FI82848C - FOERFARANDE FOER KONTAKTFRI TORKNING AV EN PAPPERS- ELLER KARTONGBANA. - Google Patents

Description

83848 | Method for non-contact drying of paper or cardboard webs For use in contact with paper or paperboard 5

The invention relates to a method for contactless drying of a paper or board web, in which method both infrared radiation and drying air jets are used for drying, by means of which the web moving through the dryer is supported in a non-contact manner, preferably bilaterally, in which the web is first directed to infrared or and in which method the infrared radiators of the infrared drying unit or units are cooled by air currents and in which the infrared drying unit or units are closed before the fluidized bed dryer so that the cooling air derived from the nozzles of the fluidized bed dryer following the infrared dryer to the drying and support air lluksiksi.

The present invention relates to the drying of a paper web, paperboard web or other similar moving web. A typical application of the invention is the drying of a paper web in connection with its coating or surface sizing.

It is already known that the so-called fluidized bed dryers for non-contact drying of paper web, paperboard web or the like. Fluidized bed dryers are used, for example, in paper coating equipment after a blade, roll or brush coater to non-contact to support and dry the wet web of coating material. Various drying and support air blowing nozzles and their configurations are used in fluidized bed dryers. Said blowing nozzles can be divided into two groups, namely overpressure or float nozzles and vacuum or foil nozzles, both of which can be applied in the method according to the invention.

The most commonly known fluidized bed dryers are already based exclusively on air blowing. For this reason, the fluidized bed dryer 2 83848 1 becomes quite space-consuming, because the range of action of the toy cultivator must be relatively long in order to obtain a sufficiently high drying power. In part, these disadvantages are due to the fact that the penetration depth of the drying remains relatively small in air drying.

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Various dryers are already known which are based on the effect of radiation, in particular infrared. The use of infrared radiation has the advantage that the radiation has a relatively large penetration depth, which increases as the wavelength decreases. The use of an infrared dryer in the drying of paper webs has been hampered by e.g. the risk of fire because the temperatures of the infrared emitters become quite high, e.g. 2000 ° C, in order to achieve a sufficiently short-wave drying radiation.

. Electric infra-dryers, when used alone or exclusively, are also energy-disadvantageous due to the relatively high cost of electrical energy compared to, for example, natural gas.

In paper coating stations, including on-machine coating stations, separate infrared dryers have been used, the drying of which is based solely on 20 radiation effects. However, these infrared dryers have not achieved sufficiently good controllability of paper quality and evaporation. In addition, the drying process becomes highly dependent on the operation of the infrared dryer.

With regard to the state of the art most closely related to the invention, reference is made to Applicant's FI patent 77707, which discloses a combined infra-fluid dryer, hereinafter "turboinfra", with the novelty of using a closed infrared unit or units before the fluidized bed dryer. is led to the infrared drying interval 30, and in the closed air circulation of the infrared drying unit or units the heated dry cooling air is led from the nozzles of the toy cultivator following the infra-dryer to the drying and / or support air blows of the drying interval.

The main object of the present invention is to develop the "turboinfra" disclosed in the above-mentioned FI patent.

i 3 83848 1 Em. In the "turboinfra" disclosed in the FI patent, the warm drying air supplied to the fluidized bed dryer is heated to about 120 ° C by blowing it through an infra-dryer. The drying energy in the fluid comes from the cooling-wasted power of the infrastructure, which is recovered by utilizing it in the fluid. In this way, the poor efficiency of the infrastructure has been improved and the evaporative energy of the fluid does not have to be produced, at least not completely, by a separate steam or gas heater. Low pressure steam in paper mills achieves approximately the same air temperature in the fluid as using infra cooling line. With a high-pressure steam and a gas burner, a temperature of 200-300 ° C is reached. With separate burners or heat exchangers, the air blowing speed can be adjusted over a fairly wide range. There is no corresponding freedom in the "turboinfra", but the structure of the infrastructure imposes certain 3 restrictions when increasing the blowing speed or rather the volume speed (m / s). Cooling air passes in the radiator module between the infrared lamp and the 15 goggles. The glass can not withstand a certain value greater pressure difference between the inside and the outside, and the pressure must be limited, a blow-off speed (volume flow) also limited.

The object of the present invention is to avoid the above-mentioned drawbacks and to provide a new method in infra-fluidized bed dryers.

It is a particular object of the invention to provide a new method in question, by means of which the production speed of the coating machine can be increased without expensive investments. The aim is also to reduce energy consumption, ie to increase the efficiency of the infra-fluidized bed dryer.

