阅读说明：本技术 一种具有飞灰烧嘴的飞灰再循环气化炉及其工作方法 (Fly ash recycling gasifier with fly ash burner and working method thereof ) 是由 徐越 罗丽珍 任永强 陶继业 王鹏杰 李小宇 刘刚 陈智 樊强 刘沅 秦建明 于 2020-12-07 设计创作，主要内容包括：本发明公开的一种具有飞灰烧嘴的飞灰再循环气化炉及其工作方法,属于气化炉技术领域。煤气除灰器的入口与气化炉的废锅出口连接,煤气除灰器的底部出口与飞灰储罐连接,飞灰储罐与充变压锁斗连接,充变压锁斗与飞灰调配系统连接,飞灰储罐连接有冲压氮气进气管,飞灰储罐、充变压锁斗和飞灰调配系统分别与排气过滤器连接,排气过滤器与反吹氮气缓冲罐连接,飞灰调配系统与飞灰烧嘴连接,飞灰烧嘴设在气化炉炉膛内壁,气化炉的气化剂系统分别与飞灰烧嘴和飞灰调配系统连接。本发明能够充分利用飞灰残碳的同时,简化飞灰输送的流程,减少磨煤及煤粉的输送负荷,控制飞灰与煤、氧及水的比例,提高气化炉的整体效率和能源的综合利用率。(The invention discloses a fly ash recycling gasifier with a fly ash burner and a working method thereof, belonging to the technical field of gasifiers. The inlet of the gas ash remover is connected with the waste boiler outlet of the gasification furnace, the bottom outlet of the gas ash remover is connected with a fly ash storage tank, the fly ash storage tank is connected with a pressure charging and changing lock bucket, the pressure charging and changing lock bucket is connected with a fly ash blending system, the fly ash storage tank is connected with a stamping nitrogen gas inlet pipe, the fly ash storage tank, the pressure charging and changing lock bucket and the fly ash blending system are respectively connected with an exhaust filter, the exhaust filter is connected with a back-blowing nitrogen buffer tank, the fly ash blending system is connected with a fly ash burner, the fly ash burner is arranged on the inner wall of the hearth of the gasification furnace, and a gasifying agent system of. The invention can simplify the flow of conveying the fly ash while fully utilizing the residual carbon of the fly ash, reduce the conveying load of coal grinding and pulverized coal, control the proportion of the fly ash to coal, oxygen and water, and improve the overall efficiency of the gasification furnace and the comprehensive utilization rate of energy.)

1. A fly ash recycling furnace with a fly ash burner is characterized by comprising a fly ash burner (1), a coal gas ash remover (2), a fly ash storage tank (3), a pressure charging lock hopper (4), a fly ash blending system (5), an exhaust filter (6) and a back-blowing nitrogen buffer tank (7);

the inlet of a gas ash remover (2) is connected with the waste boiler outlet of a gasification furnace, the bottom outlet of the gas ash remover (2) is connected with a fly ash storage tank (3), the fly ash storage tank (3) is connected with a pressure charging lock hopper (4), the pressure charging lock hopper (4) is connected with a fly ash blending system (5), the fly ash storage tank (3) is connected with a stamping nitrogen inlet pipe, the fly ash storage tank (3), the pressure charging lock hopper (4) and the fly ash blending system (5) are respectively connected with an exhaust filter (6), the exhaust filter (6) is connected with a back-blowing nitrogen buffer tank (7), the fly ash blending system (5) is connected with a fly ash burner (1), the fly ash burner (1) is arranged on the inner wall of the hearth of the gasification furnace, and a gasification agent system of the gasification furnace is respectively connected with the fly ash burner (1) and the fly ash blending.

2. The fly ash recycling furnace with fly ash burners according to claim 1, wherein the fly ash blending system (5) comprises a fly ash buffering lock hopper (5-1), a density measuring device, a flow measuring device, an online residual carbon measuring device and a processor unit (5-2), the density measuring device, the flow measuring device and the online residual carbon measuring device are respectively connected with the processor unit (5-2), the fly ash buffering lock hopper (5-1) is respectively connected with the charging lock hopper (4) and the fly ash burner (1), the fly ash buffering lock hopper (5-1) is connected with a high-pressure nitrogen inlet pipe, the high-pressure nitrogen inlet pipe is connected with a high-pressure nitrogen control system, and the processor unit (5-2) is respectively connected with a gasifying agent system and the high-pressure nitrogen control system of the gasification furnace.

3. The fly ash recycling furnace with fly ash burners as claimed in claim 2, wherein a first control valve (8) is provided on a connection pipe between the fly ash storage tank (3) and the charging pressure lock hopper (4), and a second control valve (9) is provided on a connection pipe between the charging pressure lock hopper (4) and the fly ash buffering lock hopper (5-1).

4. The fly ash recycling furnace with a fly ash burner according to claim 3, characterized in that the fly ash storage tank (3), the charging pressure lock hopper (4), the fly ash buffering lock hopper (5-1), the first control valve (8) and the second control valve (9) are connected with a bridge-removing nitrogen system.

5. A fly ash recycling gasifier with fly ash burners according to claim 4, characterized in that the inlet pipe of the bridge-removing nitrogen system is connected to the bottom of the fly ash storage tank (3), the charging pressure lock hopper (4) and the fly ash buffer lock hopper (5-1).

6. The fly ash recycling gasifier with fly ash burners according to claim 1, wherein the fly ash burners (1) and the plurality of pulverized coal burners are circumferentially and uniformly arranged in the gasification section of the gasifier.

7. A fly ash recycling gasifier with fly ash burners according to claim 6, characterized in that the fly ash burner (1) is arranged on the same horizontal plane as the plurality of pulverized coal burners.

8. A fly ash recycling gasifier with fly ash burners according to claim 7, characterized in that the fly ash burner (1) is deflected 1 ° to 5 ° in the same direction as the plurality of pulverized coal burners.

9. A fly ash recycling gasifier with a fly ash burner according to claim 1, characterized in that the fly ash burner (1) is directed towards the center of the gasifier hearth.

10. The method for operating a fly ash recycling gasifier with a fly ash burner according to any one of claims 1 to 9, comprising:

the method comprises the following steps that ash-containing crude synthesis gas discharged from a waste boiler enters a coal gas ash remover (2), the crude synthesis gas is discharged from the top of the coal gas ash remover (2), fly ash enters a fly ash storage tank (3) from the bottom of the coal gas ash remover (2), the fly ash enters a charging pressure lock hopper (4) when the fly ash storage tank (3) reaches a set maximum material level, the fly ash stops entering the charging pressure lock hopper (4) when the fly ash storage tank (3) reaches a set minimum material level, a valve of an exhaust filter (6) is opened for pressure relief, and a pressure relief valve is closed when the fly ash storage tank (3) reaches the set maximum material level;

after the flying ash stops entering the variable-pressure lock hopper (4), the variable-pressure lock hopper (4) is stamped, after the flying ash is stamped to a preset pressure, the flying ash enters the flying ash blending system (5), when the variable-pressure lock hopper (4) reaches a set minimum material level, the flying ash stops entering the flying ash blending system (5), a valve of an exhaust filter (6) is opened for pressure relief, a pressure relief valve is closed after the pressure relief, and a balance pipeline valve of the variable-pressure lock hopper (4) and a flying ash storage tank (3) is opened for pressure balance; when the exhaust filter (6) reaches the maximum material level, the fly ash collected by the exhaust filter (6) enters a fly ash blending system (5) through high-pressure nitrogen purging;

and the fly ash enters a hearth of the gasification furnace from the fly ash burner after being blended by the fly ash blending system (5) to perform combustion circulation again.

Technical Field

The invention belongs to the technical field of gasification furnaces, and particularly relates to a fly ash recycling gasification furnace with a fly ash burner and a working method thereof.

Background

The coal gasification technology is a core technology for clean and efficient utilization of coal, is a key technology for developing advanced clean coal power generation, coal chemical industry, coal-based poly-generation and other energy systems, and has important influence on the operation reliability and economy of each system. Driven by the rapid development of modern coal chemical engineering projects, coal gasification technology is developing towards large-scale, clean, efficient and wide coal adaptability. The development of coal gasification technology presents a lot of flowers, but in the development process of the high-efficiency clean coal gasification technology at the present stage, a plurality of problems still exist and need to be solved.

