Recirculated-suspension pre-calciner system

Abstract

A recirculated-suspension pre-calciner system is disclosed, comprising: a vortex cyclone dust collecting equipment including a plurality of devices, wherein a top device of the vortex cyclone dust collecting equipment is used as a feed system; a vertical combustion kiln; a blower; and a powder purge system, wherein powders in the feed system fall into the vortex cyclone dust collecting equipment and pass through a plurality of the devices to mix and exchange heat with flue gas comprising CO.sub.2, generating calcination reaction and releasing CO2 into the flue gas. and the steam is separated and transported to the feed system by the blower and acts as a carrier gas of powders.

Claims

1. A recirculated-suspension pre-calciner system, comprising: a vortex cyclone dust collecting equipment comprising a plurality of devices connected in series from highest to lowest, with a bottom side of each higher device of the vortex cyclone dust collecting equipment in the series directly connected through a rotary valve or flange to a next lower device of the vortex cyclone dust collecting equipment in the series; a vertical combustion kiln comprising a top side and a bottom side, wherein the top side of the vertical combustion kiln is connected to a lowest device of the vortex cyclone dust collecting equipment, and the bottom side of the vertical combustion kiln is connected to a highest device of the vortex cyclone dust collecting equipment; a blower is connected between the highest device and the second highest device of the vortex cyclone dust collecting equipment to transport flue gas directly from the second highest device to the highest device; and a powder purge system is directly connected to the lowest device of the vortex cyclone dust collecting equipment.

2. The recirculated-suspension pre-calciner system as claimed in claim 1, wherein the highest device of the vortex cyclone dust collecting equipment acts as a feed system of the recirculated-suspension pre-calciner system.

3. The recirculated-suspension pre-calciner system as claimed in claim 1, wherein the vortex cyclone dust collecting equipment comprises 3-7 devices.

4. The recirculated-suspension pre-calciner system as claimed in claim 2, wherein powders in the feed system fall into the vortex cyclone dust collecting equipment and pass through a plurality of the devices to mix and exchange heat with flue gas, generating calcination reaction and releasing CO.sub.2, and the flue gas comprising CO.sub.2 is transported to the feed system by the blower and acts as a carrier gas of powders.

5. The recirculated-suspension pre-calciner system as claimed in claim 4, wherein the powders comprise CaCO.sub.3.

6. The recirculated-suspension pre-calciner system as claimed in claim 4, wherein the calcination reaction uses a metal carbonate salt as an adsorbent.

7. The recirculated-suspension pre-calciner system as claimed in claim 4, wherein the metal carbonate salt comprises CaCO.sub.3, ZnCO.sub.3, MgCO.sub.3, MnCO.sub.3, or NiCO.sub.3.

8. A method for using a recirculated-suspension pre-calciner system, comprising: providing a vortex cyclone dust collecting equipment comprising a plurality of devices connected in series from highest to lowest, with a bottom side of each higher device of the vortex cyclone dust collecting equipment in the series directly connected through a rotary valve or flange to a next lower device of the vortex cyclone dust collecting equipment in the series, a vertical combustion kiln, a blower and a powder purge system, wherein a top device of the vortex cyclone dust collecting equipment acts as a feed system; causing powders in the feed system to fall into the vortex cyclone dust collecting equipment and pass through a plurality of the devices to mix and exchange heat with flue gas comprising CO.sub.2, generating calcination reaction and releasing CO.sub.2; and transporting the flue gas comprising CO.sub.2 to the feed system through the blower, wherein the flue gas acts as a carrier gas of the powders; wherein the vortex cyclone dust collecting equipment comprises a plurality of devices; wherein the vertical combustion kiln comprises a top side and a bottom side, wherein the top side of the vertical combustion kiln is connected to a lowest device of the vortex cyclone dust collecting equipment, and the bottom side of the vertical combustion kiln is connected to a highest device of the vortex cyclone dust collecting equipment; wherein the blower is connected between the highest device and the second highest device of the vortex cyclone dust collecting equipment to transport flue gas directly from the second highest device to the highest device; and wherein the powder purge system is directly connected to the lowest device of the vortex cyclone dust collecting equipment.

9. The method for using a recirculated-suspension pre-calciner system as claimed in claim 8, wherein a part of the flue gas comprising CO.sub.2 transported to the feed system is combusted with pure oxygen in the vertical combustion kiln.

10. The method for using a recirculated-suspension pre-calciner system as claimed in claim 9, wherein the combusted gas is moved to a bottom device of the vortex cyclone dust collecting equipment.

11. The method for using a recirculated-suspension pre-calciner system as claimed in claim 9, wherein pure oxygen and fuel are added during the combustion with pure oxygen.

12. The method for using a recirculated-suspension pre-calciner system as claimed in claim 9, wherein temperature of the combustion with pure oxygen is 900 C.-1200 C.

13. The method for using a recirculated-suspension pre-calciner system as claimed in claim 8, wherein the powders comprise CaCO.sub.3.

14. The method for using a recirculated-suspension pre-calciner system as claimed in claim 8, wherein the powders are reacted to form CaO through calcination.

15. The method for using a recirculated-suspension pre-calciner system as claimed in claim 8, wherein the flue gas comprising CO.sub.2 released from calcination has a temperature of 600-1000 C.

16. The method for using a recirculated-suspension pre-calciner system as claimed in claim 8, wherein the flue gas has a temperature of 500-1000 C.

17. The method for using a recirculated-suspension pre-calciner system as claimed in claim 8, wherein CO.sub.2 of the released flue gas is sealed or reapplied in a further process step.

