The present invention relates to gasifiers and more particularly to a gasifier designed to gasify biomass and other waste products.
Gasifiers are widely used to dispose of biomass such as dead animals, dead humans and materials and things that have been subjected to bacteria, viruses and other disease causing constituents. It is the principal object of a gasifier dealing with such biomass to reduce the biomass to ashes. More particularly, it is desirable to rid the biomass of any carbon and therefore the idea is to employ a process that produces white ashes as opposed to black ashes that suggest that there is remaining carbon in the ashes.
Generally, gasifiers include a primary chamber and a secondary or heat transfer chamber. A burner is utilized to heat inlet air that in turn heats the heat transfer chamber, which in turn heats the primary chamber. Many gasification processes can be divided into two phases, a gasification phase and a combustion or carbon phase. In the gasification phase, the biomass is heated in such a fashion that moisture is removed from the biomass. Once the moisture has been removed or substantially removed from the biomass, the process moves to the combustion process where the biomass actually burns and produces a flame. In both the gasification and combustion process, the biomass emits combustible gases that can be recirculated to the burner and burned or which under go exothermic reactions and produce heat. This makes many gasifier systems fuel efficient. Indeed, in some cases or in some phases of an gasification process, the gases or fumes given off by the biomass are sufficient to support the heat requirements of the process.
It is the aim of such gasification processes to heat the biomass so that the biomass is converted to harmless gases such as hydrogen and oxygen which oxidize to form water vapor and carbon dioxide and other harmless constituents.
The present invention relates to a gasifier for gasifying and burning biomass and other waste materials. The gasifier comprises a primary chamber for receiving and holding the waste to be gasified or burned and a heat transfer chamber disposed underneath the primary chamber. A burner is provided for supplying heat to the gasifier and wherein the burner is operative to heat the heat transfer chamber which in turn heats the primary chamber and the waste therein.
In one particular embodiment, the gasifier comprises one or more adjustable air flow vents for varying the quantity of fresh air directed into the gasifier. The adjustable air flow vents can be actuated or moved manually, or in another design, there is provided a processor that is operatively connected to an actuator that in turn is connected to the adjustable air flow vents for actuating the same and hence varying the air flow into the gasifier.
In another exemplary embodiment, the gasifier of the present invention is provided with a control system for controlling various phases of an gasification process. In one example, the control system includes a processor and one or more temperature sensors strategically disposed within the gasifier. By sensing temperature, the processor is able to particularly control the inlet air flow into the primary chamber so as to efficiently perform a gasification process and thereafter to efficiently perform a combustion process where the biomass is burned.
Another feature of the present invention entails the use of two distinct types of refractory bricks utilized in opposing side walls of the primary chamber. In one case, a lower section of the opposed side walls comprises refractory bricks that are more resistant to wear and abrasion than an upper section of refractory bricks that also form a part of the side walls of the primary chamber. The upper section of refractory bricks on the other hand is generally more porous and has better insulating qualities than the lower section which as stated comprise bricks that are more durable and which resist wear and abrasion.
Other objects and advantages of the present invention will become apparent and obvious from a study of the following description and the accompanying drawings which are merely illustrative of such invention.
With further reference to the drawings, the gasifier of the present invention is shown therein and indicated generally by the number 10. Gasifier 10 is designed to gasify various waste products. In one application the gasifier 10 is utilized as a gasifier for biomass. As will be explained in greater detail subsequently herein, in disposing of biomass, the gasifier 10 is utilized during a first phase to carry out a gasification process. During this process the biomass is volatized and moisture is removed from the biomass and this results in the production of gases that are utilized by the gasifier 10 as a source of fuel and heat. In a second phase of this process, there is combustion. That is, the biomass itself starts to burn (produces a flame) and during this process the gasifier 10 is effective to completely gasify the biomass in a process that is environmentally safe and clean.
