1. Field of the Invention
The present invention is related to a gas recovering system, and more particularly, to a gas recovering system to recover exhaust gas generated by thermally decomposing Dihydrogen Selenide.
2. Description of the Prior Art
Copper Indium Gallium Selenide (CIGS) thin film optoelectronic device is high efficiency solar cell. The solar substrate made by CIGS is required to go through selenization process except evaporation process. The current selenization process implements Dihydrogen Selenide (H2Se) to be reactant gas in business.
For example, when a CIGS solar cell is required to do selenization process, the multi-layer precursor or an alloy with copper, gallium and indium is formed on the glass substrate by sputtering technique and transmits to selenization furnace (a thermal furnace). The Dihydrogen Selenide (H2Se) gas is entered to the selenization furnace. When the temperature of the selenization furnace is over 400° C., Dihydrogen Selenide (H2Se) gas is reacted with the multi-layer precursor film. However, during the selenization process of the CIGS solar cell, the solar cell structure with multi-layer film stacking is required to be heated, and the solar cell can be well reacted with Dihydrogen Selenide (H2Se) gas so as to obtain good CIGS thin film layer. Because of the selenization within the selenization furnace, it is required to maintain an enough concentration of the Dihydrogen Selenide completely reacted with multi-layer precursor thin film. The extra and non-reacted gas is treated by the eliminating system and is not reused.
The selenium used in the common selenization process is obtained by solid state selenium or gaseous state selenium, but most thereof is gaseous state selenium. The gaseous state selenium includes corrosiveness and toxicity, and the gaseous state selenium is generated by reacting furnace pyrolysis for selenization. In order to provide enough concentration of selenium atoms, the addition consumption and the cost of the waste treatment is increased.
In order to solve the problems described above, one object of the present invention is to provide a gas recovering system to recover the heat cracked Dihydrogen Selenide by a high efficiency gas recovering method.
According objects above, a gas recovering system in the present invention includes at least one gas supply source, a gas reduction device and a gas separation system. The at least one gas supply source includes a supply source configured to provide at least one gas, and a gas supply unit connected to the supply source. The at least one gas treatment system is connected to the gas supply system and includes a gas reactor connected to the gas supply unit and a gas reduction device connected to the gas reactor. The gas separation system is connected to the gas treatment system and includes a first exhaust unit connected to the gas reduction device; a purifying unit connected to the first exhaust unit; a second exhaust unit connected to the connected to the purifying unit; and a heating evaporation unit connected to the purifying unit and the gas supply system.
Another object of the present invention is to provide a gas recovering device to recover the exhaust gas to reduce the cost so as to increase the usage efficiency.
According objects above, a gas recovering device in the present invention includes a gas reduction unit and a gas guiding tube. A first gas is flowed within the gas guiding tube and the gas reduction unit is connected to the gas guiding tube. The gas reduction unit includes a conduit, a reduction gas source and a microwave irradiating device. The conduit is connected to the gas guiding tube. The reduction gas source is connected to the conduit and is configured to provide a second gas flowed to the gas guiding tube. The microwave irradiating device is configured to irradiate a microwave and the microwave is irradiated to the second gas of the conduit.
According objects above, a gas recovering system in the present invention comprising: at least one gas supply system, at least one gas treatment system connected to the gas supply system and a gas separation system connected to the gas treatment system. The gas supply system including: a supply source configured to provide at least one gas; and a gas supply unit connected to the supply source. The gas treatment system including: a gas reactor connected to the gas supply unit; and a gas reduction device connected to the gas reactor, and the gas reduction device including a gas reduction unit and a gas guiding tube, and the gas reduction unit is connected to the gas guiding tube. The gas separation including: a first exhaust unit connected to the gas reduction device; a purifying unit connected to the first exhaust unit; a second exhaust unit connected to the purifying unit; and a heating evaporation unit connected to the purifying unit and the gas supply system.
The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same becomes better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:
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The supply source 21 configured to store Dihydrogen Selenide is connected to the gas supply unit 23. When the vapor within the steel cylinder of the supply source 21 reaches a balance and a high pressure status is in the steel cylinder, the Dihydrogen Selenide in the cylinder is liquid and the valve is opened to provide continuous vapor heat source. The liquid state Dihydrogen Selenide will continually evaporate to be gaseous state Dihydrogen Selenide. The supply source 21 is connected to the gas supply unit 23 by a transportation pipe. The gas supply unit 23 can adjust the gas transmitted from the supply source 21 and is configured to work with the mass flow controller 25 to control the flow of the gas. The mass flow controller 25 includes an automatic gas flow control function and will not be affected by the change of the system temperature and the pressure to maintain a certain flow rate. So the mass flow controller 25 is a flow control device and is connected to the gas treatment system 3.
The gas treatment system 3 includes a gas reactor 31 and a gas reduction device 35. Before the Dihydrogen Selenide gas is transmitted to the gas reactor 31, the Dihydrogen Selenide gas is mixed with gas, such as Nitrogen or Argon gas, to enter the gas reactor 31. The proper concentration of the mix gas can maintain the even property of the quality and distribution of the Dihydrogen Selenide in the gas reactor 31.
When the CIGS layer within the solar cell is required to do a Selenization process, a multi-layer precursor monomer or an alloy with copper, gallium and indium stacked as a cell structure is formed on a Soda Lime Glass substrate and transmitted to the gas reactor 31 and the Dihydrogen Selenide gas is transmitted to the gas reactor 31. Now, the temperature of the gas reactor 31 is above 400□, the multi-layer precursor with copper, gallium and indium will be reacted well with the Dihydrogen Selenide gas so as to obtain a good CIGS thin film layer. The following equation is a heat cracking equation of the Selenization:
H2Se→HSe−+H+
H2Se→H++Se2−
When the Dihydrogen Selenide is completely heat cracked, Se2− and 2H+ are generated. Se2− will compose with the multi-layer precursor monomer or the alloy with copper, gallium and indium and 2H+ will be vented as exhaust gas. In addition, if the Hdrogen Selenide is not completely heat cracked, it would generate HSe− and H+ and both of them will be vented as exhaust gas.
