the temperature of the product in the container with the aid of the model; measuring the temperature within the tunnel-type pasteurizer; comparing the measured temperature and/or the partial pressure, which is calculated using said temperature, in the container with the predetermined thresholds for the partial pressure and/or the temperature, and initiating measures for reducing the partial pressure in the container if the thresholds for the partial pressure and/or the temperature are exceeded.

Description

 Active tank pressure control of a tunnel pasteuriser

Field of the invention

The invention relates to a method for active container pressure control of a tunnel pasteuriser and a corresponding device.

Background of the invention

Devices for the thermal treatment of products which are filled in containers, for example bottles, PET containers or cans, are known in the prior art. For example, these devices may include pasteurization systems, heating or cooling devices. Often, these devices also occur in combination in multi-zone pasteurization systems to bring the products at least temporarily to different, defined temperature levels. The heat exchange is generally carried out by sprinkling with a process fluid, such as water. The term sprinkling should be understood to mean sprinkling or spraying of the containers. The water used in the process, also referred to as process water, is typically trickled over the product stream by means of nozzles. Due to a temperature difference to the product, the process water releases heat to the product or absorbs heat.

For example, such systems include a first section of one or more zones for heating the containers, then a second section for actual pasteurization, and finally a third section for cooling the containers. In large systems can be spoken of temperature landscapes.

(T-Tref) A commonly used, simple method of measuring pasteurisation of the liquid bottled in the containers is the use of Pasteurization Units (PU). Usually, the calculation of the PE is done by adding up the PE values achieved per time base,

(T-Tref)

L (T) = if T> T _r

 if T <T, where T indicates the current temperature in "Celsius, Tref a temperature reference, Tmin a minimum temperature, Z a value of a temperature change required to reduce the number of bacteria by a factor of 10, Δ time the time between minute and time based measurements indicate the time reference, typically in minutes Typical values for canned or bottled beer may be about a 1 minute time base, a reference temperature of 60 ° C, a Z value of 7 ° C, and a minimum temperature Tmin of 50 ° C. The values for other liquids with different pasteurization goals may be quite different, for example, for tomato juice a temperature reference of 80 ° C. and a Z value of 10 ° C. may be used.

Finally, the PE serves as a figure of merit to summarize the parameters of time and temperature for a pasteurization of a liquid, a beverage. For example, for canned or bottled beer, a minimum value of less than 10 PE, more often a value of 15-30 PE may be used to ensure a desired stability / shelf-life of the product.

The control of a pasteurization system can take into account a temperature model, ie different temperatures in different sections or zones at a certain flow rate of the product stream. The temperature model can be converted to PE (and vice versa). A certain PE has to be achieved, at the same time an overrun of the PE and thus overpasteurisation should be avoided.

However, an additional problem is the pressure building up inside the containers to be pasteurized. This problem occurs especially with carbonated drinks.

When several times in succession heating and cooling between two specified temperature levels, the pressure within the container continues to build up. The same can happen if you stay too long at a constant high temperature. Excessively high pressure build-up within the products, ie the bottles or cans, may cause them to deform or eventually result in bursting of the containers. Both is undesirable, since a deformed container does not reform back into its original shape and thus can not be sold and worse, burst containers to contamination of the system by shards or fragments and by the contents of the container being able to lead. This may require an early cleaning of the system, which in turn can mean a shutdown of the system and thus a reduction in the efficiency of the system.

The cause of the pressure build-up is the different setting rates for the carbon dioxide equilibrium, as explained below with reference to water and carbon dioxide.

A closed container, such as a can or a bottle, represents a closed system in the chemical-physical sense. As an example, a can or bottle called with carbonated water. There is no mass transfer with the environment outside the bottle. But it can give a heat exchange with the environment. There are two phases in the bottle: the gas phase and the liquid phase. The proportion of vaporized water molecules in the gas phase is practically completely negligible. Thus, the water is in the liquid phase. In both phases, however, there is the C0 ₂ . It is physically dissolved as a gas in the liquid phase. The gas phase is almost exclusively filled by C0 ₂ . The gas phase has a certain gas pressure. Gas particles are exchanged between the two phases until an equilibrium has been established. In the closed container there is an overpressure. In this case, the solubility of a gas in a liquid increases with increasing partial pressure of the gas proportional to according to the law of Henry.

