JP2002147953A - Drying device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently dry the object to be dried that is conveyed at an extremely low speed by a corrugated conveyer device by sunlight and ventilation. SOLUTION: The front wall 13 and the ceiling wall 16 of a drying box B comprises a metal plate in projection and recess shapes due to folded plate structures, and a corrugated conveyer device C provided with upper and lower supply fans 7a and 7b is arranged inside the drying box B so as to cause the air blasted from each of the supply fans 7a and 7b to impinge on sludge Q. Moreover, the air flow R reversed to the different direction is convectively circulated while making contact with each of the walls 13 and 16 of the drying box B to perform heat exchanges, thereby drying the sludge Q.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for drying an object to be dried by sunshine and ventilation while transporting the object to be dried on a wavy conveyor device at an extremely low speed.

[0002]

2. Description of the Related Art Prior art will be described with reference to the drawings of the present invention. For example, as disclosed in Japanese Patent Application Laid-Open No. Hei 7-308988, a technique is known in which organic sludge discharged from wastewater treatment facilities such as factories and cities is dried by sunlight and ventilation. In the technique disclosed in this publication, pellet-shaped sludge is dried using a drying box and a corrugated conveyor device. That is, as shown in FIG. 2, the corrugated conveyor device C arranged in the drying box B
A sludge transport net 3 is arranged in a wavy manner in the upper traveling portion of the sludge. The sludge Q charged into the charging hopper 8 is formed into pellets by the forming device D, and falls on the sludge transport net 3. When the sludge transport net 3 travels at an extremely low speed, the sludge Q is transported at an extremely low speed,
Drying is efficiently performed by the drying action by sunlight and the drying action by ventilation. In the case of the present invention, the following effects are exhibited by arranging the sludge transport net 3 in a wave shape. (1) Since the sludge is conveyed in a wavy manner by the sludge conveying net, the contact portion between the sludge and the sludge conveying net is peeled off or inverted at the upper and lower bent portions,
Both sides of the sludge are exposed to the sun. Therefore, drying of the sludge is promoted. (2) The total running length of the sludge transport net can be made longer than the entire length of the wavy conveyor device, and the wavy conveyor device can be made compact.

However, in the case of the present invention, it is difficult to raise the temperature of the air existing around the sludge above the outside air temperature.

[0004]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and has been made in view of the above problem. The task is to be able to

[0005]

SUMMARY OF THE INVENTION The present invention for solving the above-mentioned problems is directed to a drying apparatus which dries the object to be dried by sunshine and ventilation while carrying the object to be dried on a corrugated conveyor device at an extremely low speed. At least a ceiling wall portion, a south side wall portion is formed of a metal plate, a substantially closed drying box for covering the corrugated conveyor device, and at least above the corrugated conveyor device in the drying box. A blower fan for generating an airflow in the drying box, wherein the airflow that reverses on the upper surface of the conveyor belt of the corrugated conveyor device exchanges heat while contacting each wall of the drying box. The drying is performed by generating a circulating airflow in the drying box.

In the case of the first aspect of the present invention, at least the ceiling wall portion and the southern side wall portion of the drying box are portions that are most easily heated by sunlight, and this portion is formed of a metal plate. Therefore, during solar drying, heat is collected and the temperature becomes relatively high. The temperature of the air in the drying box is increased because the air in the drying box comes into contact with the ceiling wall and the side wall and is conducted and conducted. Moreover, radiant heat transfer is also performed to the air in the box, and the temperature of the air in the drying box is further increased, and becomes higher than the outside air temperature. The air in the box heated in this way collides with the object to be dried placed on the transport belt of the corrugated conveyor device by the action of each blowing fan. In addition, since the transport belt travels in a wavy shape, the directions in which the airflow from each of the blower fans disposed above the transport belt reverses on different inclined surfaces of the transport belt are different from each other. As a result, the air in the box circulates in the drying box in a turbulent state.

[0007] The heating action of this relatively hot air,
Due to the ventilation action from various directions due to the circulating convection of the air in the box, the dried object placed on the transport belt and transported at an extremely low speed has higher drying efficiency compared to the simple drying by the sun and ventilation. . Further, since the drying box is substantially closed, even if the object to be dried emits odor, the odor hardly leaks to the outside.

According to a second aspect of the present invention, on the premise of the first aspect, each wall portion formed of a metal plate of the drying box is formed to have an uneven cross section. here,
"Cross-concave shape" means that the metal plate constituting the wall of the drying box is alternately bent or bent in the opposite direction, and as a result, all the cross-sectional shapes having a larger surface area than the flat plate are obtained. Including. For this reason,
The contact area between the ceiling wall and the side wall of the drying box and the air in the box is increased, the heat transfer efficiency is increased, and the drying efficiency is further improved.

