DE202009017286U1 - Apparatus for drying plasterboard - Google Patents

Abstract

Device for drying plates,
with a conveyor for conveying arranged in floors plates by the device with main drying stage 20 and final drying stage 21st
- With at least two drying chambers 43
- Each drying chamber has transversely to the transport direction arranged in rows nozzle boxes
- With arranged in the chambers 43 Umluftkanälen having funding and heating devices for the circulating air, and means for supplying supply air and means for discharging exhaust air
characterized in that
- Between main drying stage 20 and final drying stage 21, a supply device is arranged, which directs exhaust air from the main drying stage 20 in the final drying stage 21.
- A single and or more, but a maximum of half of the drying chambers 43 are equipped with controllable supply means with which the exhaust air from the main drying stage 20 is assigned to these
- A single and or more, but a maximum of the second half of
- Drying chambers, equipped with adjustable drainage devices, with ...

Description

The The invention relates to a device for drying plate-like Materials, in particular plasterboard.

The Drying of such plate-like materials occurs in most Cases by a predominantly convective heat transfer in the form of overflow of heated Air. The plates are there, often over several floors distributed, with the help of conveyors such as roller conveyors or Sieve belts passed through the dryer.

To In the prior art, drying systems are usually in recirculation mode operated. The drying air is thereby introduced several times to the plates and reheated after each contact. The air enriches in this way increasingly with moisture, only a small one Part of the drying air is discharged to the environment as exhaust air to dissipate moisture and fumes into the environment.

One Distinguishing feature of different types of dryer forms the Type of air flow over the material to be dried. The Air can be essentially in the form of a transverse ventilation, a longitudinal ventilation, or a so-called Impounded jet ventilation to be guided to the plate.

at the cross ventilation is the drying air from the side, transverse to the conveying direction of the plate-like material, over led the Trocknungsgut. As the drying air at increasingly cooling their way over the drying material, This results in different drying speeds across the width. Therefore, this procedure is used on sensitive materials such as Plasterboard not used.

at the longitudinal ventilation moves over the drying air a long way along the longitudinal axis of the dryer, overflowed while the plate, it dries and cools it strongly from. The drying air can thus at low temperatures, energetically particularly favorable near the dew point of the drying air, be dissipated. For heating fresh air With the help of a heat exchanger can then specifically condensation heat be used.

at The impingement jet ventilation is the drying air from the Side of the drying plant in air ducts, so-called nozzle boxes, introduced and via air outlet nozzles blown perpendicular to the surface of the drying material. From there, this air flows to the opposite Side of the drying plant.

After similar Construction of working dryers are now widely used worldwide. Their advantages include that through the construction from many, relatively short drying chambers, which each individually ventilated and can be heated, the desired drying temperature and the climate over the length of the dryer free can be chosen. Thus, the Drying conditions to the needs of the drying material be adjusted. The dryer is also, z. When changing products, perfectly controllable.

By the good heat transfer at the impact jet inflow Such dryers can be built much shorter are overflowed as comparable with longitudinal ventilation Dryer.

By Adjusting the nozzle box tilt can also be a very uniform drying across the width be achieved of the material to be dried.

The Exhaust air from each chamber is discharged and collected individually. Since below also chambers with process-related high drying temperatures belong, results in a total high exhaust air temperature. Also, using a heat exchanger, the in The condensation heat contained in the exhaust air humidity hardly makes sense be used.

Such a facility is in the DE 19 46 696 A1 described under the title of a process and apparatus for accelerated drying of gypsum boards. The document deals with the description of the dryer chamber, which is designed so that the highest possible heat input and the most uniform possible drying over the width of the material to be dried is guaranteed. However, measures to reduce energy consumption are not mentioned.