The increase in solubility with an increase in pressure within the container causes the system to attempt to increase the concentration of the gas in the liquid. This reduces the number of molecules in the gas phase.

The solubility of carbon dioxide is increased at low temperatures and high pressures.

A temperature increase represents an external energy supply. This energy supply causes carbon dioxide dissolved in the water to dissolve out and collect in part in the gas space above the liquid and in part float as fine gas bubbles on the inside of the container. As the temperature increases, the pressure in the gas phase will increase rapidly. If the liquid is allowed to settle again, or if the container is cooled down again, the equilibrium is slowly restored.

For carbon dioxide, C0 ₂ , and water, H ₂ 0, the following equilibria are involved, which occur at different speeds.

(1) C0 ₂ (gaseous) + H ₂ 0 ^ C0 ₂ (dissolved) + energy (2) C0 ₂ (dissolved) + H ₂ 0 ^ H ₂ C0 ₃

(3) H ₂ C0 ₃ + H ₂ O ₃ H ₃ O ⁺ + HCO ₃ ^"

(4) C0 ₂ + 2H ₂ 0 ^ H ₃ 0 ⁺ + HCO ₃ -

(5) HCO ₃ ^" + H ₂ O ₃ C0 ₃ ^2" + H ₃ O ⁺

Equation (1) merely shows that dissolved C0 ₂ passes into the gaseous state by supplying energy, for example in the form of heat.

In the equation (2), the equilibrium is very much on the side of the dissolved gas. The proportion of the acid molecule is only about 0.2%.

Equations (2) and (3) are usually grouped into equation (4). The pK _s value of equation (4) is about 6.5. The pKs value of equation (5) is about 10.5.

Equations (2) and (3) set their equilibrium slowly, equations (4) and (5) set the equilibrium quickly.

The concentration of oxonium ions H ₃ 0 ⁺ can be indicated by the pH. The concentrations of the carbonic acid species of equations (1) - (5) described above are thus related by the law of mass action.

For the filled, closed containers, this means that the pressure within the container rises faster during heating than it falls during cooling. Thus, there is at least a risk that the pressure will increase. Only when it stays at an exit temperature long enough, or even cooled, does the pressure drop back to its original level.

Another aspect is the consideration of the thermal expansion of the liquid in the container. Temperature changes in solids and liquids result in a change in volume V. This can be represented by a material-specific, temperature-dependent volumetric expansion coefficient γ, where γ is given in units of K ^"1. Under normal conditions, the values for solids are about one to two orders of magnitude smaller than those Values for liquids The coefficient of thermal expansion is also temperature-dependent, with the thermal expansion coefficient being approximately proportional to the specific heat capacity of the material in question. For the material of the containers, this means that in the temperature range in which the pasteurization takes place, no large temperature dependence of the expansion coefficient γ for the materials of the container. That is, the volume expansion of the container can be approximated by means of linear

AV = V ₀ (\ + _r AT); where ΔΤ represents the temperature difference, AV the volume change and V ₀ the volume before the temperature increase. For the typical materials for containers, the volume change with increasing temperature is positive, ie the volume increases.

However, this change is small compared to the volume change of the liquid in the container. This can not be approximated linearly, but can only be empirically determined. The expansion coefficient γ is strongly temperature-dependent. For example, typical values of γ are in the range of typical temperatures encountered in pasteurization.

Thus, the volume change of the liquid within the closed container can make a contribution to the pressure increase inside the container.

In view of the problems described above, it is an object of the present invention to provide an integrated approach that minimizes or even eliminates the sources of deformation or bursting of filled, closed containers in the system and thus can increase the efficiency of the system.

Description of the invention

This object is achieved by a method for container pressure control of a tunnel pasteurizer for pasteurization of a container-filled product according to claim 1 and a corresponding device according to claim 8. The invention provides a method for active container pressure control of a tunnel pasteurizer for pasteurization of a product filled in containers, comprising the steps of: providing a model for determining a partial pressure within the container; Determining an upper threshold for the partial pressure and / or the temperature of the product in the container using the model; Measuring the temperature within the tunnel pasteuriser; Comparing the measured temperature and / or the thus calculated partial pressure in the container with the predetermined thresholds for the partial pressure and / or the temperature, and taking measures to reduce the partial pressure in the container if the thresholds for the partial pressure and / or the temperature exceeded are.