In the existing gasification furnace system, fly ash is conveyed to a coal grinding system, and the fly ash is subjected to the processes of pressure increase and pressure reduction due to the normal pressure of the coal grinding system, so that the equipment and the process are complicated, the energy consumption is high, and the proportion of the fly ash to coal, oxygen and water is not easy to control; meanwhile, fly ash enters a coal grinding system, extra loss is caused to the coal grinding machine, and the maintenance and cost of the system are increased.

Disclosure of Invention

In order to solve the above problems, an object of the present invention is to provide a fly ash recycling gasifier with a fly ash burner and a method for operating the same, which can simplify the flow of fly ash transportation while making full use of the residual carbon in fly ash, reduce the transportation load of coal grinding and pulverized coal, control the ratio of fly ash to coal, oxygen and water, and improve the overall efficiency of the gasifier and the comprehensive utilization rate of energy.

The invention is realized by the following technical scheme:

the invention discloses a fly ash recycling gasifier with a fly ash nozzle, which comprises a fly ash nozzle, a gas ash remover, a fly ash storage tank, a pressure charging lock hopper, a fly ash blending system, an exhaust filter and a back-blowing nitrogen buffer tank, wherein the gas ash remover is arranged in the fly ash storage tank;

the inlet of the gas ash remover is connected with the waste boiler outlet of the gasification furnace, the bottom outlet of the gas ash remover is connected with a fly ash storage tank, the fly ash storage tank is connected with a pressure charging and changing lock bucket, the pressure charging and changing lock bucket is connected with a fly ash blending system, the fly ash storage tank is connected with a stamping nitrogen gas inlet pipe, the fly ash storage tank, the pressure charging and changing lock bucket and the fly ash blending system are respectively connected with an exhaust filter, the exhaust filter is connected with a back-blowing nitrogen buffer tank, the fly ash blending system is connected with a fly ash burner, the fly ash burner is arranged on the inner wall of the hearth of the gasification furnace, and a gasifying agent system of.

Preferably, the fly ash blending system comprises a fly ash buffering lock hopper, a density measuring device, a flow measuring device, an online residual carbon measuring device and a processor unit, wherein the density measuring device, the flow measuring device and the online residual carbon measuring device are respectively connected with the processor unit, the fly ash buffering lock hopper is respectively connected with the pressure charging lock hopper and the fly ash burner, the fly ash buffering lock hopper is connected with a high-pressure nitrogen inlet pipe, the high-pressure nitrogen inlet pipe is connected with a high-pressure nitrogen control system, and the processor unit is respectively connected with a gasifying agent system and the high-pressure nitrogen control system of the gasification furnace.

Further preferably, a first control valve is arranged on a connecting pipeline between the fly ash storage tank and the charging pressure lock bucket, and a second control valve is arranged on a connecting pipeline between the charging pressure lock bucket and the fly ash buffering lock bucket.

Further preferably, the fly ash storage tank, the pressure charging lock hopper, the fly ash buffering lock hopper, the first control valve and the second control valve are all connected with a bridge-removing nitrogen system.

Further preferably, an air inlet pipe of the bridge-removing nitrogen system is connected with the bottom of the fly ash storage tank, the pressure charging lock hopper and the fly ash buffering lock hopper.

Preferably, the fly ash burners and the plurality of pulverized coal burners are circumferentially and uniformly arranged in the gasification section of the gasification furnace.

Further preferably, the fly ash burner and the plurality of pulverized coal burners are arranged on the same horizontal plane.

Further preferably, the fly ash burner and the plurality of pulverized coal burners deflect 1 to 5 degrees in the same direction.

Preferably, the fly ash burner is opposite to the center of the hearth of the gasification furnace.

The invention discloses an operating method of the fly ash recycling gasifier with the fly ash burner, which comprises the following steps:

the method comprises the following steps that ash-containing crude synthesis gas discharged from a waste boiler enters a coal gas ash remover, the crude synthesis gas is discharged from the top of the coal gas ash remover, fly ash enters a fly ash storage tank from the bottom of the coal gas ash remover, the fly ash enters a charging and transforming lock hopper when the fly ash storage tank reaches a set maximum material level, the fly ash stops entering the charging and transforming lock hopper when the fly ash storage tank reaches the set minimum material level, a valve of an exhaust filter is opened for pressure relief, and a pressure relief valve is closed when the fly ash storage tank reaches the set maximum material level;