From the DE 26 13 512 A1 is a two-stage drying process and a drying plant is known, which has the object to modify the per se known two-stage drying process or supplement so that in particular plasterboard or goods with similar properties can be dried economically with this device.

at the two-stage drying process becomes the second drying stage with the interposition of a heat exchanger from the exhaust air the first dryer stage heated. The plates should be in the first Dryer stage with high temperature and high humidity and in the second dryer stage with relatively low temperature and lower Humidity are dried. The first stage is here longitudinally ventilated, the second stage cross-ventilated. The impingement jet ventilation is not applied.

Although it can be a very with this design realize low consumption. Due to the indirect heating of the 2 stage, the temperature level is very low. Accordingly, there is a low dryer performance and a high consumption of capacity. The dryer has therefore been unable to prevail in practice.

Furthermore, from the DE 43 26 877 C1 a method for drying plates and a corresponding dryer known.

Based on the method according to DE 26 13 512 A method with the lowest possible primary and secondary energy consumption is presented. In particular, the primary energy used should be kept as low as possible by utilizing the waste heat and the heat of condensation of the exhaust air, without increasing the need for secondary energy by circulating large air mass flows.

Solved Here is this task in that in the stage B, the exhaust air the level A by a arranged in the floors of the dryer Heat exchanger is passed and the drying air with lower Temperature and low humidity in countercurrent to the exhaust air of Level A is performed.

The responsible for the cooling of the exhaust air stage B, however, has no impingement jet ventilation here and Indirect heating is the drying power of the stage B low.

Of the inventive device is therefore the Task underlying plate-like materials as possible low energy consumption by means of impingement jet ventilation gently to dry. It is desirable to existing plants as possible change cost within the meaning of the invention to be able to.

These The object is achieved with a device according to claim 1.

The Device according to the invention is hereinafter described in more detail, showing in detail:

1 : a section through a drying chamber according to the invention

2 : an exemplary functional diagram of a generic conventional dryer

3 : A functional diagram of the dryer according to the invention

4 : A schematic diagram in plan view to the air guide in the dryer according to the invention

5 By way of example, a functional diagram of an advantageous modification of the dryer according to the invention

6 By way of example, a functional diagram of a further advantageous modification of the dryer according to the invention

7 Detail illustration of the wall flaps

1 shows a section through a drying chamber according to the invention.

The arrows indicate the direction of flow of the drying air. Preheated fresh air is the burner 1 as combustion air 2 and mixed air 3 fed. Gas and oil are used as fuels. At this point, instead of the burners, steam or thermo-oil heated heating coils are also used. The air is then heated indirectly.

The forwarding of the burner 1 heated air in the pressure room 5 via the recirculation fan 4 , The pressure room 5 It is used to evenly distribute the air into the individual floors of the drying room 6 , The air is initially in so-called nozzle boxes 7 pressed, of which they over hole nozzles 36 for the sake of clarity, only in the upper drying level of the drying room 6 are shown, which are arranged on the upper or lower side of the nozzle box, perpendicular to the plates 8th is blown. The plates 8th be with a transport device 33 conveyed perpendicular to the viewing plane.

To ensure a uniform distribution of air across the width, the nozzle boxes are tapered running. Above and below the plates 8th the air then flows into the suction chamber 9 , A part of the air, which in total corresponds in essence to the combustion gases, the fresh air and the steam generated by the drying, escapes via the exhaust air discharge 10 , At the burner 1 closes the circulating air circuit. The area above pressure room 5 and suction room 9 , as well as from the drying room 6 is also called overhead 11 designated. In normal drying chambers, adjacent drying chambers in the pressure and suction chamber, as well as in the overhead 11 delimited by closed boundary walls, in the 1 It can be seen that the drying chamber according to the invention 43 from the next chamber via one or more wall flaps 34 In the suction room 9 is disconnected. For example, five flaps are shown here. This wall flaps 34 each is a wall flap control 37 assigned to specifically control the air supply in the next chamber or in the next dryer area.

