FI125145B - Cooling of cellulosic pulp web - Google Patents

Description

FIELD OF THE INVENTION

The present invention relates to a pulp dryer for drying the pulp web by hot air according to the principle of fluidized-bed web and comprising a cooling zone having a length along which the web is conveyed.

Further, the present invention relates to a method for cooling a pulp web by causing said web to pass through a cooling zone.

Background of the Invention

The pulp used for the production of paper and board is often dried by a convection-type dryer, which operates on the principle of fluidized-bed drying of the web. One example of such a dryer is disclosed in U.S. Patent 4,505,053. Hot air is blown onto the pulp web from the upper and lower blower boxes described in Figure 4 of U.S. Patent 4,505,053. The air from the blower boxes transfers heat to the web to dry while keeping the web floating at a constant distance above the lower blower boxes. The hot boxes are supplied with hot air by means of an air circulation system comprising fans and steam radiators that heat the drying air. Fluid transport of the web in a stable and unchanged position above the blow box set is also described in U.S. Patent 3,231,165. A complete pulp dryer is disclosed in WO 99/36615.

The average temperature of the dried pulp leaving the dryer portion of the pulp dryer is quite high, often in the range of 55-100 ° C, as measured from the pulp collected after the drying portion. Such a high temperature has been found to impair the quality of the pulp and lead to a decrease in the brightness of the pulp during pulp storage. Attempts have been made to avoid the problems of lightness reduction of the pulp by cooling the dried pulp prior to packaging it for baling for transport. WO 02/50370 discloses a zone divided dryer in which a final zone is supplied with cooling air to cool the pulp web.

Summary of the Invention

It is an object of the present invention to provide a pulp web cooling method which is more effective than the known method. This is accomplished by a pulp dryer for drying the pulp web by hot air according to the principle of fluidized-bed drying, comprising a cooling zone having a length of travel of the web and characterized in that the cooling zone comprises a plurality of cooling blast boxes a fluid supply means for directing coolant directly to the web in said cooling zone.

One of the advantages of the cooling zone is that it provides highly efficient web cooling combined with low consumption of coolant and cooling air and very limited increase in web moisture. Due to the effective cooling of the web, the web leaving the pulp dryer is cooler, thus reducing the problems associated with color degradation of hot pulp webs.

According to a preferred embodiment, said fluid feeding device is located at a point in the length of the cooling zone where the web has traveled 25-80% of the length of the cooling zone as viewed from the base of the cooling zone. Placing a fluid feeding device at said position along the cooling zone has proven to provide particularly efficient cooling of the pulp web.

According to one embodiment, said fluid delivery device comprises at least one jet nozzle. The jet nozzle provides an effective way of applying coolant to the web.

According to one embodiment, said cooling zone comprises at least two fluid feeding devices at different locations along the cooling zone length, of which at least one fluid feeding device is located at a point in the cooling zone length where the web has traveled 25-80% of the cooling zone length. One advantage of this embodiment is that larger amounts of liquid can be introduced into the web without creating wet areas in the cooling zone. Preferably, all of the various points mentioned are located at points where the web has traveled 25-80% of the length of the cooling zone.

According to one embodiment, said fluid supply device comprises an upper portion for cooling the upper surface of the web and a lower portion for cooling the lower surface of the web. One advantage of supplying coolant to both the top and bottom surfaces of the web is enhanced cooling efficiency.

According to one embodiment, said cooling zone comprises a plurality of upper and lower blowing boxes distributed over the length of the cooling zone and blowing cooling air to both the upper and lower surfaces of the web. For the same reasons already mentioned, the cooling of the web is enhanced if cooling air is blown on both the upper and lower surfaces of the web, especially in the case of a thick web.

Another object of the present invention is to provide a process for cooling a pulp web which is more effective than known processes. This is accomplished by a pulp web cooling process, wherein the web is passed through a cooling zone, characterized in that the web is cooled by said cooling zone by passing a plurality of cooling blades over a cooling blast over the cooling zone, directly on one or both sides of the web in at least one of the lengths of the cooling zone.

One advantage of this process is that the web is dried efficiently and quickly.

