KR20180132174A - Horizontal rotary drying machine - Google Patents

Abstract

The present invention provides a horizontal type rotary dryer having a classifying function.
A gas supply means for blowing a carrier gas from one end and passing through the rotary tube 10 and discharging the gas from the other end; a plurality of discharge ports 50 formed in the circumferential direction at the other end side end of the rotary tube 10, The exhaust hood 55 is provided so as to cover the entire other end of the other end side of the exhaust hood 55. The fixed exhaust port 57 of the object to be dried and the exhaust port 56 of the carrier gas are formed in the lower portion of the exhaust hood 55, A plurality of rising plate groups 60 extending from the inner wall of the rotating tube to the center side and spaced apart in the circumferential direction for raising the laundry to be dried together with the rotation tube are formed along the longitudinal direction at the other end side of the rotating tube.

Description

[0001] HORIZONTAL ROTARY DRYING MACHINE [0002]

The present invention relates to a horizontal type rotary dryer capable of carrying out two types of drying and classification.

In the production of conventional coke, cokes using low-cohesion coal are frequently produced due to lack of good quality coking coal (coarse coal and weak coking coal). When the moisture content is less than 6.5%, coal particles having a size of less than about 100 μm cause dust, which causes problems such as deterioration of the working environment. In addition, when fine particles of about 300 mu m were supplied to the coke oven as a drying object, carbon was deposited in the coke oven. Therefore, in order to prevent dust from being generated in the coal transportation facility or to prevent carbon from adhering to the coke oven, before the drying of the charging coal or drying, the fine particles caused by the classifier installed are classified and removed.

Conventionally, a horizontal rotary dryer or a fluidized bed dryer has been used for drying coal. The horizontal type rotary dryer is advantageous from the viewpoint of facility cost because the power consumption is smaller than that of the fluid bed dryer.

As a representative example of a conventional horizontal type rotary dryer, a so-called steam tube dryer (STD) is known. In drying using STD, a carrier gas is generally blown in order to improve drying efficiency (Patent Document 1). As shown in FIG. 5, the steam tube dryer includes a rotary tube 110 rotatable about an axis, and rotates the rotary tube 110 while rotating the rotary drum 110 from the one end to the other end And then dried in the rotary tube 110 by heating steam, which is an external heat for drying.

More specifically, the rotary tube 110 has a length of, for example, 10 m to 30 m, and between the both end plates in the rotary tube 110, (111) extend in the axial direction. Dried material such as wet powder or granular powder is heated and dried by being brought into contact with the heating tube 111 when supplied into the inside of the rotating tube 110 and is moved to the side of the outlet 112 in accordance with rotation of the rotating tube 110 .

A gas supply port 113 for blowing a carrier gas is provided at an end of the rotary tube 110 and is connected to the discharge port 112 on the other end side with evaporation gas generated in the rotary tube 110 And the carrier gas is discharged from the gas outlet 122.

However, this type of conventional conventional horizontal swivel dryer did not have a classifying function. Therefore, it is necessary to classify the material to be dried, but the classification and installation of the classifier separately increases the cost of equipment as well as the handling of the material.

On the other hand, in the rotary tube, the object to be dried flows along with the rotation of the rotary tube in the form of a so-called kiln action to update its position. To increase the contact efficiency with the heating tube, It is known.

Patent Document 1: Japanese Laid-Open Patent Publication No. 2004-44876 Patent Document 2: Japanese Utility Model Registration Application No. 3-66625 CD-ROM

The fluidized bed dryer has a problem that the power consumption is larger than that of the horizontal type rotary dryer and thus the cost is high and the facility becomes large scale. On the other hand, conventional conventional horizontal type rotary dryers are disadvantageous in that they do not have a classifying function and thus increase facility cost and increase maintenance cost.

Accordingly, a first object of the present invention is to provide a horizontal type rotary dryer having a classifying function.

A second object of the present invention is to increase the efficiency of contact of the object to be dried with the heating tube while improving the dispersion efficiency of the object to be dried and further improve the classification efficiency.

Hereinafter, the means for solving the above-mentioned problems and the effects thereof are shown.

