EP1282735A1 - Fluid guidance piece with internal temperature equalisation - Google Patents

Abstract

The present invention relates to a fluid line member for a modular fluid line system for passing therethrough a crystallizing, heat-sensitive working fluid, such as a synthetic polymer, a cellulose derivative or a solution consisting of cellulose, water and amine oxide. Such working fluids have a temperature-dependent viscosity and are subject to spontaneous decomposition phenomena under strong exothermic reaction. A temperature control of the working fluid is to be made possible by the fluid line member. This is achieved in that the fluid line member has a circular cross-section with a temperature control device instead of the core flow. According to the invention the temperature of the working fluid can thereby be controlled from the inside.

Description

 Fluid line piece with internal temperature control

The invention relates to a fluid line piece for a modular fluid line system for the passage of a crystallizing, heat-sensitive working fluid, such as a synthetic polymer, a cellulose derivative or a solution of cellulose, water and amine oxide, with a working fluid line area through which the working fluid flows.

Such fluid line pieces are known as simple pipelines and are conventionally used in spinning systems in which the working fluid is spun as a molding compound into shaped bodies. The working fluid is usually transported from a reaction vessel in which it is mixed together to a spinneret, where it is spun, through the fluid line piece.

The working fluids used are heat-sensitive and tend to spontaneously exotherm if a certain maximum temperature in the fluid line piece is exceeded or if the working fluid is stored for too long below this maximum temperature.

The working fluids that can be considered in the present invention have an overall very high, temperature-dependent viscosity. The viscosity drops with increasing temperature and increased shear rate.

A working fluid that is particularly suitable for spinning is a molding composition which consists of a spinning solution containing cellulose, water and a tertiary amine oxide, for example N-methylmorpholine N-oxide (NMMO) and stabilizers for thermal stabilization of the cellulose and the solvent and, if appropriate, other additives such as eg Titanium dioxide, barium asulfate, graphite, carboxymethyl celluloses, polyethylene glycols, chitin, chitosan, alginic acid, polysaccharides, dyes, antibacterial chemicals, flame retardants containing phosphorus, halogens or nitrogen, activated carbon, carbon black or electrically conductive carbon black, silica, organic solvents as diluents contains.

For the transport of the working fluid, the fluid line piece must on the one hand be heatable, so that the viscosity of the working fluid drops and the working fluid can be conveyed through the fluid line piece with low losses. On the other hand, the temperature temperature should not be too high to avoid decomposition and spontaneous exothermic reaction of the working fluid. Finally, a velocity profile that is as uniform as possible should form over the flow cross section of the fluid line piece through which the working fluid flows, in order to ensure a uniform flow through the fluid line piece.

To solve these problems, EP 0 668 941 B1 proposes to control the temperature in the center of the pipe and / or on the inner wall of a piece of fluid line in accordance with the formulas given there. For this purpose, a cooling medium is passed through a cooling jacket surrounding the working fluid line area. The cooling medium dissipates the heat from any exothermic reactions that may occur from the working fluid and cools the outer region of the fluid flow.

However, the fluid line system as proposed in EP 0 668 941 B1 has the disadvantage that poor efficiency is still achieved in the flow through the working fluid and that the temperature-dependent properties of the working fluid can only be influenced inaccurately ,

The invention is therefore based on the object of creating a fluid line piece which has an improved efficiency in the flow through the working fluid and which enables a more direct influence on the temperature-dependent properties of the working fluid.

According to the invention, this object is achieved for a fluid line piece of the type mentioned at the outset in that the working fluid line region has an essentially annular flow cross section and in the center of the fluid line piece, in place of the core flow of the working fluid, a temperature control device for controlling the temperature of the working fluid is arranged inside the fluid line piece is.

With this solution there is therefore no core flow. The temperature of the external fluid can thus be influenced very well over the entire flow cross section. The temperature control device takes up the position of the core flow and enables the temperature of the working fluid to be controlled from inside the flow. As a result, the working fluid and thus the temperature-dependent properties control the working fluid more precisely, the flow losses can be reduced. There is also no need to measure the temperature of the core flow, which is only possible very inaccurately and indirectly and at great expense.