According to a preferred embodiment, said method further comprises applying coolant directly to the web at at least one point along the cooling zone where the web has traveled 25-80% of the length of the cooling zone as viewed from the base of the cooling zone.

According to one embodiment of the present invention, coolant is applied directly to the web at at least one point of the cooling zone length where the web has traveled 35-75% of the length of the cooling zone as viewed from the base of the cooling zone. The supply of coolant at said point has proved to be particularly advantageous for cooling the web.

According to one embodiment of the present invention, the method further comprises measuring the temperature of the web after the cooling zone and adjusting the amount of coolant to the cooling zone taking into account the temperature of the web after the cooling zone. One advantage of this embodiment is that the coolant is not supplied more than is necessary to obtain a suitable average temperature of the pulp after the cooling zone.

In accordance with an embodiment of the present invention, the control of the coolant to be supplied takes into account the temperature of the web before the cooling zone. One advantage of this embodiment is that changes in the drying process can be quickly taken into account

According to an embodiment of the present invention, the method comprises measuring the temperature of the cooling air supplied to the cooling zone and adjusting the amount of coolant to the cooling zone taking into account this temperature of the cooling air supplied to the cooling zone. negatively to the temperature of the web leaving the cooling zone.

Other objects and features of the present invention will be apparent from the specification and claims.

Brief description of the drawings

The invention will now be described in more detail with reference to the accompanying drawings in which

Figure 1 is a schematic side view showing the pulp dryer.

Figure 2 is an enlarged side view showing the area II of Figure 1.

Figure 3 is a cross-sectional view of the cooling zone taken along line III-III of Figure 2.

Figure 4 is a schematic side view of the cooling zone showing various locations of the spray nozzles.

Figure 5 is a diagram showing the drying effect when the coolant is sprayed at various locations.

Figure 6 is a diagram showing the drying effect when the coolant is sprayed at various locations.

Fig. 7 schematically shows a control device.

Figure 8 schematically shows two ways of controlling coolant injection.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. The wet cellulosic pulp web 2 enters the pulp dryer 1 via feed 4. The arrows A indicate the direction of the web 2 pulp through the dryer 1. The web 2 is made to pass between a plurality of upper blower boxes 6 and lower blower boxes 8. Blowing boxes 6 and 8 blow hot drying air to the web 2, typically at a temperature of 110-200 ° C. The hot drying air blown by the lower blower boxes 8 holds the web 2 in a floating state, i.e., causes the air 2 to support the web 2 as it passes between the blower boxes 6 and 8. One example of the construction of a blow box is found in U.S. Patent 4,719,708. As shown in Figure 1, the web 2 is subjected to several drying treatments as it passes through the drying section 9 of the pulp dryer 1. The pulp dryer 1 has a cooling zone 10 located after the drying section 9 and described in more detail below. Partition 12 separates cooling zone 10 from drying section 9. Finally, the dried and cooled mass exits the pulp dryer 1 through outlet 14 as a dry and cool pulp web 16, which typically has a temperature below 50 ° C.

Figure 2 is an enlarged view of area II of Figure 1 showing details of the cooling zone 10. The pulp dryer cooling zone 10 employs a special combination of cooling air and water acting as the coolant. The cooling zone 10 comprises a plurality, i.e. at least two upper cooling blower boxes 18 and a lower cooling blower box 20. The upper and lower cooling blower boxes 18, 20 are essentially similar in function and function to those described above with respect to Figs. The cooling air blown by the cooling air keeps the web 2 in a floating state also in the cooling zone 10. But the air blown to the web 2 by the cooling blowing boxes 18, 20 is not hot drying air but cooling air, usually ambient air typically at 0-45 ° C. In addition to the cooling blower boxes 18, 20, the cooling zone 10 also comprises a series of upper jet nozzles 22 and a series of lower jet nozzles 24. The upper jet nozzles 22, of which only one nozzle is shown in Fig. 2, are mounted on an upper nozzle support 26 extending across the web. The lower jet nozzles 24 are mounted on the lower nozzle support 28 which extends across the width direction of the web 2.