[Invention according to claim 1]

A rotary tube having a supply port for the object to be dried and a discharge port for the object to be dried at one end and freely rotatable about the axis direction; and a plurality of heating tubes through which the thermal medium passes, A horizontal rotary type dryer in which a drying object is heated and dried by the plurality of heating tubes in a process of discharging dried materials charged from a supply port of a rotary tube from a discharge port,

A gas supply port capable of blowing a carrier gas is provided at one end of the rotating tube,

And a gas outlet for discharging the carrier gas is provided at the other end of the rotating tube,

The outlet of the laundry is also a gas outlet of the carrier gas,

A plurality of exhaust ports are formed in the circumferential direction at the other end of the rotary tube, and an exhaust hood for covering the entire other end of the rotary tube is provided,

The exhaust hood comprises:

And an upper portion constituting a settling chamber for classifying the particles contained in the carrier gas,

An intermediate portion in which the other end side portion of the rotary tube is located,

And a lower portion formed with a fixed discharge port of the object to be dried,

(L) between the outer surface of the rotating tube and the carrier gas exhaust port is set to 4.0D> L> 0.8D with respect to the inner diameter (D) of the rotating tube,

The upper portion of the exhaust hood is larger in width than the middle portion of the exhaust hood,

The carrier gas is radially discharged into the inside of the exhaust hood from a plurality of gas outlets provided in the circumferential direction of the other end side of the rotary tube, and the discharged carrier gas rises and is discharged from the exhaust port of the exhaust hood In progress,

Wherein particles contained in the carrier gas are classified by gravity.

[Function and effect]

The dried object to be dried by the heating means is mainly dropped and discharged through the discharge port by the gravity when the rotary tube rotates and the discharge port of the object to be dried is located at the lower side. The carrier gas blown from the gas supply port is discharged through the gas discharge port. The particles are discharged from the discharge port together with the carrier gas. Particles of relatively large diameters of the particles start falling at that point because the rising energy reaches the limit early due to the gravity. On the other hand, the particulate having a relatively small diameter among the particulates is exhausted to the outside from the exhaust port of the carrier gas together with the carrier gas.

Thus, particles having a large diameter are discharged from the outlet of the lower portion of the exhaust hood through the outlet of the rotary tube, while particles having a small diameter are discharged from the outlet of the upper portion of the exhaust hood through the outlet of the rotary tube. As a result, the object to be dried can be classified into particles having a larger diameter and particles having a smaller diameter.

It is conceivable to set the distance L between the outer surface of the rotary tube and the carrier gas exhaust port to L> 0.3D with respect to the inner diameter D of the rotary tube, but more preferably 0.8D <L <4.0D &Lt; L < 2.5D). The particles are discharged from the discharge port together with the carrier gas. However, the particles having relatively large diameters of the particles reach the limit at an early stage due to the gravitational force, so that the space (sedimentation) And classify it in the region.

As a result, it becomes possible to classify fine particles having a relatively small diameter among the small particles that are exhausted from the carrier gas exhaust port to the outside in a state accompanied by the carrier gas. On the other hand, the conventional STD does not have the space (sedimentation) region and thus does not substantially exhibit the classification function.

In the relation between the spacing distance L and the inner diameter D of the rotating tube, if the spacing distance L is short, the space (sinking) region can not be sufficiently secured, and the desired classifying function becomes insufficient. If the distance L is excessively long, not only the apparatus becomes excessive but also the amount of particles accompanying the carrier gas becomes small, and the aimed classifying function becomes insufficient from this point of view. The relationship between the distance L and the inner diameter D of the rotary tube is obtained from the size of the STD, the kind of the material to be dried, the required classifying ability, etc. practically used.

[Invention according to Claim 2]

The horizontal type rotary dryer as set forth in claim 1, wherein the upper portion of the exhaust hood has a straight body portion.

[Invention of Claim 3]

A rising plate extending from an inner wall of the rotating tube to a central axis is disposed at a position spaced apart in the circumferential direction for raising the object to be dried together with the rotation tube, The horizontal rotary dryer as set forth in claim 1,

[Function and effect]

A plurality of lifting plates formed at intervals in the circumferential direction for lifting the object to be dried together with the rotation of the rotary tube are provided along the longitudinal direction to the other end side of the rotary tube.

Even in the conventional STD, a minute amount of fine particles are discharged to the outside together with the carrier gas, so that the above-described classification phenomenon may occur.