In contrast to the solution pursued in EP 0 668 941 B1, in which the core temperature can only be influenced indirectly by cooling the outside temperature, the temperature-control device according to the invention, around which the working fluid flows, means that the inner region of the working fluid is directly in it Temperature can be influenced.

By arranging the temperature control device instead of the core flow of the working fluid and the resulting annular working fluid line area, the thickness of the flow cross-section to be temperature-controlled is also reduced: in the method of EP 0 668 941 A1, the thickness of the layer to be temperature-controlled corresponds to that of the inner diameter of the working fluid line area , According to the invention, the layer thickness of the working fluid to be tempered only corresponds to the wall thickness of the annular flow cross section. The reduced layer thickness reduces the time constants for heat transfer.

The temperature control device can serve both for cooling and for heating the working fluid, depending on whether the temperature of the temperature control device is higher or lower than the temperature of the working fluid. In the fluid line piece, the temperature of the temperature control device can also be controlled such that certain sections of the temperature control device act as cooling sections and other sections as heating sections. The temperature of the working fluid averaged over the flow cross section of the working fluid line region serves as the reference temperature of the working fluid.

According to a particularly advantageous embodiment, the temperature control device is designed as an inner tube which is arranged coaxially to the working fluid line region and through which a temperature control fluid flows. By means of a temperature control fluid, for example, a more uniform heat transfer can be achieved without large local temperature differences compared to electrical heating. The cooling or heating of the working fluid by the tempering fluid flowing through the tempering device can take place in countercurrent or cocurrent. The directions of flow of working fluid and temperature control fluid are essentially rectified in direct current. In countercurrent, the flow directions of working fluid and temperature control fluid are essentially opposite.

In a further, particularly advantageous embodiment of the fluid line piece, in addition to the temperature control device, a temperature jacket section can also be provided, which at least partially surrounds the working fluid line area.

In this embodiment, a temperature control device is thus provided which acts directly on the inner region of the flow, and a further temperature control device which acts on. affects the outside of the flow. Both tempering devices together have a significantly increased area for heat transfer compared to the prior art.

In a further advantageous embodiment, a temperature control fluid can flow through the temperature control jacket section. By means of a temperature control fluid, for example, a more uniform heat transfer can be achieved without large local temperature differences compared to electrical heating.

With this configuration, compared to the prior art, the heat transfer area between the working fluid and the temperature control fluid is significantly increased. The increased heat transfer area causes a large heat flow through the respective jacket surfaces. Due to the faster heat transfer, the temperature difference between the temperature control fluid and the working fluid can be reduced. The temperature and thus the viscosity of the working fluid can be controlled far more precisely than was previously possible in the prior art.

In a further advantageous embodiment, it can be provided that the temperature control fluid in the temperature control jacket section has a temperature that is controlled independently of the temperature control fluid in the temperature control device. Regardless of the temperature control device, the temperature control jacket section can be used for cooling or heating in cocurrent or countercurrent. In order to keep the heat transfer between the fluid line piece and its surroundings as low as possible, it can be provided in a further advantageous embodiment that the working fluid line section is covered at least in sections by a heat insulation layer.

To achieve the aim of the invention, it is important, among other things, that the temperature control device is flushed with the working fluid. According to a further advantageous embodiment, this is achieved in that the fluid line piece has a spacer which extends from the temperature control device into the working fluid to the inner wall of the working fluid line piece. Depending on the requirements, any number of spacers can be provided in a favorable arrangement. Separate heating of the spacers is also possible.

In order to keep the flow losses when the working fluid flows around the spacers as low as possible, the spacers can have an essentially streamlined cross section.

The heat transfer area can be enlarged again if the temperature-control fluid also flows through the spacer. This can also act directly on the working fluid that does not come into direct contact with the temperature control device or the temperature control jacket section. At the same time, this solution enables a structurally simple possibility of supplying the temperature control device with temperature control fluid.