18. The method for using a recirculated-suspension pre-calciner system as claimed in claim 8, wherein the calcination uses a metal carbonate salt as an adsorbent.

19. The method for using a recirculated-suspension pre-calciner system as claimed in claim 18, wherein the metal carbonate salt comprises CaCO.sub.3, ZnCO.sub.3, MgCO.sub.3, MnCO.sub.3, or NiCO.sub.3.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) The disclosure can be more fully understood by reading the subsequent detailed description and examples with references made to the accompanying drawings, wherein,

(2) FIG. 1 shows a sketch diagram of a recirculated-suspension pre-calciner system of an embodiment of the disclosure.

DETAILED DESCRIPTION OF DISCLOSURE

(3) It is understood that specific embodiments are provided as examples to teach the broader inventive concept, and one of ordinary skill in the art can easily apply the teaching of the present disclosure to other methods or apparatus. The following discussion is only used to illustrate the disclosure, not limit the disclosure.

(4) The disclosure discloses a calcination equipment of a CO.sub.2 capturing system, which captures released CO.sub.2, for example, from power plants to substantially increase capture of CO.sub.2, reuse adsorbents, reduce reaction time and save fuel, and may reduce capture cost of CO.sub.2. The disclosure may apply a recirculated-suspension pre-calciner to calcinate adsorbents, for example CaCO.sub.3 is calcinated to CaO, to fabricate a lightweight calcium carbonate or capture CO.sub.2.

(5) FIG. 1 shows a sketch diagram of a recirculated-suspension pre-calciner system of an embodiment of the disclosure. Referring to FIG. 1, the recirculated-suspension pre-calciner system of the embodiment comprises a feed system 102, a vortex cyclone dust collecting equipment 104 including a plurality of devices, a vertical combustion kiln 106, a blower 108 and a powder purge system 110, wherein a top device of the vortex cyclone dust collecting equipment 104 is used as the feed system 102. A bottom side of the a device of the vortex cyclone dust collecting equipment 104 is connected through a rotary valve or flange to another device of the vortex cyclone dust collecting equipment 104 to separate pressure of the devices therebetween. As shown in FIG. 1, the vertical combustion kiln 106 comprises a top side and a bottom side, wherein the top side of the vertical combustion kiln 106 is connected to the lowest device of the vortex cyclone dust collecting equipment 104. The bottom side of the vertical combustion kiln 106 is connected to the highest device of the vortex cyclone dust collecting equipment 104. The blower 108 is connected to the highest device of the vortex cyclone dust collecting equipment 104. The powder purge system 110 is connected to the lowest device of the vortex cyclone dust collecting equipment 104.

(6) The feed system 102 is operated by using the blower 108 to move high temperature CO.sub.2 with temperatures of 600 C.1000 C. at the outlet of the vortex cyclone dust collecting equipment 104 to transport CaCO.sub.3 which has come through the calcination procedure to the feed system 102, i.e. the top device of the vortex cyclone dust collecting equipment 104. After gas solid separation in the vortex cyclone dust collecting equipment 104, powders of CaCO.sub.3 are exerted by gravity to fall through devices of the vortex cyclone dust collecting equipment 104 and cross with a flue gas transported from the bottom side to the top side, wherein the flue gas is a burning reacting product from a burner, and the flue gas comprises H.sub.2O and CO.sub.2 in the embodiment. After heat fully exchanging, calcination reaction is generated to form CaO and release CO.sub.2. In the embodiment, the flue gas has a temperature of 500 C.1000 C. The flue gas comprising CO.sub.2 is transported to the feed system through the blower 108, wherein the flue gas acts as a carry gas of the powders. Part of the flue gas is released to be prepared to be sequestrated or reused and to maintain pressure and mass conservation of the entire system. Another part of the mixture gas is used as a carry gas and is added with a suitable amount of oxygen, for example pure oxygen having concentrations larger than 93%, to be heated along with fuel to 900-1200 C. for use as a combustion gas of the vertical combustion kiln 106 after gas solid separation. The mixture gas is then moved to the bottom device of the vortex cyclone dust collecting equipment 104 to increase CO.sub.2 concentration and also has a function of restraining high temperature of oxygen combustion to prevent powder sintering and equipment damage. Thereafter, the powder is moved into the powder purge system 110. The quantity of recirculation flow is a key point of controlling flue gas temperature of the equipment. The flue gas flows from bottom to top to fully exchange heat with powders and provides calcination power required for powders, wherein the primary compositions of the hot flue gas are CO.sub.2 and steam. Calcination powers can use metal carbonate salts, such as CaCO.sub.3, ZnCO.sub.3, MgCO.sub.3, MnCO.sub.3, or NiCO.sub.3, etc, as an adsorbent. If the hot flue gas is to be sequestrated or CO.sub.2 is to be reused, a step can be performed to separate the water and obtain a high concentration CO.sub.2 after cooling down and condensation. The vertical combustion kiln is helpful to improve insufficient removal of carbonate. Height of the vertical combustion kiln 106 can be increased to extend the powder residence time and thus calcination reaction rate can be kept to be more than 90%.

(7) According to the description above, the recirculated-suspension pre-calciner system of the disclosure uses the concept of oxy-combustion to perform CO.sub.2-O.sub.2 combustion in the calciner. The disclosure calcines metal carbonate salts, uses a flue gas recirculation way to keep temperature of the inlet flue gas at 900-1200 C., and gradually increases CO.sub.2 concentration of flue gas in the calciner.

(8) While the disclosure has been described by way of example and in terms of the preferred embodiments, it is to be understood that the disclosure is not limited to the disclosed embodiments. It is intended to cover various modifications and similar arrangements (as would be apparent to those skilled in the art). Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements.