EP2257751A1

EP2257751A1 - Dryer for material to be dried

Info

Publication number: EP2257751A1
Application number: EP09723198A
Authority: EP
Inventors: Franz Anibas
Original assignee: Binder and Co AG
Current assignee: Binder and Co AG
Priority date: 2008-03-19
Filing date: 2009-03-19
Publication date: 2010-12-08
Anticipated expiration: 2029-03-19
Also published as: CA2717838C; RU2010138094A; CN102016471B; US8800161B2; PL2257751T3; US20110035955A1; EP2257751B1; CA2717838A1; AT10660U1; RU2490572C2; WO2009115564A1; CN102016471A

Abstract

A dryer for material to be dried (T), wherein an air supply channel (4) for supplying a drying gas to the drying region is provided, and at least one exhaust-gas opening (8) is provided for removing the drying gas, wherein the air supply channel (4) is surrounded at a distance by an outer wall (11), which has at least one supply opening (12) and at least one removal opening (13) for the cooling medium (K), wherein between the at least one supply opening (12) and the at least one removal opening (13) a flow section (14) for the cooling medium (K) is formed between the outer wall (11) and the air supply channel (4). According to the invention, the at least one removal opening (13) is configured as a through-opening in the air supply channel (4), which connects the region bounded by the outer wall (11) to the interior of the air supply channel (4), wherein the at least one through-opening (13) is arranged in the upper regions of the air supply channel (4) and is configured in such a way as to make it possible for the cooling medium (K) to flow downwards along the inner side of the air supply channel (4).

Description

Dryers for drying material

Field of the invention

The invention relates to a dryer for Trocknungsgut with a feed point for the Trocknungsgut, a drying area, and a delivery point for the Trocknungsgut, wherein a supply air duct for the supply of a drying gas, preferably drying air, is provided to the drying area, and at least one exhaust port for the discharge of the drying gas after passing through the drying area, wherein the supply air duct is at least partially surrounded by an outer wall having at least one supply opening for the supply of a cooling medium and at least one discharge opening for the cooling medium is provided, and between the at least one supply opening and the at least one discharge opening a flow path for the cooling medium between the outer wall and the supply air duct is formed, according to the preamble of claim 1.

State of the art

Dryers of this type are used, for example, in the minerals industry, where drying material is dried by hot drying air at temperatures of several hundred degrees. The dryers can be designed differently, such as drum, belt, stationary fluidized bed, vibratory fluid bed or disc dryer. In a vibration-excited fluidized bed dryer, for example, the material to be dried is transported by vibration via a distributor plate accommodated in a housing. The housing is thereby vibrated via spring assemblies and a corresponding vibration drive. The dryer is supplied via a supply air drying air drying, which was heated by means of a hot gas generator. The supply air duct is usually located in the lower areas of the dryer, and the exhaust port in the upper areas of the Trockners, so that the drying air flows through on their way from the supply air duct to the exhaust ports, the distributor plate and the conveyed thereon Trocknungsgut, while drying the drying material.

Since due to the supply of hot drying air disposed within the housing supply air duct heated, the protective components of the housing to be protected with an inner insulation, mostly of stone or mineral wool, surrounded. The supply air duct is designed as a screwed inner trough made of heat-resistant steel sheets. However, this has the disadvantage that at the prevailing interior temperatures of the inner trough experiences a particularly high thermal expansion, and thereby strongly discards the progress of service life, and even break at individual points. Due to the high temperatures, inner trough fastening screws can also be loosened or, after a certain period of operation, can no longer be dismantled non-destructively. Furthermore, the introduced inner insulation is slowly destroyed by vibratory stress in vibration-induced dryer types, loses insulating effect with increasing operating time and must be renewed. After all, these types of dryers can not be cleaned with water on the inside, as the insulating layer would become completely saturated with water, which would have a very negative impact on the vibration behavior and the insulation effect.

DE 26 08 228 A1 discloses a furnace for baking ceramic plates. The oven has a tunnel receiving the objects to be baked, and a lower box fed with hot gases thereunder. The pressurized hot gases are forced through a porous floor from the lower box into the tunnel, whereby the objects to be baked are lifted off the ground and levitated. An outer wall is provided which surrounds both the tunnel and the lower box. The lower box is thus surrounded by the outer wall, wherein between the inner wall and outer wall, a cooling fluid, eg air circulates. The cooling air flow enters the floor laterally, is guided by horizontally extending channels within the floor, and then passes through the top of the floor and rises in the direction of the tunneling material to be backed up the tunnel.

In the system according to DE 26 08 228 Al is a system with a closed circuit. The introduced by means of a blower in the system, mixed with the hot gas cooling air is sucked in via a arranged in the ceiling region of the tunnel circulation channel and transported back into the lower box. To this end, the provision of a circulation device, e.g. a suction jet pump or an injector required.

The (cooling air) area between the outer and inner wall is connected to the lower box 3 by a tubular circulation channel.

AT 384 349 B discloses a drying plant in which the drying chamber or its baffles are equipped with cooling elements through which cooling liquid circulates.

It is the object of the invention to avoid the disadvantages of known drying systems and to realize a dryer which ensures adequate cooling of the supply air duct for the drying air without the use of an insulating material. It should be excessive thermal expansion of the

Supply air channel avoided, and thus the material stress can be reduced. Furthermore, the maintenance is to be reduced by the replacement of the insulating material can be avoided. Through improved cooling of the

Supply air duct and a lower heating of the load-bearing

Housing parts should also be achieved an increase in the carrying capacity. Finally, the cleaning should be made possible with water, which the operation of an inventive

Dryer should facilitate. PRESENTATION OF THE INVENTION

These objects are achieved by the features of claim 1. Claim 1 relates to a dryer for Trocknungsgut with a feeding point for the Trocknungsgut, a drying area, and a delivery point for the Trocknungsgut, wherein a supply air duct for the supply of a drying gas, preferably drying air, is provided to the drying area, and at least one exhaust port for the discharge the drying gas after passing through the drying region, wherein the supply air duct is at least partially spaced from an outer wall having at least one supply port for the supply of a cooling medium and at least one discharge opening for the cooling medium is provided, and between the at least one supply port and the at least a discharge opening a flow path for the cooling medium between the outer wall and the supply air duct is formed. According to the invention, it is provided that the at least one discharge opening is designed as a passage opening in the supply air channel, which connects the area bounded by the outer wall with the interior of the supply air duct, wherein the at least one passage opening in the upper regions of the supply air duct is arranged and designed to to allow a flow of the cooling medium along the inside of the supply air duct down.

The cooling air thus flows after entering the supply air duct along the inner walls of the supply air duct downwards, thereby forming a "cold air curtain" between the hot drying air and the inner wall of the supply air duct, which causes a particularly effective cooling of the supply air duct.

The supply air duct is thus effectively flowed around by a cooling medium, and causes in this way the cooling of the supply air duct, rather than to prevent the use of an insulating material heat transfer to housing parts. The cooling of the supply air duct also prevents excessive thermal expansion, so that Material stresses can be kept behind. In addition, the dryer can also be made shorter, since due to the improved cooling an increase in the drying air temperature is possible.

In order to promote the formation of a cold air curtain, guide plates for the cooling gas can be arranged in the region of the passage openings.

According to an advantageous embodiment of the invention, the cooling medium may be a cooling gas, and at least one discharge opening as a passage opening in the supply air channel, which connects the limited area of the outer wall with the interior of the supply air duct, be executed. The cooling gas is preferably cooling air. By means of the passage openings, the cooling air is conducted into the interior of the supply air duct, where, however, it does not cause a significant reduction in the temperature of the drying air.

According to an advantageous development of the invention, provision may be made for at least one discharge opening to be directed towards the area of the drying area facing the delivery location. In these areas, the drying material is already comparatively hot, so that the low temperatures of the cooling air sufficient to dissipate residual moisture in the drying material. The cooling medium thus fulfills not only its cooling function but also the function of a post-drying.

The invention is particularly advantageous when the dryer is a fluid bed dryer, in particular a vibratory fluidized bed dryer.

In a special embodiment, the at least one supply opening is arranged below the supply air duct. BRIEF DESCRIPTION OF THE FIGURES

The invention is explained in more detail below with reference to possible embodiments with reference to the accompanying drawings. It show here the

1 is a schematic side view of an embodiment of a dryer according to the invention,

2 shows the embodiment of a dryer according to the invention according to FIG. 1 seen from the left side of FIG. 1,

3 is a detail detail illustrating the passage openings in the supply air duct,

Fig. 4 is a diagram for a possible drying plant with a dryer according to the invention, and the

FIG. 5 shows an alternative embodiment in comparison to FIG. 1, in which the discharge opening is directed towards the area of the drying area facing the discharge location, and the cooling medium thus also fulfills the function of after-drying.

WAYS FOR CARRYING OUT THE INVENTION

Fig. 1 shows an embodiment of a dryer according to the invention with reference to a vibration-excited fluidized bed dryer with a housing 1, which is offset by spring assemblies 2 and a corresponding vibration drive 3 in vibration. The dryer has a feed point 9 for the material to be dried T, as well as a delivery point 10 for the material to be dried T, wherein the drying material T passes through a drying region between the feed point 9 and the delivery point 10.

The dryer is further supplied via the supply air opening 6 of a supply air duct 4 drying air, which was heated by means of a hot gas generator 5 (see Fig. 4). Of the Supply air duct 4 is usually located in the lower areas of the dryer, and is bounded above by a distributor plate 7, such as a perforated plate bottom, on which the drying material T is transported. Because of its trough-like design, the supply air duct 4 is also often referred to as "inner trough" and is firmly connected to the housing 1 (see also Fig. 3.) The exhaust gas openings 8 for the removal of the drying gas are generally located in the upper regions of the drying gas Trockners, so that the drying air flows through on their way from the supply air duct 4 to the exhaust ports 8 the distributor plate 7 and the drying material T conveyed thereon, and thereby drying the drying material T.

The supply air duct 4 is at least partially surrounded by an outer wall 11 spaced apart (see also Fig. 2), the at least one feed opening 12 for the supply of a

Cooling medium K, as well as at least one discharge opening 13 is provided for the cooling medium K, wherein between the at least one feed opening 12 and the at least one discharge opening 13, a flow path 14 for the cooling medium K between the outer wall 11 and the supply air duct 4 is formed.

The at least one discharge opening 13 is through

Through openings formed in the supply air duct 4 between the area bounded by the outer wall 11 and the supply air duct 4. The cooling medium K is about cooling air, which will generally have room temperature.

According to the invention, it is provided that the at least one discharge opening 13 is designed as a passage opening in the supply air duct 4, which connects the area delimited by the outer wall 11 to the interior of the supply air duct 4, wherein the at least one passage opening 13 is arranged in the upper regions of the supply air duct 4 and is designed to allow a flow of the cooling medium K along the inside of the supply air duct 4 down.

As can be seen in FIG. 3, the flow of the cooling air K runs downwards along the inside of the supply air duct 4, wherein guide vanes can also be provided for this purpose, which support the formation of a favorable flow path. Such a design of the discharge opening 13, a cold air curtain is formed, which effectively protects the inside of the supply air duct 4 against excessive heat load.

A strong heating of the supply air duct 4 can be prevented, and thus a strong thermal expansion of the steel sheets of the supply air 4. The cooling air K mixes with the drying air within the supply air duct 4, but causes only a slight reduction in their temperature. The cooling air K finally escapes together with the drying air through the distributor plate 7.

As can be seen in FIG. 3, throttles 15 may be provided in the vicinity of the feed opening 12, said throttles being formed approximately through openings in spacer strips extending along the longitudinal direction of the dryer. The throttles 15 favor a uniform flow of the cooling air K along the flow path 14 to the discharge openings 13. Throttles 16 may also be provided in the discharge openings 13.

Finally, FIG. 4 shows an embodiment of a possible drying plant for drying material T with a dryer according to the invention, which is located in the center of the image in FIG. 4. The dryer is supplied via the feed point 9 a drying material T, such as calcium carbonate, which leaves the dryer again via the delivery point 10. The dryer is further supplied with drying air that has been heated by means of a hot gas generator 5. The hot gas generator 5 has for this purpose a burner 17 which is supplied with fuel B, preferably gas or oil. The fuel supply is controlled via a control unit 18. The hot gas generator 5 furthermore has an ignition gas unit 31. By means of a first blower 19, combustion air V is supplied to the hot gas generator 5. Optionally, a muffler 20 may be provided here. FIG. 5 furthermore shows an alternative embodiment in comparison to FIG. 1, in which the discharge opening 13 is directed onto the region of the drying region facing the delivery location 10. In these areas, the drying material is already comparatively hot, so that the low temperatures of the cooling air sufficient to dissipate residual moisture in the drying material. The cooling medium thus fulfills not only its cooling function but also the function of a post-drying.

The drying air is supplied to the lower regions of the dryer the supply air duct 4, and discharged via exhaust ports 8, which are located in the upper region of the dryer. On its way from the supply air duct 4 to the exhaust gas openings 8, it flows through the inflow base 7 and the drying material T conveyed thereon. The drying air is subsequently fed to a filter and / or separator 21, which deposits components of the drying material T entrained with the drying air. These portions can be removed via an outlet 22. The filtered drying air leaves the separator 21 via the line 23, passes through a second fan 24, and is discharged via a muffler 25 as exhaust air. Before entering the separator 21, fresh air F may be added to the drying air to control the temperature of the drying air. For this purpose, a flow regulator 26 may be provided, which is controlled by a temperature sensor 27. Another sensor 28 monitors the drying air after passing through the dryer and regulates the control unit 18 for the fuel via a flow regulator 29. The flow regulator 29 is further controlled by a further sensor 30, which monitors the temperature of the drying air before entering the dryer.

For the cooling of the supply air duct 4 provided according to the invention, a further blower 32 is provided, which draws in fresh air as cooling medium K and supplies it to the supply air duct 4 via the supply opening 12 (not visible in FIG. 4). The cooling air K in this case has approximately room temperature. By means of the invention, a dryer is thus realized which ensures effective cooling of the supply air channel 4 without the use of an insulating material. In this case, excessive thermal expansions of the supply air duct 4 can be avoided, and thus the material stress can be reduced. Furthermore, the maintenance can be reduced because the replacement of the insulating material, or the supply air duct 4 can be avoided. By an improved cooling of the supply air duct 4 and a lower heating of the supporting housing parts, an increase in the carrying capacity can furthermore be achieved. Finally, cleaning with water is possible, which additionally facilitates the operation of the dryer according to the invention.

Claims

PATENT APPLICATIONS

1. dryer for Trocknungsgut (T) with a feed point (9) for the Trocknungsgut, a drying area, and a delivery point (10) for the Trocknungsgut (T), wherein a supply air duct (4) for the supply of a drying gas, preferably drying air to Drying region is provided, as well as at least one exhaust port (8) for the discharge of the drying gas after passing through the drying area, wherein the supply air duct (4) at least partially surrounded by an outer wall (11) is spaced, the at least one feed opening (12) for the supply a cooling medium (K), and at least one discharge opening (13) for the cooling medium (K) is provided, and between the at least one feed opening (12) and the at least one discharge opening (13) a flow path (14) for the cooling medium (K ) between the outer wall (11) and the supply air duct (4), characterized characterized the at least one discharge opening (13) as a passage opening in the supply air duct (4) which connects the area delimited by the outer wall (11) to the interior of the supply air duct (4), wherein the at least one passage opening (13) is arranged and executed in the upper regions of the supply air duct (4) is to allow a flow of the cooling medium (K) along the inside of the supply air duct (4) downwards.

2. Dryer according to claim 1, characterized in that in the region of the passage opening (13) baffles are arranged for the cooling gas.

3. Dryer according to claim 1 or 2, characterized in that at least one discharge opening (13) is directed to the discharge point (10) facing the region of the drying area.

4. Dryer according to one of claims 1 to 3, characterized in that it is the dryer is a fluidized bed dryer.

5. Dryer according to claim 4, characterized in that it is the fluidized bed dryer is a vibration-excited fluidized bed dryer.

6. Dryer according to one of claims 1 to 5, characterized in that it is the cooling medium (K) is a cooling gas.

7. Dryer according to one of claims 1 to 6, characterized in that the at least one supply opening (12) below the supply air duct (4) is arranged.

Vienna, March 19, 2008 Kliment & Henhapel Patentanwälte OG