Mentioned above and to achieve the goals will come out later, the invention is mainly characterized in that the cooling air 30 the recovered heat energy is conducted infrakuivattlmen essentially the whole side of the fluidized bed heat energy, which is on the opposite side of the dry side of the wet side of the web coated.

The present invention relates to a fluidized bed drier connected to an infrared drying unit or units, which utilizes the cooling line of the air radiators and other parts 4 83848 1 in the vicinity thereof, which is particularly suitable for drying air because it is dry and hot air. The present invention achieves an advantageous combination of an infra unit and a fluid bed dryer unit, especially in terms of energy economy.

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The invention will now be described in detail with reference to an embodiment of the invention shown in the figure of the accompanying drawing, to which the invention is not limited.

Figures 1A and 1B schematically show fluidized bed cultivators based on the invention.

Figure 2A shows an infra-fluidized bed dryer with a known air circulation according to the invention.

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Figure 2B schematically shows an infra-fluidized bed dryer with an air circulation according to the method of the invention.

Figure 3 shows in more detail a preferred embodiment of the invention.

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First, with reference to Figures 1A, 1B, 2A and 2B, the main features of the construction and operation of some of the previously known fluidized bed dryers and infrared toy dryers on which the invention is based will be described.

Figures 1A and 1B show a fluidized bed dryer 20 through which a drying space 20V bounded by two opposite halves passes a web W, the side of which marked with arrow B is coated and wet. In Figures 1A and 1B, the total heating energy marked on the fluidized bed dryer 20 is denoted by Q.

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Figures 2A and 2B show the principle of the structure of the integrated lnfra fluidized bed dryer. An infrared dryer is connected to the fluidized bed dryer 20, through which the web passes through the non-contact processing space 10V to the processing space 20V of the fluidized bed dryer 20. The infra-unit 10 comprises a radiation-35 unit 10S, in which infrared radiation power is electrically generated, which is applied to the web W passing through the processing interval 10V as a relatively large energy pulse. The infra unit 10 has a radiation unit 10S

5 83848 1 on the opposite side of the web a reflection unit 10R which returns the radiation to the web W. Figure 2A shows a previously known air circulation arrangement of an infrared fluid dryer, the details of which refer to the above-mentioned applicant's FI patent 77707.

Figure 2B shows an air circulation arrangement according to the present invention. In Figures 2A and 2B, Q denotes the thermal energy recovered in the cooling air of the infra unit 10. The reference shows the electrical power to be brought to the infra unit 10.

1Q In tests performed by the applicant with a fluidized bed dryer, it has been found that the water in the wet coating paste on the surface of the paper W escapes heat. First, the web W was dried with the fluidized bed dryer 20 of Fig. 1A so that both halves of the fluid had the same conditions, i.e., the same thermal energy ½Q was blown on the coated wet side P • jjj and the opposite dry side of the paper W. This gave the fluidized bed drying power, which is denoted by 100%. When the web W is a wet paste of the P20 half of the fluidized bed was blown (L n) in Figure IB in accordance with unheated air and the other half conditions were kept in the old (Figure IA) falling from the heating power by half to 50%, 2Q but halhdutusteho only 70 Z cent . In the former case of Fig. 1A the ratio of the evaporation power to the heating energy is 100/100 * 1 and in the latter case of Fig. 1B 70/50 to 1.4, i.e. 40 Z more.

The above observation is applied in the invention to turbolnfra, whereby the efficiency of its fluidized part can be improved by about 40%. To enable this, the invention blows the heated cooling air from the air 10 from the station 10 in place of Figure 2A substantially entirely into the half of the fluidized bed dryer 20 on the dry side of the paper W. the wet part of the paper side P I float arranged 3Q -L separate refrigerant circuit. Thus, the volume volume (m ^ / s) of the hot half rises to about twice as long as the temperature remains the same. The hot side temperature for the heat thus corresponds to 200 leijutehoa Z and Z 70 is the evaporation that is, 0.7 x 2 - 1.4.

The present invention makes it possible to increase the production speed of a coating machine without investing in expensive drying equipment. The provision of a separate air circuit 6 83848 1 for the cold fluidized bed has to be paid for, but significant savings in operating costs are achieved.

Figure 3 shows in more detail an infrared fluid dryer according to the invention.

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As a background, the invention is suitable for use in the coating of papers in which only the other side P of the web is coated. The invention is also suitable for use in the drying of double-sided coating, but in this case the coating must be applied at different stages and the coating equipment may include two the infrastructure of the fluidized • kulvatinta, between which is the other side, in the case of Figure 3 W Raman lower side of the coating station.

