SOLAR-THERMAL PROCESS TEMPERATURE CONTROL SYSTEM FOR A FILM STRETCHING UNIT

Abstract

A film stretching unit uses a solar-thermal process temperature control system for a film stretching unit. The process temperature control system comprises at least a solar heat generator and a heat storage unit. A heat consumer circuit is connected to the heat storage unit in order to be capable of drawing stored thermal energy to supply a film stretching unit 1 with thermal energy.

Claims

1. Solar-thermal process temperature control system for a film stretching unit, said process temperature control system comprising at least one solar heat generator, which is integrated into a heat generation circuit, wherein the heat generation circuit conveys a first heat transfer fluid; at least one heat storage unit, to which thermal energy is supplied via the first heat generation circuit, said thermal energy having been generated by said at least one solar heat generator, wherein the heat storage unit is configured to store the thermal energy; at least one heat consumer circuit, which conveys a second heat transfer fluid, wherein the heat consumer circuit is connected to the heat storage unit in order to be capable of drawing stored thermal energy, and wherein said at least one temperature control device comprises at least one heat transfer fluid outlet and is configured to supply the second heat transfer fluid at a defined temperature to said at least one heat transfer fluid outlet in order to supply at least one component of a film stretching unit directly or indirectly with defined temperature-controlled heat transfer fluid.

2. Process temperature control system according to claim 1, further comprising a first heat exchanger that is connected between said at least one heat storage unit and the heat consumer circuit.

3. Process temperature control system according to claim 1, further comprising a second heat exchanger that is connected between said at least one heat storage unit and the heat generation circuit.

4. Process temperature control system according to claim 2, wherein the heat storage unit is integrated into an intermediate circuit that conveys an intermediate-circuit heat transfer fluid.

5. Process temperature control system according to claim 1, wherein said at least one solar heat generator is configured to supply the first heat transfer fluid at a temperature of at least 550? C. to the heat storage unit or the second heat exchanger.

6. Process temperature control system according to claim 1, wherein the first heat transfer fluid, the second heat transfer fluid and/or the intermediate-circuit heat transfer fluid is selected from the following heat transfer fluids: water, a thermal oil, or a molten salt, wherein the first heat transfer fluid, the second heat transfer fluid and/or the intermediate-circuit heat transfer fluid may differ.

7. Process temperature control system according to claim 1, wherein said at least one heat storage unit is configured to store a heat transfer fluid at a temperature of at least 180? C., or at least 210? C. and in particular at least 240? C.

8. Process temperature control system according to claim 1, wherein said at least one solar heat generator comprises a linear concentrating solar power generator, in particular at least one parabolic trough collector and/or at least one Fresnel collector.

9. Process temperature control system according to claim 1, wherein said at least one solar heat generator is a tracking heating generator that comprises at least one single-axis tracking.

10. Process temperature control system according to claim 1, further comprising at least one pump, which is integrated into the process temperature control system in such a way to circulate the first heat transfer fluid, second heat transfer fluid and/or intermediate-circuit heat transfer fluid.

11. Process temperature control system according to claim 1, wherein the heat consumer circuit comprises a supply section and a return section, wherein the temperature control device is configured to mix heat transfer fluid of the supply section with colder heat transfer fluid, for example from the return section, in order to supply the second heat transfer fluid at a defined temperature to said at least one heat transfer fluid outlet, and/or wherein the temperature control device is configured to activate at least one pump of the process temperature control system in order to control the flow velocity of the corresponding heat transfer fluid in the circuit allocated to the pump in order to supply the second heat transfer fluid at a defined temperature to said at least one heat transfer fluid outlet.

12. Process temperature control system according to claim 1, further comprising at least one additional heating device, wherein said at least one additional heating device is allocated to the heat consumer circuit, in particular the supply section, and/or the heat storage unit.

13. Process temperature control system according to claim 1, further comprising at least one supply manifold that is connected downstream of the heat transfer fluid outlet and is configured to distribute the second heat transfer fluid to different consumers of a film stretching unit.