It is understood that the tunnel pasteurizer can be divided into several zones and / or sections and that all of the described steps can be carried out in zones or in sections. It is further understood that the containers typically include bottles or cans in which the product, ie a liquid such as a beverage, is filled and the containers are closed. It is also understood that the containers are typically transported on a conveyor, such as a conveyor belt, through the tunnel pasteurizer.

A model for determining the partial pressure within the containers may include the amount and concentration of C0 ₂ in the container. These can be determined empirically. In this case, the amount of C0 ₂ , which naturally arises during the production or ripening of the product (for example beer or wine), can also be determined empirically, as well as the amount of added C0 ₂ can be determined. Likewise, the temperature of the product can be determined prior to entering the tunnel pasteurizer.

For the containers and their filling thresholds for the prevailing in the container partial pressure can be determined empirically. Likewise, it can be empirically determined when the container (s) begin to deform or even burst. It is understood that these thresholds can also be specified as ranges and that the thresholds can be provided with safety margins. Thus, the thresholds for the containers and the temperatures or pressures can be adjusted. It will be appreciated that the model may account for the various reaction rates, such as the typically slow redissolution of gas in the liquid.

It is understood that the temperature of the product or partial pressure in a filled, sealed container can be difficult to determine. Therefore, with the aid of the model, the partial pressure in the container is calculated on the basis of the measured temperature in the tunnel pasteuriser or in a certain zone of the tunnel pasteurizer. Thus, a good estimate of the partial pressure within the container can be obtained.

Comparing with the predetermined thresholds may therefore indicate that measures must be taken to lower the partial pressure in the containers, as long as the thresholds are exceeded. Thus, the deformation or bursting of the containers can be avoided.

In the method, the measures may include lowering the temperature in the tunnel pasteurizer.

By reducing the temperature, a lower partial pressure can be set in the containers. Thus, the risk of bursting of containers and associated product loss can be reduced. Thereby the necessary reduction of the temperature online, i. be calculated directly during operation.

In the method, providing the model may be product specific, wherein providing the model may take into account the C0 ₂ content of the product and / or providing the model may take into account the thermal expansion of the liquid in the container.

This allows the model to be adapted exactly to the product type. Thus, the type of container, such as can or wall thickness of a can or bottle can be taken into account. Likewise, the gas content, for example, the C0 ₂ content of the product are taken into account, there are, for example, drinks "bubbly type" with a lot of carbon dioxide and on the other hand drinks "gentle kind" with little carbon dioxide. Likewise, the model can account for the thermal expansion of the liquid in the container. For this, empirically values for the liquid, for example water, can be included in the model, so that the model can be even more precise. To refine the model, the thermal expansion of the container materials can also be taken into account.

The method may further comprise the step of determining a time ΔΤ for which the tunnel pasteurizer is driven at a lower temperature. The method may further comprise the step of increasing the temperature within the tunnel pasteurizer after the time ΔΤ.

It may be considered that after a predetermined time ΔΤ, the partial pressure within the containers will have dropped to a desired, predetermined level. This time can be determined, for example, based on the model. It can also be predetermined on the basis of empirical values. These empirical values can also serve as a guideline for the model. Thereafter, the temperature in the tunnel pasteuriser or in one or more of the affected zones or sections of the tunnel pasteurizer can be increased again.

The method may further comprise the step of storing the calculated and measured temperature and / or partial pressures in a database; Comparing the current values with the stored values and signaling deviations of the current values from earlier calculated and measured values.

An online queryable database can be taken into account in which, for example, one of the measured and the particular data can be stored. In particular, an already existing parameterization of the model can be retrieved so that the model can be accessed even faster. Likewise, the model can be improved by improving the parameters of the model.

In the method, the measures may additionally comprise changing, in particular reducing, the transport speed of the containers through the tunnel pasteurizer.

The transport speed through the tunnel pasteuriser or through the zones of the tunnel pasteurizer can be adjusted as an additional measure. Since time and temperature are linked by the term of the pasteurization unit, in particular it is better to drive the machine more slowly, ie to reduce the transport speed. This calculation can be done online.

The invention further provides an apparatus for controlling a pasteurizer for pasteurization from a product filled in containers, comprising: means for providing a model for the partial pressure within the container; Means for determining an upper threshold for the partial pressure and / or the temperature of the product in the container by means of the model; Means for measuring the temperature within the tunnel pasteuriser; Means for comparing the measured temperature and / or the partial particle temperature calculated therewith pressure in the container with the predetermined thresholds for the partial pressure and / or the temperature, and means for taking measures to reduce the partial pressure in the container, if the thresholds for the partial pressure and / or the temperature are exceeded.

