JP6966514B2 - Carbon dioxide application device - Google Patents

Description

The present disclosure relates to a carbon dioxide application device.

A carbon dioxide application device for applying carbon dioxide into an agricultural house is known in order to improve the yield and quality of horticultural plants. On the other hand, the agricultural house is equipped with a warmer to prevent the temperature from dropping at night. The warmer burns heavy oil, kerosene, etc. and supplies warm air to the agricultural house.

Therefore, a carbon dioxide application device has been devised that recovers and stores carbon dioxide in combustion exhaust gas generated from a warmer and supplies carbon dioxide into an agricultural house at an arbitrary timing (see Patent Document 1).

In this multi-carbon dioxide application device, after the combustion exhaust gas is passed through the liquid in the purification tank to be cooled and purified, the combustion exhaust gas is sent to the adsorption tank where the adsorbent is arranged by a blower to adsorb carbon dioxide.

The carbon dioxide adsorbed on the adsorbent is, for example, desorbed from the adsorbent in the daytime and applied in an agricultural house.

Japanese Unexamined Patent Publication No. 2019-41639

In the carbon dioxide application device as described above, a control valve for adjusting the pressure of the recovery tank is arranged between the recovery tank and the blower. The regulating valve regulates the flow of flue gas from the blower to the recovery tank.

However, depending on the position where the regulating valve is arranged, the liquid in the recovery tank may be stagnant between the blower and the regulating valve, and this liquid may enter the blower.

One aspect of the present disclosure is an object of the present invention to provide a carbon dioxide application device capable of improving the reliability and durability of a blower.

One aspect of the present disclosure is a carbon dioxide application device that recovers carbon dioxide contained in combustion exhaust gas and supplies it into an agricultural house. The carbon dioxide application device has a purification tank that stores the liquid and is configured so that the combustion exhaust gas passes through the liquid, a recovery tank that recovers the water contained in the combustion exhaust gas that has passed through the liquid, and carbon dioxide in the combustion exhaust gas. It is provided with an adsorption tank in which an adsorbent for adsorbing carbon dioxide is arranged inside, a power unit including a blower for supplying combustion exhaust gas from the recovery tank to the adsorption tank, and a regulating valve for adjusting the pressure in the recovery tank. The regulating valve is arranged above the exhaust port of the combustion exhaust gas of the recovery tank and below the intake port of the blower.

According to such a configuration, since the regulating valve is arranged below the intake port of the blower, the water in the regulating valve can be returned to the recovery tank by its own weight when the blower is stopped. As a result, the reliability and durability of the blower can be improved.

In one aspect of the present disclosure, the discharge port of the recovery tank and the supply port of the combustion exhaust gas of the recovery tank may be arranged on the side of the recovery tank. The outlet may be located above the supply port. According to such a configuration, since the pipe can be extended in the horizontal direction in the recovery tank, the height of the recovery tank can be reduced.

One aspect of the present disclosure may further include a control unit that controls the power unit. The control unit may be located outside the power unit. According to such a configuration, the blower as a heat source and the control unit can be arranged apart from each other, so that the reliability of the control unit can be improved. In addition, it is not necessary to provide equipment for cooling the control unit.

In one aspect of the present disclosure, in the power unit, the blower may be arranged in a space open to the outside of the power unit. According to such a configuration, the temperature rise of the blower can be suppressed without providing a cooling facility. As a result, the miniaturization of the device and the cost reduction are promoted.

FIG. 1 is a block diagram schematically showing a configuration of a carbon dioxide application device according to an embodiment. FIG. 2 is a schematic diagram of a power unit and a control unit of the carbon dioxide application device of FIG.

Hereinafter, embodiments to which the present disclosure has been applied will be described with reference to the drawings.
[1. First Embodiment]
[1-1. composition]
The carbon dioxide application device 1 shown in FIG. 1 is a device for recovering carbon dioxide contained in combustion exhaust gas and supplying it into the agricultural house A.

The carbon dioxide application device 1 includes a combustion device 2, a purification tank 3, a recovery tank 4, a power unit 5, an adsorption tank 6, a control unit 7, and a control valve 8.
Further, the carbon dioxide application device 1 includes an exhaust gas flow path 10, a first intake flow path 11, a second intake flow path 13, a first supply flow path 15, a second supply flow path 16, and a discharge. It is provided with a flow path 17.