14. Process temperature control system according to claim 1, further comprising at least one return collector and a distributing device, wherein the return collector takes the second heat transfer fluid from at least one consumer and supplies it to the distributing device, wherein the distributing device (342) is configured to supply the heat transfer fluid to the heat storage unit (210), the first heat exchanger and/or the temperature control device.

15. Film stretching unit comprising a process temperature control system according to claim 1; as well as at least one of the following components: a drying apparatus, a feed hopper, an extruder, a blown film unit, a chill roll, a machine direction orienter, a transverse direction orienter, a simultaneous stretching unit, a pull-roll device, a wrapping device, and/or an absorption cooling machine, wherein the film stretching unit is configured in such a way that at least one of the components is supplied with thermal energy directly or indirectly by means of the process temperature control system in order to be temperature-controlled in a defined manner.

16. Film stretching unit according to claim 15, wherein at least one of the components is connected to the heat transport fluid outlet to be supplied directly with heat transfer fluid.

17. Film stretching unit according claim 15, further comprising at least one additional heating device, wherein the additional heating device is configured to supply at least one of the components of the film stretching unit with additional thermal energy.

18. Application of a process temperature control system according to claim 1 in a film stretching unit, wherein the process temperature control system supplies at least one of the components of the film stretching unit with thermal energy directly or indirectly in order to control its temperature in a defined manner.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0077] The attached figures show aspects of example embodiments. In particular,

[0078] FIG. 1 shows a schematic view of a process temperature control system comprising direct heat storage;

[0079] FIG. 2 shows a schematic view of a process temperature control system comprising direct heat storage;

[0080] FIG. 3 shows a schematic view of a process temperature control system comprising direct heat storage;

[0081] FIG. 4 shows a schematic view of a process temperature control system comprising indirect heat storage;

[0082] FIG. 5 shows a schematic view of a film stretching unit, and

[0083] FIG. 6 shows a schematic view of a transverse direction orienter (TDO).

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS

[0084] In particular, FIG. 1 shows a schematic view of a process temperature control system 10 comprising direct heat storage.

[0085] The process temperature control system 10 comprises a heat generation circuit 100. A solar heat generator 110, in particular a concentrated solar power CSP heating unit, such a parabolic trough collector, is integrated into this heat generation circuit 100. This solar heat generator 110 can convert solar radiation into usable thermal energy. The first heat transfer fluid 112 is conveyed for this purpose in the heat generation circuit 100 and heated by means of the solar heat generator 110, for example, to approx. 550? C. A pump 124, which is allocated to the heat generation circuit 100, can circulate the first heat transfer fluid 112 (for example water, steam, thermal oil, molten salt,

[0086] Furthermore, the process temperature control system 10 comprises at least one heat storage unit 210. Thermal energy for storage can be supplied to the heat storage unit 210 via the first heat generation circuit 100, said thermal energy being generated by said at least one solar heat generator 110. In the embodiment shown here, the heat storage unit 210 takes the first heat transfer fluid 112. The storage medium is therefore the first heat transfer fluid so that the thermal energy is stored directly.

[0087] Via a heat exchanger 230, a heat consumer circuit 300 conveying a second heat transport fluid 312 is connected to the heat storage unit 210. Thus, thermal energy can be drawn from the heat storage unit 210. The heat exchanger 230 can be arranged outside of the heat exchanger as shown in FIG. 1. It is also possible to arrange the heat exchanger within the heat storage unit. The heat exchanger can be a plate heat exchanger, a tubular heat exchanger and/or suchlike. This heat exchanger can be powered by direct current, alternating current or cross current.

[0088] The heat consumer circuit 300 comprises a supply section 320 and a return section 340, wherein the temperature of the second heat transfer fluid 312 is higher in the supply section 320 than in the return section 340. Furthermore, the heat consumer circuit 300 comprises at least one temperature control device 330. This temperature control device 330 comprises at least one heat transfer fluid outlet 350 that is connected to a supply manifold 500.