 The advantages of the device correspond to the advantages of the corresponding method already described above.

In the device, the means may comprise a control unit.

In particular, the device may comprise a control unit, such as a computer, wherein the tunnel pasteurizer may comprise a plurality of zones and / or sections and may comprise a plurality of control units for the individual zones and / or sections.

In the apparatus, the measures may include lowering the temperature in the tunnel pasteurizer.

In the apparatus, the provision of the model may be product-specific, wherein the provision of the model may take into account the C0 ₂ content of the product and / or and / or wherein the model may take into account the thermal expansion of the liquid in the container.

In the apparatus, the means may be configured to determine a time ΔΤ for which the tunnel pasteurizer is driven at a lower temperature.

In the apparatus, the means may be configured to increase the temperature within the tunnel pasteuriser after the time ΔΤ has elapsed.

The apparatus may further comprise a database, wherein the means may be configured to store the calculated and measured temperature and / or partial pressure values in the database; compare the current values with the stored values and signal deviations of the current values from earlier calculated and measured values.

In the apparatus, the measures may additionally include changing, in particular reducing the transport speed of the containers through the tunnel pasteurizer. Embodiments of the invention will be described below with reference to the figures. The described embodiments are to be considered in all respects only as illustrative and not restrictive, and various combinations of the recited features are included in the invention.

Brief description of the figures

Show it:

Figure 1: Qualitative representation of a pressure build-up in containers in a mehrzonigen

 Tunnel Pasteur.

Figure 2: Schematic view of a tunnel pasteurizer with three zones.

Figure 3: Schematic view of a tunnel pasteurizer with three zones with a container pressure control.

Figure 4 Schematic view of a method for active container pressure control of a

 Tunnel Pasteurizer for pasteurisation of a product filled in containers.

FIG. 5 Schematic view of a development of the method from FIG. 4.

Figure 6 Schematic view of a development of the method of Figure 5. Detailed Description

FIG. 1 shows a qualitative representation of a pressure build-up in containers in a multi-zone tunnel pasteurizer. Purely by way of example, seven zones, which are designated zone 1, zone 2, zone 7, are shown in FIG. The filled and sealed containers (not shown) are transported through the zones from left to right. The transport begins at zone 1 and then progressively passes through the remaining zones to zone 7. Although the zones are approximately equally wide, the width of the zones may be different. Likewise, the number of zones may be other than seven.

The axes of the diagram shown in Figure 1 are designated as follows. The ordinate indicates the partial pressure in the containers. The abscissa indicates the time. The direction of the time Axis corresponds essentially to the transport direction through the zones, which are passed through successively from zone 1 to zone 7. In Figure 1 it is shown that the partial pressure in the containers increases on average in most zones as a function of time, which is equivalent to the fact that the partial pressure increases as a function of the transport distance on average. In the example shown, the partial pressure in the container after passing through the zone 7 is significantly higher than in zone 1 and higher than in all previously traversed zones.

On the basis of the qualitative representation of FIG. 1, it becomes clear how - as a model - the partial pressure can build up in the containers. The significant increase in the partial pressure when passing through the tunnel pasteurizer can be caused by energy supply by increasing the temperature. This can significantly increase the risk of deforming (in the case of cans) or bursting (in the case of cans or bottles).

FIG. 2 shows a tunnel pasteurizer 100. By way of example, three zones of the tunnel pasteurizer are shown, designated Z1, Z2 and Z3. The three zones shown can also be considered as a section of a tunnel pasteurizer. In the tunnel pasteurizer 100 filled, sealed container B are transported on a conveyor belt 1 1 from left to right through the zones Z1, Z2 and then Z3. The containers are sprinkled with process water which is sprayed over or onto the containers by means of spray nozzles 13.1, 13.2 and 13.3. The process water used can be collected at least partially in catchment zones 15.1, 15.2 and 15.3 in each zone and via lines

17.1, 17.2 and 17.3 are reused.