<Combustion device>
The combustion device 2 is a device that warms the air in the agricultural house A by burning fuel such as heavy oil and kerosene mainly at night. The combustion device 2 burns fuel such as heavy oil or kerosene at night, and distributes the burned exhaust gas into the agricultural house A through the exhaust gas flow path 10. The combustion device 2 may be arranged inside the agricultural house A or may be arranged outside the agricultural house A.

<Purification tank>
The purification tank 3 is a device for cooling and purifying a part of the combustion exhaust gas generated from the combustion device 2 by the liquid L1.

The purification tank 3 stores the liquid L1 inside. Further, the purification tank 3 is configured to take in the combustion exhaust gas generated by the combustion device 2 so that the taken-in combustion exhaust gas passes through the liquid L1.

The combustion exhaust gas is cooled by heat exchange with the liquid L1 and a part of the components contained in the compound contained in the liquid L1 is removed. The volume of the liquid L1 stored in the septic tank 3 is smaller than the volume of the septic tank 3.

Specifically, the purification tank 3 is connected to the first intake flow path 11, and the combustion exhaust gas is supplied from the first intake flow path 11 into the liquid L1. The first intake flow path 11 is connected to the exhaust gas flow path 10 and takes in the combustion exhaust gas.

The combustion exhaust gas supplied into the liquid L1 floats in the liquid L1 as bubbles. That is, bubbling is performed in the purification tank 3. The combustion exhaust gas that has passed through the liquid L1 is taken into the recovery tank 4 by the second take-in flow path 13.

As the liquid L1 stored in the purification tank 3, a liquid L1 capable of removing harmful substances such as sulfides and nitrides contained in the combustion exhaust gas is preferable. For example, an aqueous solution of a compound that reacts with a sulfide or a nitride can be suitably used as the liquid L1.

A cooling air flow path (not shown) for cooling the liquid L1 is connected to the purification tank 3. The liquid L1 is cooled by supplying the cooling air into the liquid L1 from the cooling air flow path.

<Recovery tank>
The recovery tank 4 is a device for recovering the water contained in the combustion exhaust gas that has passed through the liquid L1 of the purification tank 3.

Specifically, a second intake flow path 13 is connected to the recovery tank 4, and the combustion exhaust gas and the water separated from the combustion exhaust gas are supplied from the second intake flow path 13 into the recovery tank 4. .. The combustion exhaust gas that has passed through the recovery tank 4 is supplied to the adsorption tank 6 by the first supply flow path 15 and the second supply flow path 16. On the other hand, the water L2 separated from the combustion exhaust gas is stored inside the recovery tank 4.

As shown in FIG. 2, the recovery tank 4 has a combustion exhaust gas supply port 4A, a combustion exhaust gas discharge port 4B, and a cap 4C. As the recovery tank 4, for example, a commercially available plastic tank can be used.

A second intake flow path 13 is connected to the supply port 4A. The first supply flow path 15 is connected to the discharge port 4B. Both the supply port 4A and the discharge port 4B are arranged on the side of the collection tank 4. The discharge port 4B is located above the supply port 4A.

The tip portion 13A of the second intake flow path 13 and the tip portion 15A of the first supply flow path 15 each extend horizontally in the recovery tank 4. Further, the water surface of the water L2 in the recovery tank 4 is located at a position lower than the tip portion 13A of the second intake flow path 13. Therefore, the intrusion of water in the recovery tank 4 into the tip portion 13A of the second intake flow path 13 is suppressed. As a result, the length of the portion arranged in the recovery tank 4 of the second intake flow path 13 can be reduced. This promotes weight reduction and cost reduction.

Further, the tip portion 15A of the first supply flow path 15 has a plurality of holes formed in the peripheral wall. Further, a filter 15B is wound around the peripheral wall of the tip portion 15A so as to cover a plurality of holes. The combustion exhaust gas discharged from the tip portion 13A of the second intake flow path 13 into the recovery tank 4 is taken into the tip portion 15A of the first supply flow path 15 via the filter 15B.

The recovery tank 4 can discharge the water L2 inside by tilting the posture with the cap 4C removed. By making the first supply flow path 15 flexible (for example, having a bellows shape), the water L2 can be discharged while the first supply flow path 15 is connected to the recovery tank 4. Further, the recovery tank 4 may be provided with a drain valve arranged below the tip portion 13A of the second intake flow path 13. As a result, the water L2 can be discharged more easily.

<Power unit>
The power unit 5 has a blower 5A and a frame body 5B.