after the flying ash stops entering the variable-pressure charging lock hopper, the variable-pressure charging lock hopper is stamped, after the flying ash is stamped to a preset pressure, the flying ash enters the flying ash blending system, when the variable-pressure charging lock hopper reaches a set minimum material level, the flying ash stops entering the flying ash blending system, a valve of an exhaust filter is opened to release the pressure, a pressure release valve is closed after the pressure is released, and a balance pipeline valve of the variable-pressure charging lock hopper and a flying ash storage tank is opened to balance the pressure; when the exhaust filter reaches the maximum material level, the fly ash collected by the exhaust filter enters a fly ash blending system through high-pressure nitrogen purging;

and after the fly ash is blended by the fly ash blending system, the fly ash enters a hearth of the gasification furnace through the fly ash burner to perform combustion circulation again.

Compared with the prior art, the invention has the following beneficial technical effects:

the invention discloses a fly ash recycling gasifier with a fly ash burner, wherein synthetic gas containing ash is separated and treated by a gas ash remover from a waste boiler outlet of the gasifier, then sequentially passes through a fly ash storage tank and a pressure charging lock hopper, then enters a fly ash distribution system, and after detection and calculation, enters a hearth of the gasifier through the fly ash burner to perform a secondary combustion cycle. The gasification furnace has reasonable structural design and makes full use of the residual carbon in the fly ash; the fly ash is conveyed at high pressure to the fly ash burner through the charging pressure lock hopper and the fly ash blending system, so that the flow of fly ash conveying is simplified, the conveying load of a coal grinding system and pulverized coal is reduced, and the additional loss caused by a coal mill is reduced; on the other hand, because a low-pressure conveying flow and equipment are removed, the control flow is simplified, the risk of easy blockage in low-pressure conveying is reduced, and the efficiency and the reliability are high. Meanwhile, the proportion of the fly ash entering the gasification furnace to coal, oxygen and water can be controlled through the fly ash blending system, and the overall efficiency of the gasification furnace and the comprehensive utilization rate of energy are improved.

Furthermore, the density measuring device can monitor the solid-gas ratio of the fly ash in real time, the flow measuring device can monitor the flow of the fly ash in real time, the online carbon residue measurement can monitor the carbon residue amount in the fly ash in real time, after the carbon residue amount is analyzed and processed by the processor unit, the result is fed back to the gasifying agent system to control the fly ash amount entering the gasification furnace, the fly ash is pressurized again by the high-pressure nitrogen system and then enters the gasification furnace, the proportion of the fly ash entering the gasification furnace to coal, oxygen and water is accurately controlled, and the overall efficiency of the gasification furnace and the comprehensive utilization rate of energy are improved.

Furthermore, the first control valve and the second control valve can rapidly control the feeding and discharging of the fly ash according to the material levels of the fly ash storage tank and the charging pressure lock hopper, and the automation degree is high.

Furthermore, the bridge nitrogen removal system can prevent materials from bridging, and the safety and the stability of the system are improved.

Furthermore, the bridge removal nitrogen system removes bridges at the parts which are easy to bridge and block at the bottoms of the fly ash storage tank, the variable pressure lock hopper and the fly ash buffering lock hopper, so that the pertinence is strong, the efficiency is high, and nitrogen is saved.

Furthermore, the fly ash burners and the plurality of pulverized coal burners are uniformly arranged in the gasification section of the gasification furnace in the circumferential direction, so that the fly ash is uniformly fed and is easily mixed with the pulverized coal.

Furthermore, the fly ash burner and the plurality of pulverized coal burners are arranged on the same horizontal plane, thereby being beneficial to the intersection at the central part of the gasification furnace and improving the combustion uniformity.

Furthermore, the fly ash burner and the plurality of pulverized coal burners deflect 1 to 5 degrees in the same direction and are intersected at the central part of the gasification furnace in a tangent circle mode to form stable cyclone, so that the combustion uniformity is further improved.

Furthermore, the fly ash burner is over against the center of the hearth of the gasification furnace, so that the fly ash can rapidly enter the combustion center of the gasification furnace, and the efficiency is high.

