JPH07163828A - Dehumidification drying device - Google Patents

Abstract

PURPOSE:To provide a dehumidification drying device in which drying treatment is easily performed in desired dryness corresponding to the kind of material subject to drying and capacity of treatment is increased without using a large- sized dehumidifying unit and the whole device is miniaturized. CONSTITUTION:Air sent from a blower 4 is dehumidified by a dehumidifying unit 3. The dehumidified air is introduced into a hopper 1 for drying through a dehumidified air-supplying path 2b to dry the material (m) to be dried. The air used is again returned to the blower 4. In a dehumidification drying device A, a bypass pipeline part 2d is formed in an air-supplying path 2a through which the air to be dehumidified is led from the blower 4 to the dehumidifying unit 3. A part of air sent from the blower 4 is bypassed to the dehumidified air-supplying path 2b through the bypass pipeline part 2d. Furthermore flow rate controlling valves 8, 8a are disposed to at least either of the bypass pipeline part 2d and the air-supplying path 2a.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dehumidifying / drying device of a type in which a material to be dried such as synthetic resin pellets is subjected to a drying treatment by acting dehumidified air.

[0002]

2. Description of the Related Art Conventionally, as this type of dehumidifying / drying device,
For example, the applicant of the present application has previously proposed the one described in Japanese Utility Model Publication No. 1-167318. As shown in FIG. 4, the schematic configuration of this conventional device is as follows: after air supplied from a blower 4e passes through a dehumidifying unit 3e to be dehumidified, it is appropriately heated by a heater 9e before being placed in a drying hopper 1e. By being introduced, this drying hopper 1
The material to be dried such as synthetic resin pellets contained in e is dried. The air introduced into the drying hopper 1e and used for the drying process is reduced to the intake side of the blower 4e, and the air is circulated and used.

[0003]

However, in the above-mentioned prior art, since the entire amount of the air blown by the blower 4e is supplied to the dehumidifying unit 3e and the entire amount is constantly dehumidified, the dehumidifying unit is It was necessary to match the processing capacity of 3e with the processing capacity of other drying hoppers 1e, heaters 9e, and the like. Therefore,
In order to increase the drying treatment capacity of the entire apparatus, it is inevitably necessary to use the large dehumidifying unit 3e, and as a result, the entire apparatus becomes large and the installation cost of the apparatus becomes expensive.

In this type of dehumidifying / drying device, the material to be dried is not always the same in actual use, and depending on the type of material, a high degree of dryness is required or is rather high. In some cases, dryness is not required. However, in the above-mentioned conventional method, it is difficult to appropriately adjust the dryness of the material to be dried according to the type of the material as described above, and even a material that does not require a very high dryness can be provided with a high dryness by the dehumidifying unit 3e. Dehumidified air may be supplied into the drying hopper 1e, and the material may be dried with a higher degree of drying than necessary. With this,
Not only is it wasteful in terms of processing efficiency of the drying process, but there is also a possibility that the quality of the material may be impaired by overdrying, and there is room for improvement in this respect as well.

The present invention has been proposed in view of the above points, and can easily perform a drying process with a desired dryness according to the type of material to be dried and the like without using a large dehumidifying unit. It is an object of the present invention to provide a dehumidifying / drying device capable of increasing the capacity and downsizing the entire device.

[0006]

A dehumidifying / drying apparatus according to the present invention proposed to achieve the above object is a dehumidifying unit for dehumidifying air blown from a blower, and a drier for containing a material to be dried. Hopper, a dehumidifying air supply path for introducing the dry air dehumidified by the dehumidifying unit into the drying hopper, and a use introduced into the drying hopper and used for the drying treatment of the material to be dried. In the dehumidifying / drying device having a return path of used air for reducing the used air to the blower, one of the air blown from the blower is provided in the air supply path for guiding the air to be dehumidified from the blower to the dehumidifying unit. A bypass pipe part for bypassing a part to the dehumidified air supply route is provided, and the bypass pipe part and the air supply route On at least one of the person, the dehumidified air amount and the flow rate control valve for changing or decreasing the introduced to the air amount and the dehumidifying unit is bypassed to the air supply path side.

[0007]

In the dehumidifying / drying apparatus according to the present invention having the above-mentioned structure, a part of the air blown by the blower can be introduced into the dehumidifying unit to obtain dry air, while the other remaining air is supplied. By bypassing to the dehumidifying air supply path through the bypass piping section, the air dehumidified in the dehumidifying unit and the air passing through the bypass piping section can be mixed and introduced into the drying hopper,
This air can be used to dry the material to be dried. Therefore, it is not necessary for the dehumidifying unit to be a large dehumidifying unit having the ability to dehumidify the entire amount of air blown from the blower to a certain degree of dryness. As long as the material to be dried is not required to have a very high degree of dryness, an appropriate drying process can be performed even with dry air in which two types of air are mixed as described above, and there is no problem.

