JP2000146433A - Dryer for hydrous substance - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a dryer for a hydrous substance which can be operated continuously without causing any scorch due to hot air. SOLUTION: A cylindrical hollow chamber 22 is installed laterally while containing a large number of balls 11 of a specified diameter principally comprising a metal. A cylindrical box type upper hollow chamber 23 communicating with the hollow chamber 22 is disposed above the hollow chamber 22. A hot air supply passage 24 having a forward end opening to the circumferential surface of the hollow chamber 22 in the vicinity of the bottom part thereof is installed along the tangential direction of the hollow chamber 22. A hydrous substance supply passage 25 having a forward end opening to the circumferential surface of the hollow chamber 22 is installed between the upper hollow chamber 23 and the hot air supply passage 24. An opening 26 for taking out dried hydrous substance projects from one side face of the upper hollow chamber 23.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an apparatus for drying a hydrated substance. Specifically, an object of the present invention is to provide an apparatus for drying a water-containing substance that can be continuously operated without causing the material to be dried to be scorched by hot air.

[0002]

2. Description of the Related Art As a conventional example of an apparatus for drying a water-containing substance, a tofu husk drying apparatus for drying tofu husk (okara) is shown in FIG. 4 and described (see JP-A-6-1055663). Here, FIG. 4 is a longitudinal sectional view showing the configuration of the device.

In FIG. 4, a cylindrical hollow chamber 42 is provided on a base 41, to which tofu to be dried is supplied. Ceramic ball 3 which is a spherical body made of ceramic of diameter 3
1 is housed.

[0004] The chemical composition of the ceramic balls 31, as shown in FIG. 5, materials represented by the molecular formula of SiO ₃ 7
2.86 percent, a substance is 20.59 percent represented by the molecular formula Al ₂ O _3, other, Fe ₂ 0
₃ , substances represented by the molecular formulas of CaO.MgO and K ₂ O.Na ₂ O are included.

The physical characteristics of the ceramic ball 31 are shown in FIG. 6, and the bulk specific gravity is 2.37.
Where the flexural strength is 600 kg / cm 2 and the compressive strength is 3200 kg / cm 2.

[0006] Such a ceramic ball 31 has a diameter of 1.5 to 6.0 mm and a capacity of 300.
Approximately 0 to 65,000 pieces (weight: 0.8 to 1.0 kg) are preferable, and all of them may have the same diameter, or may have different diameters. Is done. In FIG. 4, the size of the ceramic ball 31 is exaggerated for convenience of explanation.

Above the hollow chamber 42, an upper hollow chamber 43 formed in the shape of a box cylinder is disposed, and the lower end thereof communicates with the hollow chamber 42. A take-out port 46 formed in a cylindrical shape for taking out the dried tofu hull is projected.

On the peripheral surface near the bottom of the hollow chamber 42, a hot air supply for supplying hot air from a hot air generating source (not shown) disposed along a tangential direction of the circumference of the hollow chamber 42. The tip of the passage 44 is open. Further, between the hot air supply path 44 and the upper hollow chamber 43, tofu
2, a tofu shell supply path 45 is provided so as to protrude with its tip opened to the peripheral surface of the hollow chamber 42,
Above the opening at the front end, a rotary feeder 47 of an outside air blocking type for supplying a constant amount of tofu husk is provided. The structures of the upper hollow chamber 43, the hot air supply path 44, and the tofu shell supply path 45 are not particularly limited, but are preferably formed in a rectangular cross section having substantially the same width as the cylinder length of the hollow chamber 42. It has been.

Next, the operation of the tofu husk drying apparatus constructed as described above will be described.
Prior to supplying the tofu shell into the hollow chamber 42, hot air of a required wind pressure from a hot air source (not shown) is supplied into the hollow chamber 42 via a hot air supply path 44. The supplied hot air flows clockwise in the drawing along the inner peripheral surface of the hollow chamber 42, and thereby the inside of the hollow chamber 42 is heated. Also,
The hot air supplied into the hollow chamber 42 is split into the upper hollow chamber 43 and rises, so that the inside of the upper hollow chamber 43 is also heated.

At this time, the large number of ceramic balls 31 accommodated in the hollow chamber 42 are blown off by the supplied hot air, and as shown in FIG. And repeatedly bounces back and forth in the hollow chamber 42 and the upper hollow chamber 43.