The blower 5A is a device for supplying the combustion exhaust gas that has passed through the liquid L1 from the recovery tank 4 to the adsorption tank 6. The blower 5A is arranged between the first supply flow path 15 and the second supply flow path 16.

In the carbon dioxide adsorption step, the operation of the blower 5A causes negative pressure in the purification tank 3 and the recovery tank 4, and the combustion exhaust gas generated in the combustion device 2 passes through the purification tank 3 and the recovery tank 4 to the adsorption tank 6. Is pumped to.

The frame body 5B holds the blower 5A, the first supply flow path 15, and the second supply flow path 16. Specifically, the blower 5A is placed on the first floor plate 5C of the frame body 5B. The frame 5B does not have a side wall surrounding the blower 5A. That is, in the power unit 5, the blower 5A is arranged in a space open to the outside of the power unit 5.

Further, the frame body 5B has a second floor plate 5D arranged below the first floor plate 5C. A recovery tank 4 is placed on the second floor plate 5D. Therefore, the recovery tank 4 is arranged below the blower 5A.

<Suction tank>
In the adsorption tank 6 shown in FIG. 1, an adsorbent that adsorbs carbon dioxide in the combustion exhaust gas is arranged inside. In the carbon dioxide adsorption step, carbon dioxide in the combustion exhaust gas supplied by the blower 5A is adsorbed by the adsorbent. As the adsorbent, for example, a hydrophilic porous material such as activated carbon or zeolite can be used.

On the other hand, in the carbon dioxide application step, the application air is supplied into the adsorption tank 6 from the application air flow path (not shown), and the carbon dioxide is desorbed from the adsorbent. The desorbed carbon dioxide is applied to the agricultural house A via the discharge channel 17.

<Control unit>
The control unit 7 is a device that controls the operation of the carbon dioxide application device 1. Specifically, the control unit 7 controls the power unit 5 (that is, starts and stops the blower 5A), opens and closes a switching valve (for example, a solenoid valve) arranged in each flow path, and the like.

As shown in FIG. 2, the control unit 7 is arranged outside the power unit 5. That is, the control unit 7 has a housing separated from the frame body 5B of the power unit 5. Since the control unit 7 of the present embodiment is arranged inside the agricultural house A, higher weather resistance is not required as compared with the external environment of the agricultural house A. Therefore, the housing of the control unit 7 can be made of plastic, whereby the weight of the housing can be reduced.

In this embodiment, the control unit 7 is arranged on the power unit 5. However, the control unit 7 may be arranged below the power unit 5 or may be arranged apart from the power unit 5.

<Adjustment valve>
The adjusting valve 8 adjusts the pressure in the purification tank 3 and the recovery tank 4. The regulating valve 8 shuts off the flow of gas from the adsorption tank 6 to the recovery tank 4 after the operation of the blower 5A is stopped. That is, the regulating valve 8 suppresses an increase in pressure in the purification tank 3 and the recovery tank 4 after the operation of the blower 5A is stopped.

The control valve 8 is arranged in the first supply flow path 15, that is, upstream of the blower 5A in the flow direction of the combustion exhaust gas. The regulating valve 8 is arranged above the discharge port 4B of the recovery tank 4 and below the intake port 5E of the blower 5A.

As the adjusting valve 8, for example, a check valve can be used. Further, a gate valve, a globe valve, a ball valve, or the like is used as the control valve 8, the control valve 8 is opened in the carbon dioxide adsorption process, and the control valve 8 is closed manually or by the control unit 7 after the operation of the blower 5A is stopped. It may be configured as follows. However, by using the adjusting valve 8 as a check valve, the configuration can be simplified and the cost can be reduced.

In this embodiment, the regulating valve 8 is arranged so that the flow direction of the combustion exhaust gas is horizontal. However, the regulating valve 8 may be arranged so that the flow direction of the combustion exhaust gas is in the vertical direction.

<Arrangement of each device>
In the carbon dioxide application device 1, the purification tank 3, the power unit 5, and the adsorption tank 6 are arranged separately from each other.

Specifically, as shown in FIG. 1, the purification tank 3 is arranged outside the agricultural house A. Further, the power unit 5, the control unit 7, and the suction tank 6 are arranged inside the agricultural house A.

Further, the power unit 5 may be arranged closer to the adsorption tank 6 than the purification tank 3. That is, the purification tank 3, the power unit 5, and the adsorption tank 6 are provided so that the length of the second supply flow path 16 is smaller than the total length of the second intake flow path 13 and the first supply flow path 15. It should be placed. As a result, the performance of the suction tank 6 can be improved.