Further, the dryness of the dry air introduced into the drying hopper is adjusted by adjusting a flow control valve provided in at least one of the bypass pipe section and the air supply path, By increasing / decreasing the amount of air passing through the unit and the amount of air passing through the dehumidifying unit, the amount can be arbitrarily adjusted. That is, if the amount of air passing through the bypass pipe section is small and the proportion of dehumidified air dehumidified by the dehumidifying unit is increased, it is possible to introduce dry air with a high degree of dryness into the drying hopper,
The material to be dried can be processed to a high degree of dryness. On the contrary, if the amount of air passing through the bypass piping is increased, the material to be dried can be processed in a low dry state. As a result, the dry finish of the material to be dried can be easily controlled by adjusting the flow rate control valve.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory diagram showing an example of a dehumidifying / drying apparatus A according to the present invention. The dehumidifying / drying apparatus A includes a drying hopper 1 for accommodating a material m to be dried, a dehumidifying unit 3 for dehumidifying and drying air supplied to the drying hopper 1, and an air for the dehumidifying unit 3. A blower 4 for blowing air, an air supply path 2a that constitutes a circulation path of air blown from the blower 4, a dehumidified air supply path 2b, a return path 2c, and a bypass piping section 2d. ing.

Of the above, the dehumidifying unit 3 has a cylindrical dehumidifying rotor 30 formed by arranging an adsorbent (hygroscopic agent) such as silica gel or synthetic zeolite (trade name: Moricula Sieve) in a honeycomb shape as a motor. It can be freely rotated by. The dehumidifying rotor 30 is used in the adsorption zone N.
1, a regeneration zone N2, and a cooling zone N3, which are divided into three zones, of which the adsorption zone N1 has a blower 4
The air supplied from the air supply path 2a from the air is supplied to dehumidify the air. In the regeneration zone N2, the adsorbent that has adsorbed moisture is regenerated by the heated air supplied through the filter 5, the blower 6, and the heater 7. In the cooling zone N3, a part of low temperature air supplied through the air supply path 2a is introduced to cool the adsorbent. This is because the adsorbent such as synthetic zeolite has a characteristic that its adsorbed amount increases as the temperature becomes lower, and the dehumidifying ability is enhanced. With the above configuration,
While the adsorbent of the dehumidifying rotor 30 is sequentially regenerated and cooled, the air blown from the blower 4 can be continuously dehumidified in the adsorption zone N1.

The bypass piping section 2 is provided in the air supply path 2a.
d is branched and provided, but this bypass piping section 2
The other end side of d is a dehumidified air supply path 2 for supplying the air dehumidified by the dehumidifying unit 3 to the drying hopper 1 side.
connected to b. As a result, in the dehumidified air supply path 2b, the air dehumidified by the dehumidifying unit 3 and the air that has passed through the bypass pipe section 2d without being dehumidified by the dehumidifying unit 3 can be mixed with each other. . Further, flow rate control valves 8 and 8a are provided at both of the bypass piping portion 2d and the position of the air supply path 2a at a stage subsequent to the branching position of the bypass piping portion 2d, and flow through the bypass piping portion 2d. The air amount and the air amount that passes through the air supply path 2a and is supplied to the dehumidifying unit 3 can be arbitrarily adjusted to be increased or decreased. As these flow control valves 8 and 8a, it is desirable to apply remote control type valves.

The drying hopper 1 has a dehumidified air supply path 2
A heater 9 for heating the dehumidified air supplied through b to an appropriate temperature is provided, and the heated dry air heated by the heater 9 is introduced into the hopper. A return path 2c for returning the used air used for the drying process of the material m to be dried to the intake side of the blower 4 is connected to an appropriate position such as the upper surface of the drying hopper 1. In this return path 2c,
The air that has passed through the cooling zone N3 of the dehumidifying unit 3 is also configured to join, and the filter 10 and the cooling device 11 are appropriately provided.

Next, an example of use and operation of the dehumidifying / drying apparatus A having the above structure will be described. First, depending on the type of the material m to be dried, in order to sufficiently dry the material m to be dried, for example, the dew point is −40 in the drying hopper 1.
It may be necessary to introduce dry air of [° C]. In such a case, as the dehumidifying unit 3, for example, a constant air of 40 [m ³ / Hr] is -40 [°].
Supposing that a dehumidifying capacity capable of dehumidifying and drying up to the dew point of C] is adopted, in this case, the flow control valve 8 of the bypass piping section 2d is closed and the flow control valve 8a of the air supply path 2a is closed.
Open and blower 40 to dehumidifying unit 3 40
If air is supplied in an amount of [m ³ / Hr], the material to be dried m
Can be dried to the desired state.