The Dihydrogen Selenide gas is heat cracked to form HSe− gas and is transmitted to the first storage vessels 33 by the transportation pipe. The temperature of the transportation pipe is maintained in 160□ to provide the ionized Dihydrogen Selenide gas. Because it is required a predetermined time to connect the first storage vessel 33 with the gas reduction device 35, it is necessary to have the first storage vessel to delay the gas process. Now, the gas reduction device 35 will provide enough H+ to compose the waste gas HSe− from the first storage vessel to form H2Se so as to recover. The detail description of the steps will be described in
Now, the H2Se gas processed by the gas reduction device 35 will transmit to the gas separation system 5. The gas separation system 5 includes a first exhaust unit 51 and a purifying unit 55, a second gas venting unit 52 and a heat evaporating unit 57. The H2Se gas is transmitted to the first exhaust unit 51 first. The first exhaust unit 51 includes a compressor for gas absorbing and depressing and transmits the H2Se gas to the purifying unit 55 to purify the concentration of the Dihydrogen Selenide gas. The waste gas, which is not qualified to vent, is processed by the eliminating device 53 and the detail description thereof is described at the following.
The Dihydrogen Selenide gas is transmitted from the first exhaust unit 51 to the purifying unit 55. The purifying unit 55 includes a cooling device (not shown) and the temperature thereof is set at range of −40□˜−80□. When the Dihydrogen Selenide gas is passing the cooling device, the gaseous state Dihydrogen Selenide is liquefied to be liquid because the melting point of Dihydrogen Selenide is −65.73□. The liquid state Dihydrogen Seledine is separated from other gas, which is not liquefied. Now, the liquid state Dihydrogen Selenide is transmitted to the second storage vessel 58 and the rest gas is processed by the second exhaust unit 52. Because the heating vapor unit 57 processing the liquid state Dihydrogen Selenide to be the gaseous state Dihydrogen Selenide is required a certain time, the second storage vessel 58 is necessary to delay the process. The heating vapor unit 57 includes a heater (not shown) and the heater can provide a stable heat source to heat the liquid state Dihydrogen Selenide. The temperature of the heating vapor unit 57 is set to over −41.25□, the liquid state Dihydrogen Selenide is gasified to be the gaseous state Dihydrogen Selenide. The heater can provide enough heat for evaporating the liquid state Dihydrogen Selenide. Now, the gaseous state Dihydrogen Selenide is transmitted to the gas supply unit 23 to provide recovering. The recovering rate of the Dihydrogen Selenide is above 50%, and the recovering efficiency is pretty good.
In addition, the Seledium used in the present system is poisonous, it is required to process properly to put at outside. Therefore, it is necessary to develop a toxic waste handling device. The first exhaust unit 51 and the second gas venting unit 52 in the previous description are connected to a hazardous waste eliminating device 53. The hazardous waste eliminating device 53 includes some materials, such as copper hydroxide (Cu(OH)2) or Calcium hydroxide (Ca(OH)2) to absorb the Selenium elements so as to react with the Selenium to be Copper Selenide CuSe or Calcium Selenide CaSe, and the rest unhazardous waste gas can be safely released.
In addition, when the gas recovering system 1 is required to do a system maintain or temporally stop to provide the recovering Dihydrogen Selenide to stop the whole system reaction, The liquid state Dihydrogen Selenide stored in the second storage vessel 58 will be heated by the heat evaporate unit 57 to be the gaseous state Dihydrogen Selenide. The purifying unit 55 will stop the operation of the cooling device and the liquid state Dihydrogen Selenide is transmitted to the hazardous waste handling device 53 from the second exhaust unit 52 to process the non-recovering Dihydrogen Selenide gas.
The transportation pipe in each system unit of the present invention is stainless steel material covered with heat insulation cover. The thermal conductivity property of the heat insulation cover is low to reduce the heat transmitted from the transportation pipe to outside, but the material of the transportation pipe is not limited herein. Now please refer to
The gas conduit in the present description is the transportation pipe in the previous description. The transmitting gas is Oxygen or Argon gas and hazardous waste gas with HSe−. The flowing direction of the hazardous waste gas is from A end to B end, as shown in
In addition, the external wall of the transmitting pipe 3571 includes a plurality of first magnetic field coil 3515 and the magnetic field generated thereof will let cyclotron frequency and microwave frequency with coherence to generate harmony so as to generate high energy electrons to hit the gas within the conduit 3511. The previous Dihydrogen Selenide is heat cracked in the gas reactor 31 to form HSe− gas. When the gas is transmitted from the gas conduit 353 (transportation pipe) to the gas recovering device 35, the recovering gas source 600 will inject the Dihydrogen to the conduit 3511. The microwave transmitting device 357 will transmit microwave, and the transmitting pipe 3571 will ionize the Dihydrogen within the conduit 3511 to form H+. The magnetic coil in the external wall of the transmitting pipe 3571 will guild H+ to move to the bottom of the gas conduit 353 and should avoid hitting the pipe wall during the moving process. The pressure of the ionized H in the conduit 3511 is larger than the gas conduit 353, so H will from high pressure to low pressure transmit in the conduit 3511. The HSe− flowing in the gas conduit 353 will react with H to form (H2Se) and the (H2Se) can use the gas recovering system. The equation to form (H2Se) is:
HSe−+H+→H2Se
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Number | Date | Country | Kind |
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101126402 | Jul 2012 | TW | national |