Because of the recirculation fan 4 in every Drying chamber, a substantially circular running air flow is formed and a part of the air flow through the wall flaps 34 in the, a certain drying chamber 43 following, next drying chamber 43 passes, additionally creates an air flow in the longitudinal direction of the Endtrockenbereichs 21

2 shows an example of a functional diagram of a generic conventional dryer

On the right side of the 2 is a feeder 12 to recognize on which the drying material passing through the dryer, for example a series of plasterboard, is delivered. The dry material then passes through a series of dryer chambers 43 the drying area 14 last to the dryer via a sampling device 16 to leave.

Triangles mark the heating devices 17 of the individual chambers The exhaust air of the individual chambers 43 will be in a manifold 18 collected. Since the exhaust air is also removed chambers in which is dried at very high temperatures, eg. B. 220-300 ° C, the collected exhaust air is still very hot, z. 150-250 ° C.

Even if, as shown, the exhaust air in a heat exchanger 19 is used for process air heating, so mainly the so-called sensible heat is transmitted. The evaporation heat hidden in the water vapor is thus hardly or not at all used. A low energy consumption in the context of the invention can not be achieved.

3 shows a functional diagram of the dryer according to the invention.

The feeders 12 and removal device 16 are not shown here for the sake of clarity. In the Vorzone area 13 The plates are made using in the heat exchanger 19 heated fresh air through the fresh air line 40 preheated. This reduces energy consumption.

The plates then pass through the main drying stage 20 wherein the circulating air has temperatures of 150 ° C-350 ° C before contact with the plates and 120 ° C-300 ° C after contact with the plates. Depending on the chamber, the humidity of the circulating air in this stage is between 150 g / kg to 850 g / kg.

The final drying takes place in the final drying stage 21 instead of. The sealing area 15 , Advantageously reduces the unwanted escape of drying air through the dryer outlet.

With the in the individual chambers 43 protruding arrows are the heating devices 17 the individual drying chambers 43 shown.

It can be seen that not all chambers of the final drying stage 21 a heating device 17 exhibit. It is envisaged that these are not used in the operation according to the invention or with the lowest power for control. The pipes for mixed air 3 and combustion air 2 are also shown.

According to the invention as little as possible mixed air 3 are used, ideally the mixing air flaps 41 closed.

Sense of dividing the drying area into a main drying stage 20 and a final drying step 21 The intention is to remove the exhaust air of each chamber 43 the main drying stage 20 to collect and in place in the final drying stage 21 initiate at which the high temperature of the collected exhaust air, provided are 150 ° C to 250 ° C at a humidity of 200-800 g / kg, reasonable and permissible, the energy of the hot air through a clever air duct for drying in the final drying stage 21 to use and finally the air at a much lower temperature, are provided 80 ° C-130 ° C at a humidity of 250-850 g / kg, to remove at the point where such a low temperature is required anyway.

Depending on the dry material, between 10 and 30% of the drying capacity is in the final drying stage 21 be provided.

There many dry goods, especially plasterboard, against Dry at the end of drying at low temperatures need to prevent overdrying that leads to damage to the dry material.

The 3 shows as the exhaust air of the main drying stage 20 in the manifold 22 is collected, then by a fan 23 into the distribution line 24 to the final drying stage 21 to be guided. Here is the bypass control flap 25 closed, the damper A 26 is open. The air is over several supply lines 27 in the final drying stage 21 directed. Here are the flaps 38 the supply lines are regulated so that most of the air enters the first chambers of the final drying zone 21 is initiated. For this purpose, the left in the diagram arranged inlet valves 38 as far as possible open, the right discharge control valves 39 throttled as possible. It is envisaged that 1 or more of the chambers in the front of the final drying stage 21 with such leads 27 be equipped. The air is then through 1 or more exhaust ducts 28 from the back of the final drying stage 21 dissipated.

The control flap 29 between the distribution line 24 and the manifold 30 is closed in the operation of the invention, or throttled.

