JP7664091B2 - Solid adsorbent filling method - Google Patents

Description

The present invention relates to a method for filling a container of a carbon dioxide capture system with a solid adsorbent material that adsorbs carbon dioxide.

Conventionally, carbon dioxide capture systems have been known that use solid adsorbents to separate and capture carbon dioxide from a target gas. For example, Patent Document 1 discloses a moving bed type carbon dioxide capture system in which a solid adsorbent is circulated between three vessels (an adsorption tower, a regeneration tower, and a drying tower).

Specifically, in the carbon dioxide capture system disclosed in Patent Document 1, an adsorption tower, a regeneration tower, and a drying tower are arranged vertically, and the solid adsorbent material is transferred from the adsorption tower to the regeneration tower by using gravity, and from the regeneration tower to the drying tower. The solid adsorbent material is transferred from the drying tower to the adsorption tower by a conveyor.

In the adsorption tower, the carbon dioxide in the target gas is adsorbed by a solid adsorbent. The adsorption tower is connected to a first target gas pipe for supplying the target gas and a second target gas pipe for discharging the target gas from which the carbon dioxide has been removed.

In the regeneration tower, carbon dioxide is released from the solid adsorbent. The heat of condensation of water vapor is used to release the carbon dioxide. A carbon dioxide pipe is connected to the regeneration tower to discharge the carbon dioxide released from the solid adsorbent. A vacuum pump is installed in the carbon dioxide pipe.

In the drying tower, the condensed water adhering to the solid adsorbent is evaporated. The solid adsorbent is heated indirectly or directly.

JP 2013-121562 A

In a carbon dioxide capture system, the container needs to be filled with solid adsorbent material when the system is installed or when maintenance is performed to replace the solid adsorbent material. To fill the container with solid adsorbent material, it is possible to configure the container so that it can be separated into an upper and lower part, remove the upper part of the container, and pour the solid adsorbent material directly from a tank that stores the solid adsorbent material into the lower part of the container.

However, this type of work requires a lot of time and effort. In particular, it is necessary to lift the tank containing the solid adsorbent to a high position using equipment such as a hoist.

The present invention aims to provide a method for filling a solid adsorbent material that can easily fill a container of a carbon dioxide capture system with the solid adsorbent material.

In order to solve the above problem, the solid adsorbent filling method of the present invention is a method for filling a container of a carbon dioxide capture system with a solid adsorbent that adsorbs carbon dioxide, and is characterized in that a carbon dioxide pipe and other pipes are connected to the container for discharging the carbon dioxide released from the solid adsorbent from the container, the carbon dioxide pipe is provided with a vacuum pump, and a tank in which the solid adsorbent is stored is connected to the container via a supply pipe, and then the vacuum pump is operated with the valves provided on the other pipes closed to supply the solid adsorbent from the tank into the container through the supply pipe.

According to the above configuration, the solid adsorbent can be easily filled into the container of the carbon dioxide capture system by air transport using the operation of a vacuum pump. Moreover, the solid adsorbent can be filled into the container while the tank in which the solid adsorbent is stored is left installed on the ground.

According to the present invention, the solid adsorbent material can be easily loaded into the container of the carbon dioxide capture system.

FIG. 1 is a schematic diagram of a fixed bed type carbon dioxide capture system. FIG. 13 is a diagram for explaining an adsorption process. FIG. 13 is a diagram for explaining a regeneration process. FIG. 13 is a diagram for explaining a drying process. FIG. 2 is a diagram for explaining a method of filling a solid adsorbent material into the container of the carbon dioxide capture system shown in FIG. 1. FIG. 1 is a schematic diagram of a moving bed carbon dioxide capture system. FIG. 7 is a diagram for explaining a method of filling the container of the carbon dioxide capture system shown in FIG. 6 with a solid adsorbent material.

First Embodiment
1 shows a fixed-bed type carbon dioxide capture system 1A which is the subject of the solid adsorbent material filling method according to the first embodiment of the present invention. This system 1A separates and captures carbon dioxide from a target gas, and includes a container 2 which functions as an adsorption tower, a regeneration tower, and a drying tower. The number of containers 2 may be one or more.

