EP0911156A1 - Tempering assembly in printing machines - Google Patents

Abstract

Temperature control arrangement for temperature control of a dampening solution and / or selected rollers of a printing press, with a dampening solution circulation system (UI) for supplying a dampening solution application device with a dampening solution, a coolant circulation system (UII) for supplying a roller cooling device with a coolant, a cooling device with a Refrigerant circulation system (UIII), and a device (50) for the optional operation of one or more of the circulation systems. The circulation systems (UI, UII, UIII) are assigned a common heat exchange device (1), which has a plurality of flow passages arranged in a heat-transferring relationship and a distributor device for connecting the dampening solution circulation system (UI), coolant circulation system (UII) and Refrigerant circulation system (UIII) with a selected sequence of flow passages, wherein adjacent flow passages are connected to a different circulation system. Depending on the sequence of the flow passages, different heat exchange functions between the circulation systems can be obtained with little conversion effort. <IMAGE>

Description

The invention relates to a temperature control arrangement for Temperature control of a dampening solution and / or selected rollers a printing press according to the preamble of claim 1.

Known arrangements of the generic type, e.g. in documents DE-U-296 08 054, DE-A-44 26 083, EP-A-693372 are described, have for the dampening solution and Coolant circulation system each on a separate heat exchanger. The heat exchangers are either individually using cooling energy supplied by a refrigeration device, or it such a supply takes place to only one heat exchanger, by using the directly cooled dampening solution Cold energy transfer to the further heat exchanger of the Coolant circulation system is used. The well-known Types of tempering arrangements are because of the construction effort to achieve the desired Heat exchange function relatively expensive, both in the Acquisition as well as what the operating and maintenance costs concerns. In addition, the tempering arrangements can only in the unchangeable by the given Heat exchange function operated certain operating modes become.

The invention has for its object a Tempering arrangement to create that in less expensive Made way and for different heat exchange functions can be set up. In particular, a changeover from one heat exchange function to another under otherwise unchanged structure of the temperature control arrangement may be possible.

This object is achieved by the features in characterizing part of claim 1 solved. A essential feature of the invention Temperature control arrangement is the provision of a single one Three-media heat exchange device instead of several separate heat exchangers. This enables the Fluid all circulation systems in different to bring heat exchange relationship to each other so that a Variety of heat exchange functions can be realized. As a result, the invention can easily be applied to different ones Customize use cases. Despite the high flexibility and Customizability are those for providing the invention required costs lower than for plants of the known Kind, since a three-media heat exchange device according to the Invention only slightly more expensive than a single one conventional heat exchanger needs to be. Furthermore, the Basic structure of the tempering arrangement for various Heat exchange functions cannot be changed. It is only a retrofit of the only three-media heat exchange device required. All you need is her distribution device designed for a heat exchange function by another distribution device at otherwise unchanged basic structure of the heat exchange device be converted. Advantageous developments of the invention are listed in the subclaims.

Fig. 1 als Schemabild eine erfindungsgemäss aufgebaute Temperierungsanordnung,

Fig. 2 in Detailansicht eine Wärmetauscheinrichtung für die Temperierungsanordnung nach Fig. 1 in Endansicht von einem Stirnende,

Fig. 3 die Wärmetauscheinrichtung nach Fig. 2 in Seitenansicht,

Fig. 4A und 4B geschnittene schematisierte Ansichten längs der Schnittlinien IV-IV bzw. V-V in Fig. 2 mit Darstellung der Wärmetauscheinrichtung in einer ersten Wärmetauschfunktion,

Fig. 5A und 5B geschnittene Ansichten ähnlich Fig. 4A und 4B mit Darstellung der Wärmetauscheinrichtung in einer zweiten Wärmetauschfunktion, und

Fig. 6A und 6B geschnittene Ansichten ähnlich Fig. 4A und 4B mit Darstellung der Wärmetauscheinrichtung in einer dritten Wärmetauschfunktion.