The working method of the fly ash recycling gasifier with the fly ash burner disclosed by the invention can fully utilize the residual carbon of the fly ash, simplify the flow of fly ash conveying, reduce the conveying load of coal grinding and pulverized coal, control the proportion of the fly ash, coal, oxygen and water, and improve the overall efficiency of the gasifier and the comprehensive utilization rate of energy.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

In the figure: 1-fly ash burner, 2-coal gas ash remover, 3-fly ash storage tank, 4-pressure charging lock hopper, 5-fly ash blending system, 5-1-fly ash buffer lock hopper, 5-2-processor unit, 6-exhaust filter, 7-back blowing nitrogen buffer tank, 8-first control valve, 9-second control valve.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings, which are included to illustrate and not to limit the invention:

referring to fig. 1, in the fly ash recycling furnace with a fly ash burner of the present invention, an inlet of a gas ash remover 2 is connected to an outlet of a waste boiler of the gasification furnace, an outlet at the bottom of the gas ash remover 2 is connected to a fly ash storage tank 3, the fly ash storage tank 3 is connected to a pressure-charging lock bucket 4, a first control valve 8 is disposed on a connecting pipeline between the fly ash storage tank 3 and the pressure-charging lock bucket 4, the pressure-charging lock bucket 4 is connected to a fly ash blending system 5, the fly ash storage tank 3 is connected to a stamping nitrogen inlet pipe, the fly ash storage tank 3, the pressure-charging lock bucket 4 and the fly ash blending system 5 are respectively connected to an exhaust filter 6, the exhaust filter 6 is connected to a back-blowing nitrogen buffer tank 7, the fly ash blending system 5 is connected to the fly ash burner 1, the fly ash burner 1 is disposed on an inner wall of a hearth of.

The fly ash blending system 5 comprises a fly ash buffering lock hopper 5-1, a density measuring device, a flow measuring device, an online carbon residue measuring device and a processor unit 5-2, wherein the density measuring device, the flow measuring device and the online carbon residue measuring device are respectively connected with the processor unit 5-2, the fly ash buffering lock hopper 5-1 is respectively connected with a charging pressure lock hopper 4 and a fly ash burner 1, and a second control valve 9 is arranged on a connecting pipeline between the charging pressure lock hopper 4 and the fly ash buffering lock hopper 5-1; the fly ash buffering lock hopper 5-1 is connected with a high-pressure nitrogen gas inlet pipe, the high-pressure nitrogen gas inlet pipe is connected with a high-pressure nitrogen gas control system, and the processor unit 5-2 is respectively connected with a gasifying agent system and the high-pressure nitrogen gas control system of the gasification furnace.

The fly ash storage tank 3, the charging pressure lock hopper 4, the fly ash buffering lock hopper 5-1, the first control valve 8 and the second control valve 9 are all connected with a bridge-removing nitrogen system. The air inlet pipe of the bridge-removing nitrogen system is connected with the bottom of the fly ash storage tank 3, the pressure charging lock hopper 4 and the fly ash buffering lock hopper 5-1.

A fly ash leading-out branch is connected between the gas ash remover 2 and the fly ash storage tank 3, a gas stripping displacement device is arranged on the branch, an inlet of the gas stripping displacement device is connected with a nitrogen system, a solid outlet of the gas stripping displacement device is connected with a fly ash bin, and a gas outlet of the gas stripping displacement device is connected with a tail gas treatment system. The surplus fly ash can be led out and recycled after air stripping.

The coal gas ash remover 2 is preferably a cyclone separator.

The fly ash burner 1 is arranged right opposite to the center of the hearth of the gasification furnace, is uniformly arranged on the gasification section of the gasification furnace along with the plurality of pulverized coal burners in the circumferential direction, is arranged on the same horizontal plane with the pulverized coal burners, and preferably deflects 1-5 degrees along the same direction with the plurality of pulverized coal burners.

The working method of the fly ash recycling furnace with the fly ash burner comprises the following steps:

the ash-containing crude synthesis gas from the waste boiler enters a coal gas ash remover 2, the crude synthesis gas enters the next working section from the top of the cyclone, the fly ash enters a fly ash storage tank 3 from the bottom of the cyclone, when the fly ash storage tank 3 reaches the set maximum material level, a first control valve 8 is opened, the fly ash enters a charging pressure lock hopper 4, when the fly ash storage tank 3 reaches the set minimum material level, the first control valve 8 is closed, a valve connected with an exhaust filter 6 is opened for pressure relief, when the fly ash storage tank 3 reaches the set maximum material level, a pressure relief valve is closed, and the operations are repeated. And meanwhile, if the flying ash storage tank 3 does not report low material level within 1 minute, opening the corresponding bridge removal pipeline for bridge removal, and closing the bridge removal pipeline when the material level drops to reach a set stable state.