Then, when the rotary feeder 47 is operated, the tofu hulls are passed through the
And the supplied tofu hulls are continuously supplied into the hollow chamber 4.
Fall towards the bottom of 2. The tofu hulls dropped and supplied into the hollow chamber 42 rise along the inner peripheral surface of the hollow chamber 42 while being dried by the hot air supplied through the hot air supply path 44. The tofu hull that has risen inside the hollow chamber 42 is
The lower end 3 collides with the rim portion 48 at the lower end and is finely pulverized. This pulverization increases the heat transfer area of the tofu.

The tofu crushed and dried by hot air and reduced in weight rises in the upper hollow chamber 43 together with the hot air diverted into the upper hollow chamber 43, and the drying is further promoted during the rising. . The tofu hull which rises inside the upper hollow chamber 43 and is completely dried and becomes powdery reaches the upper end of the upper hollow chamber 43, and is taken out by hot air through an outlet 46 provided therein. Taken out.

In the above-described drying process, a large number of ceramic balls 31 blown off by hot air are formed in the hollow chamber 42.
And it flies endlessly in the upper hollow chamber 43. As a result, the tofu hull is formed on the inner peripheral surface of the hollow chamber 42 and the upper hollow chamber 43.
Even if it adheres to the inner wall, a large number of ceramic balls 31 colliding against the inner wall scrape off the adhering tofu hull, thereby preventing the tofu hull from sticking.

[0014]

SUMMARY OF THE INVENTION
Although it can be obtained according to the conventional example shown in FIG. 4, there are the following problems to be solved as a device for drying a hydrated substance. That is, in this conventional example, as a means for preventing the tofu shells from sticking to the inner peripheral surface of the hollow chamber 42 and the inner wall of the upper hollow chamber 43, the ceramic balls 31 are blown off by hot air and And the inner wall of the upper hollow chamber 43.

Here, the inventor of the present application conducted an experiment in which a water-containing substance (for example, porcelain clay) having a higher specific gravity than tofu husks was dried by the apparatus. In this experiment, hot air having a higher wind pressure than that of the tofu husk was required in order to blow a water-containing substance having a higher specific gravity than the tofu hull by the hot air in the hollow chamber 42.

That is, in the conventional example shown in FIG. 4, when the tofu crust is dried using the hollow chamber 42 having a volume of 0.018 cubic meters, if hot air with a static pressure of 400 mmAq is supplied into the hollow chamber 42, You can fly the tofu shells stored here. On the other hand, a hollow chamber 4 having the same volume
When drying clay with a specific gravity higher than that of tofu using the method 2, it is necessary to supply hot air having a static pressure of 600 to 900 mmAq.

However, if the wind pressure of the hot air supplied into the hollow chamber 42 is higher than that in the case of the tofu husk, the lightweight ceramic balls 31 are moved by the wind pressure.
It is blown up in 3. Then, the blown-up ceramic balls 31 are discharged to the outside through the outlet 46 of the upper hollow chamber 43 together with the dried material to be dried. Therefore, it is necessary to select the ceramic balls 31 contained in the material to be dried taken out from the outlet 46.

To cope with this, if a larger and heavier ceramic ball 31 is used,
The number of ceramic balls 31 that can be accommodated in the hollow chamber 42 is reduced. However, when the number of the ceramic balls 31 is small, the number of times that the ceramic balls 31 collide with the inner peripheral surface of the hollow chamber 42 and the inner wall of the upper hollow chamber 43 decreases. As a result, as compared with the case where the ceramic ball 31 having a small diameter is used, the area where the ceramic ball 31 collides with the inner peripheral surface or the like of the hollow chamber 42 is reduced.
The water-containing substance remains adhered to the inner peripheral surface and the like, and eventually becomes scorched.

When the pressure of the hot air supplied into the hollow chamber 42 is increased, the ceramic balls 31 may be moved by the inner peripheral surface of the hollow chamber 42 or the upper hollow chamber 4 depending on the set wind pressure.
When it collides with the inner wall of No. 3, it is crushed due to insufficient mechanical strength. The fragments of the crushed ceramic balls 31 are lifted by hot air rising in the upper hollow chamber 43 because of their light weight, and are discharged to the outside through the outlet 46 of the upper hollow chamber 43.

Therefore, the collision of the ceramic ball 31 with the inner peripheral surface of the hollow chamber 42 and the inner wall of the upper hollow chamber 43 is not repeated, and as a result, the inner peripheral surface of the hollow chamber 42 is dried. The effect of avoiding sticking and preventing burning can not be obtained.

As described above, according to the conventional example shown in FIG. 4, a water-containing substance having a higher specific gravity than tofu hulls cannot be dried without causing scorching. There was a problem to be solved in which objects were limited.

