M348205 八、新型說明: 【新型所屬之技術領域】 一種燃氣具點火控制裝置,尤指一種用以防止點火失 敗的點火控制裝置。 ” 【先前技術】 瓦斯爐、烤爐等燃氣具的點火方式,可透過一點火按 鈕來觸發一點火開關,或是透過一兼具燃氣節流調整與點 火功能的點火旋鈕來觸發一點火開關。 由於燃氣具由點火到正常燃燒的過程中,可能會產生 燃氣外浅的情形例如電力不足無法點火爐口火焰被風吹 熄爐口火燄被溢流的液體給燒滅時…等情況,而為了防止 燃氣未點燃而自燃氣具爐口持續茂出,因此習知的且 點火控制裝置通常均設有安全機制,該安全機制組成包括 有: 至>、-點火開關、一於該點火開關開啟時開啟辦氣且 爐口燃氣流通的電磁閥、一於該點火開關開啟時對其所對 應爐口之點火元件提供高壓電的點火線圈組、以及一 於對應爐口,且於達到工作溫度後能對該 燃氣流通電力的熱電偶。 顿仏開啟 當點火開關被觸發而開啟時,所對應的電 壓而開啟燃氣具焯口揪夯 曰被按 的點火元件推丄 流通,並且同時促使對應爐口 仃回墼放電點火;當爐口火燄產生並對相 應的熱電偶加熱達卫作座玍艾對相對 ,冲 作咖度後,该熱電偶即可過電而提供 ^ ,讓電磁閥保持開啟以提供燃氣流通。、 惟’點火過程中,熱電偶自爐口火焰點然後,往往需 M348205 要經過—段適當的時間才能達到可過電的項溫度,換言 \右此時使用者觀察到爐口火談已經點燃,而直覺 六停止對點火開關進行持續觸發,此時會因熱電偶尚未達 到工作溫度,而使電磁閥無法維持在開啟狀態,並且將導 致點燃的爐口火談熄滅。 、’ 因此,會造成點火作業上的不便,並且經常會發生 用者需重複多次的點火動作後,才能將爐口火焰點辨的情 形,或者,使用者必須養成點火作業過程中,要透過點火 _ 按鈕或點火旋鈕對點火開關進行持續性的觸發習慣,並且 須觸發至爐口火談產生—段時間而將熱電偶加溫至可過 電的工作溫度後,才能停止對點火開關進行持 【新型内容】 、 有鑑於此,本創作的燃氣具點火控制裝置提供一觸即 發:並且仍能於爐口火談無預警熄滅時,自動中斷對爐口 燃氣供應,以有效的改善先前技術在使用時,容易發生點 火不順手S目觀察火談產生而即時停止對點 • 的習慣…等問題。 』哪啁士 • 本創作的燃氣具點火控制裝置包括:一點火開關、一 用以開啟或關閉該燃氣具爐口燃氣流通的電磁閥、一高壓 點火器、一點火控制電路及一熱電偶。其中,高壓點火器 耦接於一點火元件,係提供一高壓電給該點火元件‘,以進 行,火。點火控制電路輕接於點火開關、電磁間及高壓點 火器,點火控制電路受控於觸發後的點火開關,係提供一 主要電力給電磁閥-段維持時間,以開啟並維持燃氣具 .U燃氣的流通’同時提供主要電力給高壓點火器該段維持 M348205 二:且=行連續點火。熱電偶耦接於電磁閥,且設置在 助=給電磁閱以維持電磁闕的開啟。 k輔 1可以㈣2作的燃氣具點火控制裝置具有以下優點: 應2.^用口|預警媳滅時,自動中斷對爐口燃氣供 :作溫;,你田進仃點火操作時,即使在熱電偶尚未到達 μ又,使用者亦不需持續觸發點火開關,即可由點火 =3供電磁闕開啟燃氣流通時所需的電力,以避免 χ,’·火開關不足,而造成點火失敗的問題。 概述與接下來的詳細說明皆為示祕質,是為 仙㈣Γ 創作的申請專利範圍。而有關本創作的盆 他目的與優點,將在後續的說明與圖示加以闡述。、 【實施方式】 請參考第一圖,為本創作實施例的電路示意圖。第一 圖,’本創作係以單-爐口燃氣具作為實施例。本創作的 燃氣具點火控制裝置i包括:—點火開關sw、一用以開 啟或關閉該燃氣具爐口燃氣流通的電磁閥10、一埶”禺 12、-點火控制電路14、—高I點火器16及—點=件 18'然而’本創作同樣也可以實施在多爐口燃氣具。在 爐口燃氣具的實施例中,每一個爐口相對應配置有點 關SW、電磁閥10、點火控制電路14及熱電偶12,且二 有的點火控制電路14皆共用高璧點火器16,以進行點火。 復參考第一圖,點火開關sw可透過一點火按鈕( 不)來供使用者觸發,或者透過—兼具燃氣節流調整與i 火功能的點火旋鈕(未標示)來觸發。電磁閥10具有二線 7 M348205 圈L ’並於線圈L通電時開啟燃氣具 於線圈L斷雷拄M卩,ω γ ^ 仏、乳的流通,或 紅位认+電關閉燃氣具爐口燃氣的流通。孰雷 J接於㈣閥1G,且設置於對應的爐 二Ί 電偶12於達到工作溫度後能夠對電磁H),熱 ^。高麗點火器16純於點火元件 电給點火7L件18以進行點火作業。點火控制電t、:差 1點火開關卯、電磁閥10及高壓點火器16,係,於: 發後的點火開關sw,以提供一主要電力版、又= 一段維持時間TD,以開啟並飧拣憮气I邊 電磁闕10 以及脾m 持乳具爐口燃氣的流通, 扣供主要電力VDD給高壓點火器16 TD,以進行連續點火。 d又維持時間 復參考第一圖,點火控制電路14主要包括 一 μ -電晶體Q卜一第二電晶體收、一第三電 :一; :電=一第:電阻R1' -第二電阻^ Q1的第私奋射2弟二電阻⑸組成。其中,第一電晶體 1的第-射極用以接收主要電力_,且第_電晶體qi 的弟一基極與弟一射極之間耦接有第一電阻Ri。另外, 第二電阻R2搞接於第一電晶體則的第一基極與點火開關 SW的一端,其中點火開關sw的另一端接地g。其中第一 電晶體Q1或第三電晶體q3為—pNp電晶體;第2電晶體 Q2或第四電晶體Q4為一 NPN電晶體。同時, 為一稽納二極體。 Μ 々復參考第一圖,第二電晶體Q2的第二射極接地〇,且 ,二電晶體Q2的第二基極與第二射極之間並聯麵接穩壓 益D1、電容C1及第三電阻R3,同時,第二電晶體Q2的 M348205 第二集極接收主要電力VDD。另外,第三電晶體Q3的第 三射極用以接收主要電力VDD,且第三電晶體Q3的第三 基極耦接第二電晶體Q2的第二集極。第四電晶體Q4的第 四集極串聯耦接於電磁閥10的線圈L與主要電力VDD, 且第四電晶體Q4的第四基極耦接於第三電晶體Q3的第三 集極,同時第四電晶體Q4的第四射極接地G。 復參考第一圖,高壓點火器16包括一第五電晶體 Q5、一震盪電路162及一高壓點火電路164,其中第五電 晶體Q5的第五基極耦接於第四電晶體Q4的第四集極,且 第五電晶體Q5的第五射極用以接收主要電力VDD,同時, 第五電晶體Q5的第五集極耦接於震盪電路162。震盪電 路162為一般的高壓震盪電路,其主要構件包括一震盪變 壓器T1、一震盪開關Q6、二極體(D3、D4、D5)及震盪電 容C2。其中,第五電晶體Q5為一 PNP電晶體。 另外,高壓點火電路164耦接於震盪電路162與點火 元件18。高壓點火電路164主要包括一高壓變壓器T2, 以令對應的點火元件18能對爐口進行高壓放電點火。 復參考第一圖,當點火開關SW被觸發而開啟時,主 要電力VDD會經過導通的第一電晶體Q1對電容C快速充 電,此時,穩壓器D1用以穩定電容C上所建立的電壓。 同時,電容C上所建立的電壓透過第三電阻R3以令第二 電晶體Q2進入導通。導通的第二電晶體Q2相繼的令第三 電晶體Q3與第四電晶體Q4形成導通狀態,而導通的第四 電晶體Q4係提供電磁閥10線圈L的一端接地G,令主要 電力VDD對電磁閥10通電,以開啟對應爐口的燃氣流通。 