Fig. 3 is a cross-sectional view of the cooling zone 10 taken in the direction of the arrows III of Fig. 2. As can be seen, the upper nozzle support 26 carries a plurality of upper jet nozzles 22. The tube 30 is arranged to supply cooling water to the upper jet nozzles 22. In addition, the lower nozzle support 28 carries a plurality of lower jet nozzles 24, and the tube 32 is arranged to supply cooling water to spray cooling water to the web 2 to cool it as described in more detail below. The upper jets 22 spray the cooling water directly onto the upper surface of the web 2 and the lower jets 24 spray the cooling water directly onto the lower surface of the web 2. The spray nozzles 22, 24 are evenly disposed on their respective nozzle supports 26, 28 to provide substantially uniform distribution of the cooling water to be sprayed across the width direction of the web 2.

One example of a possible jet nozzle that can be used to spray cooling water onto a web is a TPU nozzle size 1100050, which is a flat jet with a spray angle of 110 °, supplied by Spraying Systems Co., Wheaton, Illinois, USA. Typically, the nozzle operates at a water pressure of 2-6 bar above ambient pressure. The median diameter volume is typically between 0.1 and 0.4 mm. The cooling water temperature is normally between 0 and 35 ° C.

The upper and lower nozzles 22, 24 illustrated in connection with Figures 2 and 3 together form a cooling arrangement, and the cooling zone 10 may be provided with one or more of the described water cooling arrangements disposed at different locations, as described below.

Figure 4 illustrates different locations of one or more water cooling arrangements in the cooling zone 10, the type of arrangements previously described with reference to Figures 2 and 3, each of which water cooling arrangement comprises upper and lower jets 22, 24. The cooling zone 10 comprises a plurality of and a plurality of lower cooling blower boxes 20. The cooling zone 10 typically has a length L, from the first to the last cooling blower box 18, 20, which is 20 to 140 m long. The cooling blower boxes 18, 20 are substantially uniformly distributed over this length. as described below, places the refrigeration zone 10 very precisely at defined points along the length L in order to achieve optimum cooling of the web 2. The arrow A indicates the direction of travel of the web 2 through the cooling zone 10.

Figure 4 illustrates four positions along the dimension of the cooling zone 10 in which one or more water cooling arrangements may be placed with the spray nozzles 22, 24. These four positions are designated as "0%", "40%", "60%" and "80%". Thus, "0%" refers to the position B at the beginning of cooling zone 10, B being the location of the first cooling blowers 18, 20 in cooling zone 10, as viewed in the direction of travel of web 2. Further, "40%" refers to where web 2 has passed. % of the length of the cooling zone 10, etc. Thus, if the length L of the cooling zone 10 is 50 meters, "40%" refers to a position 20 meters from the beginning of the cooling zone 10, "60%" refers to 30 meters from the beginning of the cooling zone 10. "refers to a point 40 meters from the beginning of refrigeration zone 10 B.

Fig. 5 is a diagram showing the results of experiments in which the spray nozzles 22, 24 were located at different locations along the length L of the cooling zone 10 as shown in Fig. 4. It will be appreciated that in some of the experiments performed, water was sprayed only at one point along the cooling zone 10 along the length L, while in other experiments water was sprayed at two different points along the cooling zone 10 along the length L. In the experiments where cooling water was sprayed , 24, as shown in Figures 2 and 3. Thus, in all experiments, water was sprayed on both the upper and lower surfaces of web 2 at each of the locations mentioned. Table 1 summarizes the results of the tests performed:

Table 1: Spray points and spray rates at different spray points.

Figure 5 is a graph showing the results of the experiments. The Y-axis depicts a decrease in surface temperature, ° C, as compared to the situation where cooling in the cooling zone 10 was accomplished only by means of the blow boxes 18, 20. Thus, "0 ° C" on the Y axis refers to a case where the effect of cooling water is completely absent, i.e. the only cooling effect comes from the cooling air. The cooling air temperature was about 28 ° C. Typically, the average pulp temperature, as measured from the pulp stack collected after the cooling zone 10, was 38-42 ° C, with no effect of cooling water. Thus, "0 ° C" on the Y axis in Figure 5 corresponds to an average pulp temperature of 38-42 ° C. In addition, the cooling water temperature was about 15 ° C. The pulp web was a typical softwood web having a basis weight of about 830-860 g / m2, as measured by TAPPI T410. The total width of the pulp web 2 was about 4.2 m, but cooling tests were performed at a width of about 500 mm. The dryness of the pulp web 2 at the beginning of the cooling zone 10 was about 89%, as measured by TAPPI T412. The length L of the cooling zone 10 was approximately 40 meters. The web 2 passed through cooling zone 10 at a rate of about 150 m / min. The X-axis represents the total amount of water sprayed to the web 2 in liters per hour.