Turning to a more detailed discussion of the structure and design of the gasifier 10, as viewed in
Mounted on the top of housing 12 of the gasifier 10 is a burner 24. In this embodiment, burner 24 is a gas fired burner and includes a fan motor and an air inlet associated therewith. Note in
Now turning to a discussion of the primary chamber 16,
A beam structure 45 extends transversely across the lower back portion of the primary chamber 16. See
Disposed about the lower front of the primary chamber 16 is a retainer 44. In some embodiments, the retainer 44 is constructed of the same material as the conductive floor 40. As alluded to above, one construction for the conductive floor 40 and the retainer 44 is a silicon carbide-mortar construction. In any event, retainer 44 includes a face 44A and an inclined back surface 44B. See
The primary chamber 16 has a unique side wall structure. As seen in
Secured to the front of the gasifier 10 is a door 50. Door 50 is movable between open and close positions. In the closed position, shown in
Formed in the door is a system or mechanism for varying air flow directly into the primary chamber 16. This system or mechanism includes a series of flow vents having adjustable size openings. In particular, formed in the door 50 is a series of openings 54. See
Slide bar 58 includes a series of slots 58B. A series of studs 59 project outwardly from the door 50 or interface 56 through the slots 58B. A spring 61 is disposed around each stud 59 and is retained on the stud in such a manner that the springs engage the slide bar and effectively bias the slide bar against the interface 56. Effectively, the studs 59 and springs 61 hold the slide bar firmly against the interface.
In
Disposed underneath the primary chamber 16 is the heat transfer chamber 18. Heat transfer chamber 18 functions in substantial part to heat the primary chamber 16. The heat transfer chamber 18 is open to or communicatively connected to both the vertical heating chamber 20 and the vertical exhaust chamber 22. As seen in
Extending upwardly from the top of the gasifier 10 is an exhaust flue 60. See
The burner 24 includes a fan motor associated therewith and an air inlet. The fan is operative to pull fresh inlet air into the gasifier 10 and particularly to pull or induce air into the burner 24 to facilitate combustion. It should be noted that gasifiers generally operate in the absence of substantial oxygen. Therefore, the air induced by the fan motor associated with the burner 24 is for the purpose of supplying oxygen to support the burner. In addition, the gasifier 10, shown in
There is provided a heat exchanger, indicated generally by the number 70, for preheating the inlet air that is directed to the burner 24 and to the auxiliary fan 82. The heat exchanger 70 is shown in
Gasifier 10 can be provided with a control system for controlling gasification and combustion processes as well as the overall gasifier process. An exemplary control system is shown in
The gasifier 10 of the present invention can be utilized to dispose of biomass and other waste products in a clean and environmentally friendly way and without releasing harmful gases and toxins to the environment. In one application, the gasifier 10 is utilized to dispose a biomass through a gasification phase or process that is followed by a combustion or carbon process. In this case, the biomass is loaded into the primary chamber 16 and the door 50 is closed and forms an airtight sealed relationship with the primary chamber.
The burner 24 is fired and this begins the process. Generally, at the beginning of the gasification process more heat from the burner 24 may be required than is required during subsequent periods of the process. As described later, the biomass itself during the gasification process produces fuel that is burned and exothermic reactions that supply heat to the gasification process.
During the gasification process the burner 24 heats incoming air that passes into the gasifier through the air inlet associated with the burner as well as the air that enters via the auxiliary air inlet 82. The air heated by the burner 24 is directed down the vertical heating chamber 20 and into the heat transfer chamber 18. The heat transfer chamber 18 heats the overlying conductive floor 40 that supports the biomass. As the temperature increases in the primary chamber 16, portions of the biomass begin to volatize, creating fumes that include constituents that include hydrogen-carbon bonds and other bonds. The primary chamber 16 operates at a negative or reduced pressure relative to the heat transfer chamber 18. The fumes generated in the gasification process in the primary chamber 16 move through the opening 42 in the back wall of the primary chamber and pass into the vertical heating chamber. Here the resulting fumes are mixed with the inlet heated air that is directed into the vertical chamber 20. As the fumes move downwardly through the vertical heating chamber 20 towards the heat transfer chamber 18, the bonds of the various compounds tend to breakdown and oxidize and produce an exothermic reaction. This reaction releases heat and this additional heat is utilized to heat the heat transfer chamber 18 and ultimately the primary chamber 16.