9 M348205 在此同時,導通的第四電晶體Q4同時提供第五電晶 體Q5的第五基極接地G,以令第五電晶體Q5進入導通。 此時,主要電力VDD經由導通的第五電晶體Q5對震盪電 路162與高壓點火電路164通電,以令對應的點火元件 18能對爐口進行高壓放電點火。 復參考第一圖,當點火開關SW觸發停止時,電容C1 即進行放電’放電時間TD=R3x C1。在此放電時間TD内’ . 第二電晶體Q2、第三電晶體Q3及第四電晶體Q4保持導 | 通狀態,並且令主要電力VDD仍舊繼續對電磁閥10通電, 以維持開啟對應爐口的燃氣流通。透過電容C1的放電動 作,即可以維持主要電力VDD對電磁閥10通電一段時間, 因此,使用者在點火作業過程中,不需對點火開關SW進 行持續的觸發,爐口的燃氣供應也不會因此而中斷。 另外,在此放電時間TD内,第二電晶體Q2、第三電 晶體Q3及第四電晶體Q4保持導通狀態,並且令第五電晶 體Q5也保持導通,此時,主要電力VDD仍舊繼續對高壓 > 點火器16通電,以令對應的點火元件18能持續的對爐口 進行高壓放電點火。如此,透過電容C1的放電動作,即 * 可以維持主要電力VDD對高壓點火器16通電一段時間, 因此,使用者在點火作業過程中,不需對點火開關SW進 行持續的觸發,點火動作也不會因此而中斷。 在電容C1放電動作結束前,熱電偶12已經由爐口所 產生的火燄增溫至適當的工作溫度,此時電磁閥10的線 圈L即從熱電偶12取得輔助電力Vs,以令爐口燃氣保持 在流通的狀態。因此,當電容C1放電完成時,電磁閥10 10 M348205 „的磁吸力已經改由輔助電力Vs提供,故可 使爐口燃氣仍然保持在流通狀態。 到達m用者在進行點火作業時,即時在熱電偶尚未 ,度’使用者亦不需持續觸發點火開關SW,即 所需的電力,以避免因觸發= 成點火失敗的問題火開關㈣間不足,而造 &配ί二一;’請參考第二圖。第二圖為本創作的操作 ::=思圖。在本創作的燃氣具點火控制裝置1操作中, 觸發而啟動後,主要電力、隨 二二望:電容Π上所建立的電壓用以保持第 二曰曰體广、弟三電晶則3、第四電晶體Q4及第五電晶 :、5,通一段時間,進而令主要電力_對電磁閥i。保 持通电,以開啟燃氣具爐口燃氣的流通 火 器16保持通電,以進行自動點火(Si〇2)。H點火 被二^⑷透二電二心偵測’用以判斷火焰是否 :皮點燃(S104) ’如果火焰尚未被點燃,則在一 :内,持續的開啟燃氣具爐口燃氣的流通盘 丄 (S102),若是在放電時間TD結束時(si〇 ^ 未被點燃,則停止點火動作與燃氣具爐口燃氣的 (S1 〇7 }。相反的,如果火焰點煥 /瓜 (S106)。在步驟Sl06後,判斷是入丁自動點火動作 如果進入關機,則停止電二:否的 =機狀態(晴, 爐口燃氣的流通(S109 )。 以關閉燃氣具 綜上所述,本創作不需以人力方式對點火開關進行持 11 M348205 續性的觸發,使點火作業可以一 時的便利性。另外,在安全考^即發,大幅提升了操作 無法點火、火料預_ 賴作於電力不足 口溢出的效果。 滅時’仍具防止燃氣自爐 惟,以上所述,僅為本創作是 詳细今昍彻闽斗、,^ 卞取佳之一的具體實施例之 内,可鉍旦田β 。°Λ項技藝者在本創作之領域 了I易心及之變化或修飾皆 範圍。 / φ白了涵盍在以下本案之專利M348205 VIII. New description: [New technical field] A gas appliance ignition control device, especially an ignition control device for preventing ignition failure. [Prior Art] The ignition mode of gas stoves, ovens and other gas appliances can trigger an ignition switch through an ignition button or trigger an ignition switch through an ignition knob that also has a gas throttle adjustment and ignition function. Since the gas appliance is in the process of ignition to normal combustion, there may be a situation in which the gas is shallow, such as insufficient power, and the flame of the furnace mouth is extinguished by the air blown out by the wind. In order to prevent the gas from being ignited and continuing from the mouth of the gas appliance, the conventional ignition control device is usually provided with a safety mechanism, and the safety mechanism comprises: to>, an ignition switch, and the like. a solenoid valve that opens the gas when the ignition switch is turned on and the gas flows through the furnace mouth, an ignition coil group that supplies a high voltage to the ignition element of the corresponding furnace mouth when the ignition switch is turned on, and one corresponding to the furnace mouth, and A thermocouple capable of circulating electric power to the gas after reaching the operating temperature. When the ignition switch is triggered to be turned on, the corresponding voltage is turned on to open the gas appliance.