JP2019154400A - Management system of plant cultivation chamber, and management control method of plant cultivation chamber - Google Patents

Abstract

To provide a management system of a plant cultivation chamber and a management control method of a plant cultivation chamber which have a simple configuration and are capable of performing regeneration processing of zeolite used in a plant cultivation chamber.SOLUTION: A management system comprises: a dehumidifying device which dehumidifies exhaust gas generated in combustion treatment by allowing moisture of the exhaust gas to be adsorbed to zeolite in a dehumidifying tower; a COfeeding device which, when dehumidified exhaust gas flows in, recovers carbon dioxide by allowing zeolite in a pooling tower to adsorb CO, and when air with low COconcentration flows in, feeds COinto a cultivation chamber by allowing COadsorbed to zeolite in the pooling tower to be desorbed; a heater for dehumidifying tower which heats zeolite in the dehumidifying tower; a heater for pooling tower which heats zeolite in the pooling tower; and a controller which turns the heater for dehumidifying tower to an ON state when regeneration processing timing of zeolite in the dehumidifying tower comes, and turns the heater for pooling tower to an ON state when regeneration processing timing of zeolite in the pooling tower comes.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a plant cultivation room management system and a plant cultivation room management control method.

In general, in plant cultivation, by increasing the concentration of carbon dioxide (CO ₂ ), the photosynthesis of plants can be promoted to increase the growth. Therefore, by installing a CO ₂ supply device to the cultivation room, the process for supplying the CO ₂ is carried out the cultivation room as needed.

The CO ₂ supply device contains zeolite inside, takes in the exhaust gas generated by the combustion device installed to heat the cultivation room, adsorbs the CO ₂ contained in the exhaust gas to the zeolite, and temporarily Store in. And CO ₂ is supplied into the cultivation room by desorbing the stored CO ₂ from the zeolite during the day when the plant performs photosynthesis.

Japanese Patent No. 5578469

Since zeolite has a high moisture adsorption capacity, a large amount of moisture is adsorbed by the zeolite when the exhaust gas containing a large amount of water is passed through the above-described CO ₂ supply device, and the amount of CO ₂ adsorption decreases. For this reason, in order to efficiently adsorb more CO ₂ to the zeolite, it is necessary to remove the moisture in the exhaust gas generated in the combustion apparatus as much as possible and incorporate it into the CO ₂ supply apparatus.

Therefore, a dehumidification tower using zeolite is separately installed in the front stage of the CO ₂ supply device, and moisture in the exhaust gas is adsorbed to the zeolite in the dehumidification tower so that the dehumidified exhaust gas is taken into the CO ₂ supply device. Can do.

  In order to maintain the dehumidifying function of the dehumidifying tower, it is necessary to periodically perform a zeolite regeneration process for desorbing moisture adsorbed on the zeolite to be used. This zeolite regeneration treatment is performed by a procedure in which conventionally used zeolite is transported to a drying furnace outside the cultivation room, heat-treated for about 1 day to desorb moisture adsorbed on the zeolite, and then returned to the cultivation room again. It has been broken. However, the amount of zeolite used in the dehumidifying tower in the cultivation room is large, ranging from several tens to several hundred kg. Therefore, in order to perform this zeolite regeneration treatment, there are problems such as requiring a lot of time and labor for the transportation work of the zeolite and requiring a large drying furnace for heat-treating a large amount of zeolite. It was.

Further, the dehumidifying tower in the cultivation room described above may be used for dehumidification to keep the cultivation room at an appropriate humidity even when the CO ₂ supply device is not operating. The frequency of regeneration processing was high.

  The present invention has been made in view of the above circumstances, and has a simple configuration and can perform regeneration treatment of zeolite used in a plant cultivation room, a plant cultivation room management system, and a plant cultivation room management. The purpose is to provide a control method.

  In order to achieve the above object, a plant cultivation facility management system according to the present invention comprises a combustion apparatus that is installed in a plant cultivation room and performs a combustion treatment of fuel, and a dehumidification tower that contains zeolite, and the combustion apparatus When the exhaust gas generated by the combustion treatment by the gas flows into the dehumidifying tower, the dehumidifying device dehumidifies the exhaust gas by adsorbing moisture to the stored zeolite, and the storage tower containing the zeolite. When the dehumidified exhaust gas flows into the storage tower, carbon dioxide is recovered by adsorbing carbon dioxide to the contained zeolite, and when air with a low carbon dioxide concentration flows into the storage tower, A carbon dioxide supply device for supplying carbon dioxide into the cultivation room by desorbing carbon from the zeolite, and the dehumidification so as to heat the zeolite in the dehumidification tower A heater for the dehumidification tower installed in the storage tower, a heater for the storage tower installed in the storage tower so as to heat the zeolite in the storage tower, and desorbing moisture of the zeolite in the dehumidification tower When the execution timing of the regeneration process arrives, the controller for turning on the heater for the dehumidifying tower and turning on the heater for the storage tower when the execution timing of the regeneration process of the zeolite in the storage tower comes It is characterized by providing.