On the other hand, in the rotary tube, the object to be dried flows along with the rotation of the rotary tube in the form of a so-called kiln action, and the position is updated. In this state, the amount of particles accompanying the carrier gas is very small.

Therefore, according to the present invention, when a plurality of groups of rising plates extending from the inner wall of the rotating tube to the center side and lifting the laundry with rotation of the rotating tube are formed at intervals in the circumferential direction, A large amount of particulates can be brought into the carrier gas because the carrier gas escapes, so that the amount of the particulate in the exhaust hood can be increased. Further, the contact efficiency between the object to be dried and the heating tube is further increased by the group of the rising plate, and the drying efficiency is further enhanced.

[Invention of claim 4]

Wherein the lifting plate of at least the most downstream of the lifting plate group has a base end of the lifting plate at a position close to the downstream edge of the lifting plate with respect to the rotating direction of the rotating tube, dryer.

[Function and effect]

If the rising plate base end of the rising plate group at least the most downstream of the rising plate group is disposed at a position near the downstream edge of the discharge port with reference to the rotating direction of the rotating tube, A large amount of the object to be dried can be wrapped and raised between the object and the next outlet located downstream in the rotating direction of the rotary tube. As a result, the classification ratio can be increased.

[Invention of claim 5]

The horizontal rotary dryer as set forth in claim 3, wherein stirring means for stirring the drying object supplied to the inside of the rotary tube is provided at one end side of the rotary tube than the rising plate group.

[Other Explanation]

Wherein the lifting plate extends from the base end to the center of the rotating tube and the leading end portion of the lifting plate is formed to be bent forward with respect to the rotating direction of the rotating tube.

[Function and effect]

This form can also lift and lift many objects to be dried between the next discharge port downstream of the rotation tube in the rotation direction when the object to be dried is lifted with the rotation. As a result, the classification ratio can be increased.

[Other inventions]

And a heating means for heating the inside of the rotary tube and a rotary tube having a supply port for the object to be dried and a discharge port for the object to be dried at one end and freely rotatable about the axis direction, A horizontal rotary type dryer in which a drying body is heated and dried by the heating means in a process of discharging the dried body from a discharge port,

A gas supply port capable of blowing a carrier gas is provided at one end side of the rotary tube,

A gas discharge port capable of discharging the carrier gas is provided at the other end side of the rotary tube,

A plurality of the discharge ports are formed in the circumferential direction at the other end of the rotary tube, and an exhaust hood is provided covering the entire other end of the rotary tube,

A fixed outlet of the object to be dried is formed in a lower portion of the exhaust hood, an exhaust port of the carrier gas is formed in an upper portion,

Wherein the distance L between the outer surface of the rotating tube and the outlet of the carrier gas is L > 0.3D with respect to the inner diameter D of the rotating tube.

[Other inventions]

A dispersing gas supply means for accommodating the object to be dried discharged from the discharge port and providing a dispersion plate for guiding the object to be discharged to the discharge port and blowing gas into the discharge hood from the outside through the dispersion plate, A horizontal rotary dryer.

[Function and effect]

As described above, particles having a large diameter are mainly dropped and discharged through the discharge port due to gravity when the discharge tube of the object to be dried is rotated downward by the rotation of the rotating tube. At this time, There are particles in which particles are physically accompanied between particles having a large diameter. However, when a dispersion plate for receiving the object to be dried discharged from the discharge port and guiding to the discharge port is provided on the lower side of the end portion on the other end side of the rotary tube and the gas is blown into the discharge hood from the outside through the dispersion plate, While the height is small, the diameter of the small diameter is high, so it can be classified by the carrier gas.

[Other inventions]

Wherein the dispersion plate forms a falling chute downwardly inclined at an outlet of the laundry.

[Function and effect]

The particles having a larger diameter can be quickly dropped to the discharge port through the falling chute as compared with the case where the dispersion plate is horizontal, so that the separation efficiency between particles having a larger diameter and particles having a smaller diameter can be higher.

