JP5764272B2 - Plant cultivation system - Google Patents

Description

  The present invention relates to a plant cultivation system used in a plant factory or the like.

  For example, in a plant factory, a light source is provided in a cultivation room, and the plant is grown by repeating the light period when the light source is turned on and the dark period when the light source is turned off alternately. Has been done.

JP 2000-93010 A

  However, in the method as described above, the concentration of carbon dioxide increases excessively in the dark period or the concentration of carbon dioxide decreases excessively in the light period due to respiration and photosynthesis performed by plants. May adversely affect the growth of the plant.

  In view of such a problem, the present invention can suppress an increase in the carbon dioxide concentration in the dark period and can suppress a decrease in the carbon dioxide concentration in the light period, thereby improving the growth of the plant. It is another object of the present invention to provide a plant cultivation system that can be realized by a rational configuration without waste.

Said subject is the 1st room for plant cultivation provided with the light source for cultivation, the 2nd room for plant cultivation similarly provided with the light source for cultivation, and the fan which sends the air of the 1st room to the 2nd room A fan for sending the air in the second chamber to the first chamber, and a control unit,
The controller is
The light period when the cultivation light source is turned on and the dark period when the cultivation light source is turned off, when one of the first and second rooms is in the light period, the other room is in the dark period , Light source control for performing alternately repeating control in each room with respect to the light source in each room;
When the first chamber is in the light period and the second chamber is in the dark period, the air in the second chamber is sent into the first chamber, and when the first chamber is in the dark period and the second chamber is in the light period, the first chamber This is solved by a plant cultivation system characterized by performing fan control for controlling the drive of the fan so that the air is fed into the second chamber (first invention).

  In this system, the fan is controlled so that air with a high carbon dioxide concentration in the dark room is fed into the light room, so that the carbon dioxide concentration in the dark room can be reduced. While the rise is suppressed, the decrease in the carbon dioxide concentration in the light period chamber is suppressed, and the growth of plants in the first and second chambers can be made favorable.

  In addition, the decrease in the carbon dioxide concentration in the light period room is suppressed by sending the air in the dark period room to increase the carbon dioxide concentration into the light period room. Therefore, the growth of the plant can be improved by a rational configuration without waste.

  In the first aspect of the invention, when the light period chamber is configured to have a positive pressure by the air feeding action by the fan from the dark period chamber to the light period chamber (second invention), It is easy to keep the chamber of the period clean.

In the first and second inventions, an air conditioner is provided in each of the first and second chambers,
The controller may be configured to perform air conditioner control for controlling the operation of each air conditioner so that the room temperature in the light period is higher than the room temperature in the dark period (third invention).

  In this case, the carbon dioxide in the dark room is sent to the light room by the fan, and the cold air in the dark room is also sent to the light room, and the temperature in the light room rises. It is possible to improve the speed of photosynthesis of plants in the light period room by suppressing the decrease in humidity, and to suppress the increase in humidity in the dark period room.

In the first to third inventions, a carbon dioxide supply source for supplying carbon dioxide to the first and second chambers is provided,
The controller is configured so that carbon dioxide is supplied from a carbon dioxide supply source to a light period room, and carbon dioxide supply from the carbon dioxide supply source is stopped to a dark period room. Carbon dioxide supply control for controlling the supply of carbon dioxide from a carbon dioxide supply source may be performed (fourth invention).

  In this case, carbon dioxide from the carbon dioxide supply source is combined with a configuration in which the fan is controlled so that air with a high carbon dioxide concentration in the dark room is sent into the light room. Can be reduced.

In the fourth invention, each of the first and second chambers is provided with a sensor for detecting the carbon dioxide concentration,
Based on the detection signal from the sensor in the light room, the control unit supplies the carbon dioxide supply source with carbon dioxide to the light room when the carbon dioxide concentration is lower than the set concentration. When the carbon dioxide concentration is equal to or higher than the set concentration, the carbon dioxide supply source may be controlled to stop the supply of carbon dioxide to the light room (the fifth invention).

  In this case, the supply of carbon dioxide from the carbon dioxide supply source can be automatically and actually reduced by such control by the control unit.