曰The ignited element is pushed and circulated, and at the same time, the corresponding furnace mouth is turned back to the 墼 discharge and ignited; when the furnace mouth flame is generated and the corresponding thermocouple is heated to the opposite side of the 玍 对, The thermocouple can be supplied with electricity and the solenoid valve can be kept open to provide gas circulation. However, during the ignition process, the thermocouple is fired from the furnace mouth and then M348205 is required to pass the appropriate period of time. The temperature of the overheated item, in other words, the right user observes that the furnace mouth fire has been ignited, and the intuition six stops continuously triggering the ignition switch. At this time, the solenoid valve cannot be maintained because the thermocouple has not reached the working temperature. It is turned on, and will cause the ignited fire to be extinguished. ', Therefore, it will cause inconvenience in the ignition operation, and it often happens that the user needs to repeat the ignition action before the burner flame can be identified. Alternatively, the user must develop a continuous triggering action on the ignition switch through the ignition _ button or the ignition knob during the ignition operation. When the fire is sent to the mouth of the furnace, the thermocouple is warmed to the overheatable working temperature for a while, and then the ignition switch can be stopped. [New content] In view of this, the gas appliance ignition control device of the present invention provides At the touch of a hair: and still can talk about the gas supply to the furnace mouth when the furnace mouth is fired without warning, to effectively improve the prior art. When it is used, it is easy to cause the ignition to be unsatisfactory. The habit of...etc.. "Where is the gentleman? The gas appliance ignition control device of this creation includes: an ignition switch, a solenoid valve for opening or closing the gas flow of the gas burner, a high pressure igniter, An ignition control circuit and a thermocouple, wherein the high voltage igniter is coupled to an ignition element to provide a high voltage power to the ignition element to perform a fire. The ignition control circuit is lightly connected to the ignition switch, the electromagnetic chamber, and The high-voltage igniter, the ignition control circuit is controlled by the ignition switch after the trigger, and provides a main power to the solenoid valve-segment maintenance time to open and maintain the gas appliance. The circulation of gas 'at the same time provides the main power to the high-voltage igniter section to maintain M348205 2: and = continuous ignition. The thermocouple is coupled to the solenoid valve and is set to assist the electromagnetic reading to maintain the electromagnetic opening. K auxiliary 1 can be used in the gas appliance ignition control device of (4) 2 to have the following advantages: 2. When the port is used for warning, the gas supply to the furnace mouth is automatically interrupted: when the field is in operation, Even if the thermocouple has not yet reached the μ, the user does not need to continuously trigger the ignition switch, and the electric power