JP3215064U - Humidity adjustment device - Google Patents

Abstract

A humidity adjusting device having a high effect of suppressing fluctuations in humidity is provided. A humidity adjusting device adjusts humidity in an agricultural facility. The humidity adjusting device 1 includes a container 3, an inlet 5 and an outlet 7 provided in the container 3, a porous material installed in the container 3, and an air flow that sequentially passes through the inlet 5, the porous material, and the outlet 7. A fan unit including a fan 13 for generating As the porous material, silica gel 11 is preferable, and B-type silica gel is particularly preferable. The humidity adjusting device 1 further includes a water supply unit that supplies water to the porous material. [Selection] Figure 1

Description

  The present disclosure relates to a humidity control apparatus.

In an agricultural facility such as a greenhouse, if the humidity is too low, the pores of the crop are closed, and it is difficult to absorb CO ₂ and photosynthesis is inhibited. Moreover, when humidity is too high, problems, such as generation | occurrence | production of mold and a disease, will arise. Therefore, it is necessary to control the humidity in the agricultural facility. Patent Document 1 discloses a method for controlling humidity in a greenhouse.

Japanese Utility Model Publication No. 04-040450

  In the conventional method, it has been difficult to sufficiently suppress fluctuations in humidity. An object of one aspect of the present disclosure is to provide a humidity adjusting device that has a high effect of suppressing fluctuations in humidity.

  One aspect of the present disclosure is a humidity adjustment device that adjusts humidity in an agricultural facility, the container, an inlet and an outlet provided in the container, a porous material installed in the container, and the inlet A humidity adjusting device comprising: the porous material; and a blower unit that generates an air flow that sequentially passes through the outlet. The humidity adjusting device according to one aspect of the present disclosure has a high effect of suppressing fluctuations in humidity in an agricultural facility.

1 is a cross-sectional view illustrating a configuration of a humidity adjusting device 1. 1 is a cross-sectional view illustrating a configuration of a humidity adjusting device 1. It is a graph showing the test result in 1st test conditions. It is a graph showing the test result in 2nd test conditions. It is a graph showing the test result in 3rd test conditions. It is a graph showing the test result in 4th test conditions.

An embodiment of the present disclosure will be described with reference to the drawings.
<First Embodiment>
1. Configuration of Humidity Adjustment Device 1 The configuration of the humidity adjustment device 1 will be described with reference to FIG. The humidity adjusting device 1 is installed in an agricultural facility and has an application for adjusting humidity in the agricultural facility. Examples of agricultural facilities include a greenhouse, a plastic house, and a plant factory. In this specification, humidity means relative humidity unless otherwise specified.

  The humidity adjusting device 1 includes a container 3, an inlet 5, an outlet 7, a net 9, a silica gel 11, and a fan 13. Silica gel 11 corresponds to a porous material. The fan 13 corresponds to a blower unit.

  The container 3 includes a main body portion 15, a first duct 17, and a second duct 19. The main body 15 is a hollow container having a cylindrical shape. The axial direction of the main body 15 is the vertical direction. A circular opening 23 is formed on the bottom surface 21 of the main body 15. The opening 23 communicates with the inside and outside of the main body 15. A circular opening 24 is formed in the top plate 22 of the main body 15. The opening 24 communicates with the inside and outside of the main body 15. The inner diameter of the main body 15 is, for example, 60 cm. The height of the main body 15 is, for example, 90 cm.

The first duct 17 is a cylindrical member. The inner diameter of the first duct 17 is smaller than the inner diameter of the main body portion 15. The axial direction of the first duct 17 is the vertical direction. The vicinity of the upper end 25 of the first duct 17 is inserted into the opening 23. The outer peripheral surface of the first duct 17 and the inner peripheral surface of the opening 23 are in contact with each other without a gap. A part of the first duct 17 including the upper end 25 (hereinafter referred to as an upper part 27) is located above the bottom surface 21 and is inside the main body part 15. A portion of the first duct 17 excluding the upper portion 27 is located below the main body portion 15. The inner diameter of the first duct 17 is, for example, 30 cm.
The second duct 19 is a cylindrical member. The inner diameter of the second duct 19 is smaller than the inner diameter of the main body portion 15. The axial direction of the second duct 19 is the vertical direction. The vicinity of the lower end 29 of the second duct 19 is inserted into the opening 24. The outer peripheral surface of the second duct 19 and the inner peripheral surface of the opening 24 are in contact with each other without a gap. A portion of the second duct 19 other than the vicinity of the lower end 29 is located above the main body portion 15. The inner diameter of the second duct 19 is 30 cm, for example.