According to the present invention, as described above, since the horizontal rotary dryer having the classifying function is provided, it is possible to reduce the facility cost and can be freed from the troublesome handling due to the separate installation of the classifier. It is possible to increase the efficiency of contact of the object to be dried with the heating tube while improving the dispersion efficiency of the object to be dried and further improve the classification efficiency.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a view showing a first embodiment of a horizontal type rotary dryer, which is a horizontal type rotary dryer related to the present invention; FIG.
Fig. 2 is a partially enlarged view of Fig. 1, in which the exhaust hood is omitted. Fig.
3 is a view showing the direction of the arrow XX in Fig.
Fig. 4 shows a second embodiment of a horizontal type rotary dryer, which is a horizontal type rotary dryer related to the present invention, and corresponds to Fig. 3.
5 is a view showing an example of a conventional horizontal type rotary dryer.
Fig. 6 is a view corresponding to Fig. 3 and schematically showing the movement of the object to be dried in the exhaust hood.
Fig. 7 is a view corresponding to Fig. 4 and schematically showing the movement of the object to be dried in the exhaust hood.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a horizontal type rotary dryer according to the present invention will be described with reference to the accompanying drawings.

[First Embodiment]

1 to 3 show a horizontal type rotary dryer according to the present invention. The horizontal rotary type dryer has a cylindrical rotary tube 10 and its axial center is slightly inclined with respect to the paper surface, and one end thereof is located higher than the other end. Two support units 20 and a motor unit 30 are provided on the lower side of the rotary tube 10 to support the rotary tube 10 and the rotary tube 10 is supported by the motor unit 30, So that rotational motion around the direction is free. The rotary tube 10 is rotated in the direction of arrow R shown in FIG. 3, and the rotational speed is, for example, less than 1 m / s at the peripheral speed.

Inside the rotary tube 10, a pipe made of metal and a plurality of steam tubes 11 extending in the axial direction of the rotary tube 10 are installed so that steam as a heating medium can flow. The plurality of steam tubes 11 are arranged in the circumferential direction and in the radial direction so as to be concentric with the axis of the rotary tube 10, for example.

As shown in Figs. 1 and 2, a plurality of discharge ports 50 are formed in the peripheral wall on the other end side of the rotary tube 10 in the present invention. The discharge ports 50 are arranged at two intervals in the circumferential direction of the rotary tube 10 in the illustrated example and spaced apart from each other. The discharge ports 50 are all formed in the same shape.

As shown in Figs. 1 to 3, a plurality of rising plates 61 are provided inside the rotating tube 10 so as to extend from the inner wall of the rotating tube 10 toward the axial direction of the rotating tube 10 . These rising plates 61 are arranged so as to form three rows (a rising plate row 60 shown in FIG. 1) in the example shown along the circumference of the central axis. The lift plate groups 60 are composed of, for example, four lift plates 61 spaced apart at equal intervals from each other.

The rising plate 61 is formed of a thick metal and has a tip end bent into a hook shape slightly toward the downstream side in the rotating direction R of the rotating tube 10. The extending length of the lifting plate 61 is 1/10 to 3/10 of the diameter of the rotating tube 10.

3, each of the ascent plates 61 passes through the end of the discharge port 50 located on the downstream side with respect to the rotation direction R of the rotary tube 10, And extends in the vicinity of a straight line parallel to the axial direction of the rotor. 3, the discharge port 50 does not exist on the downstream side of the rising plate 61 and the inner wall of the rotating tube 10 exists.

1 and 2, the lifting plate group 60 is disposed in the rotary tube 10 between the discharge port 50 and a supply port 41 described later and is connected to the rotary tube 10 rather than the discharge port 50, It does not exist on the other end side within the range. More specifically, the lift plate group 60 is disposed between the discharge port 50 and the supply port 41 at a portion close to the discharge port 50.

A stirring means 65 for stirring the object to be dried W supplied in the rotary tube 10 is installed at one end side of the rotary tube 10 in the present invention rather than the rising plate group 60 in the rotary tube 10 . The stirring means 65 is separated from the rising plate group 60 disposed on the other end side in the rotary tube 10. The stirring means (65) is not particularly limited, and a known stud type or reverse blade can be exemplified. Particularly, it is desirable to select the reverse blade for the reasons of particulate separation effect and structure limitation of STD.