  The plant cultivation facility management control method of the present invention includes a combustion device that is installed in a plant cultivation room and performs a combustion treatment of fuel, and a dehumidification tower that contains zeolite, and is a combustion treatment by the combustion device. When the generated exhaust gas flows into the dehumidifying tower, the dehumidifying device dehumidifies the exhaust gas by adsorbing moisture to the stored zeolite, and the exhaust gas dehumidified by the dehumidifying device having a storage tower containing zeolite. Is flowed into the storage tower, carbon dioxide is recovered by adsorbing carbon dioxide to the contained zeolite, and when air having a low carbon dioxide concentration flows into the storage tower, the stored carbon dioxide is removed from the zeolite. A carbon dioxide supply device for supplying carbon dioxide into the cultivation room by desorption, and a dehumidification tower installed in the dehumidification tower so as to heat the zeolite in the dehumidification tower A plant cultivation room management system comprising a heater and a storage tower heater installed in the storage tower so as to heat the zeolite in the storage tower desorbs the moisture of the zeolite in the dehumidification tower When the execution timing of the regeneration process for the storage tower arrives, the heater for the dehumidifying tower is turned on, and when the execution timing of the regeneration process for the zeolite in the storage tower comes, the heater for the storage tower is turned on. It is characterized by.

  According to the plant cultivation room management system and the plant cultivation room management control method of the present invention, regeneration treatment of zeolite used in a plant cultivation room can be performed with a simple configuration.

It is a general view which shows the structure of the cultivation room management system by 1st Embodiment. It is the (a) cross-sectional view and (b) top view which show the dehumidification tower and storage tower in the cultivation room management system by 1st Embodiment. It is a flowchart which shows the operation | movement at the time of the regeneration process execution of the dehumidification tower in the cultivation room management system by 1st Embodiment. It is a flowchart which shows the operation | movement at the time of the regeneration process execution of the storage tower in the cultivation room management system by 1st Embodiment. In cultivation room management system according to the second embodiment, it is an overall view showing the pipe connection state when performing a CO ₂ recovery process or supply process. In the cultivation room management system by 2nd Embodiment, it is a general view which shows the piping connection state in the case of performing a regeneration process simultaneously with respect to a dehumidification tower and a storage tower. It is a flowchart which shows the operation | movement at the time of the regeneration process execution of the dehumidification tower and the storage tower in the cultivation room management system by 2nd Embodiment. In the cultivation room management system by 2nd Embodiment, it is a general view which shows the piping connection state in the case of carrying out the regeneration process simultaneously with respect to a some dehumidification tower and a storage tower.

<< First Embodiment >>
<Configuration of cultivation room management system according to the first embodiment>
The configuration of the cultivation room management system 1A according to the first embodiment of the present invention will be described with reference to FIG.

A cultivation room management system 1A according to the present embodiment includes a combustion device 11, a purification device 12, a first three-way valve 13, a second three-way valve 14, and a first blower installed in a plant cultivation room X to be managed. 15, a third three-way valve 16, a dehumidifying device 17, a fourth three-way valve 18, a CO ₂ supply device 19, and a control device 20 </ _b > A.

  The combustion device 11 is installed in a heater or the like that heats the inside of the cultivation room X, and performs a fuel combustion process. The purification device 12 introduces the exhaust gas generated in the combustion device 11 through the pipe d1, and removes nitrogen oxide (NOx) and sulfur oxide (SOx) from the exhaust gas for purification.

  The first three-way valve 13 includes a connection port 13b connected to the purification device 12 via a pipe d2, a connection port 13c connected to the second three-way valve 14 via a pipe d3, and a pipe d4 connected to the first blower 15. And a connection port 13a connected to each other. The first three-way valve 13 switches the flow path of the pipe d2 → pipe d4 and the flow path of the pipe d3 → pipe d4 by controlling the opening and closing of the connection ports 13a, 13b, and 13c.

  The second three-way valve 14 is connected to the space in the cultivation room X via the pipe d5, the connection port 14c connected to the outdoor space via the pipe d6, and the first three-way valve 13 is piped. and a connection port 14a connected through d3. The second three-way valve 14 switches the flow path of the pipe d5 → pipe d3 and the flow path of the pipe d6 → pipe d3 by controlling the opening and closing of the connection ports 14a, 14b and 14c.

  The first blower 15 blows air that has flowed in through the pipe d4 to the third three-way valve 16. As long as the 1st air blower 15 has an air blowing function, you may use apparatuses other than an air blower.

The third three-way valve 16 includes a connection port 16a connected to the first blower 15 via a pipe d7, a connection port 16b connected to the dehumidifier 17 via a pipe d8, and a pipe d9 connected to the CO ₂ supply device 19. And a connection port 16c connected via The third three-way valve 16 switches the flow path of the pipe d7 → pipe d8 and the flow path of the pipe d7 → pipe d9 by controlling the opening and closing of the connection ports 16a, 16b, and 16c.

  The dehumidifying device 17 includes a sixth three-way valve 171, a first dehumidifying tower 172, and a second dehumidifying tower 173. The sixth three-way valve 171 includes a connection port 171a connected to the third three-way valve 16 via a pipe d8, a connection port 171b connected to the first dehumidification tower 172 via a pipe d10, and a second dehumidification tower 173. And a connection port 171c connected via a pipe d11. The sixth three-way valve 171 switches the flow path of the pipe d8 → pipe d10 and the flow path of the pipe d8 → pipe d11 by controlling the opening and closing of the connection ports 171a, 171b, and 171c.