[0089] This supply manifold 500 is configured to distribute the second heat transfer fluid 312 to different consumers (components) of a film stretching unit 1 (see FIG. 5). Thus, different consumers, such as the extruder, machine direction orienter (MDO), transverse direction orienter (TDO) and suchlike, can be supplied with thermal energy. If only one consumer is to be supplied with heat transfer fluid 312, this can be connected to the heat transfer fluid outlet 350. The supply manifold 500 is thus optional. Accordingly, the return collector 400 is also optional, for example, if the heat transfer fluid 312 is returned from only one consumer.

[0090] To control the temperature as exactly as possible, the temperature control device 330 is configured to mix the second heat transfer fluid 312 of the supply section 320 and the second heat transfer fluid 312 of the return section 340 in such a way to provide the second heat transfer fluid 312 at a defined temperature at said at least one heat transfer fluid outlet 350.

[0091] The process temperature control system 10 from FIG. 1 also comprises at least one return collector 400 and one distributing device 342. The return collector 400 takes the returning second heat transfer fluid 312 from at least one consumer of the film stretching unit and supplies this to the distributing device 342. The distributing device 342 then supplies the returning second heat transfer fluid 312 to the heat exchanger 230. There, it can absorb thermal energy from the heat storage unit 210 again and be conveyed to the supply section 320.

[0092] In particular, pumps 322, 326, which convey or circulate the second heat transfer fluid 312, can be provided in the heat consumer circuit 300. Similarly, these can be controllable by means of the temperature control device 330.

[0093] Furthermore, the process temperature control system 10 comprises at least one additional heating device 324 that is integrated into the heat consumer circuit 300. Thus, additional thermal energy can be provided if this is required. Via the controllable valve 323, heat transfer fluid 312 can be conveyed to the additional heating device 324 and thus be heated additionally. The controllable valve 323 can be a proportional valve which allows the flow volume to be controlled. In particular, the valve 323 can be controlled by means of the temperature control device 330.

[0094] FIG. 2 shows a schematic view of a further process temperature control system 10 comprising direct heat storage. This process temperature control system 10 differs from the process temperature control system 10 shown in FIG. 1, in particular in the way in which the heat consumer circuit 300 is designed.

[0095] The heat consumer circuit 300 of the process temperature control system 10 shown in FIG. 2 comprises a supply section 320 and a return section 340, wherein the temperature of the second heat transfer fluid 312 is higher in the supply section 320 than in the return section 340.

[0096] Furthermore, the heat consumer circuit 300 comprises at least one temperature control device 330. This temperature control device 330 comprises at least one heat transfer fluid outlet 350 that is connected to a supply manifold 500.

[0097] This supply manifold 500 is configured to distribute the second heat transfer fluid 312 to different consumers (components) of a film stretching unit 1 (see FIG. 5). Thus, different consumers, such as the extruder, machine direction orienter (MDO), transverse direction orienter (TDO) and suchlike, can be supplied with thermal energy. If only one consumer is to be supplied with heat transfer fluid 312, this can be connected to the heat transfer fluid outlet 350. The supply manifold 500 is thus optional. Accordingly, the return collector 400 is also optional, for example, if the heat transfer fluid 312 is returned from only one consumer.

[0098] To control the temperature as exactly as possible, the temperature control device 330 is configured to mix the second heat transfer fluid 312 of the supply section 320 and the second heat transfer fluid 312 of the return section 340 in such a way to supply the second heat transfer fluid 312 at a defined temperature at said at least one heat transfer fluid outlet 350. To this end, the valves 330a, 330b and 330c are provided.

[0099] Furthermore, the process temperature control system 10 from FIG. 2 comprises at least one return collector 400. The return collector 400 takes the returning second heat transfer fluid 312 from at least one consumer of the film stretching unit and supplies this, among other things, to the valve 330a and the value 330c. Via the valve 330c, the returning second heat transfer fluid 312 can be conveyed to the heat exchanger 230. There, it can absorb thermal energy from the heat storage unit 210 again and be conveyed to the supply section 320.