  The inlet 5 is a lower opening in the first duct 17. The outlet 7 is an upper opening in the second duct 19. Therefore, the inlet 5 and the outlet 7 are provided in the container 3. The container 3 includes an air flow path F that sequentially passes through the inlet 5, the inside of the first duct 17, the inside of the main body 15, the inside of the second duct 19, and the outlet 7.

  The net 9 is attached inside the main body 15. The net 9 divides the internal space of the main body portion 15 into two vertically. The net 9 is located above the upper part 27. The air flowing through the flow path F can pass through the net 9. The mesh size of the net 9 is large enough to hold the silica gel 11.

  The silica gel 11 is installed inside the main body 15, and more specifically, is installed on the net 9. Silica gel 11 is B-type silica gel. The silica gel 11 has a granular form. The silica gel 11 is laminated over the entire net 9. The mass of the silica gel 11 is 20 kg, for example. The capacity of the silica gel 11 is 40 L, for example. The stacking height of the silica gel 11 is 15 cm, for example.

The pore volume of the silica gel 11 is preferably in the range of 0.50 to 1.30 ml / g. The specific surface area of the silica gel 11 is preferably in the range of 250 to 600 m ² / g. The pore diameter of the silica gel 11 is preferably in the range of 5 to 15 nm. B-type or ID-type silica gel has physical properties corresponding to these ranges. When the physical properties of the silica gel 11 are in the above range, the effect of suppressing fluctuations in humidity is high. The physical properties of the silica gel 11 may be between the physical properties of the B-type silica gel and the ID-type silica gel. The RH during humidification is preferably the ID type.
The pore volume of the silica gel 11 is more preferably in the range of 0.50 to 0.90 ml / g. The specific surface area of the silica gel 11 is more preferably in the range of 400 to 600 m ² / g. The pore diameter of the silica gel 11 is more preferably in the range of 5 to 9 nm. When the physical properties of the silica gel 11 are in the above range, the effect of suppressing fluctuations in humidity is even higher.

  The fan 13 is attached to the upper side in the main body 15. The fan 13 is above the silica gel 11, and there is a gap between the fan 13 and the surface of the silica gel 11. The fan 13 generates an air flow that flows along the flow path F. This air flow passes through the net 9 and the silica gel 11. The superficial velocity of the air flow in the first duct 17 and the second duct 19 is, for example, 0.5 m / s. The superficial velocity of the air flow in the silica gel 11 is, for example, 0.12 m / s. The humidity adjusting device 1 can be installed on the ground in a direction shown in FIG.

2. Effect of humidity adjusting device 1 (1A) The humidity adjusting device 1 is installed in an agricultural facility, and the fan 13 is turned on. Then, the air in the agricultural facility is taken in from the inlet 5, flows in the container 3 along the flow path F, and is discharged from the outlet 7. When the humidity in the air in the agricultural facility is high, water vapor in the air is absorbed by the silica gel 11 when the air passes through the silica gel 11. As a result, the air is dehumidified. From the outlet 7, air having a lower humidity than the air taken in from the inlet 5 is released.

  Moreover, when the humidity in the air in an agricultural facility is low, when the air passes through the silica gel 11, the water vapor retained on the silica gel 11 is released into the air. As a result, the air is humidified. From the outlet 7, air having a higher humidity than the air taken in from the inlet 5 is released. Therefore, the humidity adjustment apparatus 1 can suppress the fluctuation | variation of the humidity in an agricultural facility by said effect | action.

  As a result, the humidity adjusting apparatus 1 can suppress the humidity in the agricultural facility from becoming excessively high, and thus can suppress the occurrence of mold, disease, etc. in the agricultural facility. Moreover, since the humidity adjustment apparatus 1 can suppress that the humidity in an agricultural facility becomes low too much, it can accelerate | stimulate the photosynthesis of agricultural products.