  The structure of the 1st dehumidification tower 172 and the 2nd dehumidification tower 173 is demonstrated with reference to FIG. The first dehumidifying tower 172 and the second dehumidifying tower 173 have the same configuration, and FIG. 2A is a cross-sectional view showing the first dehumidifying tower 172 and the second dehumidifying tower 173, and FIG. (B) is a top view. The first dehumidification tower 172 and the second dehumidification tower 173 have a cylindrical container 101 in which the zeolite 102 is accommodated. The first dehumidifying tower 172 and the second dehumidifying tower 173 dehumidify the zeolite 102 by adsorbing the moisture of the air flowing in through the pipes d10 and d11 connected to the lower portions thereof. Each of the first dehumidification tower 172 and the second dehumidification tower 173 is provided with a dehumidification tower heater for heating the contained zeolite 102. The dehumidifying tower heater is installed in the first heater 103 so as to cover the outer periphery of the container 101, and the vertically long object that is installed in the zeolite 102 when the lid 105 is closed. The panel-shaped or bar-shaped second heater 106 is used. The first heater 103 heats the zeolite in the dehumidification tower from the outside of the dehumidification tower, and the second heater 106 heats the zeolite in the dehumidification tower from the inside of the dehumidification tower. A heat insulating material 104 is further installed on the outer periphery of the first heater 103. Although the second heater 106 is described as being installed on the lid 105, it may be installed on the bottom of the container.

  In the present embodiment, in the dehumidifying device 17, the first dehumidifying tower 172 is used as a regular dehumidifying tower, and the second dehumidifying tower 173 is a spare used when the dehumidifying capacity of the first dehumidifying tower 172 is reduced. It is installed as a dehumidifying tower. In the present embodiment, two dehumidifying towers are used in parallel in the dehumidifying device 17, but three or more dehumidifying towers may be installed, and a plurality may be used as regular dehumidifying towers. By installing a larger number of dehumidifying towers, the dehumidifying capacity can be improved. When installing a plurality of dehumidification towers, it is convenient to replace or maintain the zeolite by providing a valve at each entrance.

Returning to FIG. 1, the fourth three-way valve 18 is connected to the first dehumidification tower 172 and the second dehumidification tower 173 via a pipe d12, and to the CO ₂ supply device 19 via a pipe d13. And a connection port 18c connected to the space in the cultivation room X via a pipe d14. The fourth three-way valve 18 switches the flow path of the pipe d12 → pipe d13 and the flow path of the pipe d12 → pipe d14 by controlling the opening and closing of the connection ports 18a, 18b, and 18c.

The CO ₂ supply device 19 includes a seventh three-way valve 191, a first storage tower 192, and a second storage tower 193. The seventh three-way valve 191 is connected to the third three-way valve 16 via the pipe d9 and connected to the fourth three-way valve 18 via the pipe d13, and the pipe d15 is connected to the first storage tower 192. And a connection port 191b connected to the second storage tower 193 via a pipe d16. The seventh three-way valve 191 switches the flow path of the pipe d9 or d13 → pipe d15 and the flow path of the pipe d9 or d13 → pipe d16 by controlling the opening and closing of the connection ports 191a, 191b, and 191c.

The first storage tower 192 and the second storage tower 193 have the same configuration as the first dehumidification tower 172 and the second dehumidification tower 173, as shown in FIG. In the 1st storage tower 192 and the 2nd storage tower 193, the 1st heater 103 and the 2nd heater 106 function as a heater for storage towers. In the present embodiment, the first storage tower 192 is used as a regular storage tower in the CO ₂ supply device 19, and the second storage tower 193 has a reduced CO ₂ storage capacity of the first storage tower 192. It is installed as a reserve storage tower for use in. The 1st storage tower 192 and the 2nd storage tower 193 are connected to the space in the cultivation room X through the piping d17.

The first storage tower 192 and the second storage tower 193 store zeolite, and adsorb and store the CO _{2 in} the air flowing in through the pipes d15 and d16, respectively, in a high CO ₂ environment. CO ₂ is recovered. The first storage tower 192 and a second storage column 193 is in a low CO ₂ environment, supplies the CO ₂ to the reservoir the CO ₂ in the cultivation chamber X via the pipe d17 desorbed. In this embodiment, _two storage towers are used in parallel in the CO ₂ supply device 19, but three or more storage towers are installed, and a plurality of storage towers are used as regular storage towers. Good. By installing a larger number of storage towers, the CO ₂ recovery and supply capacity can be improved. When installing multiple storage towers, providing a valve at each entrance makes it convenient for zeolite replacement and maintenance.

When the night combustion apparatus 11 is in operation, the control apparatus 20A is configured so that the exhaust gas discharged from the combustion apparatus 11 and purified by the purification apparatus 12 flows into the first dehumidification tower 172 of the dehumidification apparatus 17. Controls the open / close state of the valve. Then, the open / close state of each three-way valve is controlled so that the air dehumidified by the first dehumidification tower 172 flows into the first storage tower 192 of the CO ₂ supply device 19.

Further, the control device 20A determines that the supply of CO ₂ in the cultivation facility A is necessary when the CO ₂ concentration in the cultivation room X is equal to or less than the predetermined value in a state where there is an illuminance greater than a predetermined value in the daytime. And each three-way so that the stored CO ₂ may be desorbed by flowing outside air and the first storage tower 192 and the second storage tower 193 are made to have a low CO ₂ atmosphere to flow into the cultivation room X. Controls the open / close state of the valve.