The invention is explained in more detail below using an embodiment and the drawing. Show it:

1 shows a temperature control arrangement constructed according to the invention as a schematic image,

2 in a detailed view a heat exchange device for the temperature control arrangement according to FIG. 1 in an end view from an end face,

3 is a side view of the heat exchange device according to FIG. 2,

4A and 4B are schematic sectional views along the section lines IV-IV and VV in FIG. 2, showing the heat exchange device in a first heat exchange function,

5A and 5B are sectional views similar to FIGS. 4A and 4B, showing the heat exchange device in a second heat exchange function, and

6A and 6B are sectional views similar to FIGS. 4A and 4B, showing the heat exchange device in a third heat exchange function.

With reference to FIG. 1, a temperature control arrangement according to the invention comprises a dampening solution circulation system U _I , a coolant circulation system U _II and a refrigerant circulation system U _III .

The dampening solution circulation system U _I is designed as an open system and contains a buffer memory 30 for storing a suitable amount of dampening solution. A pump 34 and a temperature sensor 35 are provided one behind the other at a point downstream of the buffer store 30. A line 33 branches off from the main circuit on the downstream side of the temperature sensor 35 in order to lead a partial quantity of the dampening solution circulating in the main circuit U _I to a storage container 32 of a dampening solution application device. The dampening solution can flow back from the storage container 32 into the buffer container 30 via a line 31. Suitable devices, for example in the form of a throttle 35, are provided in the branch line 33 to ensure that the branched-off amount of dampening solution is always smaller than the amount that circulates in the main circuit.

The dampening solution circulating in the circulation system U _I is also passed through a three-medium heat exchange device which bears the general reference number 1 in FIG. 1 and which will be discussed in more detail below.

The coolant circulation system U _II , which is preferably designed as a closed system, contains a control valve 40 and a pump 41 on the upstream side of a roller cooling device (not shown) and a temperature sensor 42 on the downstream side of the roller cooling device. The coolant circulating in the circulation system U _II is likewise passed through the three-medium heat exchange device 1 . A bypass line 43 is provided on the downstream side of the control valve 40 and contains a flow restriction throttle 44 and a heating device 45.

The refrigerant circulation system U _III is part of a refrigeration device which, in a manner known per se, consists of at least one compressor 20, a condenser 21, a collecting container 22, a control valve 23, preferably in the form of a solenoid valve, a dryer 24, a sight glass 25 and an expansion valve 26. In addition, the three-medium heat exchange device 1 is supplied with refrigerant by integrating it into the refrigerant circulation system U _III like the other two circulation systems U _I and U _II . The refrigerant circulation system U _III is designed as a closed system.

A control device 50 is provided in order to operate each such system independently or jointly by switching the pumps 34 or 41 of the dampening solution or coolant circulation system U _I or U _II on and with cooling energy from the refrigerant. To supply circulation system U _III , depending on the heat exchange function in which the three-media heat exchange device 1 is operated, which will be discussed in more detail below. The control device 50 also controls the operation of the refrigerant circulation system U _III and can monitor the temperature of the dampening solution and coolant circulation system U _I and U _II .

2 and the following reference is made, which show the three-media heat exchange device 1. Here the terms "top" and "bottom" refer to the location the structural parts of the heat exchange device 1, as in the Drawing is shown. However, the invention is based on a such position of use of the heat exchange device 1 is not limited.

As shown in FIGS. 2 and 3, the heat exchange device 1 can preferably be designed in the form of a plate exchanger, consisting of a multiplicity of plates 2 arranged side by side in succession, for example plates 2 ₁ , 2 ₂ , 2 ₃ ... 2 _n , in whose respective surfaces complementary grooves or grooves are made, so that flow channels 10, in particular 10 ₁ , 10 ₂ , 10 ₃ ... 10 _n , each with an inlet and an outlet end, are formed after assembly between adjacent plate surfaces, cf. e.g. Figures 4A and 4B. A fluid, for example water, can be introduced into a relevant flow channel 10 via a distributor device and can be discharged to the outside again after flowing through the flow channel 10. The flow channels 10 are hermetically sealed from one another and can each be distributed in a meandering manner or in some other suitable manner over the plate surfaces.

