DE102014100733A1 - Cooling system for container treatment plants - Google Patents

Abstract

Plant for the beverage processing industry comprising a plurality of individual machines, including at least one blow molding machine, a labeling and a filler, characterized in that the system comprises a common water cooling circuit with a cooler for cooling components of the individual machines and a corresponding method for cooling such a system.

Description

The present invention relates to a refrigeration system for equipment in the beverage processing industry.

State of the art

Known container treatment plants consist partly of several container treatment machines. These include, but are not limited to, fillers or blow molding machines or sealers. The cooling of these individual machines or process units is usually also in common container treatment plants, in which these process units are arranged together, via individual cooling systems, which are designed so that they meet the cooling requirements of the individual machine with which they are assigned. Thus, for example, for blow molding water cooling systems are used with very high performance, since the individual components of the blow molding machine, in particular the blow molds must be cooled quickly, but have a high heat capacity and therefore therefore a large amount of heat must be dissipated. In contrast, other machines, such as labellers or fillers, partially cooled only with air, since they basically produce less heat, which must be dissipated by a cooling system.

Thus, a large number of different cooling systems may be necessary to cool the individual machines of the entire system, which means a very high maintenance and process can be confusing.

task

Based on the prior art, the object of the invention is therefore to provide a cooling system for installations for the beverage processing industry, which enables effective cooling and at the same time is economical.

solution

This object is achieved by the plant for the beverage processing industry according to claim 1 and the method for cooling a plant in the beverage processing industry according to claim 8. Advantageous developments of the invention are covered in the subclaims.

The plant according to the invention for the beverage processing industry comprises a plurality of individual machines, including at least one blow molding machine, a labeling machine and a filler and is characterized in that the system comprises a common water cooling circuit with a cooler for cooling components of the individual machines. Thus, only a single cooling system with a cooler is required for the entire plant, even if it comprises several individual machines, resulting in a considerable reduction in the complexity of the entire cooling system for the plant and at the same time is more economical than separate cooling systems for the individual machines. Due to the use of a water cooling system even single machines with high cooling requirements can be sufficiently cooled.

According to one embodiment, the water cooling circuit comprises at least one supply line for water for each individual machine. By at least partially separate supply lines, the cooling medium, here water, can be selectively fed to the individual machines.

It can be provided that in at least one individual machine, a heat exchanger is provided, which is connected to the supply line. The provision of heat exchangers in the individual machines allows the provision of smaller, special cooling circuits within the individual machines, the waste heat can be dissipated through the common cooling system via the heat exchangers.

In an advantageous embodiment of the invention, the system is characterized in that a main line is provided, which distributes water from the radiator in the cooling circuit and is connected to the supply lines. The provision of a main line allows the management of a considerable amount of water or cooling medium, which can be supplied to the individual machines as needed via the supply lines.

In one embodiment, an air-water heat exchanger is provided in at least one individual machine, which is connected to the water cooling circuit and / or it is provided that in at least one of the individual machines, a cold plate is provided, which is connected to the water cooling circuit. This design of the cooling systems in the individual machines can meet certain requirements of this to the cooling.

Furthermore, it can be provided that flow regulators are provided in the water cooling circuit, which can control the cooling power supplied to a single machine. Varies the necessary cooling capacity for a particular single machine, for example, depending on the load, here, the supply of water as a cooling medium and thus the supplied cooling power can be regulated and thus produced more energy-efficient.

Furthermore, the system may be characterized in that the individual machines as successive processing units are formed, which can execute sequential processes. The advantages of the cooling system according to the invention can thus also be used in complex, composite installations in which a container can be transported from production to completion and filling.

The invention further comprises a method for cooling a plant in the beverage processing industry with a plurality of individual machines, which is characterized in that the individual machines of the plant are cooled by a common water cooling circuit. This method for cooling the individual machines of the system is just from the process engineering point of view more effective and more economical.

In one embodiment of the method, water is supplied to the individual machines via feed lines. The separate supply of water as a cooling medium to the individual machines optionally allows the selective control of the cooling process of some individual machines, without affecting the cooling of the other individual machines, which means a high degree of flexibility.

It can also be provided that the water exchanges heat with a heat exchanger in the single machine and cools the single machine. The use of the heat exchanger allows the removal of waste heat, which is produced in the individual machine and is removed, for example, by an internal cooling system, out of the single machine.

In a further embodiment, the method is characterized in that the water is transported via a main line in the supply lines. The transport of water as a cooling medium through a main line allows a high maximum cooling capacity.

It can be advantageous if the cooling of the individual machine takes place by heat exchange of the water with air in an air-water heat exchanger. Hereby, the waste heat generated in one or more individual machines, which is dissipated by a separate, internal air cooling system, removed by the subsequent water cooling cycle from the single machine or the individual machines.

Furthermore, it can be provided that the supplied cooling power is controlled for each individual machine. This enables economical and targeted cooling of the individual machines and their components.