As can be seen in Figure 5, the result of Experiments 1-3 and 5 was that the web 2 cooled at about 8 ° C with a water jet flow of about 110 l / h. Test # 6, in which all cooling water was sprayed at the beginning of cooling zone 10, B gave the pulp web 2 a cooling result of only about 3-4 ° C with the same water jet stream. As a result of Experiment 4, web 2 cooled to 7 ° C with the same water jet stream. The moisture content of the web 2 after the cooling zone 10 was essentially independent of the spraying points. Thus, the positioning of the spray nozzles 22, 24 along the length L of the cooling zone 10 has a great effect on the cooling efficiency but a limited effect on the moisture content of the pulp.

Fig. 6 shows the calculated cooling of the pulp web by combining cooling air blasting in a cooling zone and spraying water at various points along the cooling zone length. Calculations were made using a mathematical model based on experimental results similar to Figure 5. Calculations are made for an arrangement similar to Figure 4. The cooling water flow rate was set at about 115 l / h, the cooling water temperature was about 15 ° C, and the cooling air temperature was about 28 ° C. The simulated web was a typical softwood web having a basis weight of about 850 g / m2, measured according to TAPPI T410, and had a width of about 500 mm. The dryness of the pulp web at the beginning of the cooling zone 10 was about 89% as measured by TAPPI T412. The length of the cooling zone L was 40 meters. The web 2 passed through cooling zone 10 at a rate of about 150 m / min. In all cases, water was sprayed against the web 2 at only one point, but at both that point above and below the pulp web. The X axis of Figure 6 refers to the L point of the cooling zone 10 where water was sprayed. Thus, "0%" refers to the position at the beginning B of the cooling zone 10 as viewed in the direction of travel of the web 2 and as shown in Figure 4. Further, "10%" refers to the point where the web 2 has traveled 10% of the length L of the cooling zone 10, etc. The Y-axis in Figure 6 shows the surface temperature decrease in degrees Celsius compared to the case with cooling zone 10 only . Thus, "0 ° C" on the Y axis refers to a case where the effect of cooling water is completely absent, i.e. the only cooling effect comes from the cooling air.

As can be seen in Figure 6, the cooling efficiency is greatest when water is sprayed at a location within the range 25% -80% of the length L of the cooling zone 10 of Figure 4 as viewed from the base B of the cooling zone 10. % of total length L of cooling zone 10 as viewed from base B of cooling zone 10. Thus, if total length L of cooling zone 10 is 50 meters, the spray nozzles 22, 24 should be located at least 12.5 meters from beginning of cooling zone 10 and up to 40 meters from B cooling zone. Referring again to Fig. 6, a more preferred spacing of the spray nozzles 22, 24 is at 35-75% of the length of the cooling zone 10 as viewed from the base B of the cooling zone 10, and an even more preferred spacing of the jets 22, 24 is at 45-70% of the length of the cooling zone viewed from the cooling zone en 10 platform B. The most optimum location for the jet nozzles 22, 24 is at 55-63% of the length L of the cooling zone 10 as viewed from the beginning of the cooling zone 10.

Figure 7 schematically shows a control valve 36 arranged to control the amount of coolant to be supplied to the spray nozzles 22, 24 shown schematically in Figure 7. The control device 40, such as a process computer, is responsible for controlling the control valve 36. The control device 40 receives information from the first heat sensing probe 42, the function of which is to measure the mass of the web 2 surface temperature just before cooling zone 10, the pulp web 2 advances in the arrow A direction, and on the other the temperature sensors 44, the function of which is to measure the mass of the web 2 surface temperature immediately after cooling zone 10.