  Further, the control device 20A holds information indicating the timing of performing the regeneration process of zeolite in the first dehumidification tower 172 and information indicating the timing of performing the regeneration process of zeolite in the first storage tower 192, or these Determine the timing. Then, when it is determined that the execution timing of the regeneration process of zeolite in the first dehumidification tower 172 has arrived, the first heater 103 and the second heater 106 of the first dehumidification tower 172 are turned on. Then, the open / close state of each three-way valve is switched so that air is blown out intermittently from the first blower 15 to the first dehumidification tower 172 and the air flows out of the first dehumidification tower 172. In the present embodiment, the regeneration process of the first dehumidification tower 172 and the regeneration process of zeolite in the first storage tower 192 are set to be executed at different timings.

Further, when the control device 20A determines that the execution timing of the regeneration process of zeolite in the first storage tower 192 of the CO ₂ supply device 19 has arrived, the first heater 103 and the second heater 106 of the first storage tower 192 are turned on. To. Then, the open / close state of each three-way valve is switched so that air is allowed to flow intermittently from the first blower 15 to the first storage tower 192 and out of the first storage tower 192.

<Operation of the cultivation room management system according to the first embodiment>
Next, operation | movement of the cultivation room management system 1A by this embodiment is demonstrated. In the cultivation room management system 1A, when the combustion device 11 is operating at night or the like, a CO ₂ recovery process is executed. In the CO ₂ recovery process, the control device 20A opens / closes each three-way valve so that the exhaust gas discharged from the combustion device 11 and purified by the purification device 12 flows into the first dehumidification tower 172 of the dehumidification device 17. Is controlled. Specifically, the connection ports 13b and 13a of the first three-way valve 13 are open, the connection port 13c is closed, the connection ports 16a and 16b of the third three-way valve 16 are open, and the connection port 16c is closed. It is controlled to become. Further, the connection ports 171a and 171b of the sixth three-way valve 171 are controlled to be in an open state and the connection port 171c is closed.

Then, the open / close state of each three-way valve is controlled so that the air dehumidified in the first dehumidification tower 172 flows into the first storage tower 192 of the CO ₂ supply device 19. Specifically, the connection ports 18a and 18b of the fourth three-way valve 18 are controlled to be in an open state and the connection port 18c is in a closed state. Further, the connection ports 191a and 191b of the seventh three-way valve 191 are controlled to be in an open state and the connection port 191c is closed.

When the CO ₂ recovery process is performed in this way, when the moisture adsorption capacity of the zeolite 102 of the first dehumidifying tower 172 reaches the limit, the dehumidifying function is lowered, and the exhaust gas becomes the second dehumidifying tower 173. The open / close state of the sixth three-way valve 171 is switched so as to flow into the valve. Specifically, switching is performed so that the connection ports 171a and 171c of the sixth three-way valve 171 are in the open state and the connection port 171b is in the closed state. The open / close state of the sixth three-way valve 171 is set at a timing when a preset time has elapsed as a time when the moisture adsorption capacity of the zeolite 102 of the first dehumidifying tower 172 reaches the limit, or near the outlet of the first dehumidifying tower 172. The hygrometer (not shown) is switched based on the measured value.

When the CO ₂ concentration in the cultivation room X becomes equal to or less than the predetermined value in a state where the illuminance is higher than the predetermined value in the daytime, the control device 20A determines that the supply of CO ₂ into the cultivation facility A is necessary. Then, incorporate outside air, by the first storage tower 192 and a second storage column 193 and low CO ₂ atmosphere, the CO ₂ supply process to flow out pooled CO ₂ in the cultivation chamber X desorbed As is done, the open / closed state of each three-way valve is switched.

  Specifically, the connection ports 13a and 13c of the first three-way valve 13 are open, the connection port 13b is closed, the connection ports 14a and 14c of the second three-way valve 14 are open, and the connection port 14b is closed. It is switched to become.

As described above, when the execution timing of the regeneration process of the zeolite in the first dehumidification tower 172 arrives while the CO ₂ recovery process and the supply process are appropriately executed in the cultivation room management system 1A, FIG. This will be described with reference to the flowchart of FIG.

  In the control device 20A, when it is determined that the execution timing of the regeneration process of zeolite in the first dehumidification tower 172 has arrived (“YES” in S1), the first heater 103 and the second heater 106 of the first dehumidification tower 172 are Controlled to ON state. When the first heater 103 and the second heater 106 are turned on, the zeolite 102 in the first dehumidifying tower 172 is heated, and the adsorbed moisture is desorbed. In that case, since the heat insulating material is installed in the outer periphery of the 1st heater 103, the zeolite 102 is heated efficiently.

  At this time, air is intermittently blown from the first blower 15 to the first dehumidification tower 172, and the air that has passed through the first dehumidification tower 172 flows out to a space outside the first dehumidification tower 172, for example, a space in the cultivation room X. Thus, the open / closed state of each three-way valve is switched (S2). Specifically, the connection ports 18a and 18c of the fourth three-way valve 18 are switched to the open state and the connection port 18b is switched to the closed state. The intermittent air blowing process at this time is continued until a preset regeneration process period ends ("NO" in S3). By intermittently ventilating the inside of the first dehumidification tower 172, the moisture desorbed from the zeolite 102 due to the heating of the first heater 103 and the second heater 106 of the first dehumidification tower 172 does not stay in the cultivation room X. And re-adsorption onto the zeolite 102 is prevented.