(1B) The humidity adjusting device 1 includes B-type silica gel as a porous material. Therefore, the fluctuation | variation of the humidity in an agricultural facility can be suppressed further.
(1C) The humidity adjusting device 1 includes an upper portion 27. Back pressure is applied to the air that has passed through the upper portion 27 in order to pass through the wire mesh 9 and the particle gaps of the silica gel 11. The air with back pressure spread over the entire surface of the wire mesh 9. There is an effect of removing moisture absorbed and released from individual particles of the silica gel 11 by air passing through the particle gaps of the silica gel 11. As a result, the water vapor can be exchanged between the air and the silica gel 11 more efficiently.
Second Embodiment
1. Differences from the First Embodiment Since the basic configuration of the second embodiment is the same as that of the first embodiment, the differences will be described below. Note that the same reference numerals as those in the first embodiment indicate the same configuration, and the preceding description is referred to.

  In 2nd Embodiment, as shown in FIG. 2, the water supply piping 31 is provided. A part of the water supply pipe 31 including one end portion (hereinafter referred to as a distal end portion 33) is inserted into the main body portion 15 from the side surface of the main body portion 15. The tip 33 is located inside the silica gel 11. A plurality of supply ports 35 are formed in the distal end portion 33. The water supply pipe 31 is connected to a water supply source 37 (for example, a water tap) on the side opposite to the tip portion 33. The water supply pipe 31 discharges water flowing from the water supply source 37 through the supply port 35 and supplies it to the silica gel 11. The supply of water to the silica gel 11 may be performed continuously or intermittently. The water supply pipe 31 and the water supply source 37 correspond to a water supply unit. Excess water is discharged from the hole 26 provided in the bottom surface 21.

2. Effects exhibited by the humidity adjusting device 1 According to the second embodiment described in detail above, the effects (1A) to (1C) of the first embodiment described above are exhibited, and the following effects are further achieved.

  (2A) The humidity adjusting apparatus 1 can supply water to the silica gel 11 by the water supply pipe 31 and the water supply source 37. Therefore, when the humidity in the air in the agricultural facility is low, the effect of humidifying the air is even higher. As a result, the humidity in the agricultural facility can be adjusted.

3. Test for confirming the effect of the humidity adjusting device 1 (3-1) Test method
(i) First test condition: The humidity adjusting apparatus 1 was installed in a room with a volume of 13.6 m ³ . An air conditioner with dehumidifying operation was used to maintain a low humidity environment. Silica gel 11 is B-type silica gel (manufactured by Fuji Silysia Chemical). The volume of the silica gel 11 is 20L. The height of the silica gel 11 is 26 cm. The packing density of the silica gel 11 is 0.50 g / cm ³ . A water supply pipe 31 was installed at a position where the height from the wire net 9 was about 5 cm. The physical properties of the silica gel 11 are as follows.

Pore volume: 0.8ml / g
Specific surface area: 450 m ² / g
Pore diameter: 7.0 nm
Next, the humidity adjusting apparatus 1 was operated. The superficial velocity in the silica gel 11 was 0.6 m / s. The amount of water supplied from the water supply pipe 31 to the silica gel 11 was 15 ml / min. The humidity at the inlet 5 and the outlet 7 was continuously measured. The humidity at the entrance 5 reflects the humidity in the room.

  (ii) Second test condition: The test condition is basically the same as the first test condition, but the test was performed with the silica gel 11 removed from the humidity control apparatus 1. The superficial velocity in the main body 15 was 2.2 m / s. Moreover, the water supply by the water supply pipe 31 was stopped.

  (iii) Third test condition: The test condition is basically the same as the first test condition. However, the air conditioner was not used, and a water bath was installed and humidified continuously by heating. Moreover, the water supply by the water supply pipe 31 was stopped.

  (iv) Fourth test condition: The test condition is basically the same as the third test condition, but the test was performed with the silica gel 11 removed from the humidity control apparatus 1. The superficial velocity in the main body 15 was 2.2 m / s. Further, similarly to the third test condition, the supply of water from the water supply pipe 31 was stopped.