The inner diameter of the fluid line piece is denoted by D _A and the outer diameter of the temperature control device by Dj, where D _A corresponds to the outer diameter and Di the inner diameter of the annular working fluid line area, and an adequate fluid line diameter D _AD TO V (D _A ² - D | ² ) is determined. , then a surface ratio can be defined as follows: O = (Dι + D _A ) / D _AD . This surface ratio O is preferably between 0 = 1 to 0 = 4, particularly preferably between 0 = 1 to 0 = 1.8. The ratio of the diameters D _A and Di can be specified via a working fluid layer thickness ratio A, which is the ratio of the layer thickness S = (D _A -D |) / 2 - in the case of a version with a temperature control device (ring-shaped) - or S = D _A - without temperature control device (only outer tube) - to the outer diameter D _{A of} the working fluid line area, A = S / D _AD : This ratio is preferably less than 0.5, particularly preferably less than 0.4.

With regard to the stability and the manufacture of the fluid line piece, it can be particularly favorable if the spacer is arranged at an end of the fluid line piece located in the direction of passage of the working fluid.

To construct a modular fluid line system, the fluid line piece can have at least one connection section at at least one end located in the flow direction of the working fluid, which is configured in such a way that the fluid line piece can be connected to other fluid line pieces.

In a further advantageous embodiment, the temperature control fluid for the temperature control device can be supplied at the connecting section. For this purpose, the connecting section can have at least one temperature control fluid opening, through which the temperature control fluid can be supplied to the temperature control device from outside the fluid line piece.

In the case of a plurality of fluid line pieces connected in series, a separate supply of the individual fluid line pieces with temperature control fluid can be omitted if the temperature control device has at least one end in the direction of flow of the working fluid with a passage opening for the temperature control fluid in the temperature control device, which cannot be connected to a corresponding passage opening of another fluid line piece. In this advantageous embodiment, the temperature control devices of fluid line pieces connected in series are directly connected to one another. For this purpose, corresponding receiving means can be provided at the respective passage openings.

In certain cases it can also be provided that a further fluid line piece is connected to the fluid line piece, which piece does not have a piece according to the invention inner tempering device is provided. In this case, a closure means can be provided which can be attached to the passage opening for the temperature control fluid of the inner heating section and through which the passage opening can be sealed. The closure means prevents the temperature control fluid from escaping into the working fluid. In order to keep the flow losses as low as possible at the location of the closure means, it can be provided in a further advantageous embodiment that the closure means has an essentially streamlined outer shape. The closure means can be arranged at an end of the temperature control device located in or against the direction of passage of the working fluid.

In the configurations described above, the fluid line piece can take on any functional form customary in line technology.

Thus, the fluid line piece according to the invention can be designed as a straight or arbitrarily curved pipe section, which has a connection section for connecting two further fluid line sections at each end located in the flow direction of the working fluid. With such a piece of fluid line, the working fluid can be transported over long distances with a precisely controllable temperature profile.

However, the fluid line piece can also be equipped as a distributor piece with at least three connecting sections for connecting further fluid line pieces. Such distributor pieces can be designed, for example, in a Y shape, in a T shape or in any other three-dimensional shape.

Another possibility is to design the fluid line piece as an end piece with only one connecting section for connecting only one further fluid line piece. In this case, the one passage opening for the working fluid is expediently closed.

The fluid line piece can also be designed as a reducer, the flow cross-section of which the working fluid flows is smaller at one end in the direction of flow of the working fluid than at the end opposite in the direction of flow. set end. Such a reducer can be used to create transitions between different fluid line systems.

Furthermore, in a further advantageous embodiment, the fluid line piece can have a built-in mixing reactor for treating the working fluid and for influencing the polymer characteristics. The fluid line piece can also have one or more fluid filter groups for filtering the working fluid.

The invention is not restricted to the special type of temperature control fluid. Liquids and gases can be used as the temperature control fluid.

Any material which is corrosion-resistant with respect to the working fluid and pressure-resistant with regard to the possible exothermic reactions can be used as the material for the temperature control device, the working fluid line section or the temperature-jacket section. A possible material is steel or stainless steel or chromed steel or stainless steel. In order to minimize the adhesion and friction of the working fluid on the walls, the outer wall of the temperature control device or the inner wall of the working fluid line area can be machined particularly smoothly or be provided with a friction-minimizing coating.

The invention also relates to a modular fluid line system which is constructed from at least two fluid line pieces which can be connected in series according to one of the configurations described above. The fluid line system can furthermore have a regulating or shut-off device which serves to control the working fluid. The control or shut-off device can be fed via the temperature control fluid supply system.