The control device 40 may adjust the amount of coolant to be sprayed onto the web 2 on a feedback basis based on information from the second temperature sensor 44 to maintain the temperature of the web 2 leaving the cooling zone 10 at a specific setpoint, such as 38 ° C. The control device 40 may also, in accordance with the feed-in principle, take into account the temperature changes of the web 2 measured by the first heat sensor 42 before controlling the control valve 36. In addition, the control device 40 may also obtain information from the CPD 46, e.g. temperature, steam entering the dryer, drying capacity of the dryer, and other process values. The control device 40 may take into account such information from the central process computer 46 as it feeds in control of the control valve 36. The purpose of the feedforward control is to eliminate the temperature disturbances of the pulp . The feed-forward control can be applied in a number of known ways, including so-called. pulse compensation.

Figure 7 schematically illustrates a fan 48 which serves to provide cooling air to the upper and lower cooling blower boxes 18, 20 previously described with reference to Figure 2. It should be noted that in practice, blowers 48 may have more than one to produce cooling air for our cooling blades 20, still in Fig. 7, the function of the air temperature sensor 50 is to measure the temperature of the air produced by the fan 48 to the cooling blower boxes 18, 20. The air temperature sensor 50 transmits a signal to the control device 40. The control device 40 can thus take into account changes in the cooling air temperature, and in particular the cooling air temperature, when controlling the control valve 36.

Figure 8 schematically illustrates two possible ways of incorporating a feed-in signal from the first temperature sensor 42 in the control of the control valve 36 of Figure 7. Both ways of including a feed-in signal in a control circuit are known per se in other fields of technology. In the first alternative, shown in solid lines in Fig. 8, the set point and feedback according to the result, i.e. the temperature of the web 2 after the cooling zone 10 measured by the second temperature sensor 44, is supplied to the PID controller. According to the first way, the measurement of the control valve 36 defect, e.g. the temperature measured by the first temperature sensor 42 before the cooling zone 10, passes through the filter qff and affects the PID controller output so that the signal transmitted by the PID controller 7 According to another method, control of the control valve 36 is carried out by means of a so-called. pulse compensation, as indicated by dashed lines in Figure 8. Pulse compensation comprises passing a measured disturbance, e.g., the temperature measured by the first temperature sensor 42, before cooling zone 10, possibly through a filter qff, to a model such as a mathematical model. The result of the model influences the input to the PID controller to account for the measured interference. It will be appreciated that a similar control circuit may be used to provide feedback, other than the temperature of the web immediately prior to the cooling zone, in a feed-in manner. For example, control of the coolant supply could take into account, in a feed-in manner, a sensor 50 previously described in connection with FIG. 7 to measure the temperature of the cooling air.

It will be appreciated that several variations of the embodiments described above are possible within the scope of the appended claims.

For example, it would be possible to use a cooling zone having lower cooling air blowers 20 but not upper cooling air blowers. Such a cooling zone would still operate on a fluidized-bed principle, but its cooling effect would be slightly less than that of the drying zone comprising both upper and lower blow boxes 18, 20 as shown in Figure 4. The width of each blower box 18, 20 as viewed across the length L of the cooling zone 10 could vary within wide limits. Typically, the width of each blast box as viewed along the length L could be 100-500 mm.

The cooling zone 10 is described above, in which the web passes once, from left to right, as shown in Figure 4, through the cooling zone 10. However, it is also possible to provide a cooling zone 10 through which the web passes several times, similarly to that described previously in connection with Fig. 1 with respect to the drying section 9 of the pulp dryer 1. In this case, the cooling zone 10 could comprise one passage. In the latter case, the total length of the cooling zone is the sum of all the passages of the cooling zone.

It has been stated above that the cooling water is directed to the web in the cooling zone by means of the spray nozzles 22, 24. It will be appreciated that other devices may be used to conduct water to the web 2. Such devices include e.g. märkätelat. Conducting cooling water by means of the jets 22, 24 is often advantageous for practical reasons.

It has been stated above that one possible coolant is water. Although water is often an inexpensive coolant, there are other potential coolants. Examples of such coolants are e.g. alcohols such as ethanol and glycol, and various ethers. The coolant may also comprise a mixture such as water and glycol. In addition, the coolant may comprise chemical additives which are usually less than 10% of the coolant and which may have a beneficial effect on the quality of the pulp.