Brief description of the figures

1 Schematic representation of a plant according to the invention.

2 Schematic representation of another embodiment of a system according to the invention.

3 Schematic representation of an embodiment of the supply line.

Detailed description

1 shows a schematic representation of a system according to the invention 100 for the beverage industry. This includes all systems that are used for the production of, for example, containers, such as bottles, but also systems that allow labeling or further processing of the containers manufactured to facilities that accomplish a filling, sealing and packaging of the container to understand , According to the invention, the plant comprises 100 a series of stand-alone machines that become a composite 110 are summarized. These single machines 111 - 114 include at least a blow molding machine, a labeling machine and a filler. There are also other container treatment machines, such as direct printing machines, sterilization facilities or the like conceivable. Also conceivable are machines of packing and palletizing technology. The single machines 111 - 114 may be interconnected by transport means for containers. These include, for example, conveyors or holders that transport the containers in the neck-handling method.

According to the invention, the plant comprises 100 continue a cooling system 115 , This for the single machines 111 - 114 common cooling system 115 includes a cooler 120 that has a water cooling cycle with the single machines 111 - 114 in the composite 110 connected is. This connection of the radiator 120 with the single machines 111 - 114 can have partly separate supply lines 121 - 124 be realized. These leads 121 - 124 transport cooling water from the radiator 120 to the single machines 111 - 114 and can "spent" cooling water, so cooling water, the cooling of the individual machines 111 - 114 or components of these was used, transport away. This removal does not have to be done back to the cooler. The used cooling water can also be disposed of or made available to other individual machines for heating. These individual machines can, but do not have to be, part of the composite 110 be.

Although the supply lines 121 - 124 in 1 are shown separated from each other, it can also be provided that the supply lines 121 - 124 at least partially coincide and only branch off at certain points from each other, to cooling water the individual machines 111 - 114 supply. Furthermore, each supply line 121 - 124 in 1 shown as a single line that can transport according to the arrow directions cooling water to the individual machines and away from them. However, it can also be provided that the return transport takes place in a different way than the forward transport of the cooling water. For example, it may be provided that the supply of cooling water to the individual machines 111 - 114 in separate supply lines 121 - 124 , as shown, whereas the recirculation of the spent cooling water to the radiator 120 via a common return line.

2 shows a further embodiment of the system according to the invention 100 , In this is provided that a main line 250 emanating from the radiator, transported away in the cooling water from the radiator and used cooling water can be transported back to the radiator. As already in 1 described, can also be provided here that the return of the cooling water in a different way, so not through the main line shown 250 , he follows. From the main line 250 branches at several points the already described supply lines 121 - 124 from. These lead the cooling water to the individual machines 111 - 114 if necessary, they can also be transported away from them.

It can be provided that the individual machines 111 - 114 of the composite 110 via internal cooling systems 231 - 234 feature. These internal cooling systems can be designed very differently. For example, can be provided in the context of a blow molding machine, that a plurality of cooling circuits is provided, which remove the resulting waste heat in the blow molds from these. So would a corresponding blow molding machine 111 a cooling system 231 in which a separate cooling circuit with a large number of branches is provided according to the number of blow molds. The heat absorbed by the cooling system can then be, for example, via a heat exchanger in the cooling system 231 to the cooling water flowing through the supply line 121 transported, which makes it out of the single machine 111 is transported away.

However, other stand-alone machines, such as labellers, may also use a different form of refrigeration. Thus it can be provided that a labeling machine 113 via an independent or internal air cooling system 233 features. Also in this, an air-water heat exchanger may be provided, which of the air cooling circuit in the labeling machine 113 absorbed waste heat of the components on the cooling water in the supply line 123 is transported, thereby removing the cooling water through the supply line 123 the waste heat of the labeling machine is removed from this labeling machine.

Many other embodiments are also conceivable here, for example with the aid of coldplates or other cooling systems. According to the invention, all internal cooling systems for the individual machines 111 - 114 conceivable, provided that a transfer of these absorbed waste heat to the cooling water from the supply lines 121 - 124 can be done for example via suitable heat exchanger. The use of heat exchangers may or may not be required if the internal cooling system is also a water cooling system. In this case, the cooling circuit in the single machine either via a heat exchanger, the absorbed waste heat of the components to the cooling water from the water cooling circuit 115 discharged or the water from the water cooling circuit 115 can be used directly to cool the components of each machine by using it in the internal cooling circuit.