The container 2 is filled with a solid adsorbent 10 that adsorbs carbon dioxide. The solid adsorbent 10 is, for example, a porous material that supports an amine compound. Activated carbon, activated alumina, etc. can be used as the porous material.

The container 2 is cylindrical and extends in the vertical direction, and the first target gas pipe 31, the first dry gas pipe 61, and the carbon dioxide pipe 41 are connected to the top of the container 2. The container 2 side portions of the first target gas pipe 31, the first dry gas pipe 61, and the carbon dioxide pipe 41 merge with each other to form a common flow path.

The first target gas pipe 31, the first dry gas pipe 61, and the carbon dioxide pipe 41 are provided with valves 32, 62, and 42, respectively. The first target gas pipe 31 is for supplying the target gas to the container 2, and the first dry gas pipe 61 is for supplying a dry gas (e.g., dry air) to the container 2.

The carbon dioxide pipe 41 is for discharging the carbon dioxide released from the solid adsorbent material 10 from the container 2. A vacuum pump 43 is provided downstream of the valve 42 in the carbon dioxide pipe 41.

The water vapor pipe 51, the second target gas pipe 33, and the second dry gas pipe 63 are connected to the bottom of the container 2. The container 2 side portions of the second target gas pipe 33 and the second dry gas pipe 63 merge with each other to form a common flow path.

The water vapor pipe 51, the second target gas pipe 33, and the second dry gas pipe 63 are provided with valves 52, 34, and 64, respectively. The water vapor pipe 51 is for supplying water vapor to the container 2.

The second target gas pipe 33 is for discharging the target gas from which carbon dioxide has been removed (CO2-free gas) from the container 2, and the second dry gas pipe 63 is for discharging the dry gas from the container 2.

The carbon dioxide capture system 1A performs an adsorption process in which the carbon dioxide in the target gas is adsorbed onto the solid adsorbent material 10, a regeneration process in which water vapor is used to release carbon dioxide from the solid adsorbent material 10, and a drying process in which condensed water adhering to the solid adsorbent material 10 is evaporated.

In the adsorption process, as shown in FIG. 2, valves 42, 52, 62, and 64 are closed and valves 32 and 34 are opened. This causes the target gas to flow from the first target gas pipe 31 through the container 2 to the second target gas pipe 33, and the carbon dioxide in the target gas is adsorbed by the solid adsorbent material 10.

In the regeneration process, as shown in FIG. 3, valves 32, 34, 62, and 64 are closed, valves 42 and 52 are opened, and vacuum pump 43 is operated. As a result, water vapor is supplied from water vapor pipe 51 into container 2, and vacuum pump 43 creates a negative pressure inside container 2. In container 2, water vapor condenses on the surface of solid adsorbent 10, and the heat of condensation causes carbon dioxide to be released from solid adsorbent 10. Carbon dioxide released from solid adsorbent 10 is collected through carbon dioxide pipe 41 into a carbon dioxide holder (not shown).

The reason for creating a negative pressure inside the vessel 2 using the vacuum pump 43 is to make the temperature of the steam supplied into the vessel 2 less than 100°C. Such low-temperature steam can be generated with little energy. For example, the pressure inside the vessel 2 during the regeneration process is -81.3 to -53.9 kPaG when the temperature of the steam is 60 to 80°C.

In the drying process, as shown in FIG. 4, valves 32, 34, 42, and 52 are closed and valves 62 and 64 are opened. This causes the dry gas to flow from the first dry gas pipe 61 through the container 2 to the second dry gas pipe 63, and the condensed water adhering to the solid adsorbent material 10 evaporates.

Next, a method for filling the container 2 with the solid adsorbent material 10 will be described with reference to FIG. 5.

A nozzle 21 that communicates with the inside of the container 2 is provided at the top of the container 2. The tip of the nozzle 21 is normally closed by a lid or the like. The nozzle 21 may be dedicated to filling the solid adsorbent material 10, or a short tube with a thermometer and pressure gauge inside may be used as the nozzle 21.

When filling the container 2 with the solid adsorbent material 10, first, the tank 11 in which the solid adsorbent material 10 is stored is connected to the nozzle 21 via the supply pipe 12. Then, the vacuum pump 43 is operated with the valve 42 open and the other valves 32, 34, 52, 62, and 64 closed. This causes the solid adsorbent material 10 to be supplied from the tank 11 into the container 2 through the supply pipe 12. The flow rate in the supply pipe 12 at this time is, for example, 10 to 15 m/s.