  Since the present invention is as described above, an increase in the carbon dioxide concentration in the dark period can be suppressed, and a decrease in the carbon dioxide concentration in the light period can be suppressed, so that plant growth is favorable. Moreover, it can be realized by a reasonable configuration without waste.

Fig. (A) is an explanatory plan view showing the plant cultivation system of the embodiment, and Fig. (B) is a table showing the mode of switching between the light period and the dark period in each room. FIGS. 1A and 1B are plan views showing the operating state of the system under control.

  Next, embodiments of the present invention will be described with reference to the drawings.

  In the plant cultivation system of the embodiment shown in FIG. 1A, 1 is a first chamber for plant cultivation, 2 is the second chamber, and the first chamber 1 and the second chamber 2 are adjacent to each other. The front chamber 4 is provided so as to be adjacent to both the first chamber 1 and the second chamber 2, and the front chamber 4 is also provided with the first and second chambers. Each of the chambers 1 and 2 is provided with a partition 5.

  Each of the first and second chambers 1 and 2 is provided with a plant cultivation shelf 6 and a cultivation light source 7 such as an LED for supplying light to the plants grown on the shelf 6. .

  The partition 3 that partitions the first chamber 1 and the second chamber 2 includes a first fan 8 that sends air from the first chamber 1 to the second chamber 2 and air from the second chamber 2 to the first chamber. And a second fan 9 that feeds into the vehicle 1. A fan that can be driven in forward and reverse rotation may be used.

  Furthermore, an air conditioner 10 is provided in each of the first and second chambers 1 and 2.

  The front chamber 4 is provided with a cylinder 11 as a carbon dioxide supply source so that carbon dioxide can be supplied to the first chamber 1 or the second chamber 2.

  And the lighting on / off control of the cultivation light source 7 in each chamber 1, the drive control of the fans 8, 9, the operation control of the air conditioner 10 in each chamber 1, and the carbon dioxide supply control from the carbon dioxide cylinder 11. For this purpose, a control unit 12 is provided.

  That is, the control unit 12 has a light period when the cultivation light source 7 is turned on and a dark period when the cultivation light source 7 is turned off, and one of the first chamber 1 and the second chamber 2 is in the light period. At this time, the light sources 7 and 7 in the respective chambers 1 and 2 are controlled so as to be alternately repeated in the respective chambers 1 and 2 so that the other chamber is in the dark period. Specifically, for example, as shown in FIG. 1B, the light period and the dark period are controlled to repeat every 12 hours.

  In addition, as shown in FIG. 2A, the control unit 12 sends air from the second chamber 2 into the first chamber 1 when the first chamber 1 is in the light period and the second chamber 2 is in the dark period. As shown in FIG. 2B, when the first chamber 1 is in the dark period and the second chamber 2 is in the light period, the fans 8 and 9 are sent so that the air in the first chamber 1 is sent into the second chamber 2. It is made to control the drive of the. In this control, in the present embodiment, the partition portion that partitions the front chamber 4 and the first chamber 1 is provided with a vent including an undercut portion of the door, and the front chamber 4 and the second chamber 2. Similarly, a vent is also provided in the partitioning section, so that the air in the light period becomes positive pressure by the air feeding action by the fans 8 and 9 from the dark room to the light room. It is configured. Note that the front chamber 4 is provided with a fan vent 13 provided with a total heat exchanger.

  Further, the control unit 12 controls the operation of the air conditioners 10 and 10 in the first and second rooms 1 and 2 so that the room temperature of the light room is higher than the room temperature of the dark room. ing. Specifically, for example, the room temperature in the light period is controlled to 25 ° C., and the room temperature in the dark period is set to 18 ° C.

  In addition, the control unit 12 supplies carbon dioxide from the carbon dioxide cylinder 11 to the light-period room, and stops supply of carbon dioxide from the carbon dioxide cylinder 11 to the dark-period room. Thus, the supply of carbon dioxide from the carbon dioxide cylinder 11 is controlled.