[0022]

The present invention has been made in order to solve the above-mentioned problems. For this purpose, in the present invention, a means for preventing the scorching of the hydrated substance adhered to the inner peripheral surface of the hollow chamber or the inner wall of the upper hollow chamber by receiving and colliding with the hot air, thereby preventing the scorching by the hot wind A ball having the same mechanical diameter as that of the ceramic ball used in the conventional example but having a large mechanical strength was used.

That is, a cylindrical hollow space provided horizontally,
A box-shaped upper hollow chamber disposed above the hollow chamber and having a lower end communicating with the hollow chamber is provided, and a hot air supply path for supplying hot air from a hot air generating source is provided near the bottom of the hollow chamber. The tip is open to the peripheral surface of the hollow chamber and is disposed along the tangential direction of the circumference of the hollow chamber, and a water-containing substance supply path for supplying a water-containing substance into the hollow chamber is provided by the upper hollow chamber and the hot air supply path. The upper end of the upper hollow chamber is provided with an outlet for taking out the dried hydrated substance on one side of the upper hollow chamber. Thus, a large number of balls having a predetermined diameter containing metal as a main component are accommodated in the hollow chamber.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention is shown in FIG.
And will be described. Here, FIG. 1 is a perspective view, partially cut away, of the apparatus for drying a hydrated substance in the present embodiment.

In FIG. 1, a base 21, a hollow chamber 22, an upper hollow chamber 23, a hot air supply path 24, a water-containing substance supply path 25,
The take-out port 26 and the rotary feeder 27 are the base 41, the hollow chamber 42, the upper hollow chamber 43, the hot air supply path 44, the tofu shell supply path 45, and the take-out port 46 in the conventional example shown in FIG.
Since the configuration is the same as that of the rotary feeder 47, the description thereof is omitted.

Therefore, the present embodiment differs from the conventional example shown in FIG. 4 in that a large number of balls 11 having a different chemical composition from the conventional ceramic balls 31 are accommodated in the hollow chamber 22. And a hopper 28 for containing a water-containing substance to be supplied into the hollow chamber 22 is connected to the rotary feeder 27.

As shown in FIG. 2, the chemical composition of the ball 11 accommodated in the hollow chamber 42 is 93.38% for Al ₂ O ₃ , 5.12% for SiO ₃ , and Fe _{20. 3} , CaO.MgO and K ₂ O.Na ₂ O are slightly contained. Thus, in the present invention, unlike the conventional example shown in FIG. 4, and the Al ₂ O ₃ as a main component of the ball 11.

The physical properties of the ball 31 are, as shown in FIG. 3, a bulk specific gravity of 3.6, which is larger than that of the ceramic ball 31 (FIG. 1). The bending strength is 28
00 kilograms per square centimeter and the compressive strength is 16000 kilograms per square centimeter.
This is about 4.7 times the flexural strength and 5 times the compressive strength as compared with the ceramic ball 31 in the conventional example shown in FIG.

As in the conventional example shown in FIG. 4, such a ball 11 has a diameter of 1.5 to 6.0 millimeters and preferably has a capacity of about 3000 to 65000 pieces. Or different diameters may be mixed. In FIG. 1, the size of the ball 11 is exaggerated.

Using this apparatus having the above configuration,
A description will be given of the case of drying a fluid clay containing, for example, water as a water-containing substance. First, the clay is stored in the hopper 28 before the apparatus is started. Then, when the apparatus is started, the clay is dropped and supplied into the hollow chamber 22 under the operation of the rotary feeder 27.

At this time, since the potter's clay has a higher specific gravity than the tofu crust, the pressure of the hot air to be supplied is made higher than that of the conventional example shown in FIG. 4 and the hot air having a static pressure of about 600 mmAq is supplied to the hot air supply path 24. Through the hollow chamber (volume is 0.018
(Cubic meter) 22. Thereafter, in the same manner as described in the conventional example, the inside of the hollow chamber 22 and the upper hollow chamber is dried by hot air, and the dried porcelain clay is removed from the outlet 2 provided at the upper end of the upper hollow chamber 23.
6 will be taken out.

In the drying process, a large number of balls 11 housed in the hollow chamber 22 are blown off by hot air and repeatedly hit the inner peripheral surface of the hollow chamber 22 and the inner wall of the upper hollow chamber 23. , The ceramic
Since the mechanical strength is significantly higher than the ball 31, the ball 11 is not crushed by such a collision.

Therefore, even when a water-containing substance having a higher specific gravity than tofu husk such as porcelain clay is dried, continuous operation can be performed according to the present invention, and sufficient measures can be taken.