Here are the flaps 39 the exhaust ducts 28 adjusted so that the largest part of the exhaust air in the last chambers 43 the final drying stage 21 is derived. These are the right in the illustration arranged exhaust air valves 39 wide open, the left inlet flaps 38 throttled. It is envisaged that one or more of the chambers 43 the final drying stage 21 with such derivatives 28 be equipped. About a manifold 30 conveys an exhaust fan 31 the air through a heat exchanger 19 for fresh air preheating to the outside. Due to the low exhaust air inlet temperature into the exchanger, the energy for fresh air heating now comes to a considerable extent from the condensation heat of the exhaust air.

The bypass line 32 is used when air must be discharged directly into the exchanger. For this purpose, the bypass control flap 25 opened, the damper A 26 closed and the control flap B 29 open. The ventilator 23 will be turned off. This is the case, for example, in the case of exceptional operating conditions (startup and shutdown of the system, product changes). The dryer can thus be regulated more favorably for these conditions

4 shows a schematic diagram of the air flow within the dryer according to the invention.

From the air supply 27 the air enters the suction chamber 9 and mixes there with the circulating air located there. The excess part of the air, in the amount in essen- tial the sum of the supplied exhaust air, and the evaporated water according to the suction chamber of the adjacent, located in the transport direction drying chamber 43 sucked. The side walls of the suction chamber, as well as the side walls of the area of the overhead 11 to the circulating air fan 4 , each to the adjacent Trochnungskammern 43 There are over the wall flaps 34 adjusted to allow the most efficient passage of this air. The circulating air is via the circulating air fan 4 in the pressure room 5 directed and distributed from there to the individual nozzle boxes. The side walls of the pressure room 5 are closed.

In the actual drying room 6 the side boundary surfaces of the chambers are sealed so that essentially only the plates can pass through. According to the invention, the passage openings, not shown here for reasons of clarity, are adjustable and / or adjustable, depending on the thickness of the continuous plates of the material to be dried plus tolerance. This is necessary to achieve uniform drying across the width of the plates. The cooled by the drying air and the water vapor flow past the plate back into the suction chamber 9 , There, the circulating air circuit closes. This process is repeated in the following drying chambers with the difference that here also the drying air of the previous chambers is mixed.

The derivative 28 works analogously. Air is here the suction 9 taken, another part of the drying air in the subsequent chamber 43 sucked. In the last chamber 43 the drying air is discharged.

5 shows an example of an advantageous modification of the dryer according to the invention.

Here every chamber has 43 via its own exhaust air supply 27 and exhaust air discharge 28 , This arrangement is advantageous if the supplied amount of exhaust air is so large that when entering the chamber 43 the final drying stage 21 , As well as the passage from chamber to chamber would result in large pressure losses or if the temperature profile must be moved so from drying technical reasons, that in the first half of the chambers 43 the final drying stage 21 with something lower, in the second half of the chambers 43 but should be dried with slightly higher temperatures than it is in 3 the case is. According to the invention, the dryer is adjusted to 60-100% in the first half of the final drying stage 21 60-100% in the second half of the final drying stage 21 is derived.

This modification also includes a bypass line 32 , with the excess exhaust air directly to the heat exchanger 19 can be derived. This is the case for exceptional operating conditions see 3

6 shows by way of example a further advantageous modification of the dryer according to the invention.

at some dry goods, such. B. ceiling panels it is possible and useful, towards the end of drying with high Temperatures, z. B. 150-250 ° C to dry. This is z. As is the case when the good is not due to the high temperatures is damaged and if the good a low thermal conductivity has.

The Air can then not in the rear area at low temperatures Accordingly, no exhaust air can be used for final drying become.

As the figure shows, it is possible by mirroring the arrangement of the final drying stage 21 and the main drying stage 20 to modify the dryer so that the exhaust air from the now downstream main drying stage 20 in the now upstream final drying stage 21 the dryer can be used for heating the goods and for predrying. The Vorzone 13 does not make sense for the post-drying and is eliminated.

The passage of exhaust air from chamber 43 to chamber 43 in the suction room 9 takes place opposite to the transport direction.

7 , shows a detailed representation of the wall flaps.