  Thereafter, when it is determined that the regeneration process period has ended (“YES” in S3), the first heater 103 and the second heater 106 of the first dehumidification tower 172 are controlled to be in the OFF state, and from the first blower 15 The intermittent blowing process to the first dehumidifying tower 172 is stopped (S4). Then, the connection ports 18a and 18b of the fourth three-way valve 18 are switched to the open state and the connection port 18c is switched to the closed state, and the process returns to step S1.

  Further, a process when the execution timing of the regeneration process of the zeolite in the first storage tower 192 arrives will be described with reference to the flowchart of FIG.

  In the control device 20A, when it is determined that the execution timing of the regeneration process of zeolite in the first storage tower 192 has arrived (“YES” in S11), the first heater 103 and the second heater 106 of the first storage tower 192 are turned on. Controlled to ON state. And it is made to blow intermittently from the 1st air blower 15 to the 1st storage tower 192, and the air which passed the 1st storage tower 192 flows out into the space outside the 1st storage tower 192, for example, the space in cultivation room X. In addition, the open / close state of each three-way valve is switched (S12).

  Specifically, the connection ports 16a and 16c of the third three-way valve 16 are switched to the open state and the connection port 16b is switched to the closed state. The intermittent air blowing process at this time is continued until a preset regeneration process period ends (“NO” in S13). By intermittently ventilating the inside of the first storage tower 192, moisture desorbed from the zeolite 102 due to the heating of the first heater 103 and the second heater 106 of the first storage tower 192 does not stay in the cultivation room X. And re-adsorption onto the zeolite 102 is prevented.

  When it is determined that the regeneration processing period has ended ("YES" in S13), the first heater 103 and the second heater 106 of the first storage tower 192 are controlled to be in the OFF state, and from the first blower 15 The intermittent blowing process to the first storage tower 192 is stopped (S14). Then, the connection ports 16a and 16b of the third three-way valve 16 are switched to the open state and the connection port 16c is switched to the closed state, and the process returns to step S11.

According to the first embodiment, with respect to the dehumidifier 17 and the CO ₂ supply device zeolite 102 installed in the 19 cultivation chamber X of the plant, it is possible to perform the reproduction process is automatically cultivation chamber X . Accordingly, the CO ₂ recovery process and the supply process can be continuously performed without carrying the zeolite 102 out of the cultivation room X in order to perform the regeneration process.

  In the first embodiment described above, information indicating the timing of performing the regeneration process of zeolite in the second dehumidification tower 173 and the second storage tower 193 is also held in the control device 20A, and the second dehumidification tower 173 and the second storage tower are stored. A similar reproduction process may be executed for 193.

<< Second Embodiment >>
<Configuration of cultivation room management system according to the second embodiment>
The structure of the cultivation room management system 1B by 2nd Embodiment of this invention is demonstrated with reference to FIG.

  The cultivation room management system 1B does not install the third three-way valve 16, the pipe d9, the fourth three-way valve 18, the sixth three-way valve 171, and the seventh three-way valve 191, except that the second blower 22 is newly installed. Since it is the same as that of 1 A of cultivation room management systems, detailed description of the part which has the same function is abbreviate | omitted. The second blower 22 is connected to a pipe d 19 that can be connected to the first dehumidification tower 172 and the first storage tower 192. As long as the 2nd air blower 22 has an air blowing function, you may use apparatuses other than an air blower.

  The control device 20B holds information indicating the timing for regeneration of the zeolite in the first dehumidification tower 172 and the zeolite in the first storage tower 192, or determines the timing. And if it judges that the said timing has come, the regeneration process of the zeolite of the 1st dehumidification tower 172 and the 1st storage tower 192 will be performed individually or simultaneously, respectively.

<Operation of the cultivation room management system according to the second embodiment>
Next, operation | movement of the cultivation room management system 1B by this embodiment is demonstrated. First, when the first dehumidification tower 172 and the first storage tower 192 are used to perform the CO ₂ recovery process or the supply process, the pipe d19 is not connected to the dehumidifier 17 and the CO ₂ supply apparatus 19. That is, the second blower 22 is separated from the operation line of the cultivation room management system 1B. FIG. 5 shows a state where the second blower 22 is separated from the operation line of the cultivation room management system 1B by indicating the pipe d19 with a dotted line.

Further, when the first dehumidification tower 172 and the first storage tower 192 are used and the CO ₂ recovery process or the supply process is performed, the pipe d7 and the second dehumidification tower 173 are connected as shown in FIG. The pipe d11 is removed. Further, a pipe d16 connecting the pipe d12 and the second storage tower 193 is removed. Further, the connection between the second dehumidifying tower 173 and the pipe d12 is disconnected. Further, the connection between the second storage tower 193 and the pipe d17 is disconnected.

  Then, before regenerating the zeolite in the first dehumidification tower 172 and the zeolite in the first storage tower 192, the administrator first manually disconnects the pipe d10 from the first dehumidification tower 172 to be regenerated. Further, the pipe d15 is disconnected from the first storage tower 192 to be regenerated. By removing these pipes d10 and d15, the first dehumidification tower 172 and the first storage tower 192 are separated from the operation line in the cultivation room management system 1B.