For retrofitting existing fluid line systems or for installation in conventional fluid line pipes, the temperature control device can be constructed as a separate part to which a conventional fluid line piece or a conventional line pipe can be attached. For this purpose, the temperature control device has a connecting means which can be connected to a connecting means of a further temperature control module or a further piece of fluid line and to which the fluid line piece can be tightly fastened at the same time. The temperature control device takes the place of the core Flow in the fluid conduit, so that an essentially annular, thin-film-like flow cross section is formed between the temperature control device and the retrofitted fluid conduit.

The invention is described below using exemplary embodiments with reference to the figures.

Show it:

Figure 1 shows a first embodiment of a fluid line piece in a longitudinal section.

Fig. 2 shows the fluid line piece of Fig. 1 in cross section and

Fig. 3 shows a second embodiment of the fluid line piece according to the invention.

1 shows a first exemplary embodiment of a fluid line piece 1 according to the invention in a longitudinal section along a center line M of the fluid line piece M. The fluid line piece 1 is essentially tubular and is rotationally symmetrical about the central axis M. The fluid line piece of FIG. 1 is specially designed for the passage of a spinning solution , containing water, cellulose and tertiary amine oxide, designed as a working fluid. The working fluid is passed through a working fluid line area 2 with an annular flow cross section. The working fluid line area has an outer wall 3 and an inner wall 4, which limit the flow cross section of the working fluid line area 2.

The inner wall 4 of the working fluid line area 2 is formed by a temperature control device 5.

The temperature control device 5 has a line section or inner body 6 which is formed coaxially to the working fluid line area 2 and whose interior 7 is flowed through by a temperature control fluid. The inner body 6 is essentially tubular. The temperature control device 5 is washed around outside by the working fluid in the working fluid line area 2. Since the temperature of the tempering fluid in the interior 7 of the tempering device 5 has a temperature difference to the temperature of the working fluid in the working fluid line area 2, a heat exchange takes place through the wall of the line pipe 6. Depending on whether the temperature of the tempering fluid is higher or lower than the temperature of the working fluid, heat is exchanged from the working fluid to the tempering fluid or from the tempering fluid to the working fluid.

Thus, the temperature control device can be used both for heating and for cooling the working fluid.

The outer wall 3 of the working fluid line area 2 is formed by a tubular body 8, which represents a tempering jacket section. For this purpose, the tube 8 is surrounded by a cavity 9, which can also have a temperature control fluid around it. Regardless of the temperature of the temperature control fluid in the temperature control device 5, the temperature of the temperature control fluid in the temperature control jacket section 9 can be higher or lower than the temperature of the working fluid. The outer wall 3 can thus be used for cooling or for heating the working fluid independently of the temperature control device 5.

The temperature control jacket section is provided with connections for supplying temperature control fluid. The temperature control fluid is supplied to the temperature control jacket section 9 at a predetermined controllable temperature.

The temperature control device 5 is supplied with temperature control fluid via radially extending feed lines 10 which end in through openings 11.

The passage openings 11 are arranged on a flange-shaped connecting section 12 of the fluid line piece 1. The connecting section 12 serves to connect the fluid line piece 1 to further fluid line pieces, not shown. The working fluid flows through an annular passage opening 13 from one piece of fluid line to another. The connecting section can be provided, for example, with through or threaded openings 14, through which a fluid-tight and pressure-resistant connection can be established by means of screws with the connecting section of a further fluid line piece.

The fluid line piece of FIG. 1 is to explain different variants of the supply of temperature control fluid to the temperature control device 5 with different connecting sections at the two in the direction of passage of the working fluid, i.e. Ends shown in the direction of the central axis M.

At the left end shown in FIG. 1, the section for supplying the temperature control device with temperature control fluid is firmly connected to the temperature control device 5.

In Fig. 1, a closure means 15 is attached to the end of the conduit 6 of the temperature control device 5, through which the passage opening for the temperature control fluid in the temperature control device 5 is closed.