As shown in Figs. 1 to 3, an exhaust hood 55 is provided at the other end of the rotary tube 10 so as to cover the discharge port 50 and to exhaust the carrier gas. The exhaust hood 55 is formed of a thick metal. As shown in Fig. 3, the upper portion 55u is slightly larger in width than the middle portion 55c, while the lower portion 55d is narrow . The inside of the upper portion 55u is a settling chamber 90 which is a space filled with air. The exhaust hood 55 is fixed to the ground by means not shown and does not rotate in accordance with the rotary motion of the rotary tube 10. [

In the upper part of the upper part 55u, a tubular exhaust port 56 is opened toward the upper side, and the exhaust port 56 is connected to a dust collecting means or the like not shown. The distance L between the outer surface of the rotary tube 10 and the exhaust port 56 of the carrier gas is L> 0.3D with respect to the inner diameter D of the rotary tube 10, more preferably 0.8D <L &Lt; 4.0D, particularly 1.0D < L < 2.5D. If it is 0.8D or less, the classifying function can not be sufficiently exhibited, and the object to be dried having a large particle diameter is also discharged to the dust collecting means together with the carrier gas, thereby increasing the load of the dust collecting means. If it is more than 4.0D, it is not economical to provide space beyond the distance necessary for classifying.

On the lower side of the lower portion 55d, a tubular discharge port 57 as a fixed discharge port opens downward. The discharge port 57 is connected to a belt conveyor or the like Respectively.

A second classifying means 58 is provided in the lower portion 55d inside the exhaust hood 55. [ This second classifying means 58 is covered by a dispersing plate 58a whose top portion is a net. The second classifying means 58a is inclined downward toward the discharge port 57 to form a falling chute. (Not shown) for supplying a classifying gas to the second classifying means 58 is provided and a gas necessary for dispersion is supplied. The supplied classifying gas passes through the dispersing plate 58a and is supplied into the exhaust hood 55 along the arrow N. [

As the classifying gas, air or an inert gas (for example, nitrogen gas or argon gas) may be used, and it may be selected in accordance with the characteristics of the object to be treated. For example, in the case of an object having an ignitability such as coal, it is preferable to use the inert gas.

When the classifying gas is blown into the exhaust hood 55 from the outside through the dispersing plate 58a, particles having a large diameter do not float or rise in height, whereas particles having a small diameter rise to a high height, The classification becomes possible. In addition, since the particles having a larger diameter can be quickly dropped to the discharge port 57 through the falling chute than when the dispersing plate 58a is horizontal, the separation efficiency between particles having a large diameter and particles having a small diameter can be enhanced.

1, a steam supply pipe 70 and a drain pipe 71 for the steam tube 11 are provided at the other end of the rotary tube 10.

One end of the rotary tube 10 is provided with a screw feeder 42 having a screw therein and being fitted into the rotary tube 10. One end of the screw feeder 42 is provided with a driving means 43 such as a motor for rotating a screw provided inside the screw feeder 42. A feed port 41 is open at the top of the screw feeder 42 and is openable and closable by an upper lid. The feed port 41 and the screw feeder 42 communicate with each other.

The dried object W to be dried by the horizontal type rotary dryer according to the present embodiment is supplied from the supply port 41 into the screw feeder 42 and the screw provided in the screw feeder 42 is driven by the driving means 43 So as to be supplied to the interior of the rotary tube 10. Gas supply means (not shown in the drawing) for blowing air as a carrier gas from a supply port 41, which is also a gas supply port, is provided in the vicinity of the screw feeder 42, Is injected into the inside of the rotary tube 10 toward the other end side of the rotary tube 10.

Next, the operation of the horizontal type rotary dryer according to the present embodiment will be described.

In order to dry the article W with the horizontal type rotary dryer according to the present embodiment, as shown in Fig. 1, the article to be dried W is supplied to the supply port 41 along arrow A in advance. The object to be dried W supplied from the supply port 41 is charged into the rotary tube 10 by the screw feeder 42 and is contacted with the steam tube 11 heated by the supplied steam, 10).

When the workpiece W reaches the position where the agitating means 65 is present, the workpiece W is agitated by the agitating means 65. Then, as shown in Fig. 3, Is raised by the plate (61). When the lifting plate 61 is located on the upper side of the rotary tube 10, the lifted laundry 8 is naturally dropped as shown by the arrow B, and the fine particles contained in the laundry W are transferred to the rotary tube 10 10 (so-called flight action).