The heat released by these exothermic reactions can result in the temperature within the heat transfer chamber 18 reaching approximately 800-1000° C. As the fumes from the biomass generate more and more exothermic energy, the fuel supply to the burner 24 can be decreased because more and more of the energy required to carry out the gasification process is provided by the biomass itself. The processor and control system shown in
In addition, the temperature within the primary chamber 16 can be controlled directly by modulating a fuel supply valve that supplies fuel to the burner 24. In addition, the air flow control vents provided on the door 50 can be adjusted to increase the flow of inlet air directly into the primary chamber 16 via the vents provided in the door. Generally, these vents are designed to provide a relatively low volume of air into the primary chamber during certain phases of the gasification process. As is appreciated, by allowing a relatively small amount of air to be directed through these vents into the primary chamber 16 enables the temperature within the primary chamber to increase.
The heat transfer chamber 18 is communicatively connected with the vertical exhaust chamber 22 that extends upwardly through the gasifier 10 adjacent the back wall of the primary chamber 16. Thus during the process, a portion of the exhaust gases is directed from the heat transfer chamber 18 into the vertical exhaust chamber 22 and into the exhaust flue 60 which is communicatively connected with the vertical exhaust chamber of the gasifier. There are various ways to control the exhaust of gases from the gasifier. In one example, a damper such as a butterfly draft control can be strategically positioned to permit an appropriate amount of gases to be expelled from the gasifier via the exhaust flue 60. In one example, a butterfly draft control is utilized and this device uses a counter weight that is adjustable to control the draft of the gasifier.
Continuing to refer to the gasification process, after the burner 24 has been started, the heat transfer chamber 18 is heated and this causes the temperature to rise in the primary chamber 16. As the temperature in the primary chamber 16 increases this causes moisture to be released from the biomass. More particularly, portions of the biomass are volatized, producing the fumes discussed above. These are also exothermic reactions that produce heat. Thus, the exothermic reactions resulting from the biomass continue to heat up the heat transfer chamber 18 and that in turn results in the temperature in the primary chamber 16 increasing. This increased heat energy given off by the biomass is added to the energy supplied by the burner 24 to heat the heat transfer chamber 18. Again, it should be pointed out that by using temperature sensors such as thermocouples in the heat transfer chamber 18 of the primary chamber 16 and directing temperature control signals from these temperature sensors to the processor 100 shown in
In any event, eventually the gasification process will reach a point where the biomass has been reduced to a point that combustion of the biomass occurs. Once the combustion or carbon phase of the process begins, the biomass itself begins to burn and generate a flame. The control system shown in
The present invention provides a gasifier 10 that provides for a controlled gasification-combustion process for biomass and other waste products. The process carried out by the gasifier 10 is designed to minimize particulates in the fumes produced in the primary chamber and particulates that might be exhausted by the exhaust flue 60. More particularly, the process is designed to minimize the production of fly ash. Furthermore the gasifier 10 and the control system is designed to control and maintain a stable temperature in the primary chamber 16. In the end the process is environmentally friendly as the exhaust gases from the exhaust flue 60 contain little or no hydrocarbons, dioxins and other harmful gases or particulates. The present system and process is designed to dispose of the biomass or the waste product such that in the end all that remains is white ash that is generally free of carbon.
The present invention may, of course, be carried out in other ways than those specifically set forth herein without departing from essential characteristics of the invention. The present embodiments are to be considered in all respects as illustrative and not restrictive, and all changes coming within the meaning and equivalency range of the appended claims are intended to be embraced therein.
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