  In addition, the administrator connects the pipe d19 to which the second blower 22 is connected to the first dehumidification tower 172 and the first storage tower 192. By connecting the pipe d19 to the first dehumidification tower 172 and the first storage tower 192, air can be sent from the second blower 22 to the first dehumidification tower 172 and the first storage tower 192, and the second blower 22 is It is connected to the operation line of the cultivation room management system 1B. FIG. 6 shows the pipe d19 by a solid line and the pipes d10 and d15 by a dotted line, whereby the second blower 22 is connected to the operation line of the cultivation room management system 1B, and the first dehumidification tower 172 and the first storage tower 192 are shown. Shows a state separated from the operation line.

Further, the administrator disconnects the first dehumidification tower 172 and the pipe d12, and the pipe d21 is connected to the first dehumidification tower 172 so that the air passing through the first dehumidification tower 172 is discharged out of the first dehumidification tower 172. Connect. Further, the pipe d11 connects the pipe d7 and the second dehumidification tower 173, and the pipe d16 connects the pipe d12 and the second storage tower 193. Further, the second dehumidifying tower 173 is connected to the pipe d12. Further, the connection between the first storage tower 192 and the pipe d17 is disconnected, and the pipe d23 is connected to the first storage tower 192 so that the air passing through the first storage tower 192 is discharged from the pipe d23 to the outside of the first storage tower 192. Connect. Further, the second storage tower 193 is connected to the pipe d17 so that the air passing through the second storage tower 193 is discharged from the pipe d17 to the outside of the second storage tower 193. By changing the connection of the pipes in this way, the second dehumidification tower 173 and the second storage tower 193 are used so that the CO ₂ recovery process or the supply process is performed.

  And the process performed by the control apparatus 20B when the timing which regenerates the zeolite of the 1st dehumidification tower 172 and the zeolite of the 1st storage tower 192 comes is demonstrated with reference to the flowchart of FIG.

  When it is determined that the timing has arrived (“YES” in S21), the control device 20B controls the first heater 103 and the second heater 106 of the first dehumidification tower 172 and the first storage tower 192 to the ON state. The Then, air is intermittently blown from the second blower 22 to the first dehumidification tower 172 and the first storage tower 192 to flow out of the first dehumidification tower 172 and the first storage tower 192 (S22).

  The intermittent air blowing process at this time is continued until a preset regeneration process period ends (“NO” in S23). By intermittently ventilating the inside of the first dehumidification tower 172, the moisture desorbed from the zeolite 102 due to the heating of the first heater 103 and the second heater 106 of the first dehumidification tower 172 does not stay and the first dehumidification tower 172 is flowed out and re-adsorption to the zeolite 102 is prevented. Similarly, by intermittently ventilating the inside of the first storage tower 192, the moisture desorbed from the zeolite 102 due to the heating of the first heater 103 and the second heater 106 of the first storage tower 192 is not retained and It flows out of the 1 storage tower 192, and the re-adsorption to the zeolite 102 is prevented.

By performing the processing in this way, the CO ₂ recovery processing or supply processing using the second dehumidification tower 173 and the second storage tower 193 is executed, and at the same time, the first dehumidification tower 172 and the first storage tower 192 Playback processing can be executed.

  Thereafter, when it is determined that the regeneration process period has ended (“YES” in S23), the first heater 103 and the second heater 106 of the first dehumidification tower 172 and the first storage tower 192 are controlled to be in the OFF state. Moreover, the intermittent ventilation process from the 2nd air blower 22 to the 1st dehumidification tower 172 and the 1st storage tower 192 is stopped (S24).

  Then, the administrator removes the pipe d19 from the first dehumidification tower 172 and the first storage tower 192, connects the pipe d10 to the first dehumidification tower 172, and connects the pipe d15 to the first storage tower 192. Also, the pipe d21 is removed from the first dehumidification tower 172, the first dehumidification tower 172 is connected to the pipe d12, and the second dehumidification tower 173 is removed from the pipe d12. Then, the process returns to step S21.

According to the above 2nd Embodiment, the regeneration process can be simultaneously performed in the cultivation room with respect to the zeolite in the 1st dehumidification tower 172 and the 1st storage tower 192 in the cultivation room X of a plant. Further, the CO ₂ recovery process and the supply process by the second dehumidification tower 173 and the second storage tower 193 can be performed while the regeneration process of the first dehumidification tower 172 and the first storage tower 192 is performed. Furthermore, the CO ₂ regeneration process by the second dehumidification tower 173 and the second storage tower 193 can be performed while the CO ₂ recovery process and supply process of the first dehumidification tower 172 and the first storage tower 192 are executed. .

  In the second embodiment described above, all of the first dehumidification tower 172, the second dehumidification tower 173, the first storage tower 192, and the second storage tower 193 are reached when the timing for performing the regeneration treatment of the zeolite in the system comes. On the other hand, the playback process may be executed simultaneously.