The distributor device comprises a two-chamber distributor arrangement 3 for the separate supply and discharge of the dampening solution or coolant originating from the circulation systems U _I and U _II , and a single-chamber distributor arrangement 6 for the supply and discharge of the refrigerant from the circulation system U _III , in each case into the relevant flow channels 10. Each two-chamber distributor arrangement and single-chamber distributor arrangement 3, 6 comprises a distributor pipe near the upper ends of the flow channels 10 and a distributor pipe near their lower ends. The distributor pipes penetrate the plate exchanger axially and are accommodated in the plates 2 in receiving bores that are aligned with one another. They also preferably extend parallel to one another.

Each distributor pipe of the two-chamber distributor arrangement 3 comprises an upper longitudinal chamber 4 and a lower longitudinal chamber 5, which are hermetically sealed from one another by an intermediate partition wall. The upper chamber 4 has an open and a closed axial end 4a and 4b, and likewise the lower chamber 5 has an open and a closed axial end 5a and 5b. An open axial end 4a of the upper chamber 4 is adjacent to a closed axial end 5b of the lower chamber 5, and conversely a closed axial end 4b of the upper chamber 4 is adjacent to an open axial end 5a of the lower chamber 5. This arrangement facilitates the connection of the relevant manifold to the respective circulation system U _I , U _II , U _III .

The single chamber manifold assembly 6 includes, as shown in FIG. 4B shows, an upper and a lower simple manifold each with an open axial end 6a for supply and discharge of the refrigerant and an opposing closed one axial end.

Along each manifold of the two-chamber manifold assembly 3 are at selected axial distances from each other Openings 7, 8 are provided which the interior of the concerned Chamber 4 or 5 with selected flow channels 10 connect so that only the selected flow channels 10 be charged with the fluid that in the relevant chamber 4 or 5 was introduced. In the same Ways are along each manifold of the single chamber manifold assembly 6 at selected axial intervals from each other openings 9 are provided around the in the single chamber manifold assembly 6 introduced refrigerants in selected Forward flow channels 10. This can be achieved be that adjacent flow channels 10 with different fluids are applied and they come into heat transfer relationship with each other.

Depending on the sequence of the flow channels 10 can have different heat exchange functions , whereupon with reference to FIG. 4A, 4B; 5A, 5B and 6A, 6B is discussed in more detail.

First heat exchange function

The first heat exchange function is shown in FIGS. 4A and 4B and is characterized in that the refrigerant flows through the single-chamber distributor arrangement 6 connected to the circulation system U _III and the openings 9 formed therein into the sequence of flow channels 10 ₂ , 10 ₆ , 10 ₁₀ , 10 ₁₄ , etc. are introduced, which are indicated in FIGS. 4A and 4B by cross-dashed lines. Each upper and lower distributor pipe consequently has openings 9 which lie at an axial distance along the distributor pipe, which corresponds to the sequence of four flow channels 10 arranged one behind the other.

Openings 7 are provided on each distributor pipe of the two-chamber distributor arrangement 3 and connect the upper chamber 4, which is connected to the coolant circulation system U _II , to the flow channels 10 ₄ , 10 ₈ , 10 ₁₂ etc. The coolant of the circulation system U _II introduced into the chamber 4 therefore only reaches these selected flow channels, as is shown in FIGS. 4A and 4B by non-hatched areas. The sequence of the openings 8 of the lower chamber 5 of the two-chamber distributor arrangement 3 connected to the dampening solution circulation system U _I is such that only the flow channels 10 ₁ , 10 ₃ , 10 ₅ etc. are acted upon with the dampening solution which is in the circulation system U _I circulates as hatched in Figures 4A and 4B.

In this way it is achieved that one flow channel, for example 10 ₂ , for the refrigerant between a pair of flow channels, for example 10 ₁ , 10 ₃ for the dampening solution and one flow channel, for example 10 ₄ , for the coolant between a pair of flow channels, for example 10 ₃ , 10 ₅ , for the dampening solution comes to rest. Cold energy can thus be transferred directly from the refrigerant to the dampening solution, but not directly to the coolant. Rather, the coolant will only be able to obtain cooling energy indirectly via the dampening solution.