3 shows an embodiment of the supply of cooling water from the radiator 120 to a single machine 111 that have a separate or internal cooling system 231 may include. The supply line can, as with respect to 2 described, via a main line 250 and one of them branching supply line 121 respectively. However, this embodiment is not mandatory, it may also be a supply line from the radiator 120 directly to the single machine 111 be provided as they relate to 1 has been described. According to the embodiment in FIG 3 is a flow regulator 361 provided, the flow of cooling water through the supply line 121 can control. This includes or is connected to a controller that evaluates data, run programs and the flow controller 361 can control. This flow regulator 361 can either be directly in the cooler 120 be integrated or in an area of the supply line, in the presence of a main line 250 , preferably at the branch of the supply line 121 directly. The flow regulator 361 Can the one for the single machine 111 control the amount of cooling water delivered from the cooling system. This control can be based on several parameters and is generally very flexible and preferably programmable. Thus it can be provided in one embodiment that a permanent measurement of the individual components of the single machine 111 given heat is made and thus the need for cooling capacity and thus cooling water is calculated. According to the result, the flow regulator 361 then provide the required amount of cooling water, preferably losses due to the heating of the cooling water in the supply line 121 and optionally the main line 250 can be considered. Thus, with high accuracy, the amount of cooling water to be used can be determined and thus energy-saving procedure with the cooling. Alternatively, the flow controller or the controller can also evaluate information about the internal cooling system in general, so for example, only the total of this currently provided cooling power or recorded by this amount of heat or its cooling medium consumption and determine therefrom the required amount of cooling water through the supply line the individual machine must be supplied. To fulfill these tasks, it is provided that the controller or the flow regulator 361 Sensor data from the internal cooling systems can receive or that corresponding sensors are arranged in the individual machines, the process data, such as current temperature or current coolant consumption and capture the control of the flow controller 361 to transfer. Alternatively, you can also control the flow regulator 361 and the individual controls of the separate cooling systems of the individual machines be connected so that a data exchange, preferably bidirectionally but in any case of the individual controls for controlling the flow controller is possible. Either raw data or already processed data regarding the function of the individual machine in question can then be sent to the flow controller or its controller via this connection, whereupon it determines the required amount of cooling water.

Alternatively or additionally, control of the amount of cooling water provided by the flow regulator 361 also be time-dependent, for example, if it is known that certain machines are not in continuous operation but are only turned on at certain times during which they require cooling. At times when the machine is not in operation, the flow regulator can 361 the supply line 121 Close completely, so that no cooling water is wasted here. Here can also be certain "warm-up phases" in which the single machine 111 is brought to its operating temperature and may already be required cooling, are taken into account. Even "decay phases", in which the machine itself no longer processes containers, but in which it still requires cooling (in particular blow molding machines), can also be taken into account.

Claims (13)

Investment ( 100 ) for the beverage processing industry comprising several individual machines ( 111 - 114 ), including at least one blow molding machine, a labeling machine and a filler, characterized in that the plant ( 100 ) a common water cooling circuit ( 115 ) with a cooler ( 120 ) for components of individual machines to be cooled ( 111 - 114 ). Investment ( 100 ) according to claim 1, characterized in that the water cooling circuit ( 115 ) at least one supply line ( 121 - 124 ) for water for each individual machine ( 111 - 114 ). Investment ( 100 ) according to claim 2, characterized in that in at least one individual machine ( 111 - 114 ) A heat exchanger is provided which is connected to the supply line. Investment ( 100 ) according to claim 2, characterized in that a main line ( 250 ), the water from the radiator ( 120 ) in the water cooling circuit ( 115 ) and with the supply lines ( 121 - 124 ) connected is. Investment ( 100 ) according to claim 1 to 4, characterized in that in at least one individual machine ( 111 - 114 ) an air-water heat exchanger is provided, which is connected to the water cooling circuit ( 115 ) and / or that in at least one of the individual machines ( 111 - 114 ) a coldplate is provided, which is connected to the water cooling circuit ( 115 ) connected is. Investment ( 100 ) according to one of claims 1 to 5, characterized in that in the water cooling circuit ( 115 ) Flow regulator ( 361 ) are provided, that of a single machine ( 111 - 114 ) can control supplied cooling power. Investment ( 100 ) according to one of claims 1 to 6, characterized in that the individual machines ( 111 - 114 ) are formed as a series-connected process units that can run successive processes. Method for cooling a plant ( 100 ) in the beverage processing industry with several individual machines ( 111 - 114 ), characterized in that the individual machines ( 111 - 114 ) the plant ( 100 ) by a common water cooling circuit ( 115 ) are cooled. A method according to claim 8, characterized in that water the individual machines ( 111 - 114 ) via supply lines ( 121 - 124 ) is supplied. A method according to claim 9, characterized in that the water heat with a heat exchanger in the single machine ( 111 - 114 ) and the single machine ( 111 - 114 ) cools. Method according to claim 9, characterized in that the water is conveyed via a main pipeline ( 250 ) into the supply lines ( 121 - 124 ) is transported. A method according to claim 8 to 12, characterized in that the cooling of the single machine ( 111 - 114 ) is carried out by heat exchange of the water with air in an air-water heat exchanger. Method according to one of claims 8 to 12, characterized in that the supplied cooling power for each individual machine ( 111 - 114 ) is controlled.

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