In the description of 1 it was noted that the flow conditions in the final drying stage 21 Almost arbitrarily adjustable and can be adapted in real time to changing operating parameters. Another way to influence these flow conditions targeted consists in a particular embodiment of the wall flaps 34 , Thus, by changing the profile or the cross section in the manner of a wing profile of one or more wall flaps 34 a direct influence on the flow velocity of passing air can be achieved. An aerodynamic equivalent represent the pressure conditions on the underside and the top of a wing in aircraft. By means of corresponding flow sensors 35 Thus, further control parameters, such as the speed of the flowing air, can be detected immediately.

1

burner

2

Combustion air line

3

Mixed air line

4

circulation fan

5

pressure chamber

6

drying room

7

nozzle boxes

8th

plates

9

suction

10

exhaust air discharge

11

overhead

12

feeder

13

Vorzonenbereich

14

drying area

15

sealing area

16

removal device

17

heating devices

18

Exhaust manifold

19

heat exchangers

20

Main drying stage A

21

final drying stage B

22

manifold A

23

fan

24

distribution line

25

Bypass damper

26

control flap A

27

air supply

28

exhaust duct

29

control flap B

30

manifold B

31

exhaust fan

32

bypass line

33

transport means

34

wall flaps

35

flow sensors

36

hole nozzles

37

Wall flap control

38

Zuluftregelklappen

39

Exhaust air dampers

40

Fresh air line

41

Mixed air control dampers

43

drying chamber

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 1946696 A1 [0012]
• DE 2613512 A1 [0013]
• - DE 4326877 C1 [0016]
• - DE 2613512 [0017]

Claims (9)

Device for drying plates, with a conveyor for conveying plates arranged in floors through the device with main drying step 20 and final drying stage 21 - each with at least two drying chambers 43 - Wherein each drying chamber has transverse to the transport direction floor-mounted nozzle boxes - with in the chambers 43 arranged recirculation ducts with conveying means and heaters for the circulating air, and means for supplying supply air and means for discharging exhaust air, characterized in that - between the main drying stage 20 and final drying stage 21 a supply device is arranged, which exhaust air from the main drying stage 20 in final drying stage 21 passes. - A single and or more, but not more than half of the drying chambers 43 , equipped with adjustable feeders, with which the exhaust air from the main drying stage 20 a single and or more, but at most the second half of the - drying chambers, equipped with controllable discharge facilities, with which the exhaust air from final drying stage 21 this can be removed. - The feeder between main drying stage 20 and final drying stage 21 equipped with a conveyor. - In final drying stage 21 on the suction side of the drying chamber 43 the boundary surfaces to the adjacent drying chamber 43 of the same section are open. Apparatus according to claim 9, characterized in that the collecting line A 22 with the distribution line 24 through a bypass line 32 and a control flap A 25 are connected and the distribution with the manifold B 30 with a control flap B 29 connected to each other. Apparatus according to claim 9, characterized in that - the distribution line the entire final drying stage 21 covering and every chamber 43 has a controllable connection - The manifold B 22 the entire final drying stage 21 covering and every chamber 43 has a controllable connection. Apparatus according to claim 1 to 3 characterized by a Vorzonebereich 13 , which before the main drying stage 20 and final drying stage 21 is arranged. Device according to one of claims 1 to 4, characterized in that in the transport direction of the final drying section 21 before the main drying stage 20 is arranged. Device according to one of claims 1 to 5, characterized in that the transport device 33 consists of sieve bands. Device according to one of claims 1 to 6, characterized in that the suction-side openings between the drying chambers 43 be designed as adjustable flaps. Device according to one of claims 1 to 7, characterized in that each drying chamber 43 one or more differently sized, in the longitudinal direction and or in the transverse direction of the drying chamber arranged, wall flaps 34 having. Apparatus according to claim 8, characterized in that at least one wall flap 34 each having a wall flap control, and that at least one wall flap has a fluidically active active surface and a flow sensor.