The first heat exchange function therefore enables primary transfer of cooling energy to the dampening solution circulation system U _I. Excessive cooling energy can be stored in the buffer store 30 and, if necessary, can also be passed on to the coolant circulation system U _II via the heat exchange device 1.

Second heat exchange function

The second heat exchange function is shown in FIGS. 5A and 5B and is characterized in that, analogously to the above-described mode of operation, the openings 9 of the single-chamber distributor arrangement 6 are spaced such that the sequence of flow channels 10 ₂ , 10 ₄ , 10 ₆ etc. is charged with the refrigerant. In contrast, the openings 7, 8 of the two-chamber distributor arrangement 3 are provided such that the flow channels 10 ₃ , 10 ₆ , 10 ₉ etc. with the dampening solution and the flow channels 10 ₁ , 10 ₅ , 10 ₉ , 10 ₁₃ etc. with the coolant be supplied. This means that the refrigerant has a direct heat-exchanging relationship with the other two fluids, without these having a direct heat-exchanging relationship with one another.

With the second heat exchange function it is achieved that Fountain solution and coolant to essentially the same Temperature can be cooled without mutually exclusive influence.

Third heat exchange function

The third heat exchange function is shown in FIGS. 6A and 6B and is characterized in that the refrigerant acts on the flow channels 10 ₃ , 10 ₆ , 10 ₉ etc., while the openings 7, 8 of the two-chamber distributor arrangement 3 are arranged in such a way that the dampening agent acts on the flow passages 10 ₂ , 10 ₅ , 10 ₈ , 10 ₁₁ etc. and the coolant acts on the flow passages 10 ₁ , 10 ₄ , 10 ₇ , 10 ₁₀ etc.

This ensures that the refrigerant has a direct heat-transferring relationship with the other two fluids, similar to the second heat exchange function, but the two other fluids are also directly heat-exchanging with one another. The third heat exchange function therefore has an immediate heat exchange relationship among all fluids. This enables the integration of a buffer memory similar to the buffer memory 30 in both circulation systems U _I and U _II .

Other heat exchange functions are also possible. The heat exchange preferably takes place between neighboring ones Flow channels 10 take place in countercurrent by this in opposite directions from the respective fluid be flowed through.

Each opening 7, 8, 9 of the manifolds of the two-chamber manifold assembly 3 or single chamber manifold assembly 6 can with the relevant flow channel 10 corresponding to the desired heat exchange function soldered or in another Be hermetically sealed. A can Plate exchanger with basically unchanged basic structure be used. The distribution pipes 3, 6 could also can be arranged interchangeably Heat exchange device according to the invention by mere Exchange of the two-chamber distributor arrangement 3 and / or Single chamber manifold assembly 6 for another To be able to convert heat exchange function. Finally, could instead of a two-chamber distributor arrangement, also separate ones Single chamber manifold arrangements for each fluid be provided.

In the following, the operation of the Temperature control arrangement according to the invention with the three-media heat exchange device 1 in the first heat exchange function described.

Only dampening solution cooling

When the refrigeration device is switched on and the three-media heat exchange device 1 is acted upon with refrigerant, the pump 34 is started, while the pump 41 of the coolant circulation system U _{II is} out of operation. The buffer store 30 is thus continuously supplied with cooled dampening solution. A partial amount of the dampening solution circulated in the circulation system U _II by the pump 34 circulates via the branch line 33 into the storage container 32 for further processing by the dampening solution application device. The pump 35 is dimensioned such that a sufficient volume flow of dampening solution always passes through the three-medium heat exchange device 1. The dampening solution is cooled in the three-medium heat exchange device 1 as a function of the dampening solution temperature determined by the temperature sensor 35 on the downstream side of the buffer store 30.

Fountain solution and coolant cooling

The pumps 34 and 41 are in operation, so that all three fluids pass through the three-medium heat exchange device 1 when the refrigeration device is switched on. The coolant flowing through the three-media heat exchange device 1 draws cold energy from the direct heat exchange with the coolant-cooled dampening solution, the buffer accumulator 30 ensuring that a sufficient amount of dampening solution is always available for cooling the coolant. This can also be supported by the fact that the temperature of the dampening solution in the circulation system U _{I is} preferably set to a sufficiently low value.