At the right end of the fluid line piece 1 in FIG. 1, another variant of the connecting section 12 or the feeding of the temperature control fluid into the temperature control device 5 is shown. Instead of a feed connected in one piece to the temperature control device 5, the feed forms a separate feed module or a separate fastening body 16 at the right end of the fluid line piece 1. The feed module 16 is provided with a line section 16 ′ which can be tightly connected to the temperature control fluid line 6 of the temperature control device 5. In the embodiment of FIG. 1, this is achieved in that the line section 16 'is inserted into the line or the inner body 6. The interior 7 of the temperature control fluid line 6 is connected via the line section 16 to the radial or spoke-shaped feed lines 10 of the feed module 16.

The feed lines 10 of the fastening body 16 end in through openings 11 which are connected to a temperature fluid supply, not shown. The temperature control fluid supply, not shown in the figures, conveys the temperature control fluid through the temperature control device 5 and at the same time controls the temperature of the temperature control fluid as a function of predetermined process parameters, such as the composition of the working fluid, the conveying speed of the working fluid, the mass flow of the working fluid and the like.

Different temperature control fluid supply systems can be provided for supplying the temperature control jacket section 9 and the temperature control device 5.

In the exemplary embodiment in FIG. 1, the surface ratio is O = (D | + D _A ) / D _AD , which is the quotient of the sum of the outer diameter D _A and the inner diameter D | of the working fluid line area 2 and an adequate fluid line diameter D _AD = V (D _A ² -D | ² ) is formed, between 0 = 1 to 0 = 4, particularly preferably between 0 = 1 to 0 = 1.8.

The ratio A = S / D _{AD of} the layer thickness S = (D _A -D |) / 2 to the adequate fluid line diameter D _{AD of} the working fluid line area 2 is preferably less than 0.5, in the embodiment of FIG. 1 less than 0.4 ,

FIG. 2 shows a cross section perpendicular to the center line M along the line II-II of FIG. 1.

It can be seen in FIG. 2 that the feed lines 10 run in a straight line in the radial direction and are arranged in a star shape. The number of feed lines is arbitrary, as is their arrangement. In order to prevent dead water areas behind the feed lines, their cross section is streamlined in the direction of passage of the working fluid.

2, the feed lines 10 are connected to form an annular space 17. This annular space 17 can be connected to the temperature control fluid supply system (not shown here) via one or more connections.

The closure means 14 is used in each case when the temperature control devices 5 of successive pieces of fluid line are to be insulated from one another. This can serve, for example, to keep the temperature drop along the flow direction of the temperature control fluid in the temperature control device 5 low, or to alternately heat or cool successive pieces of fluid line.

The direction of flow of the temperature control fluid in the temperature control device 5 can be in the same direction or opposite to the direction of flow through the working fluid line section 2, that is to say in cocurrent or in countercurrent.

3 shows a second exemplary embodiment of a fluid line piece 1 according to the invention. In this exemplary embodiment, the same reference symbols are used for elements which have the same or similar function as in the exemplary embodiment in FIG. 1.

The fluid line piece of FIG. 3 is designed as a distributor piece which is designed in a Y shape. The embodiment of FIG. 3 can also be in the form of any other distributor piece, for example in a T-shape or in any three-dimensional shape.

In the exemplary embodiment in FIG. 3, the distributor piece is provided with two curved pipe sections 20 which end in connecting sections 12 in accordance with one of the variants in FIG. 1. In certain applications, there is no need to interpose a pipe section. In this case, the connecting sections 12 lie directly on the distributor 1.

The distributor 1 is provided on the outside with a tempering jacket section 9 which surrounds an outer wall 8 of the working fluid line section 2. The tempering jacket section 9 is connected to the tempering device 5 in the distributor of FIG. 3 via the feed lines 8.

The distributor piece 1 is connected to a total of three fluid line pieces (not shown). In the area in which the working fluid line ranges branch out, no ^'tempering 5 are attached to the flow of the working fluid not block. The temperature control devices 5 of the two pipe sections 20 end before the intersection of the respective center lines M of the corresponding fluid line piece. In order to obtain a favorable, loss-free flow in the region of the ends of the temperature control devices 5 without formation of stagnation areas, in which the working fluid could degrade, the closure pieces 14 are of streamlined design, in the present case conical. With this configuration, a clean division of the flow of the working fluid in the distributor piece 1 is achieved. An exchange of tempering fluid of the tempering devices 5 of the two pipe sections 20 takes place via the section 21 of the tempering jacket section 9.