[0100] The valves 330a, 330b and 330c can be controllable valves that are controlled by the temperature control device 330. In particular, the valves 330a, 330b and 330c can be proportional valves which allow the flow volume to be controlled. By means of the targeted control of the valves 330a, 330b and 330c, the heat transfer fluid 312 can be mixed and supplied at a defined temperature to the heat exchanger 210 and/or the heat transfer fluid outlet 350.

[0101] In particular, a pump 321 can be provided in the heat consumer circuit 300 that conveys or circulates the second heat transfer fluid 312. Optionally, a pump 222 can also be provided between the heat storage unit 210 and the heat exchanger 230 for conveying the corresponding heat transfer fluid. These pumps 321, 222 can also be controllable by means of the temperature control device 330.

[0102] Furthermore, the process temperature control system 10 comprises at least one additional heating device 324 that is integrated into the heat consumer circuit 300. Thus, additional thermal energy can be provided if this is required. Via a controllable valve 323, heat transfer fluid 312 can be conveyed to the additional heating device 324 and thus heated additionally. The controllable valve 323 can be a proportional valve which allows the flow volume to be controlled. In particular, the valve 323 can be controlled by means of the temperature control device 330.

[0103] FIG. 3 shows a schematic view of a further process temperature control system 10 comprising direct heat storage. This process temperature control system 10 differs from the process temperature control systems shown in FIGS. 1 and 2, in particular in the way in which the heat consumer circuit 300 is designed.

[0104] A pump 222 conveys heat transfer fluid from the heat storage unit 210 to the heat exchanger 230. The pump 331 is upstream of the heat exchanger 230. Furthermore, the heat consumer circuit 300 comprises multiple (for example two here) additional heating devices 324a, 324b that are connected parallel to the heat exchanger 230. In each case, a pump 332, 333 is upstream of the additional heating devices 324a, 324b.

[0105] The return collector 400 takes the returning second heat transfer fluid 312 from at least one consumer of the film stretching unit and supplies this to the pumps 331, 332, 333.

[0106] These pumps 222, 331, 332, 333 can be controlled by means of the temperature control device 330 in order to control the flow velocity of the corresponding heat transfer fluid in the circuit allocated to the pump. By means of the pump 222, the flow velocity of the heat transfer fluid allocated to the heat storage unit 210 can be controlled in the heat exchanger 230. By means of the pump 331, the flow velocity of the heat transfer fluid 312 can be controlled in the heat exchanger 230. Thus, the amount of thermal energy to be drawn from the heat storage unit 210 via the pump(s) 222 and/or 331 can be controlled.

[0107] Via the pumps 332 and 333, the flow velocity of the heat transfer fluid 312 can be controlled in the additional heating devices 324a, 324b. Thus, the amount of thermal energy transferred to the heat transfer fluid 312 can also be controlled here.

[0108] After the heat transfer fluid 312 has passed the branches of the additional heating device(s) 324a, 324b and/or the heat exchanger 230, the branches are mixed and supplied to the heat transfer fluid outlet 350 or the supply manifold 500. As already described above, the supply manifold 500 is optional and can be omitted if only one consumer is to be supplied with heat transfer fluid 312. Accordingly, the return collector 400 is also optional, for example, if the heat transfer fluid 312 is returned from only one consumer.

[0109] FIG. 4 shows a schematic view of a process temperature control system 10 comprising indirect heat storage. This process temperature control system 10 differs from the process temperature control system 10 shown in FIG. 1, in particular in way in which the heat storage unit 210 is integrated into the process temperature control system 10. In the system shown in FIG. 4, the first heat transfer fluid 212 is not conveyed directly into the heat storage unit 210 but conveyed through a heat exchanger 215. This heat exchanger 215 is integrated into an intermediate circuit 200, in which the heat exchanger 210 is also integrated. The intermediate circuit 200 conveys an intermediate-circuit heat transfer fluid 212. This intermediate-circuit heat transfer fluid 212 can differ from the first heat transfer fluid 112 and/or the second heat transfer fluid 312.