[1-2. effect]
According to the embodiment described in detail above, the following effects can be obtained.
(1a) Since the regulating valve 8 is arranged below the intake port 5E of the blower 5A, the water in the regulating valve 8 and the first supply flow path 15 is returned to the recovery tank 4 by its own weight when the blower 5A is stopped. Can be done. As a result, the reliability and durability of the blower 5A can be improved.

(1b) By arranging the discharge port 4B and the supply port 4A of the recovery tank 4 on the side of the recovery tank 4, the pipe can be extended in the horizontal direction in the recovery tank 4. As a result, the height of the recovery tank 4 can be reduced.

(1c) By arranging the control unit 7 outside the power unit 5, the blower 5A, which is a heat source, and the control unit 7 can be arranged apart from each other. As a result, the reliability of the control unit 7 can be improved. Further, it is not necessary to provide equipment for cooling the control unit 7.

(1d) In the power unit 5, by arranging the blower 5A in a space open to the outside of the power unit 5, the temperature rise of the blower 5A can be suppressed without providing a cooling facility. As a result, the miniaturization of the device and the cost reduction are promoted.

[2. Other embodiments]
Although the embodiments of the present disclosure have been described above, it is needless to say that the present disclosure is not limited to the above-described embodiments and can take various forms.

(2a) In the carbon dioxide application device of the above embodiment, the control unit does not necessarily have to be arranged outside the power unit. That is, the control unit may be arranged inside the power unit.

(2b) In the carbon dioxide application device of the above embodiment, the blower does not necessarily have to be arranged in a space open to the outside of the power unit. For example, the blower may be placed in a space surrounded by a side wall.

(2c) In the carbon dioxide application device of the above embodiment, the discharge port and the supply port of the recovery tank do not necessarily have to be arranged on the side of the recovery tank.
(2d) In the carbon dioxide application device of the above embodiment, the power unit, the control unit and the adsorption tank may be arranged outside the agricultural house.

(2e) The functions of one component in the above embodiment may be dispersed as a plurality of components, or the functions of the plurality of components may be integrated into one component. Further, a part of the configuration of the above embodiment may be omitted. Further, at least a part of the configuration of the above embodiment may be added or substituted with respect to the other configurations of the above embodiment. It should be noted that all aspects included in the technical idea specified from the wording described in the claims are embodiments of the present disclosure.

1 ... carbon dioxide application device, 2 ... combustion device, 3 ... purification tank, 4 ... recovery tank,
4A ... Supply port, 4B ... Discharge port, 4C ... Cap, 5 ... Power unit, 5A ... Blower,
5B ... Frame, 5C ... 1st floor plate, 5D ... 2nd floor plate, 5E ... Intake port, 6 ... Suction tank,
7 ... Control unit, 8 ... Adjustment valve, 10 ... Exhaust gas flow path, 11 ... First intake flow path,
13 ... 2nd intake flow path, 13A ... tip portion, 15 ... first supply flow path, 15A ... tip portion,
15B ... filter, 16 ... second supply flow path, 17 ... discharge flow path.

Claims (4)

A carbon dioxide application device that collects carbon dioxide contained in combustion exhaust gas and supplies it to an agricultural house.
A purification tank that stores the liquid and is configured to allow the combustion exhaust gas to pass through the liquid.
A recovery tank that recovers the water contained in the combustion exhaust gas that has passed through the liquid, and
An adsorption tank in which an adsorbent that adsorbs carbon dioxide in the combustion exhaust gas is arranged inside,
A power unit including a blower that supplies the combustion exhaust gas from the recovery tank to the adsorption tank, and
A regulating valve that regulates the pressure in the recovery tank,
Equipped with
The control valve is a carbon dioxide application device arranged above the exhaust gas discharge port of the combustion exhaust gas of the recovery tank and below the intake port of the blower. The carbon dioxide application device according to claim 1.
The discharge port of the recovery tank and the supply port of the combustion exhaust gas of the recovery tank are arranged on the side of the recovery tank.
The discharge port is a carbon dioxide application device located above the supply port. The carbon dioxide application device according to claim 1 or 2.
Further equipped with a control unit for controlling the power unit,
The control unit is a carbon dioxide application device arranged outside the power unit. The carbon dioxide application device according to claim 3.
In the power unit, the blower is a carbon dioxide application device arranged in a space open to the outside of the power unit.

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