  Specifically, before the timing to regenerate the zeolite in the system arrives, the administrator first removes the pipes in front of the dehumidification tower and storage tower to be treated as shown in FIG. That is, the pipe d10 is disconnected from the first dehumidifying tower 172, the pipe d11 is disconnected from the second dehumidifying tower 173, the pipe d15 is disconnected from the first storage tower 192, and the pipe d16 is connected from the second storage tower 193. Disconnect. Further, the pipe d19 to which the second blower 22 is connected is connected to the first dehumidification tower 172, the second dehumidification tower 173, the first storage tower 192, and the second storage tower 193. Also, the first dehumidification tower 172 and the second dehumidification tower 173 are removed from the pipe d12, and the air passing through the first dehumidification tower 172 is discharged to the outside of the first dehumidification tower 172 to the pipe d21. Connect. Further, the pipe d22 is connected to the second dehumidification tower 173 so that the air that has passed through the second dehumidification tower 173 is discharged to the outside of the second dehumidification tower 173. In addition, the first storage tower 192 and the second storage tower 193 are removed from the pipe d17, and the air passing through the first storage tower 192 is discharged from the pipe d23 to the outside of the first storage tower 192. The pipe d23 is connected. Further, the pipe d24 is connected to the second storage tower so that the air passing through the second storage tower 193 is discharged from the pipe d24 to the outside of the second storage tower 193.

When the timing for regenerating the zeolite in the system arrives, the first heater 103 and the second heater of the first dehumidification tower 172, the second dehumidification tower 173, the first storage tower 192, and the second storage tower 193 106 is controlled to be in an ON state. In addition, air is intermittently blown from the second blower 22 to the first dehumidification tower 172, the second dehumidification tower 173, the first storage tower 192, and the second storage tower 193, and flows out of the corresponding dehumidification tower or storage tower, respectively. Let After completion of the regeneration process, the administrator restores the connection of each pipe and restarts the CO ₂ recovery process and the supply process.

  By performing the treatment in this manner, the regeneration treatment can be simultaneously performed on the zeolites of all the dehumidification towers and storage towers.

  In 2nd Embodiment mentioned above, the case where an administrator performed manually the process which connects piping between each apparatus, and the process which removes a connection was demonstrated. However, the present invention is not limited to this, and an on-off valve or a three-way valve may be installed at a location where the connection of the pipe is switched, and the connection state may be automatically switched by controlling the opening / closing of these valves from the control device.

1A, 1B Cultivation room management system 11 Combustion device 12 Purification device 13 First three-way valve 13a, 13b, 13c Connection port 14 Second three-way valve 14a, 14b, 14c Connection port 15 First blower 16 Third three-way valve 16a, 16b, 16c connection port 17 dehumidifying device 18 fourth three-way valve 18a, 18b, 18c connection port 19 CO ₂ supply device 20A, 20B control device 22 second blower 101 container 102 zeolite 103 first heater 104 heat insulating material 105 lid 106 second heater 171 Sixth three-way valve 171a, 171b, 171c Connection port 172 First dehumidification tower 173 Second dehumidification tower 191 Seventh three-way valve 191a, 191b, 191c Connection port 192 First storage tower 193 Second storage tower

In order to achieve the above object, the plant cultivation facility management system of the present invention comprises a combustion apparatus installed in a plant cultivation room for performing a combustion treatment of fuel, zeolite, and the moisture of the air that has flowed in the zeolite. A dehumidifying device having a plurality of dehumidifying towers for dehumidifying the air by adsorbing to the zeolite, storing zeolite, and storing carbon dioxide by adsorbing carbon dioxide to the zeolite when the carbon dioxide concentration is introduced into the air; A carbon dioxide supply device having a plurality of storage towers for supplying carbon dioxide into the cultivation room by desorbing the stored carbon dioxide from the zeolite when air having a low carbon dioxide concentration is introduced, and the plurality of dehumidification towers a plurality of dehumidifying tower for heater installed respectively, and a plurality of storage towers for heater installed to each of the plurality of storage towers, waste generated in the combustion device A first blower that blows air to the dehumidifying device and the carbon dioxide supply device, a second blower that blows air to the dehumidifying device and the carbon dioxide supply device, and the exhaust gas generated in the combustion process, When the dehumidifying tower in the dehumidifying device and the storage tower in the carbon dioxide supply device are blown from the blower, exhaust gas dehumidification processing and carbon dioxide recovery processing are executed, and when a predetermined timing arrives While performing the dehumidification process of the exhaust gas and the carbon dioxide recovery process, the heaters for the dehumidification towers of other dehumidification towers and the heaters for the storage towers of other storage towers are turned on, and the other from the second blower And a control device that executes a regeneration process for desorbing moisture from the dehumidification tower and the storage tower by blowing air to the other dehumidification tower and the other storage tower. It is characterized by that.