[0110] The energy generated by the solar heat generator 110 is initially transferred to the first heat transfer fluid 112 (in the solar heat generator 110) and then transferred to the intermediate-circuit heat transfer fluid 212 in the heat exchanger 215 for storage, in order to be stored in the heat storage unit 210 (indirect storage).

[0111] FIG. 5 shows a schematic view, in very simplified form, of a film stretching unit 1, which is configured for bi-axial stretching of a film 9. This film stretching unit 1 comprises several components that constitute the individual process steps of the film manufacture. In particular, the film stretching unit 1 is configured for sequential bi-axial stretching of the film 9.

[0112] The starting material to be processed, i.e. a polymer (granules and/or powder), is initially supplied to an extruder 3 via a proportioner comprising a feed hopper 2 and is melted in the extruder 3.

[0113] By means of a nozzle unit 3a (for example a slot die) that is downstream of the extruder(s) 3, the polymer melt is applied to a chill roll 4 and cooled. The film 9 formed as a result is then stretched by means of a machine direction orienter (MDO) 5 in the machine direction, i.e. longitudinally. Materially and depending on the process, this machine direction stretching occurs at a temperature range of approx. 80? C. to approx. 140? C.

[0114] Subsequently, the film is fed into a transverse direction orienter (TDO) 6 and stretched here in the transverse direction. The stretching is described again in detail with regard to FIG. 6. Materially and depending on the process, this transverse direction stretching occurs at a temperature range of approx. 80? C. to approx. 200? C., wherein the temperature range for stretching depends on the material. For PA, PET and PP films, this temperature range is approx. 80?-200? C. The oven of the transverse direction orienter (TDO) can be temperature-controlled at a higher level, for example at a range from 80? to 240? C.

[0115] Then, the film 9 is drawn out of the oven by means of a pull-roll device 7 (what is termed a pull roll) and subsequently wound by means of the wrapping device 8.

[0116] Similarly, the stretching does not have to occur sequentially, but may occur simultaneously. The difference between simultaneous and sequential stretching is that in simultaneous stretching the film is stretched in the machine direction (longitudinal direction) and the transverse direction at the same time. This occurs in what is termed a simultaneous stretching unit (e.g. a simultaneous stretching oven). The simultaneous stretching unit is temperature controlled and accelerates a gripped film in such a way that this film is stretched simultaneously in the machine direction and in the transverse direction. A separate machine direction orienter is therefore not required.

[0117] By means of a process temperature control system 10 described previously (see FIG. 1, 2, 3 or 4), the individual components (for example the feed hopper 2, the extruder 3, the chill roll 4, the machine direction orienter (MDO) 5, the transverse direction orienter (TDO) 6, the pull-roll device 7 and/or wrapping device 8) can be temperature-controlled. Thus, solar energy can be used for film manufacture and the use of fossil fuels can be reduced.

[0118] The following example illustrates this. A solar heat generator is assumed that comprises linear Fresnel collectors. In the case of the solar heat generator amounting to 5000 m.sup.2, approx. 3,520 MWh thermal energy is yielded at a temperature level of the heat transfer fluid of approx. 250? C. for an average direct normal irradiance (DNI) of 340 W/m.sup.2. At a total annual heat requirement of approx. 15,000 MWh for the TDO and MDO devices, which currently are supplied by the fossil fuel coal, this equals 23% or 1.471 tCO.sub.2e.

[0119] As the above example demonstrates, using concentrated solar power contains significant energy savings potential in the case of heat generation for a film stretching unit.

[0120] FIG. 6 shows a schematic view of a transverse direction orienter (TDO). It is also conceivable that the stretching unit is a simultaneous stretching unit. The transverse direction orienter 6 comprises an oven 612, a transport system 614 as well as a compensation device 616.

[0121] The oven 612 has a drawing direction R that is the direction of travel of the film 9 to be stretched. The transverse direction Q of the oven 612 runs transverse to the drawing direction R as well as horizontally and the vertical direction H runs vertically.