As described above, in the solid adsorbent filling method of this embodiment, the solid adsorbent 10 can be easily filled into the container 2 of the carbon dioxide capture system 1A by air transport using the vacuum pump 43. Moreover, the solid adsorbent 10 can be filled into the container 2 while the tank 11 containing the solid adsorbent 10 remains installed on the ground.

Second Embodiment
6 shows a moving bed type carbon dioxide capture system 1B which is the subject of the solid adsorbent material filling method according to the second embodiment of the present invention. This system 1B separates and captures carbon dioxide from a target gas, and includes three containers, an adsorption tower 2A, a regeneration tower 2B, and a drying tower 2C.

The adsorption tower 2A, regeneration tower 2B, and drying tower 2C are aligned vertically, and the solid adsorbent 10 is transferred from the adsorption tower 2A to the regeneration tower 2B by gravity, and from the regeneration tower 2B to the drying tower 2C. The solid adsorbent 10 is transferred from the drying tower 2C to the adsorption tower 2A by a conveyor 15.

Between the adsorption tower 2A and the regeneration tower 2B, a first adsorbent pipe 71 is provided for transferring the solid adsorbent 10 that has adsorbed carbon dioxide from the adsorption tower 2A to the regeneration tower 2B. In other words, the first adsorbent pipe 71 is connected to both the adsorption tower 2A and the regeneration tower 2B. The first adsorbent pipe 71 is provided with a valve 72.

Between the regeneration tower 2B and the drying tower 2C, a second adsorbent pipe 73 is provided for transferring the solid adsorbent 10 that has released carbon dioxide from the regeneration tower 2B to the drying tower 2C. In other words, the second adsorbent pipe 73 is connected to both the regeneration tower 2B and the drying tower 2C. A valve 74 is provided on the second adsorbent pipe 73.

In this embodiment, the first target gas pipe 31 and the second target gas pipe 33 are connected to the adsorption tower 2A, the water vapor pipe 51 and the carbon dioxide pipe 41 are connected to the regeneration tower 2B, and the first dry gas pipe 61 and the second dry gas pipe 63 are connected to the drying tower 2C.

Next, referring to Figure 7, we will explain how to fill the regeneration tower 2B with the solid adsorbent material 10.

A nozzle 23 communicating with the inside of the regenerator 2B is provided at the top of the regenerator 2B. The tip of the nozzle 23 is normally closed with a lid or the like. The nozzle 23 may be a nozzle dedicated to filling the solid adsorbent material 10, or a short tube with a thermometer and a pressure gauge disposed therein may be used as the nozzle 23 .

When filling the regeneration tower 2B with the solid adsorbent 10, first, the tank 11 in which the solid adsorbent 10 is stored is connected to the nozzle 23 via the supply pipe 12. Then, the vacuum pump 43 is operated with the valve 42 open and the other valves 32, 34, 52, 62, 64, 72, and 74 closed. This causes the solid adsorbent 10 to be supplied from the tank 11 into the container 2 through the supply pipe 12. The flow rate in the supply pipe 12 at this time is, for example, 10 to 15 m/s.

As described above, in the solid adsorbent filling method of this embodiment, the solid adsorbent 10 can be easily filled into the regeneration tower 2B of the carbon dioxide capture system 1B by air transport using the vacuum pump 43. Moreover, the solid adsorbent 10 can be filled into the regeneration tower 2B while the tank 11 containing the solid adsorbent 10 remains installed on the ground.

After the regeneration tower 2B is filled with the solid adsorbent 10, the valve 74 is opened to transfer the solid adsorbent 10 from the regeneration tower 2B to the drying tower 2C. Then, the valve 74 is closed and the regeneration tower 2B is filled with the solid adsorbent 10 again. This process is repeated until the adsorption tower 2A, the regeneration tower 2B, and the drying tower 2C are all filled with the solid adsorbent 10.

Other Embodiments
The present invention is not limited to the above-described embodiment, and various modifications are possible without departing from the gist of the present invention.