On the other hand, the carrier gas sucked from the supply port 41 passes through the rotary tube 10 by the suction device formed on the one end side of the rotary tube 10, and is discharged from the discharge port 50, which is also the gas discharge port, . At this time, the carrier gas is discharged from the discharge port (50) together with the fine particles dispersed in the rotary tube (10) by the rising plate (61). The carrier gas discharged from the discharge port 50 is exhausted from the exhaust hood 55 through the exhaust port 56 along with the fine particles along the arrow C. At the same time, the classifying gas is sprayed toward the upper side of the exhaust hood 55 by the dispersing gas supplying means and supplied.

When the carrier gas is discharged from the discharge port 50, for example, the flow rate is 5 to 10 m / s. The flow velocity is appropriately adjusted in accordance with the area of the discharge port 50 and the suction velocity of the carrier gas.

A large particle diameter and heavy weight fall down from the discharge port 50 along the arrow G without being discharged from the discharge port 50 by the carrier gas because the discharge is dropped in the settling chamber 90. [ The article to be dried W which has spontaneously dropped from the discharge port 50 is discharged from the discharge port 57 along arrow E. Particles (coarse particles) having a large diameter, which have been discharged by the carrier gas but are heavy in weight and can not reach the exhaust port 56 together with the carrier gas fall downward along the arrow F due to inertia, And is discharged from the discharge port 57 together with the other objects W to be dried.

Next, the operation and effect of the horizontal type rotary dryer according to the present embodiment will be described.

Since the rising plate 61 is formed in the rotating tube 10 like the horizontal rotating type dryer according to the present embodiment, the fine particles contained in the dried article W are dispersed in the space in the rotating tube 10 , And these fine particles can be carried in the carrier gas and discharged together with the carrier gas from the discharge port 56. As a result, the fine particles contained in the object to be dried W can be classified.

Each rising plate 61 passes through the end of the discharge port 50 located on the downstream side with respect to the rotational direction R of the rotary tube 10 and is parallel to the axial direction of the rotary tube 10 The object to be dried W placed on the ascent plate 61 is positioned immediately downstream of the discharge port 50. In this case, The object to be dried W on the rising plate 61 can be prevented from directly entering the discharge port 50 so that the object to be dried W in a state in which fine particles are mixed is discharged from the discharge port 50 none.

Since the plurality of lifting plate groups 60 are intermittently positioned along the axial direction of the rotary tube 10, the laundry W moving in the rotary tube 10 is moved in the direction in which the lifting plate 61 is located And non-existent portions alternately. In this case, the object to be dried W is divided by a plurality of circuits, so that the rising efficiency is improved.

In addition, if the lifting plates 61 are intermittently positioned so as to be spaced equidistantly from each other along the circumferential direction of the rotary tube 10, the laundry D can be efficiently raised.

More specifically, the lift plate group 60 of the lift plate 61 extending from the inner wall of the rotary tube 10 to the center side and lifting the laundry W with the rotation of the rotary tube 10 is moved in the circumferential direction If a plurality of spacers are formed, the carrier gas escapes from the rising plate 61 to the dropping position, so that many fine particles can be caused to accompany the carrier gas, and the amount of the gas to be fed from the exhaust hood 55 can be increased.

There is a further advantage that the contact efficiency between the laundry W and the steam tube 11 as a heating tube is further increased by the soldering elevating plate group 60 of the rising plate 61, thereby increasing the drying efficiency.

On the other hand, in the present embodiment, the rising plate 61 of the rising plate group 60 at least at the most downstream side of the rising plate group 60 is disposed on the downstream side of the discharge port 50 with reference to the rotating direction of the rotating tube 10 And has a base end of the rising plate 61 at a position close to the edge and extending from the inner wall of the rotating tube 10 toward the center.

Therefore, if there is a base end of the lifting plate 61 at a position close to the downstream edge of the discharge port 50 with reference to the rotating direction of the rotating tube 10, A large number of objects W can be wrapped and raised between the next discharge port 50 located downstream in the rotating direction of the tube 10. As a result, the object to be dried (W) is more finely stirred as compared with the kiln action, and the classifying effect of the object to be dried W can be enhanced.

In this embodiment, the rising plate 61 extends from the base end to the center of the rotating tube 10, and the extending end is formed to be bent forward with reference to the rotating direction of the rotating tube 10.

Therefore, when the laundry W is wrapped and raised along with the rotation, many objects to be dried W can be lifted up between the next discharge port 50 downstream in the rotating direction of the rotary tube 10. As a result, the classification ratio can be increased.