In the above, the case where the clay is dried by the present apparatus has been described as an example. However, according to experiments performed by the present inventor, in addition to the above, fruits such as soy sauce, anko and apple, pomace, finely cut or crushed vegetables, ground taro, mozuku, or a raw material of synthetic resin, Furthermore, experimental results have shown that the sediment in the septic tank in the process of producing recycled paper can be sufficiently dried by the water-containing substance drying apparatus according to the present invention.

The main component of the ball 11 is Al ₂ O ₃
Is not limited to that shown in FIG. 2, and may be in the range of 70 to 98%, and the main component of the ball 11 may be a metal other than Al ₂ O _3. .

[0036]

As is apparent from the above description, according to the present invention, the water-containing substance supplied into the hollow chamber adheres to the inner peripheral surface of the hollow chamber and the inner wall of the upper known hollow chamber and receives hot air. As a means to prevent scorching, a ball mainly composed of a metal having a higher bulk specific gravity than a ceramic ball is made to collide with the inner peripheral surface of the hollow chamber and the inner wall of the upper hollow chamber by hot air. . Therefore, even when supplying hot air having a high wind pressure to blow a water-containing substance having a large specific gravity into the hollow chamber, it is not necessary to increase the diameter of the ball, and a large amount of balls can be accommodated in the hollow chamber.

Therefore, since the number of times the ball collides with the inner peripheral surface of the hollow chamber and the like does not decrease, the area of the inner peripheral surface and the like of the hollow chamber where the ball collides does not decrease. Burning due to adhesion of a water-containing substance to the inner peripheral surface or the like can be prevented.

Further, since a ball having a high mechanical strength is used as a main component of a metal, the ball is not crushed at the time of collision with the inner peripheral surface of the hollow chamber or the like. Drying can be surely and continuously performed without causing scorching. Therefore, according to the present invention, a practically remarkable effect can be obtained.

[Brief description of the drawings]

FIG. 1 is a partially cutaway perspective view showing an embodiment of the present invention.

FIG. 2 is a display diagram showing a chemical composition of the ball shown in FIG.

FIG. 3 is a display diagram showing physical characteristics of the ball shown in FIG. 1;

FIG. 4 is a longitudinal sectional view showing a configuration of a conventional example.

FIG. 5 is a display diagram showing a chemical composition of the ceramic ball shown in FIG. 4;

FIG. 6 is a display diagram showing physical characteristics of the ceramic ball shown in FIG. 4;

FIG. 7 is an explanatory view for explaining a state of movement of the ceramic ball shown in FIG. 4 in the hollow chamber and the upper hollow chamber.

[Explanation of symbols]

 Reference Signs List 11 ball 21 base 22 hollow chamber 23 upper hollow chamber 24 hot air supply path 25 water-containing substance supply path 26 outlet 27 rotary feeder 28 hopper 31 ceramic ball 41 base 42 hollow chamber 43 upper hollow chamber 44 hot air supply path 45 tofu Shell supply path 46 Outlet 47 Rotary feeder 48 Edge

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 3L113 AB03 AC01 AC45 AC46 AC49 AC52 AC54 AC56 AC63 AC67 AC76 AC77 AC79 BA01 CA01 DA05 DA07 4B020 LC10 LG07 LP20 4B022 LA04 LB06 LR01 LT05

Claims (3)

[Claims] 1. A horizontal hollow cylindrical chamber (22) accommodating a large number of balls (11) mainly composed of metal and having a predetermined diameter, and a lower end disposed above the hollow chamber and having a lower end. A box-shaped upper hollow chamber (23) that communicates with the hollow chamber; and a tip near the bottom of the hollow chamber that is open to the peripheral surface of the hollow chamber and disposed along a tangential direction of the circumference of the hollow chamber. A hot-air supply path (24) for supplying hot air from a hot-air generation source, and a tip end opened between the upper hollow chamber and the hot-air supply path on the peripheral surface of the hollow chamber to protrude. A water-containing substance supply passage (25) provided for supplying a water-containing substance into the hollow chamber, and a suction port protruding from one side surface of the upper hollow chamber for taking out the dried water-containing substance. An apparatus for drying a hydrated substance, comprising an outlet (26). Wherein the main component material in which the ball is represented by the molecular formula of _{Al 2 O 3, SiO 3,} Fe 2 O 3, CaO
· MgO and K ₂ O · Na ₂ O drying apparatus the water-containing material according to claim 1, wherein it is made of a material represented by the molecular formula. 3. The compound represented by the molecular formula of Al ₂ O ₃ having a compounding ratio of 70 to 98%.
An apparatus for drying a hydrous substance according to the above.