Claims

claims

1.Fluid line piece for the passage of a crystallizing, heat-sensitive working fluid such as a synthetic polymer or a polymer solution, a cellulose derivative, a solution of cellulose, water and amine oxide, and also mixtures thereof with a working fluid line area through which the working fluid flows, characterized in that the working fluid line area ( 2) has an essentially annular flow cross-section, and that an inner temperature control device (5) for controlling the temperature of the working fluid within the working fluid line area (2) is arranged in the center (M) of the fluid line piece (1) instead of the core flow of the working fluid ,

2. Fluid line piece according to claim 1, characterized in that the inner temperature control device (5) is designed as a preferably tubular temperature control fluid line (8) through which a temperature control fluid flows.

3. Fluid line piece according to one of the above claims, characterized in that the temperature of the temperature control device (5) is greater than the temperature of the working fluid.

4. Fluid line piece according to one of claims 1 to 2, characterized in that the temperature of the temperature control device (5) is lower than the temperature of the working fluid.

5. Fluid line piece according to one of the above claims, characterized in that the flow direction of the temperature control fluids in the temperature control device (5) is substantially the same as the flow direction of the working fluid through the working fluid line area (2).

6. Fluid line piece according to one of claims 1 to 4, characterized in that the flow direction of the tempering fluids in the tempering device (5) is essentially opposite to the flow direction of the working fluid through the working fluid line region (2).

7. Fluid line piece according to one of the above claims, characterized in that the fluid line piece (1) has a tempering jacket section (9) for controlling the temperature of the working fluid, which surrounds the working fluid line area (2) at least in sections.

8. fluid line piece according to claim 7, characterized in that the working fluid line region (2) is flowed through by a tempering fluid.

9. Fluid line piece according to claim 7, characterized in that the temperature of the temperature control fluid in the temperature control jacket section (9) is higher than the temperature of the temperature control device (5).

10. Fluid line piece according to claim 7, characterized in that the temperature of the temperature control fluid in the temperature jacket section (9) is lower than the temperature of the temperature control device (5).

11. Fluid line piece according to one of claims 7 to 10, characterized in that the flow direction of the temperature control fluid in the temperature jacket section (9) is equal to the flow direction of the working fluid in the working fluid line region (2).

12. Fluid line piece according to one of claims 7 to 10, characterized in that the flow direction of the temperature control fluid in the outer temperature jacket section (9) is opposite to the flow direction of the working fluid in the working fluid line region (2).

13. Fluid line piece according to one of the above claims, characterized in that the working fluid line region (2) is at least partially covered by a heat insulation layer.

14. Fluid line piece according to one of the above claims, characterized in that at least one spacer (10) extends from the temperature control device (5) to the outer wall (3) of the working fluid line region (2) into the working fluid.

15. Fluid line piece according to claim 14, characterized in that the spacer (10) has a substantially streamlined cross section.

16. Fluid line piece according to claim 14 or 15, characterized in that the spacer (10) is flowed through by the temperature control fluid in the temperature control device (5).

17. Fluid line piece according to one of claims 14 to 16, characterized in that the spacer (10) is arranged at an end of the fluid line piece (1) located in the direction of passage of the working fluid.

18. Fluid line piece according to one of claims 14 to 17, characterized in that the spacer (10). is formed on a separate feed module (16) which is attached to the temperature control device (5).

19. Fluid line piece according to one of the above claims, characterized in that the connecting section (12) is provided with at least one tempering fluid opening (11) through which tempering fluid can be fed from outside the fluid line piece (1) to the tempering device (5).

20. Fluid line piece according to one of the above claims, characterized in that the temperature control device (5) has at least at one end in the direction of passage of the working fluid an opening (14 ') for the temperature control fluid in the temperature control device (5), which has a corresponding opening (14 ') of a further piece of fluid line (1) is tightly connectable.

21. Fluid line piece according to one of the above-mentioned claims, characterized in that a closure means (15) is provided which can be attached to the passage opening (14 ') for the temperature control fluid of the temperature control device (5) and through which the passage opening (14') is sealed is lockable.

22. Fluid line piece according to claim 21, characterized in that the closure means (15) has a substantially streamlined outer shape.