required for the gas circulation can be turned on by the ignition = 3 to avoid the smashing, and the ignition switch is insufficient. The problem of failure. Both the overview and the detailed descriptions below are for the sake of the secret, and are the scope of the patent application for the creation of Xian (4). The purpose and advantages of this creation will be explained in the following description and illustration. [Embodiment] Please refer to the first figure, which is a schematic circuit diagram of the present embodiment. First, 'this creation is based on a single-furnace gas appliance as an example. The gas appliance ignition control device i of the present invention comprises: an ignition switch sw, a solenoid valve 10 for opening or closing the gas flow of the gas appliance mouth, a 埶"禺12, an ignition control circuit 14," High I igniter 16 and - point = 18' however, the creation can also be implemented in a multi-furnace gas appliance. In the embodiment of the furnace gas appliance, each furnace port is correspondingly configured to be somewhat closed, The solenoid valve 10, the ignition control circuit 14 and the thermocouple 12, and the two ignition control circuits 14 all share the high igniter 16 for ignition. Referring to the first figure, the ignition switch sw can pass an ignition button (not) It can be triggered by the user, or triggered by an ignition knob (not shown) that has both gas throttle adjustment and i-fire function. Solenoid valve 10 has two lines 7 M348205 circle L ' and turns on the gas appliance when coil L is energized. In the coil L, the smashing 拄M卩, ω γ ^ 仏, the circulation of the milk, or the red position recognition + electricity shuts off the circulation of the gas at the mouth of the gas appliance. The 孰雷J is connected to the (4) valve 1G and is disposed in the corresponding furnace. The second Ί 12 can reach the working temperature and can be electromagnetic H), hot ^. The device 16 is purely ignited by the ignition element to ignite the 7L piece 18 for ignition operation. The ignition control circuit t, the difference 1 ignition switch 卯, the solenoid valve 10 and the high voltage igniter 16 are, after: the ignition switch sw after the issue, Provide a main power version, and = a period of maintenance time TD, to open and pick up the circulation of the xenon electromagnetic side 10 and the spleen m holding the mouth gas, and deduct the main power VDD to the high voltage igniter 16 TD, For continuous ignition. d again to maintain the time reference to the first figure, the ignition control circuit 14 mainly includes a μ - transistor Q a second transistor, a third: one; : electricity = a: resistance R1 ' - The second resistor ^ Q1 is composed of a second resistor (5), wherein the first emitter of the first transistor 1 is used to receive the main power _, and the base of the first transistor qi is A first resistor Ri is coupled between the emitter and the emitter. In addition, the second resistor R2 is coupled to the first base of the first transistor