In Figure 3, a tunnel pasteurizer 200 according to the present invention is shown. The tunnel pasteurizer 200 is similar to the tunnel pasteurizer 100 shown in FIG. 2. Like elements are designated by like reference numerals. The tunnel pasteurizer 200 also includes three zones purely by way of example. In Tunnelpasteur 200 filled, sealed container B are transported on a conveyor belt from left to right. The containers are also sprinkled in the tunnel pasteurizer 200 with process water from a sprinkler system with spray nozzles, which are not explicitly shown in the individual zones Z1, Z2, and Z3. FIG. 2 also has in each of the zones Z1, Z2 and Z3 at least one means for detecting or determining the temperature in the respective zone. These may be temperature sensors or temperature sensors. These means are denoted by the reference numeral 21 .1,

21 .2, and 21.3. It is understood that more than one agent per zone may be provided. In principle, it is also possible that zones in which, for example, only is cooled, no temperature sensor or the like are provided. The means 21.1, 21 .2, 21.3 for detecting or determining the temperature in the respective zone Z1, Z2, Z3 can determine the temperature in the respective zone practically online. Via line 23.1, 23.2 and 23.3, each of the means 21.1, 21.2 and 21.3 its temperature data to a control and monitoring unit 27 on. The control and monitoring unit 27 may include, for example, a computer. In principle, a wireless communication between the units 21 .1, 21 .2, 21.3 and the control and monitoring unit 27 is possible.

The control and monitoring unit 27 may be a mobile unit. The control and monitoring unit 27 may be connected to a database 29. In this case, the control and monitoring unit can be used to create a model for determining a partial pressure within a container. This model can be created empirically with the help of suitable measuring equipment and then used in standard operation of the pasteurizer.

The tunnel pasteurizer 200 shown in Figure 3 may further comprise one or more measuring means and control units 25 for controlling the transport speed of the containers. It is understood that the zones Z1, Z2 and Z3 need not be the same width, so that the time spent by the containers B at a mean constant transport speed in the respective zones may be different. The containers B are transported on the transport conveyor belt 11 through the tunnel pasteurizer. The speed of the transport can be controlled by means of the unit 25 in order to transport the containers through the pasteuriser 200 faster or slower. Thus, in addition to the direct temperature control, there is another possibility of influencing the temperature indirectly. In particular, the regulation of the temperature and the control of the transport speed can also be combined in order to achieve the best possible adaptation of the partial pressure of the containers to the model. The unit 25 may include a motor or be connected to a motor (both not shown) that can drive the transport conveyor belt 1 1. Via a line 26, the unit 25 may be connected to the control and monitoring unit 27. Thus, the unit 27 can control each unit 21.1, 21 .2, 21 .3 and 25 individually in a master functions, whereby the model can be implemented.

In accordance with the present invention, methods for active vessel pressure control of a tunnel pasteurizer for pasteurization from a product filled in containers are illustrated in Figs. 4-6.

FIG. 4 illustrates a corresponding method. In step S210, a model is provided for determining a partial pressure within the container. This can For example, done empirically and with the aid of the control unit 27. In this case, product-specific and / or container-specific parameters such as CO ₂ content / carbonic acid content and / or thermal expansion of the liquid in the container or specific heat capacity can be taken into account. Furthermore, container volume, container filling etc. can be taken into account. It can also be considered the thermal expansion of the solid container material.

In step S220, an upper threshold can be determined empirically, above which there is at least the risk that they deform or even burst or burst the containers. The upper threshold may be expressed by a partial pressure of the gas / gases present in the container and / or a temperature.

The steps S210 and S220 may be performed before the normal operation of the tunnel pasteuriser.

Step S230 is typically carried out in the normal control operation of the tunnel pasteuriser. The temperature is typically in all zones, i. For example, in the zones Z1, Z2 and Z3 in Figure 3, performed the tunnel pasteurizer. In step S240, the measured temperature and / or the partial pressure thus calculated in the container are compared with the predetermined thresholds from S220 for the partial pressure and / or for the temperature in the tunnel pasteurizer. In step S250, a decision may be made, for example by the control unit 27 of FIG. 3, as to whether measures should be taken. The measures can be initiated, for example, when the thresholds of S220 for partial pressure and / or temperature in the tunnel pasteuriser, resulting in the model over the temperature in the container, are exceeded. Thus, it can be reacted to a high partial pressure in the container and the bursting of the container can be avoided.

FIG. 5 shows the same steps as FIG. 4. In addition, FIG. 5 shows step S255, which includes the lowering of the temperature in the tunnel pasteuriser, if the thresholds have been exceeded in step S250. Thus, the partial pressure in the containers can be lowered and the bursting of the containers can be avoided.