Claims (16)

A pulp dryer, which is arranged to dry a pulp web (2) by means of hot air in accordance with the principle of airborne web (2) and has a cooling zone (10) which has a length (L) along which the web (2) should characterized in that the cooling zone (10) has a plurality of cooling blowers (18, 20) distributed along the length (L) of the cooling zone (10) and arranged to blow cooling air towards the web (2), and at least one liquid supply device (22, 24), arranged to supply coolant directly to the web (2) in the cooling zone (10). Massage dryer according to claim 1, wherein the liquid delivery device (22, 24) is placed in a position along the length (L) of the cooling zone (10), in which the web (2) has been moved 25-80% of the length (L) of the cooling zone (10). ), seen from the beginning (B) of the cooling zone (10). Massage dryer according to any one of claims 1-2, wherein the liquid supply device has at least one spray nozzle (22, 24). Massage dryer according to any one of claims 1-3, wherein the cooling zone (10) has at least two liquid delivery devices (22, 24) located in different positions along the length (L) of the cooling zone (10), wherein at least one of the liquid supply devices (22). , 24) is placed in a position along the length (L) of the cooling zone (10), in which the web (2) has been moved 25-80% of the length of the cooling zone (10). Massage dryer according to claim 4, wherein each of said different positions is located where the web (2) has been moved 25-80% of the length (L) of the cooling zone (10). Massage dryer according to any one of the preceding claims, wherein the liquid delivery device has an upper part (22) arranged to cool the top of the web (2) and a lower part (24) arranged to cool the bottom of the web (2). Massage dryer according to any one of the preceding claims, wherein the cooling zone (10) has a plurality of upper and lower cooling blowers (18, 20) distributed along the length (L) of the cooling zone (10) and arranged to blow cooling air towards the web (2). ) top and bottom. 8. A method of cooling a pulp web by advancing the web (2) through a cooling zone (10), characterized in that the web (2) is cooled in the cooling zone (10) by passing the web (2) past a plurality of cooling blowers (18, 20). ), which are distributed along the length (L) of the cooling zone (10), and cooling air with a temperature of 0-45Ό is blown towards the web (2) by means of these cooling bi-box drawers (18, 20) and coolant is supplied directly to the web (2). in at least one position along the length (L) of the cooling zone (10). The method of claim 8, further comprising providing coolant directly to the web (2) in at least one position along the length (L) of the cooling zone (10), in which the web (2) has been displaced 25-80% of the cooling zone (10). length (L), seen from the beginning (B) of the cooling zone (10). 10. A method according to any one of claims 8-9, in which coolant is supplied both on the upper side of the web (2) and on its underside. A method according to any of claims 8-10, wherein coolant is supplied in at least two different positions along the length (L) of the cooling zone (10), wherein at least one of said at least two different positions is a position along the length of the cooling zone (10). ) in which the web (2) has been moved 25-80% of the length (L) of the cooling zone (10). The method of any of claims 8-11, wherein coolant is applied directly to the web (2) in at least one position along the length (L) of the cooling zone (10), in which the web (2) has been moved 35-75% of the cooling zone ( 10) length (L), seen from the beginning (B) of the cooling zone (10). The method of any of claims 8-12, further comprising measuring the temperature of the web (2) downstream of the cooling zone (10) and controlling the amount of coolant supplied to the cooling zone (10) with respect to the temperature of the web (2) downstream of the cooling zone (10). ). The method of any of claims 8-13, further comprising measuring the temperature of the web (2) upstream of the cooling zone (10) and controlling the amount of coolant supplied to the cooling zone (10) with respect to the temperature of the web (2) upstream of the cooling zone (10). ). The method of any of claims 8-14, further comprising collecting data correlated to at least one process parameter describing the function of a dryer section (9) located upstream of the cooling zone (10) and supplied to the cooling zone (10) is regulated with respect to this data. The method of any of claims 8-15, further comprising measuring the temperature of the cooling air supplied to the cooling zone (10) and controlling the amount of coolant supplied to the cooling zone (10) with respect to the temperature of the cooling air supplied to the cooling zone (10). ).