-J5 The combined infrared fluid conveyor shown in Fig. 3 comprises an infrared conveyor 10 having two successive infrared drying units 10A and 10B, through which the processing intervals 10V1 and 10Vg pass the paper web W. The infra units ΙΟΑ, ΙΟΒ are followed substantially immediately or at a short distance E by a fluidized bed dryer 20, through which a web W 20 which is supported in contact and at the same time to be dried passes. The passage of the web W through the infrared fluid dryer is illustrated in Fig. 3 by a flat line -W.

In Fig. 3, the infra units 10A and 10B are electrically operated units 25 known per se, having an overhead radiation unit 10S and an opposite counter-cushioning unit 10R, which returns the web W to the transmitted radiation treatment interval 10V and LOV. The infrared radiators 105 of the electrically operated infra units • 101 must be cooled so that their temperature does not rise to a purple high in terms of their durability. Cooling air 30 is supplied through a duct 17 with first a filter unit 11, a control grille 12 and a fan 13 in the air supply direction. The air inlet duct 17 is connected by ducts 16A and 16B to nozzle units 14A and 14B, through which the supply flow F between 10V ^ and 10Vg on both sides of the web W to be dried. The nozzle-35 units 14A and 14B preceding the infra-units 10A and 10B have coanda nozzles as blowing nozzles, followed by bearing surfaces between which i 7 83848 1 the web W passes with support blows FgA and F <, g stably supported.

According to Figures 2A, 2B and 3, the passage of the web W is horizontal as it first passes through the processing intervals 10VA and 10Vg of the infra units 10A and 10B and then through the processing interval 20V of the fluidized bed dryer 20. The passage of the web W can also be vertical or oblique.

According to Fig. 3, the cooling air blown inside the radiation units 10S is not blown into the treatment intervals 10VA and 10Vg, but the circulation of the cooling air is closed in this respect. In connection with the radiators of the units 10S (not shown), the heated cooling air is taken out of the units 10S through the air ducts 18A and 18B as flows FA and Fg. The air system includes control dampers and grilles 19 with which the air volumes can be • set and adjusted. The flow FA and Fg are connected to the duct 18 and led by the fan 21 to a duct 22 with a branch part 22a, through which too much air for the fluidized bed dryer 20 can be blown out of the infrared toy dryer FQut, if necessary.

2Q As shown in Figure 3, the duct 22 leads to the inlet side of the gas burner 23. The gas burner 23 el is often not necessary, but the cooling air of the infrared dryer 10 is generally sufficient for the supply air of the fluidized bed dryer 20. The gas burner 23 on the output side is derived from the channel 24 fluidized ^ £ 20 in the lower case 30 so that the recovered-25 infrakuivattlmen the cooling air taken into the thermal energy Q is used for the whole web of the U and the wet coated side P of the drying energy opposing the dry side. If there is no gas burner 23, the duct 22 is connected directly to the duct 24. Cold circulation is introduced into the upper space 30 of the fluidized bed dryer 20 through the channel 24 and the associated nozzles 25.

Through the channel 24, the flows FC2 are led to the lower nozzle 252 of the nozzle box 32 and through them to the drying and support wall of the fluidized bed 20 on both sides of the treatment space 20V. From the treatment interval 20V, cooled and humidified air is taken through connections 26j and 262 as flows Fgj and Fp2 * and P ° ist ° air is collected in the duct 27.

The fluidized bed dryer 20 of Figure 3 consists of housings 30 and 302 on opposite sides of the web W. The nozzle boxes 31,32 have planar bearing surfaces 35 8 83848 1 which act as either overpressure or underpressure bearing surfaces through which nozzles, preferably coanda nozzles 25 and 25 drying and / or support blowers Fc ^ and F ^ · Between the nozzle box nozzles 31 and 32, the flows Fqj and F ^ »are taken and collected from inside the boxes 31 and 32 into the channel 27.

Moist and cooled air is directed as a flow through the FQ control grille 29 to the suction side of the exhaust air fan 28 and from the pressure side of the fan 28 the air is blown out as a flow FQUt.

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The length E between the infrared dryer 10 and the fluidized bed 20 is not critical in the invention, but preferably the dryers 10 and 20 are placed as close to each other as possible so that at least some of the heated blowdowns F1 and 10Vg FgB W follow the ralna W during its run Wq, the web W enters the processing interval 20V of the fluidized bed conveyor 20. Arrows F illustrate these flows.