Since the agitating means 65 for agitating the laundry W supplied in the rotary tube 10 is provided at one end side of the rotary tube 10 rather than the rising plate group 60, The object to be dried W is stirred at the front end for raising the dried material W, so that the fine particles contained in the object to be dried W can be removed. Therefore, the diffusion of the fine particles by the rising plate 61 can be more efficiently performed.

An outlet 50 formed on the circumferential wall of the rotary tube 10 to move together with the rotary motion of the rotary tube 10 and a lower portion of an exhaust hood 55 provided to cover the outlet 50 Since the discharge port 57 which does not move and the discharge port 56 formed at the upper portion of the exhaust hood 55 are combined with each other, the classification by the carrier gas is performed in the space between the discharge port 50 and the discharge port 57 . Concretely, the fine particles are discharged from the discharge port 56 together with the carrier gas, and the other coarse particles are classified by being dropped toward the discharge port 57 and discharged.

Therefore, in the present embodiment, the distance L between the outer surface of the rotary tube 10 and the outlet 56 of the carrier gas is set to L> 0.3D with respect to the inner diameter D of the rotary tube. More preferably, 0.8D <L <4.0D (particularly 1.0D <L <2.5D) can be considered.

In other words, the fine particles are discharged from the discharge port 50 together with the carrier gas. However, the relatively large diameter particles in the fine particles have a space (sedimentation) region in which the rising energy reaches the limit early due to the gravity, And classify it in that area.

As a result, it becomes possible to classify fine particles having a relatively small diameter among the small particles that are exhausted from the exhaust port 56 of the carrier gas to the outside in a state accompanied by the carrier gas.

Specifically, in the relationship between the separation distance L and the inner diameter D of the rotary tube 10, if the separation distance L is short, the space (sinking) region can not be sufficiently secured, .

On the other hand, if the distance L is excessively long, not only the apparatus becomes excessive but also the amount of particles accompanying with the carrier gas becomes small, and the aimed classifying function becomes insufficient from this point of view.

The relationship between the above-described distance L and the inner diameter D of the rotary tube 10 is obtained by various simulations such as the size of the STD, the type of material to be dried, and the required classifying ability practically used.

Since the inside of the upper portion 55u is the sedimentation chamber 90 which is a space filled with air, the particles of the defect accompanied by the carrier gas are dropped by the inertia in the sedimentation chamber 90, .

Since the dispersion gas supplying means for spraying the classifying gas toward the upper side is formed on the lower side of the discharge port 50, it is possible to raise the fine particles falling from the discharge port 50 toward the discharge port 56. As a result, Can be improved.

That is, as described above, the particles having a large diameter of the object to be dried W are dropped and discharged through the discharge port 50 by gravity mainly when the rotary tube 10 rotates and the discharge port 50 is positioned on the lower side, At that time, there is a case in which particles having a small diameter are not accompanied by a carrier gas and are physically accompanied between particles of particles having a large particle diameter.

A distribution plate 58a for receiving the object to be dried W discharged from the discharge port 50 and guiding the object W to the discharge port 57 is provided below the end of the other end of the rotary tube 10, When the gas is blown into the exhaust hood 55 through the exhaust hood 55, particles having a large diameter do not float or have a small height of rising, while particles having a small diameter have a high rising height and can be classified with the carrier gas.

As compared with the case where the dispersion plate 58a is horizontal, the particles having a large diameter can be quickly dropped to the discharge port 57 through the falling chute, so that the separation efficiency between particles having a large diameter and particles having a small diameter can be enhanced.

Here, a conceptual diagram of a modified example of the horizontal type rotary dryer according to the present embodiment is shown in Fig. 6, and this modified example will be described below.

6, in the present modified example, the center of rotation of the rotary tube 10 from the inner wall of the rotary tube 10 is the center of rotation of the rotary tube 10, And a pair of rising plates 61 extending in the direction of the arrows are arranged.

Therefore, in this modified example, the rising effect of the rising plate 61 is increased because the number of the rising plates 61 is increased, so that the fine particles contained in the laundry W are dispersed more efficiently in the rotating tube 10 do.

Next, another embodiment of a horizontal type rotary dryer according to the present invention will be described with reference to the accompanying drawings.