The invention described in claim 3 is the first or second invention.
On the premise of the invention described in the above, an opening is provided in a side wall portion serving as the north side of the drying box, and the opening is blocked by a zonal airflow ejected from an air curtain device, and the suction air is It is configured to be deodorized by the deodorizer. Outside the sunshine hours, when the opening of the drying box is opened and the opening is blocked by a belt-like airflow ejected from the air curtain device, the air in the box containing the odor is prevented from flowing out of the opening. The air in the box is sucked together with the suction air of the air curtain device, and the suction air is discharged to the atmosphere via a deodorizing device. Thereby, the air in the odorous drying box can be released to the atmosphere in a deodorized state.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in more detail with reference to embodiments. In this embodiment, the material to be dried is sludge Q
Is described. 1 is an overall perspective view of a drying apparatus A according to the present invention, FIG. 2 is also a front sectional view, FIG. 3 is a side sectional view, FIG. 4 is a rear view, and FIG. FIG. 6 is a sectional view of the molding apparatus D. The drying device A of the present embodiment is provided with a drying box B that is configured in a substantially closed state, and is disposed in the drying box B.
A wavy conveyor device C for drying the sludge Q while being conveyed at a low speed, and a molding for disposing the sludge Q into a pellet, which is disposed outside the drying box B and at an upstream end of the wavy conveyor device C. And a device D.

First, the corrugated conveyor device C will be described. As shown in FIGS. 1 to 3, the corrugated conveyor device C of the present embodiment has a configuration in which, when the drive motor 1 is operated, the drive roll 2 is driven to rotate, and the sludge transport net 3 travels around. A plurality of upper driven rolls 4 and a plurality of press rolls 5 are alternately arranged in a wavy shape at different heights in the upper traveling portion of the sludge transport net 3. Further, a lower driven roll 6 is disposed at an upstream end and a downstream end of the lower traveling portion, respectively. And the above-mentioned drive roll 2, each upper driven roll 4, each presser roll 5, each lower driven roll 6
, An endless sludge transport net 3 is mounted. For this reason, the sludge transport net 3 travels around the wavy conveyor device C in a wavy manner.

The pellet-like sludge Q dropped on the upper part of the sludge transport net 3 constituting the above-mentioned corrugated conveyor device C
Is transported from the upstream side to the downstream side at an extremely low speed as the sludge transport net 3 travels around at an extremely low speed. The sludge Q is peeled off or inverted from the sludge transport net 3 at the upper and lower bent portions of the sludge transport net 3 arranged in a wavy manner, so that the back surface is also dried. Further, the total traveling length of the sludge transport net 3 can be longer than the entire length of the corrugated conveyor device C. For this reason, the corrugated conveyor device can be made compact.

Blowers 7a and 7b are disposed above and below the sludge transport net 3 in the upper traveling section, respectively. The upper blower fan 7a is for blowing airflow from above to the sludge Q on the sludge transport net 3, and the lower blower fan 7b is for blowing airflow from below. Since the drying of the sludge Q is promoted by the action of the airflow blown from each of the blowing fans 7a and 7b,
The drying efficiency of the sludge Q is improved. In addition, these blower fans 7a and 7b also have a function (described later) of circulating and circulating the air in the drying box B.

Outside the drying box B, upstream of the corrugated conveyor device C, a forming device D for forming the sludge Q into pellets is provided. Next, the molding apparatus D will be described. As shown in FIG. 6, the forming apparatus D has a configuration in which a pair of forming rolls 9 are provided below a charging hopper 8. The pair of forming rolls 9 are mounted so that their axes are perpendicular to the circumferential traveling direction of the sludge transport net 3 and are in contact with each other. Each of the molding rolls 9 has a large number of molding grooves 9a formed in the circumferential direction at predetermined intervals along the axial direction. Moreover, the molding grooves 9a formed on the molding rolls 9 are shifted from each other along the axial direction. The pair of forming rolls 9 are supported by bearings (not shown), and the two forming rolls 9 are driven and rotated in opposite directions. The miso-like sludge Q introduced between the charging hopper 8 and the pair of molding rolls 9 enters between the molding grooves 9a of the respective molding rolls 9 and is rotated by a predetermined angle. The sludge is peeled off by a scraper 11 attached immediately below the sludge 9 and turns into sludge Q in the form of pellets.