On the other hand, depending on the kind of the material m to be dried, dry air having a dew point of -40 [° C] is not required,
For example, it may be sufficient to introduce dry air having a dew point of about 0 [° C] into the drying hopper 1. In such a case, the flow control valve 8 of the bypass pipe section 2d is opened, and the total blown air amount of the blower 4 is set to, for example, 80 [m ³ / H].
r] or more, of which 40 [m ³ / Hr] of air is supplied to the dehumidifying unit 3 similarly to the above, while an appropriate amount of air blown from the blower 4 (40 [M ³ / Hr]) should be bypassed.

In this way, the air having passed through the bypass pipe section 2d is mixed with the dew point -40 [° C] dehumidified by the dehumidifying unit 3 in the dehumidified air supply path 2b. Dry air having a dew point of about 0 [° C] can be obtained. Further, since this dry air can be supplied into the drying hopper 1 and used for the drying process, it is possible to eliminate the situation where the material m to be dried is over-dried. Moreover, in this case, the total amount Q of dry air supplied into the drying hopper 1 is equal to the amount Q1 of air supplied into the dehumidifying unit 3 and the bypass pipe portion 2
The sum of the amount of air Q2 passing through d and the amount of dry air Q introduced into the drying hopper 1 can be made larger than the processing capacity of the dehumidifying unit 3. Therefore, even if the dehumidifying unit 3 is not made large, it is possible to enhance the drying processing capacity of the dehumidifying / drying apparatus A.

Furthermore, if the amount Q2 of air passing through the bypass pipe section 2d is increased or decreased, the dew point of the dry air introduced into the drying hopper 1 can be arbitrarily changed. It is possible to arbitrarily adjust the drying degree according to the type of m and the like.

In the above embodiment, the bypass piping section 2d is used.
Although the flow rate control valves 8 and 8a are provided on both the air supply path 2a and the air supply path 2a, the present invention is not limited to this. For example,
The flow control valve 8 may be provided only on the side of the bypass piping portion 2d as shown in FIG. 2, or the flow control valve 8a may be provided only on the side of the air supply path 2a as shown in FIG. Even in these cases, the mixing ratio of the air dehumidified by passing through the dehumidifying unit 3 and the air passing through the bypass piping portion 2d can be arbitrarily changed by adjusting the flow rate control valve 8 or 8a, It is possible to achieve the object of the present invention.

Further, in the present invention, the specific constitutions of the dehumidifying unit 3, the drying hopper 1 and the like are not limited to those of the above embodiment, and the design can be arbitrarily changed. Further, the blower referred to in the present invention may be any one as long as it has a function of blowing air, and is a concept regardless of the type of fan, air pump, or the like. Besides, in the present invention, the specific type of the material to be dried is not limited to the synthetic resin pellets.

[0019]

As can be understood from the above description, according to the dehumidifying / drying apparatus of the present invention, when it is not necessary to finish the material to be dried to a very high degree of dryness, the air used for the drying treatment is By dehumidifying only part of it with the dehumidifying unit and bypassing the remaining air, the total amount of air used for the drying process can be greater than the dehumidifying processing capacity of the dehumidifying unit. As a result, it is possible to obtain a special effect that the drying processing capacity can be improved after downsizing the entire apparatus. Moreover, the drying condition of the dry air introduced into the drying hopper can be arbitrarily adjusted by the flow rate control valve provided in at least one of the bypass pipe section and the air supply path, so that the type of material to be dried, etc. The degree of dryness can be appropriately adjusted according to the above, and there is an advantage that it is possible to easily prevent overdrying.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing an example of a dehumidifying / drying device according to the present invention.

FIG. 2 is a principal part explanatory view showing another example of the dehumidifying and drying apparatus according to the present invention.

FIG. 3 is a principal part explanatory view showing another example of the dehumidifying and drying apparatus according to the present invention.

FIG. 4 is a schematic explanatory view showing an example of a conventional dehumidifying and drying apparatus.

[Explanation of symbols]

 1 Drying hopper 2a Air supply path 2b Dehumidification air supply path 2c Return path 2d Bypass piping part 3 Dehumidification unit 4 Blower 8,8a Flow control valve 9 Heater 10 Filter 11 Cooling device m Drying target material A Dehumidification drying device

Claims (1)

[Claims] 1. A dehumidifying unit for dehumidifying air blown from a blower, a drying hopper for containing a material to be dried, and a dry air dehumidified by the dehumidifying unit into the drying hopper. In a dehumidifying and drying apparatus having a dehumidified air supply path, and a return path of the used air introduced into the drying hopper to reduce the used air used for the drying process of the material to be dried to the blower, In the air supply path for guiding the air to be dehumidified from the blower to the dehumidifying unit, a bypass pipe section for bypassing a part of the air blown from the blower to the dehumidified air supply path is provided in a branched manner, and At least one of the bypass piping section and the air supply path has an empty space bypassed to the dehumidified air supply path side. The amount that the dehumidified air quantity introduced into the unit and the flow control valve to change increase or decrease the are provided with dehumidifying and drying apparatus characterized.