[Second Embodiment]

4 shows a second embodiment of the horizontal type rotary dryer according to the present invention.

The horizontal type rotary dryer according to the present embodiment is different from the horizontal type rotary dryer according to the first embodiment in that the position of the second classifying means 58 is different in the exhaust hood 55. More specifically, in the horizontal type rotary dryer according to the present embodiment, the discharge port 57 is not opened toward the lower side but opened toward the side. A second classifying means 58 is formed on the lower side of the discharge port 57, and the dispersing plate 58a is formed horizontally.

Since the horizontal type rotary dryer according to the present embodiment is configured as described above, the discharge port 57 can be provided on the side of the exhaust hood 55. [ Therefore, the space for forming the exhaust port 57 on the lower side of the exhaust hood 55 need not be sufficient.

Here, a conceptual diagram of a modified example of the horizontal type rotary dryer according to the present embodiment is shown in Fig. 7, and this modified example will be described below.

7, in the present modification, the center of rotation of the rotary tube 10 from the inner wall of the rotary tube 10 is the center of rotation of the rotary tube 10, And a pair of rising plates 61 extending in the direction of the arrows are arranged.

Therefore, in this modified example, the effect of providing the discharge port 57 on the side of the exhaust hood 55 is obtained, and since the number of the rising plates 61 is increased, The effect that fine particles contained in the object to be dried W are dispersed more efficiently in the rotary tube 10 can be obtained.

[Other Embodiments]

In the horizontal type rotary dryer, which is a horizontal type rotary dryer related to the present invention, the number of the rising plates 61 per unit area of the rising plate group 60 is not limited to four and may be four to six .

The number per one row of the discharge ports 50 is not particularly limited, but is preferably 10 to 17 in consideration of reduction in pressure loss, dispersion of fine particles, mechanical strength of the rotary tube 10, and the like.

The present invention is not limited to the drying of coal but can be widely applied to industries requiring drying and classification, such as drying and classification of food in the food industry, and dry classification of chemical products in the chemical industry.

10: rotating tube 11: steam tube (heating means)
41: feed port 50: outlet
55: exhaust hood 56: exhaust port
57: exhaust port 58a:
60: rising plate group 61: rising plate
65: stirring means

Claims (5)

A supply port for a laundry to be dried at one end; A rotary tube having an outlet of the object to be dried and freely rotatable about the axial direction and a plurality of heating tubes through which the thermal medium passes are provided in the rotary tube, A horizontal rotary type dryer in which a drying object is heated and dried by the plurality of heating tubes in a process of discharging dried material from a discharge port,
A gas supply port capable of blowing a carrier gas is provided at one end of the rotating tube,
And a gas outlet for discharging the carrier gas is provided at the other end of the rotating tube,
The outlet of the laundry is also a gas outlet of the carrier gas,
A plurality of exhaust ports are formed in the circumferential direction at the other end of the rotary tube, and an exhaust hood for covering the entire other end of the rotary tube is provided,
The exhaust hood comprises:
An upper portion constituting a sedimentation chamber for forming an exhaust port of the carrier gas on the upper portion and classifying particles contained in the carrier gas by gravity by first particles and second particles,
An intermediate portion in which the other end side portion of the rotary tube is located,
And a lower portion formed with a fixed discharge port of the object to be dried,
(L) between the outer surface of the rotating tube and the carrier gas exhaust port is set to 4.0D>L> 0.8D with respect to the inner diameter (D) of the rotating tube,
The upper portion of the exhaust hood is configured to have a width larger than the middle portion of the exhaust hood,
Wherein the first particle is exhausted through an exhaust port of the carrier gas, and the second particle is exhausted through an exhaust port of the laundry. The method according to claim 1,
And a direct portion at an upper portion of the exhaust hood. The method according to claim 1,
A rising plate extending from an inner wall of the rotating tube to a central axis is disposed at a position spaced apart in the circumferential direction for raising the object to be dried together with the rotation tube, Installed horizontal rotary dryer. The method of claim 3,
Wherein the rising plate of the rising plate group at least at the downstream of the rising plate group has a base end of the rising plate at a position close to the downstream edge of the discharge hole with reference to the rotating direction of the rotating tube. The method of claim 3,
And an agitating means for agitating the object to be dried supplied to the inside of the rotary tube is provided at one end side of the rotary tube than the rising plate group.

Images