Next, the drying box B will be described.
As shown in FIGS. 1 to 3, the drying box B according to the present embodiment is large enough to cover the above-described corrugated conveyor device C, and has a peripheral wall portion ( A ceiling wall portion 16 is attached to the front wall portion 13, the rear wall portion 14, and the respective side wall portions 15) on both sides, and is configured in a substantially sealed state. The front wall portion 13 and the ceiling wall portion 16 are provided in a continuous state. The bottom plate 12, the rear wall portion 14 and the side wall portions 15 of the peripheral wall portion are formed of a flat plate made of metal, while the front wall portion 13 which is the remaining peripheral wall portion is formed. The ceiling wall 16 is made of an uneven plate made of metal. This uneven plate material has a folded plate structure having an uneven cross section, and has a higher strength and a larger surface area than a normal flat plate material. Here, the “cross-sectional unevenness” refers to all cross-sectional shapes that have a larger surface area than a flat plate by alternately bending or bending a metal plate in the opposite direction. For this reason, when the sun T (solar heat) is received, the air in the drying box B is efficiently heated. In order to more efficiently heat the air in the drying box B, it is preferable to use a metal material having a high thermal conductivity (for example, copper or aluminum) as the material of the uneven plate material. In FIG. 1,
Reference numeral 10 denotes a door for an operator to enter and exit the drying box B.

Also, louvers 17 are attached to both side walls 15 of the drying box B, respectively. A deodorizing device 18 is attached to each louver 17 inside the drying box B. The odor of the sludge Q in the drying box B is deodorized by each of the deodorizing devices 18 and then flows out through the louvers 17 to the outside. For this reason, the odor in the drying box B does not leak to the outside.

As shown in FIGS. 2 and 4, an opening 14 is formed at substantially the center of the back wall 14 of the drying box B.
a is provided. Furthermore, inside the drying box B,
The opening 14a of the rear wall portion 14 is provided with the opening 14a.
A shutter device S for closing a is mounted. Outside the sunshine hours such as at night, the shutter plate 19 constituting the shutter device S is wound up and housed in the winding box 21 to open the opening 14a. By doing so, ventilation inside and outside the drying box B can be performed.

Further, as shown in FIGS. 4 and 5, in the case of the drying apparatus A of this embodiment, outside the drying box B,
An air curtain device E is installed in the above-described opening 14a. The air curtain device E has an outlet 23 in which a plurality of fans 22 for blowing are installed in the height direction.
And a suction port 24 in which a plurality of suction fans (not shown) corresponding to the blower fan 22 are provided in the height direction. The air outlet 23 and the suction port 24 are installed to face each other outside the opening 14 a of the rear wall portion 14. When the air curtain device E is actuated, the belt 14 flows out of each fan 22 provided in the outlet 23 and is sucked into the suction port 24 to block the opening 14a outside the opening 14a. , An air curtain 25 is formed. Therefore, it is possible to reduce the odor in the drying box B from leaking to the outside.
At this time, a part of the zonal airflow enters the drying box B. And part of the odor in the drying box B is
The air is sucked into the suction port 24 together with the zonal airflow, and is released to the atmosphere via a deodorizing device 26 installed at the discharge port of the suction port 24. In this way, the odorous air in the drying box B can be released to the atmosphere in a deodorized state.

The operation of the drying apparatus A of this embodiment will be described. As shown in FIGS. 3 and 7, the drying box B
And the corrugated conveyor device C is disposed inside, and the front wall 13 to which the metal plate is mounted is installed facing south. By doing so, the drying box B
, The front wall portion 13 and the ceiling wall portion 16 made of
Can be installed at a position where solar radiation T (solar heat) can be received most.

The sludge Q dehydrated to a predetermined water content by a screw press (not shown) constituting a wastewater treatment facility is placed in a charging hopper 8 of a molding apparatus D provided at an upstream end of the corrugated conveyor apparatus C. , Are intermittently supplied through a supply pipe 27. The miso-like sludge Q in the charging hopper 8 is supplied between a pair of molding rolls 9 constituting a molding device D disposed immediately below the same, and the molding groove 9a of each molding roll 9 is formed.
Get into it. The sludge Q is rotated by a predetermined angle along with the rotation of each forming roll 9, and then is rotated by a predetermined angle.
Is separated by a scraper 11 attached immediately below the sludge transporting net 3 in the form of pellets. The sludge transport net 3 is traveling around at a very low speed, and the pellet-like sludge Q dropped thereon is transported downstream.