[0122] The oven 612 has different zones along the drawing direction R for treating the film 9 to be stretched.

[0123] In the first zone 622, also termed preheating zone, the film is heated. In the following second zone 624 (stretching zone), the film is stretched in the transverse direction Q so that it has a larger width at the end of the second zone 624 than at the start.

[0124] After the stretching is completed, the film 9 then passes through a third zone 626 (termed heat treatment zone, further heating zone and/or annealing zone), in which a relaxation of the film 9 can occur at high temperatures.

[0125] Then, the film 9 passes through a fourth zone 628 and a fifth zone 630 (cooling zone), wherein the film is cooled in the fifth zone 630.

[0126] The fourth zone 628 is termed the neutral zone and is used to separate the third zone 626 from the fifth zone 630. The neutral zone is, for example, an empty space without ventilation.

[0127] The transport system 614 comprises, in a known manner, two transport rails 632 that are located mirror-symmetrically in respect to a central plane M of the stretching unit 6 and the oven 612 as well as extend at least in part into the oven 612.

[0128] In an entry zone 634 as well as an exit zone 636, in which the film to be stretched of the stretching unit 6 is fed and removed, the transport rails 632 run outside of the oven 612.

[0129] The film 9 is gripped in the known manner by grippers (not shown) of the transport system 614, which are guided along the transport rails 632, and transported through the oven 612 in the drawing direction R. The film runs in a film track F that is defined in the oven 612 by the transport system 614. The film track F intersects the central plane M.

[0130] In particular, the zones 634, 622, 624, 626, 628, 630 and 636 of the oven 612 can be temperature-controlled in a defined manner by means of the process temperature control system 10.

[0131] In addition, several nozzle boxes (not shown) are located in the oven 612 that convey the hot (temperature-controlled) air in the direction of the film web F. By means of the hot air, the interior of the oven and thus the film 9 is heated, cooled or kept at a predefined temperature. The air can be temperature-controlled via a suitable heat exchanger of the transverse direction orienter by means of the process temperature control system 10.

LIST OF REFERENCE SIGNS

[0132] 1 film stretching unit [0133] 2 feed hopper [0134] 3 extruder [0135] 4 chill roll [0136] 5 machine direction orienter (MDO) [0137] 6 transverse direction orienter (TDO) [0138] 7 pull-roll device [0139] 8 wrapping device [0140] 9 film [0141] 10 process temperature control system [0142] 100 heat generation circuit [0143] 110 solar heat generator [0144] 112 first heat transfer fluid [0145] 124 pump [0146] 200 intermediate circuit [0147] 210 heat storage unit (buffer storage) [0148] 212 intermediate-circuit heat transfer fluid [0149] 215 heat exchanger (generator side) [0150] 222 pump [0151] 230 heat exchanger (consumer side) [0152] 300 heat consumer circuit [0153] 312 second heat transfer fluid [0154] 320 supply section [0155] 322 pump [0156] 321 pump [0157] 323 valve (for additional heating) [0158] 324 additional heating device [0159] 324a additional heating device [0160] 324b additional heating device [0161] 326 pump [0162] 330 temperature control device [0163] 330a valve [0164] 330b valve [0165] 330c valve [0166] 331 pump [0167] 332 pump [0168] 333 pump [0169] 340 return section [0170] 342 distributing device [0171] 350 heat transport fluid outlet [0172] 400 return collector [0173] 500 supply manifold [0174] 612 oven [0175] 614 transport system [0176] 616 compensation device [0177] 622 preheating zone [0178] 624 stretching zone [0179] 626 heat treatment zone, further heating zone and/or annealing zone [0180] 628 neutral zone [0181] 630 cooling zone [0182] 632 transport rail [0183] 634 entry zone [0184] 636 exit zone [0185] H vertical direction of the oven 612 [0186] Q transverse direction of the oven 612 [0187] R drawing direction [0188] M central plane of the transverse direction orienter