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According to Fig. 3, the cold air 20 introduced through the inlet duct 17 is led through the ducts 16A and 16B to the supply blows FgA and Fgg of the web W1. Another alternative is to take the airflows of said escort fans from the air duct 18 or ducts 18A and / or 18B, in which the heated dry air passes in the infra units 10A and 10B.

In the infra units 10A and 10B, a relatively short pulse of drying energy is preferably applied to the web W per unit area, preferably substantially higher than the average wear power of the dryer. The water vaporized by this energy • pulse in the web W is mainly released from the runner W only in the passage interval 20V of the fluidized bed conveyor 20, where the ralna W is flushed while supporting it with a dry air jet.

The details of the structure of the infrared dryer 10 and the Lei dryer 20 have not been described in detail above, but they can be found, for example, in the applicant's FI publications Nos. 35 The length L of the fluid unit 20 is mainly determined by the drying need and how much cooling air the fluid units 10A and 10B produce.

9 83848 f Figure 3 shows two infra units 10A and 10B in succession.

It is to be understood that within the scope of the invention, there may be only one Infrastructure Unit or more than two consecutive units may be used.

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The invention also includes embodiments in which a smaller number of lnfrakuivattimen the recovered heat energy Q is also applied to the coated side of the web W P leijulaatlkkoon the supporting and drying air. In this case, in Fig. 3, a chokeable one can be led from the channel 22 or 2 to the channel 24.

The following claims set forth within the scope of the inventive idea, the various details of the invention may vary and differ from those set forth above by way of example only.

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Claims (8)

A method for non-contact drying of a paper or board web (V), which method uses both infrared radiation and air jets to be dried to support the web (W) moving through the dryer (10,20) in a non-contact manner, preferably bilaterally, wherein the web (W) ) is directed first to the infrared drying interval or intervals (10VA, 10VB) and then to the fluid drying interval (20V) and in which method the infrared radiators (105) of the infrared drying unit or units (ΙΟΑ, ΙΟΒ) are cooled by air flows (F ^ .F ^) and in which method a closed infra-drying unit or units (ΙΟΑ, ΙΟΒ) are used before the fluidized bed dryer (20) in such a way that the cooling air is not led to at least a substantial amount of infrared drying interval (10VA, 10VB), in addition to the infra-drying unit (s) cooling air is conducted infrak uivatinta next fluidized bed (20) of the nozzles (25, 252) drying and kannatusilmapuhalluksiksi its drying gap (20V), characterized in that the infrared dryer (10) of the cooling air the recovered heat energy (Q) is essentially a whole is passed fluidized bed (20) in its side (302 ) 20 heating energy, which is half (302) is on the opposite side of the coated dry the wet side (P) of the web (W). 1 Claims A method according to claim 1, characterized in that: the half of the fluidized bed dryer (30,) which is the web (W) to be dried On the coated side (P), cold, and preferably dry, air is passed through the duct (24,) for use in a fluidized bed dryer blower; you (Fcl). Method according to Claim 1 or 2, characterized in that the thermal energy recovered in the cooling air of the infrared dryer is conducted completely to the coated wet side (P) of the web (W) to be dried, opposite to the fluidized bed (20) side (302). Method according to one of Claims 1 to 3, characterized in that the thermal energy (Q) recovered in the cooling air of the infrared dryer (10) is conducted to the lower half (302) of the fluidized bed dryer (20). 11 83848 Method according to one of Claims 1 to 4, characterized in that in the method the evaporating power of the fluidized bed dryer (20) is increased by about 40% compared with the heat energy (Q) recovered in the cooling air of the previous infrared dryer (10) being distributed equally. le to the halves (30,, 30,) of the fluidized bed dryer (20) opposite to the coated web. Method according to one of Claims 1 to 5, characterized in that the fluidized bed dryer (20) does not use any thermal energy other than the thermal energy (Q) recovered in the cooling air of the infrared dryer (10) preceding the jQ. Method according to one of Claims 1 to 5, characterized in that the air supplied to the fluidized bed dryer (20) is heated in addition to the infrared radiators by a separate heating device, preferably a gas burner (23) or a steam heat exchanger. A method according to claim 7, characterized in that the cooling air of the infrared dryer (10) containing the thermal energy (Q) recovered from the infrared dryer 2Q is led to a duct (22) leading to the inlet side of the gas burner (23), steam heat exchanger or other similar heating device, and that said gas burner (23) or the like lämmityslaitten the output side is derived from the channel (24) and the air flow rate (Fc) of the web (W) coating the wet side for use (P), left-to 25 dry side of the opposing supporting and drying air. 30 35 i2 83848