During the sunshine hours, the opening 14a of the back wall 14 of the drying box B is closed and the drying box B is closed.
Is almost closed. As described above, the front wall portion 13 and the ceiling wall portion 16 of the drying box B are arranged so as to be most susceptible to sunlight T. Further, as shown in FIG. 8, the front wall portion 13 and the ceiling wall portion 16 are provided.
Has a folded plate structure in which a metal plate having a high thermal conductivity is formed in an uneven shape, so that the portion becomes relatively high in temperature due to heat collection. Then, in the drying box B, the air in contact with the front wall portion 13 and the ceiling wall portion 16 is heated by conduction and heat transfer (heat flow). Further, when the front wall portion 13 and the ceiling wall portion 16 are heated, radiant heat transfer is also performed to the air in the drying box B, and the air is further heated. For this reason, the air in the drying box B becomes higher than the outside air temperature.

As shown in FIG. 3, the sludge Q placed on the sludge conveying net 3 of the corrugated conveyor device C and conveyed at an extremely low speed is provided with a blowing fan disposed above and below the sludge conveying net 3. 7a, 7b, the airflow R of the heated air
Is sent. This airflow R collides with the sludge Q and reverses. Then, by colliding with each inner wall of the drying box B, the direction is changed again. Since the sludge transport net 3 is arranged in a wave shape, the directions of the airflows R that are reversed on the inclined surface are different from each other. Moreover, heat exchange is performed by colliding with each inner wall of the drying box B, and the temperature is raised. In this way, the reversed airflow R comes into contact with the sludge Q while circulating in the drying box B in a turbulent state. In other words, the sludge Q is
It receives the ventilation action of the high temperature airflow R from various directions. Moreover, high-temperature air does not stay only in the upper part of the drying box B, and the air temperature in the entire area of the drying box B is increased. In this way, the air containing the water evaporated from the sludge Q does not stay around the sludge Q, and the sludge Q is always brought into contact with the high-temperature and relatively low-moisture air. . As a result, drying of the sludge Q is promoted.

The sludge Q transported to the downstream end of the corrugated conveyor device C is transported by the scraper 28 to the sludge transport net 3.
From the drying box B by the discharge conveyor 29.

Outside the sunshine hours, such as at night, the shutter plate 19 attached to the back wall 14 of the drying box B is opened to open the opening 14a. Then, the air curtain device E is operated. As shown in FIG. 5, a zonal airflow is ejected from the outlet 23 of the air curtain device E toward the suction port 24, and an air curtain 25 is formed outside the opening 14a. Therefore, the odor of the sludge Q placed on the sludge transport net 3 and transported at an extremely low speed does not flow out. In addition, a part of the belt-like air flow enters the drying box B, and the odor in the drying box B is removed together with the suction air sucked into the suction port 24 by the suction port 2.
4 and is released to the atmosphere via the deodorizing device 26. As a result, the evaporation of the water in the sludge Q is promoted, and the odorous air in the drying box B is released to the atmosphere in a deodorized state. In this way, the air inside and outside the drying box B is ventilated, and the drying of the sludge Q is promoted even outside the sunshine hours.

The present applicant manufactured a drying apparatus A according to the present invention, and conducted an experiment on the drying treatment capacity of sludge Q. The size of the drying box B is 7.7 m in length, 2.945 m in width, and 3.2 m in height. On the front wall 13 and the ceiling wall 16,
A copper plate having a thickness of 0.4 mm and a folded plate structure was used. The thermal conductivity of the copper plate is 385 (W / m · ° C). here,
The area of the front wall portion 13 is 7.7 mx 3.2 m = 24.6.
4 m ² , and the area of the ceiling wall 16 is 7.7 m × 2.
945 m = 22.67 m ² . Further, above and below the corrugated conveyor device C disposed in the drying box B,
Nineteen blowers 7a, 7b are mounted on each of them, and the airflow per fan of each blower 7a, 7b is 29.5 m ³ per minute. For this reason, the circulating air volume of the blowing fans 7a and 7b above and below the wavy conveyor device C is 29.
^{5 (m 3 / min) ×} 38 units /2=560.5(m ³ / min)
It is. Thus, the wind speed at the front wall 13 is 56
0.5 (m ³ /min)/24.64 m ² = 22.75 (m
/ min), and the wind speed at the ceiling wall 16 is 560.
5 (m ³ /min)/22.67 m ² = 24.72 (m / mi
n). However, since the actual air flow is turbulent, the average is [22.75 (m / min) +24.72].
(M / min)] / 2 = 23.7 (m / min).