FIG. 6 shows the same steps as FIG. 5. In addition, FIG. 6 also shows the step S260. On the basis of the model it is possible to calculate how long the temperature of the tunnel pasteuriser or at least of one or more zones of the tunnel pasteurizer has to be reduced in order to reduce the partial pressure in the containers to a desired level. In this case, control measurements of the temperature can be made in the respective zones. is a calculated time ΔΤ has passed, the temperature in the tunnel pasteurizer can be increased again in step S265. Thus, the efficiency of the tunnel pasteurizer can be optimized. It is understood that the steps S220 - S250, S255, S260, S265 can be cycled. In addition, in steps S255, S260, S265 of FIGS. 5 and 6, a reduction in the transport speed may also be taken into account.

It therefore applies: It is modeled u.a. determines the partial pressure within a container, which passes through the tunnel pasteuriser. Here, chemical equilibrium reactions and their reaction rates are considered. The model can provide a prediction to set product-specific and container-specific pressure and temperature limits of the individual products. For example, when the thresholds are set, the pasteurization temperature may be lowered to avoid excessive pressure within the container. Thus, bursting of the containers within the tunnel pasteurizer can be avoided.

Claims

claims 1. A method for active container pressure control of a tunnel pasteurizer for pasteurization of a product filled in containers, comprising the steps of:  Providing a model for determining a partial pressure within the container;  Determining an upper threshold for the partial pressure and / or the temperature of the product in the container using the model;  Measuring the temperature within the tunnel pasteuriser;  Comparing the measured temperature and / or the thus calculated partial pressure in the container with the predetermined thresholds for the partial pressure and / or the temperature, and  Initiate measures to reduce the partial pressure in the container if the thresholds for the partial pressure and / or the temperature are exceeded. 2. The method of claim 1, wherein the measures include lowering the temperature in the tunnel pasteurizer. 3. The method according to claim 1, wherein the providing of the model is product-specific and wherein the provision of the model takes into account the C0 ₂ content of the product and / or wherein the model takes into account the thermal expansion of the liquid in the container. 4. The method according to at least one of claims 1-3, further comprising the step of determining a time ΔΤ for which the tunnel pasteurizer is driven at a lower temperature. 5. The method of claim 4, further comprising the step of raising the temperature within the tunnel pasteurizer after the time ΔΤ. 6. The method according to at least one of claims 1-5, further comprising the step of storing the calculated and the measured temperature and / or partial pressure values in a database; Compare the current values with the stored values and signal deviations of the current values from earlier calculated and measured values. 7. The method according to at least one of claims 1-6, wherein the measures additionally comprise changing, in particular reducing the transport speed of the container through the tunnel pasteurizer. 8. Apparatus for controlling a tunnel pasteurizer for pasteurization of a product filled in containers, comprising:  Means for providing a model of the partial pressure within the container; Means for determining an upper threshold for the partial pressure and / or the temperature of the product in the container by means of the model;  Means for measuring the temperature within the tunnel pasteuriser;  Means for comparing the measured temperature and / or the thus calculated partial pressure in the container with the predetermined thresholds for the partial pressure and / or the temperature, and  Means for taking measures to reduce the partial pressure in the container, if the thresholds for the partial pressure and / or the temperature are exceeded. 9. Apparatus according to claim 8, wherein the means comprise a control unit. 10. The device according to at least one of claims 8 - 9, wherein the measures include lowering the temperature in the tunnel pasteurizer. 1 1. The apparatus of at least one of claims 8-10, wherein the providing of the model is product specific and wherein providing the model takes into account the C0 ₂ content of the product and / or wherein the model takes into account the thermal expansion of the liquid in the container. 12. The device according to at least one of claims 9 - 1 1, wherein the means are adapted to determine a time ΔΤ, for which the tunnel pasteurizer is driven at a lower temperature. 13. The device according to least claim 12, wherein the means are adapted to increase the temperature within the tunnel pasteuriser after the time ΔΤ has elapsed. 14. The device according to at least one of claims 8 - 13, further comprising a database, wherein the means are formed, the calculated and the measured temperature and / or partial pressure values in the database to memory; the current values with the stored values and to signal deviations of the current values from earlier calculated and measured values. 15. The device according to at least one of claims 8 - 14, wherein the measures additionally comprise changing, in particular reducing the transport speed of the container through the tunnel pasteurizer.