23. Fluid line piece according to one of the above-mentioned claims, characterized in that the fluid line piece (1) has a connecting section (12) for connecting the fluid line piece (1) to a further fluid line piece (1) on at least one end located in the direction of passage of the working fluid.

24. Fluid line piece according to one of the above claims, characterized in that a surface ratio O = (D | + D _A ) / D _AD from the sum of the outer diameter D _A and the inner diameter D | of the annular working fluid line region (2) and an adequate fluid line diameter D _AD = V (D _A ² -D | ² ) is between 0 = 1 to 0 = 4, particularly preferably between 0 = 1 to 0 = 1.8.

25. Fluid line piece according to one of the above claims, characterized in that a working fluid layer thickness ratio A = S / D _AD from the ratio of the layer thickness S = (D _A -D |) / 2 to the adequate fluid line diameter D _{AD of} the working fluid line region (2) is preferably less is less than 0.5, particularly preferably less than 0.4.

26. Fluid line piece according to one of the above claims, characterized in that the fluid line piece (1) is designed as a straight or arbitrarily curved pipe section, the connection section (12) at each end in the flow direction of the working fluid for connecting two further fluid line pieces (1 ) having.

27. Fluid line piece according to one of claims 1 to 26, characterized in that the fluid line piece (1) is designed as a distributor piece with at least three connecting sections for connecting further fluid line pieces (1).

28. Fluid line piece according to one of claims 1 to 26, characterized in that the fluid line piece (1) is designed as an end piece with only one connecting section (12) for connecting only one further fluid line piece (1).

29. Fluid line piece according to one of the above claims, characterized in that the fluid line piece (1) has a built-in pump for conveying the working fluid.

30. Fluid line piece according to one of the above claims, characterized in that the fluid line piece (1) has a built-in mixing reactor for treating the working fluid and influencing the polymer characteristics.

31. Fluid line piece according to one of the above claims, characterized in that the fluid line piece (1) has one or more fluid filter groups for filtering the working fluid.

32. Fluid line piece according to one of the above claims, characterized in that the tempering fluid is a liquid.

33. Fluid line piece according to one of claims 1 to 32, characterized in that the tempering fluid is gaseous.

34. Fluid line piece according to one of the above claims, characterized in that the fluid line piece (1) in the working fluid line area (2) is made of steel, stainless steel or chromed steel.

35. Fluid line piece according to one of the above claims, characterized in that the temperature control device (5) is made of steel or stainless steel or chromed steel or stainless steel.

36. Modular fluid line system for the passage of a crystallizing, heat-sensitive working fluid such as a synthetic polymer or a polymer solution, a cellulose derivative, a solution of cellulose, water and amine oxide, and also mixtures with one another, characterized in that the fluid line system has at least two fluid line pieces (1) which can be connected in series. according to one of the above claims.

37. Modular fluid line system for the passage of a crystallizing, heat-sensitive working fluid consisting of a spinning solution containing cellulose, water and a tertiary amine oxide, for example N-methylmorpholine N-oxide (NMMO) as well as stabilizers for thermal stabilization of the cellulose and the solvent and, if appropriate, other additives such as For example, titanium dioxide, barium asulfate, graphite, carboxymethyl celluloses, polyethylene glycols, chitin, chitosan, alginic acid, polysaccharides, dyes, antibacterial chemicals, flame retardants containing phosphorus, halogens or nitrogen, activated carbon, carbon black or electrically conductive carbon black, silica, organic solvents, characterized as thinners that the fluid line system has at least two fluid line pieces (1) which can be connected in series according to one of the above-mentioned claims.

38. Temperature control device for installation in a fluid line piece (1) of a modular fluid line system for passing through a crystallizing, heat-sensitive working fluid such as a synthetic polymer, a cellulose derivative and a solution of cellulose, water and amine oxide, the fluid line piece (1) having a working fluid line area (2) through which the working fluid flows, the temperature control device (5) having a connecting means (12) which can be connected to a connecting means (12) of a further temperature control device (5) or a further piece of fluid line (1) and on which the fluid line piece (1) is tightly fastened, and wherein the temperature control device (5) takes the place of the core flow of the working fluid line area (2).