The plant cultivation facility management control method according to the present invention is installed in a plant cultivation room, performs combustion processing of fuel, contains zeolite, and adsorbs moisture of the air that has flowed into the zeolite. The dehumidifying device having a plurality of dehumidifying towers for dehumidifying the air and the zeolite are stored, and when the carbon dioxide concentration is introduced into the air, the carbon dioxide is stored by adsorbing the carbon dioxide to the zeolite. A carbon dioxide supply device having a plurality of storage towers for supplying carbon dioxide into the cultivation chamber by desorbing the stored carbon dioxide from the zeolite when low air is introduced, and the plurality of dehumidification towers, respectively. A plurality of dehumidification tower heaters, a plurality of storage tower heaters respectively installed in the plurality of storage towers, and an exhaust gas generated by the combustion device is used as the dehumidification apparatus. And the first blower that blows air to the carbon dioxide supply device, and the exhaust system generated in the combustion process by the management system of the plant cultivation room that includes the dehumidifier and the second blower that blows air to the carbon dioxide supply device Is exhausted from the first blower to any one of the dehumidifying towers in the dehumidifying device and any one of the storage towers in the carbon dioxide supply device, thereby performing exhaust gas dehumidification processing and carbon dioxide recovery processing, When the above timing arrives, the dehumidification treatment of the exhaust gas and the carbon dioxide recovery treatment are performed, while the dehumidification tower heaters of other dehumidification towers and the storage tower heaters of other storage towers are turned on, and the first 2 Regeneration processing for desorbing moisture from the dehumidifying tower and the storage tower is performed by blowing air from the blower to the other dehumidifying tower and the other storage tower. It is characterized by that.

Claims (6)

A combustion apparatus installed in a plant cultivation room and performing a combustion process of fuel;
A dehumidification tower having a dehumidification tower containing zeolite, and when the exhaust gas generated by the combustion treatment by the combustion apparatus flows into the dehumidification tower, the dehumidification apparatus dehumidifies the exhaust gas by adsorbing moisture to the contained zeolite;
When the exhaust gas dehumidified by the dehumidifier is flowed into the storage tower, the carbon dioxide is recovered by adsorbing carbon dioxide to the stored zeolite, and the concentration of carbon dioxide is low. When air flows into the storage tower, a carbon dioxide supply device that supplies carbon dioxide into the cultivation room by desorbing the stored carbon dioxide from the zeolite,
A heater for the dehumidifying tower installed in the dehumidifying tower so as to heat the zeolite in the dehumidifying tower;
A storage tower heater installed in the storage tower to heat the zeolite in the storage tower;
When the execution timing of the regeneration process for desorbing the moisture of the zeolite in the dehumidification tower comes, turn on the heater for the dehumidification tower, and when the execution timing of the regeneration process of the zeolite in the storage tower comes, A plant cultivation room management system comprising: a controller for turning on the storage tower heater. A first blower;
A valve for switching between a flow path of air to be blown from the first blower to the dehumidification tower and a flow path of air to be blown from the first blower to the storage tower;
When the execution timing of the regeneration treatment of the zeolite in the dehumidification tower comes, the control device intermittently blows air from the first blower to the dehumidification tower and flows out of the dehumidification tower, and the zeolite in the storage tower 2. The valve according to claim 1, wherein the valve is controlled to intermittently blow air from the first blower to the storage tower and to flow out of the storage tower when the execution timing of the regeneration process is reached. Plant cultivation room management system. A second blower for blowing air to the dehumidification tower and the storage tower;
When the execution timing of the regeneration treatment of the zeolite in the dehumidification tower and the storage tower comes, the control device intermittently blows air from the second blower to the dehumidification tower and flows out of the dehumidification tower. The plant cultivation room management system according to claim 1 or 2, wherein the storage tower is intermittently blown to flow out of the storage tower. The dehumidifying tower heater is composed of a heater for heating the zeolite in the dehumidifying tower from the outside of the dehumidifying tower, and a heater for heating from the inside of the dehumidifying tower,
The said storage tower heater is comprised with the heater which heats the zeolite in the said storage tower from the said storage tower outside, and the heater which heats from the said storage tower inside, Any one of Claims 1-3 characterized by the above-mentioned. The management system of the plant cultivation room of Claim 1. A combustion apparatus installed in a plant cultivation room and performing a combustion process of fuel;
A dehumidification tower having a dehumidification tower containing zeolite, and when the exhaust gas generated by the combustion treatment by the combustion apparatus flows into the dehumidification tower, the dehumidification apparatus dehumidifies the exhaust gas by adsorbing moisture to the contained zeolite;
When the exhaust gas dehumidified by the dehumidifier is flowed into the storage tower, the carbon dioxide is recovered by adsorbing carbon dioxide to the stored zeolite, and the concentration of carbon dioxide is low. When air flows into the storage tower, a carbon dioxide supply device that supplies carbon dioxide into the cultivation room by desorbing the stored carbon dioxide from the zeolite,
A heater for the dehumidifying tower installed in the dehumidifying tower so as to heat the zeolite in the dehumidifying tower;
A plant cultivation room management system comprising a storage tower heater installed in the storage tower so as to heat the zeolite in the storage tower,
When the execution timing of the regeneration process for desorbing the moisture of the zeolite in the dehumidification tower comes, turn on the heater for the dehumidification tower, and when the execution timing of the regeneration process of the zeolite in the storage tower comes, A management control method for a plant cultivation room, wherein the storage tower heater is turned on. The management system further includes a first blower, a valve that switches between a flow path of air that is blown from the first blower to the dehumidification tower, and a flow path of air that is blown from the first blower to the storage tower. ,
When the execution timing of the regeneration process of the zeolite in the dehumidification tower comes, the intermittent blower from the first blower to the dehumidification tower flows out of the dehumidification tower, and the regeneration process of the zeolite in the storage tower is performed 6. The plant cultivation room according to claim 5, wherein when the timing arrives, the valve is controlled so that air is intermittently blown from the first blower to the storage tower and flows out of the storage tower. Management control method.

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