The setting one for the roller application device suitable temperature of the coolant is carried out using the depending on the temperature sensor on the downstream side 42 measured temperature controlled control valve 40. At too low coolant temperature, the heater 45 in the bypass line 43 are put into operation by the the bypass line 43 constantly flowing coolant portion to warm up.

Coolant cooling only

This operating mode corresponds essentially to that with the exception that the The refrigeration system is only put into operation when required is by the necessary for cooling the coolant Cooling energy primarily that in the buffer storage 30 stored amount of dampening solution is withdrawn. A Loss of energy due to the circulation of dampening solution through the Secondary circuit is because of the dampening solution application device is out of order, negligible. If necessary, a could also be in the branch line 33 Shut-off valve can be arranged to flow the Completely switch off dampening solution by the secondary circuit.

Although this is not described in detail, it goes without saying that, depending on the heat exchange function of the three-media heat exchange device 1, various other operating modes of the temperature control arrangement can be implemented. In particular in the second or third heat exchange function, a direct transfer of cooling energy from the refrigerant of the refrigerant circulation system U _III to the other two fluids can be obtained, which can be advantageous in the case of a high cooling energy requirement of the roller cooling device fed by the coolant circulation system U _II .

Claims (10)

Temperature control arrangement for temperature control of a dampening solution and / or selected rollers of a printing press, with a dampening solution circulation system (U _I ) for supplying a dampening solution application device with a dampening solution, a coolant circulation system (U _II ) for supplying a roller cooling device with a coolant, and a cooling device with a refrigerant circulation system (U _III ) which is in a heat-exchanging relationship with at least one of the dampening solution and coolant circulation systems, and a device for the optional operation of one or more of the circulation systems, characterized in that the circulation systems (U _I , U _II , U _III ) is assigned a common heat exchange device (1) which has a plurality of flow passages (10) arranged in a heat-transferring relationship and a distributor device (3,6) for connecting the dampening solution circulation system (U _I ) and the coolant circulation system (U _II ) and Käl includes circulating system (U _III ) with a selected sequence of flow passages, adjacent flow passages being connected to a different circulation system. Temperature control arrangement according to claim 1, characterized characterized in that a flow passage (10) for the refrigerant between a pair of adjacent ones Flow passages for the dampening solution is arranged, and that at each flow passage for the dampening solution Flow passage for the coolant adjoins. Temperature control arrangement according to claim 1, characterized characterized in that a flow passage (10) for the refrigerant between adjacent flow passages for the dampening or cooling agent is arranged. Temperature control arrangement according to claim 3, characterized characterized in that adjacent flow passages (10) for the dampening solution or coolant between each pair Adjacent flow passages for the refrigerant are arranged are. Temperature control arrangement according to one of the preceding claims, characterized in that the distributor device comprises a multi-chamber distributor pipe arrangement (3) for connection to the dampening solution circulation system (U _I ) or coolant circulation system (U _II ) with outlet orifices aligned with the flow passages of the selected sequence. / Entry openings (7,8). Temperature control arrangement according to claim 2, characterized in that the dampening solution circulation system (U _I ) is designed as an open circulation system. Temperature control arrangement according to claim 6, characterized in that the dampening solution circulation system (U _I ) comprises a dampening solution buffer store (30). Temperature control arrangement according to claim 6, characterized in that the dampening solution circulation system (U _I ) comprises a secondary circulation (31, 33) containing the buffer store (30) for supplying the dampening solution application device (32), which is branched off from the main circulation , wherein the amount of dampening solution flowing in the secondary circulation is smaller than the amount of dampening solution flowing in the main circulation. Temperature control arrangement according to one of the preceding claims, characterized by a control device (50) in order to keep the temperature of the dampening solution of the dampening solution circulating system (U _I ) below that of the coolant of the coolant circulation system (U _II ). Temperature control arrangement according to one of the preceding Claims, characterized in that the coolant circulation system a control valve (40) for controlling the Volume flow of coolant depending on it Temperature at the outlet of the roller cooling device includes.

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