In summer, the surface temperature of the front wall 13 and the ceiling wall 16 was about 80 ° C. When the blowers 7a and 7b are stopped, the internal temperature becomes 60 to 70 ° C.
become. The temperature difference between the inside and outside of the drying box B is 3
１６16 ° C. In this state, the corrugated conveyor device C
Is operated for one day (day, one rotation, night, one rotation), the sludge Q treatment capacity is 600 to 750 (kg / day),
It was about twice the processing capacity [300 (kg / day)] of the conventional apparatus.

The shutter plate 19 constituting the above-mentioned shutter device S may be operated electrically. In this case, by linking the shutter device S with observation equipment (not shown) such as a temperature sensor and a rain sensor, the shutter plate 19 is automatically operated in response to a change in weather to open the opening 14a. Or can be blocked.

The drying box B of the present embodiment includes a peripheral wall (a front wall 13, a rear wall 14, and both side walls 15 on both sides).
The ceiling wall 16 has a configuration made of a metal plate. For this reason, since heat flows through all the peripheral wall portions and the ceiling wall portion 16, the sludge Q is efficiently dried. However, the peripheral wall other than the front wall 13 installed facing south may be made of a non-metallic material such as wood or resin.

In the present embodiment, the material to be dried is sludge Q, but may be other materials, for example, pomace such as herbs, sawdust, and straw.

[0030]

According to the drying device of the present invention, at least the ceiling wall and the south side wall are formed of a metal plate.
A substantially closed drying box for covering all or most of the corrugated conveyor device, and disposed at least above the corrugated conveyor device in the drying box for generating an airflow in the drying box. And a blower fan. For this reason, the ceiling wall portion and the side wall portion of the drying box made of a metal plate are heated by the sun, and the air in the drying box in contact with each of the wall portions is conductively heated to be heated. In addition, the air blown to the object to be dried by the blower fan is reversed in different directions and circulated and convected in the drying box. As a result of the above, the object to be dried conveyed at an extremely low speed by the corrugated conveyor device is subjected to the circulating ventilation action by the heated airflow, so that the drying of the object to be dried is promoted.

[Brief description of the drawings]

FIG. 1 is an overall perspective view of a drying apparatus A according to the present invention.

FIG. 2 is a front sectional view of the same.

FIG. 3 is a side sectional view of the same.

FIG. 4 is a rear view of the same.

FIG. 5 is a plan view partially broken away.

FIG. 6 is a sectional view of a molding device D.

FIG. 7 is a diagram illustrating a state in which the drying device A receives the sunshine T;

FIG. 8 is a diagram showing a state in which air existing near the inside of the ceiling wall portion 16 of the drying box B is heated by the sun T;

[Explanation of symbols]

 A: Drying device B: Drying box C: Wavy conveyor device D: Molding device E: Air curtain device Q: Sludge R: Air flow T: Sunlight 3: Sludge transport net (transport belt) 7a, 7b: Blow fan 13: Front Wall part (side wall part) 14: Back wall part (side wall part) 14a: Opening 15: Side wall part 16: Ceiling wall part 18, 26: Deodorizing device

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 3L113 AA08 AB02 AC02 AC25 AC31 AC36 AC45 AC46 AC52 AC60 AC63 AC64 AC74 AC76 AC87 AC90 BA37 DA10 DA24 4D059 AA03 BD02 BD21 BK09 CA03 CA16 CB04

Claims (3)

[Claims] 1. A drying apparatus for drying an object to be dried on a corrugated conveyor device and transporting the object at an extremely low speed by sunlight and ventilation, wherein at least a ceiling wall and a side wall serving as a south surface are formed of a metal plate. And a substantially closed drying box for covering the corrugated conveyor device, and disposed at least above the corrugated conveyor device in the drying box to generate an airflow in the drying box. A blower fan is provided, and the airflow that reverses on the upper surface of the conveyor belt of the corrugated conveyor device exchanges heat while contacting with the walls of the drying box, and generates a circulating airflow in the drying box to perform drying. A drying device characterized by the above-mentioned. 2. The drying apparatus according to claim 1, wherein each of the walls of the drying box formed of a metal plate is formed to have an uneven cross section. 3. An opening is provided in a side wall portion on the north side of the drying box, and the opening is cut off by a belt-like airflow ejected from an air curtain device, and the suction air is removed by a deodorizing device. The drying device according to claim 1, wherein the drying device is configured to be deodorized.