(3-2) Test Results FIG. 3 shows the test results under the first test conditions. The test results under the second test conditions are shown in FIG. The test results under the third test conditions are shown in FIG. The test results under the fourth test condition are shown in FIG. The device inlet in FIGS. 3 to 6 means the inlet 5. Device outlet means outlet 7.

In the first test condition in which the silica gel 11 was attached to the humidity adjusting apparatus 1 and operated, a humidity that did not hinder photosynthesis could be secured in spite of the severe conditions of constant dehumidification. In the third test condition, it was possible to secure a humidity at which molds and diseases are unlikely to occur despite severe conditions of constant humidification. Moreover, the fluctuation | variation of the humidity was suppressed also in any of the 1st test condition and the 3rd test condition. On the other hand, under the second test conditions in which the silica gel 11 was removed from the humidity control apparatus 1 and operated, humidity that did not hinder photosynthesis could not be secured. Under the fourth test condition, it was not possible to secure a humidity at which molds and diseases are difficult to occur. Moreover, the fluctuation | variation of the humidity was large also in any of the 2nd test condition and the 4th test condition.
<Other embodiments>
As mentioned above, although embodiment of this indication was described, this indication is not limited to the above-mentioned embodiment, and can carry out various modifications.

(1) Instead of the silica gel 11, another porous material may be used. Examples of other porous materials include cardboard.
(2) Silica gel 11 may be silica gel other than B-type silica gel. For example, the silica gel 11 may be ID type silica gel or the like.

The pore volume of the ID type silica gel is preferably in the range of 0.9 to 1.3 ml / g. The specific surface area of the ID type silica gel is preferably in the range of 250 to 370 m ² / g. The pore diameter of the ID type silica gel is preferably in the range of 9 to 15 nm. The packing density of the ID type silica gel is preferably in the range of 0.40 to 0.48 g / ml. When the physical properties of the ID-type silica gel are in the above range, the effect of suppressing fluctuations in humidity is even higher.

(3) The position of the fan 13 can be selected as appropriate. For example, the position of the fan 13 may be positioned upstream of the silica gel 11 with respect to the flow path F. The fan 13 may be built in the main body 15 or may be attached to the outside of the main body 15.
(4) The type of the fan 13 is not particularly limited, and can be appropriately selected from known fans.

  (5) A function of one component in each of the above embodiments may be shared by a plurality of components, or a function of a plurality of components may be exhibited by one component. Moreover, you may abbreviate | omit a part of structure of each said embodiment. In addition, at least a part of the configuration of each of the above embodiments may be added to or replaced with the configuration of the other above embodiments. It should be noted that all aspects included in the technical idea specified from the words described in the claims of the utility model registration are embodiments of the present disclosure.

  (6) In addition to the humidity adjusting device described above, the present disclosure can be realized in various forms such as a system including the humidity adjusting device as a constituent element and a humidity adjusting method.

DESCRIPTION OF SYMBOLS 1 ... Humidity adjustment apparatus, 3 ... Container, 5 ... Inlet, 7 ... Outlet, 9 ... Net, 11 ... Silica gel, 13 ... Fan, 15 ... Main part, 17 ... 1st duct, 19 ... 2nd duct, 21 ... Bottom , 22 ... top plate, 23 ... opening, 24 ... opening, 25 ... upper end, 27 ... upper part, 29 ... lower end, 31 ... water supply piping, 33 ... tip part, 35 ... supply port, 37 ... water supply source

Claims (4)

A humidity adjusting device for adjusting humidity in an agricultural facility,
A container,
An inlet and an outlet provided in the container;
A porous material installed in the container;
A blower unit that creates an air flow through the inlet, the porous material, and the outlet sequentially;
A humidity control device comprising: The humidity adjusting device according to claim 1,
A humidity adjusting device further comprising a water supply unit for supplying water to the porous material. The humidity adjusting device according to claim 1 or 2,
The humidity adjusting device, wherein the porous material is silica gel. The humidity control apparatus according to any one of claims 1 to 3,
The humidity adjusting device, wherein the porous material is B-type silica gel.