  In particular, in the present embodiment, as shown in FIG. 1A, each of the first and second chambers 1 and 2 is provided with a sensor 14 for detecting the carbon dioxide concentration, and the control unit 12 When the carbon dioxide concentration is lower than the set concentration or less based on the detection signal from the sensor 14 in the period chamber, the carbon dioxide cylinder 11 is made to supply carbon dioxide to the light period chamber, When the concentration is equal to or higher than the set concentration, the carbon dioxide cylinder 11 is controlled to stop the supply of carbon dioxide to the light period chamber. In addition, the thick line arrow in FIG. 1 (a) represents an administrator flow line.

  In the system described above, the drive control of the fans 8 and 9 is performed so that air with a high carbon dioxide concentration in the dark room is sent into the light room, so the carbon dioxide in the dark room While an increase in the concentration is suppressed, a decrease in the carbon dioxide concentration in the light period chamber is suppressed, thereby making it possible to improve the growth of the plants in the first and second chambers.

  In addition, the decrease in the carbon dioxide concentration in the light period room is suppressed by sending the air in the dark period room to increase the carbon dioxide concentration into the light period room. Therefore, the growth of the plant can be improved by a rational configuration without waste.

  In addition, the light period chamber is configured to have a positive pressure by the air feeding action of the fans 8 and 9 from the dark period room to the light period room, so that the light room is in a clean state. Can be easily maintained.

  Furthermore, by controlling the room temperature using the air conditioners 10 and 10 in combination with the fans 8 and 9, it is possible to suppress the temperature increase and the humidity decrease in the light room and improve the speed of plant photosynthesis in the light room. In addition, an increase in humidity in the dark room can be suppressed.

  Further, in combination with the configuration in which the drive of the fans 8 and 9 is controlled so that air having a high carbon dioxide concentration in the dark room is sent into the light room, the carbon dioxide cylinder 11 The carbon dioxide supply from the carbon dioxide cylinder 11 is automatically and actually reduced by the carbon dioxide supply control using the carbon dioxide concentration sensors 14 and 14. be able to.

DESCRIPTION OF SYMBOLS 1 ... 1st chamber 2 ... 2nd chamber 7 ... Light source for cultivation 8, 9 ... Fan 10 ... Air conditioner 11 ... Carbon dioxide cylinder (carbon dioxide supply source)
12 ... Control unit 14 ... Carbon dioxide sensor

Claims (4)

A first chamber for plant cultivation provided with a light source for cultivation, a second chamber for plant cultivation similarly equipped with a light source for cultivation, a fan for sending air from the first chamber to the second chamber, and a second chamber A fan for sending the air to the first chamber, and a control unit,
The controller is
The light period when the cultivation light source is turned on and the dark period when the cultivation light source is turned off, when one of the first and second rooms is in the light period, the other room is in the dark period , Light source control for performing alternately repeating control in each room with respect to the light source in each room;
When the first chamber is in the light period and the second chamber is in the dark period, the air in the second chamber is sent into the first chamber, and when the first chamber is in the dark period and the second chamber is in the light period, the first chamber And the fan control for controlling the driving of the fan so that the air is sent into the second chamber ,
A plant cultivation system , wherein the light period chamber is set to a positive pressure by the air feeding action from the dark period chamber to the light period chamber by the fan . An air conditioner is provided in each of the first and second rooms,
2. The plant cultivation system according to claim 1 , wherein the control unit performs air conditioner control for controlling the operation of each air conditioner so that a room temperature in a light period is higher than a room temperature in a dark period. A carbon dioxide supply source for supplying carbon dioxide to each of the first and second chambers;
The controller is configured so that carbon dioxide is supplied from a carbon dioxide supply source to a light period room, and carbon dioxide supply from the carbon dioxide supply source is stopped to a dark period room. The plant cultivation system according to claim 1 or 2 , wherein carbon dioxide supply control for controlling supply of carbon dioxide from a carbon dioxide supply source is performed. A sensor for detecting the carbon dioxide concentration is provided in each of the first and second chambers,
Based on the detection signal from the sensor in the light room, the control unit supplies the carbon dioxide supply source with carbon dioxide to the light room when the carbon dioxide concentration is lower than the set concentration. 4. The plant cultivation system according to claim 3 , wherein when the carbon dioxide concentration is equal to or higher than the set concentration, the carbon dioxide supply source is controlled to stop the supply of carbon dioxide to the light-period room.

Images