And after the control valve 8 is closed, the pressure charging lock hopper 4 is punched, after the pressure charging lock hopper is punched to 4MPa, the second control valve 9 is opened, the fly ash goes to the fly ash blending system 5, when the pressure charging lock hopper 4 reaches the set minimum material level, the second control valve 9 is closed, a valve connected with the exhaust filter 6 is opened for pressure relief, a pressure relief valve is closed after the pressure relief, a balance pipeline valve of the fly ash storage tank 4 is opened, the pressure is balanced, and the operations are repeated. During the process, if the charge level of the charge pressure lock hopper 4 is not low within 1 minute, the corresponding bridge removal pipeline is opened to remove the bridge, and the bridge removal pipeline is closed when the charge level drops to reach a set stable state.

If the flying ash buffering lock hopper 5-1 reports that the material level is not low within 1 minute, the corresponding bridge removal pipeline is opened to remove the bridge, and the bridge removal pipeline is closed when the material level is lowered to reach a set stable state. The exhaust line connecting the fly ash buffer lock hopper 5-1 with the exhaust filter 6 is a spare line and is opened only when the system needs to be depressurized. The fly ash collected by the exhaust filter 6 enters a fly ash buffer lock hopper of the fly ash blending system 5 through high-pressure nitrogen purging.

The system repeats the above steps in sequence. The density measuring device detects the density of the fly ash, the flow measuring device detects the flow of the fly ash, the online carbon residue measuring device detects the percentage of carbon residue, the result is fed back to a gasifying agent system of the gasification furnace after being analyzed and processed by the processor unit 5-2, the amount of the fly ash entering the gasification furnace is controlled, the fly ash is pressurized again by the high-pressure nitrogen system and then enters the gasification furnace, and the combustion cycle is performed again.

The effect of the invention is further explained below in a specific example:

1260t/d two-section dry pulverized coal pressurized gasification furnace, the fly ash yield is 8124kg/h, and the fly ash is returned to the first section of the fly ash burner of the gasification furnace through the system for gasification reaction.

4 pulverized coal burners are arranged on one section, and each pulverized coal burner is added with 8124kg/h of pulverized coal; adding 7344kg/h of oxygen into each pulverized coal burner; 790kg/h of steam is added into each pulverized coal burner; 1 fly ash burner is arranged, and 8124kg/h of fly ash is added into the fly ash burner.

2 pulverized coal burners are arranged at the second section, and each pulverized coal burner is added with 5938kg/h of pulverized coal; 1696.9kg/h of steam are added into each pulverized coal burner.

Arranging burners: 4 pulverized coal burners and 1 fly ash burner at one section of the gasification furnace are uniformly distributed at the other section of the gasification furnace at the same angle, and simultaneously deflect 1.5 degrees clockwise, 5 burners form a stable gasification tangent circle at one section of the gasification furnace, so that slag is favorably captured; the 2 pulverized coal burners of the second section of the gasification furnace are centrosymmetric.

The fly ash is captured by a coal gas ash remover and is blended in a fly ash blending system to a solid-gas ratio of 10kg fly ash/kgN₂And the pressure is 3.5MPa, and the fly ash is fed into a fly ash burner. Fly ash carbon residueMeasuring fly ash carbon residue by an online measuring instrument to be 40%, and calculating the oxygen injection rate of a fly ash burner to be 2938kg/h through experience; the fly ash burner sprays 325kg/h of steam.

Under the condition of not influencing the reaction and stable operation of the gasification furnace, the fly ash returns to the fly ash burner of the gasification furnace for recycling, and the synthetic gas of the gasification furnace increases 7217Nm³The slag increase 1950 kg/h. Greatly reduces the abrasion of the coal mill and the load of a conveying system

The above description is only a part of the embodiments of the present invention, and although some terms are used in the present invention, the possibility of using other terms is not excluded. These terms are used merely for convenience in describing and explaining the nature of the invention and are to be construed as any additional limitation which is not in accordance with the spirit of the invention. The foregoing is merely an illustration of the present invention for the purpose of providing an easy understanding and is not intended to limit the present invention to the particular embodiments disclosed herein, and any technical extensions or innovations made herein are protected by the present invention.