(summary)
The solid adsorbent filling method of the present invention is a method for filling a container of a carbon dioxide capture system with a solid adsorbent that adsorbs carbon dioxide, the container is connected to a carbon dioxide piping and other piping for discharging carbon dioxide released from the solid adsorbent from the container, the carbon dioxide piping is provided with a vacuum pump, and a tank in which the solid adsorbent is stored is connected to the container via a supply pipe, and then the vacuum pump is operated with valves provided on the other piping closed, thereby supplying the solid adsorbent from the tank into the container through the supply pipe.

According to the above configuration, the solid adsorbent can be easily filled into the container of the carbon dioxide capture system by air transport using the operation of a vacuum pump. Moreover, the solid adsorbent can be filled into the container while the tank in which the solid adsorbent is stored is left installed on the ground.

The container functions as an adsorption tower, a regeneration tower, and a drying tower, and the other piping may include a first target gas piping for supplying a target gas to the container, a second target gas piping for discharging the target gas from which carbon dioxide has been removed from the container, a first dry gas piping for supplying a dry gas to the container, a second dry gas piping for discharging the dry gas from the container, and a water vapor piping for supplying water vapor to the container. This configuration is suitable for a fixed-bed carbon dioxide capture system.

The container may be a regeneration tower, and the other piping may include a first adsorbent piping for transferring the solid adsorbent that has adsorbed carbon dioxide from the adsorption tower to the regeneration tower, a second adsorbent piping for transferring the solid adsorbent that has released carbon dioxide from the regeneration tower to a drying tower, and a water vapor piping for supplying water vapor to the regeneration tower. This configuration is suitable for a moving bed type carbon dioxide capture system.

1A, 1B Carbon dioxide capture system 10 Solid adsorbent material 11 Tank 12 Supply pipe 15 Conveyor 2 Container 2B Regeneration tower (container)
21, 23 Nozzle 31 First target gas pipe 32, 34, 42, 52, 62, 64 Valve 33 Second target gas pipe 41 Carbon dioxide pipe 43 Vacuum pump 51 Water vapor pipe 61 First dry gas pipe 63 Second dry gas pipe 71 First adsorbent pipe 72, 74 Valve 73 Second adsorbent pipe

Claims (2)

A method for filling a solid adsorbent material that adsorbs carbon dioxide into a container that functions as an adsorption tower, a regeneration tower, and a drying tower in a carbon dioxide recovery system , comprising the steps of:
to the container, a carbon dioxide pipe for discharging the carbon dioxide released from the solid adsorbent from the container, a first target gas pipe for supplying a target gas to the container, a second target gas pipe for discharging the target gas from which carbon dioxide has been removed from the container, a first dry gas pipe for supplying a dry gas to the container, a second dry gas pipe for discharging the dry gas from the container, and a water vapor pipe for supplying water vapor to the container are connected;
a vacuum pump is provided in the carbon dioxide pipe, and valves are provided in the first target gas pipe, the second target gas pipe, the first dry gas pipe, the second dry gas pipe, and the water vapor pipe, respectively;
a tank in which the solid adsorbent is stored is connected to a nozzle provided on the container via a supply pipe, and then the vacuum pump is operated with the valve closed, thereby supplying the solid adsorbent from the tank into the container through the supply pipe and the nozzle . A method for filling a regeneration tower between an adsorption tower and a drying tower in a carbon dioxide recovery system with a solid adsorbent material that adsorbs carbon dioxide, comprising the steps of :
The regeneration tower is connected to a carbon dioxide pipe for discharging the carbon dioxide released from the solid adsorbent from the regeneration tower, a first adsorbent pipe for transferring the solid adsorbent that has adsorbed carbon dioxide from the adsorption tower to the regeneration tower, a second adsorbent pipe for transferring the solid adsorbent that has released carbon dioxide from the regeneration tower to the drying tower, and a water vapor pipe for supplying water vapor to the regeneration tower ,
a vacuum pump is provided in the carbon dioxide pipe, and valves are provided in the first adsorbent pipe, the second adsorbent pipe, and the water vapor pipe, respectively;
a tank in which the solid adsorbent is stored is connected to a nozzle provided in the regeneration tower via a supply pipe, and then the vacuum pump is operated with the valve closed, thereby supplying the solid adsorbent from the tank into the regeneration tower through the supply pipe and the nozzle .

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