and one end of the ignition switch SW, wherein the other end of the ignition switch sw is grounded to g. Wherein the first transistor Q1 or the third transistor q3 is a -pNp transistor; the second transistor Q2 or the fourth transistor The body Q4 is an NPN transistor. At the same time, it is a nano electrode. Μ 々 参考 reference to the first figure, the second emitter of the second transistor Q2 is grounded, and the second base of the second transistor Q2 The parallel connection between the second emitter and the second emitter is connected to the voltage regulator D1, the capacitor C1 and the third resistor R3, and the second collector of the M348205 of the second transistor Q2 receives the main power VDD. In addition, the third transistor Q3 is The third emitter is coupled to the second collector of the second transistor Q2, and the fourth collector of the fourth transistor Q4 is coupled in series to the solenoid valve. The coil L of 10 is connected to the main power VDD, and the fourth base of the fourth transistor Q4 is coupled to the third collector of the third transistor Q3 while the fourth emitter of the fourth transistor Q4 is grounded to G. Referring to the first figure, the high voltage igniter 16 includes a fifth transistor Q5, an oscillating circuit 162 and a high voltage ignition circuit 164. The fifth base of the fifth transistor Q5 is coupled to the fourth transistor Q4. The fourth collector of the fifth transistor Q5 is configured to receive the main power VDD, and the fifth collector of the fifth transistor Q5 is coupled to the oscillating circuit 162. The oscillating circuit 162 is a general high-voltage oscillating circuit, and its main components include an oscillating transformer T1, an oscillating switch Q6, a diode (D3, D4, D5) and an oscillating capacitor C2. The fifth transistor Q5 is a PNP transistor. In addition, the high voltage ignition circuit 164 is coupled to the oscillating circuit 162 and the igniter element 18. The high voltage ignition circuit 164 mainly includes a high voltage transformer T2 to enable the corresponding ignition element 18 to perform high voltage discharge ignition of the furnace port. Referring to the first figure, when the ignition switch SW is triggered to be turned on, the main power VDD will quickly charge the capacitor C through the turned-on first transistor Q1. At this time, the regulator D1 is used to stabilize the capacitor C. Voltage. At the same time, the voltage established on the capacitor C is transmitted through the third resistor R3 to bring the second transistor Q2 into conduction. The turned-on second transistor Q2 successively causes the third transistor Q3 and the fourth transistor Q4 to be in an on state, and the turned-on fourth transistor Q4 provides a grounding G of the coil L of the solenoid valve 10, so that the main power VDD pair The solenoid valve 10 is energized to open the gas flow corresponding to the furnace port. 9 M348205 At the same time, the turned-on fourth transistor Q4 simultaneously supplies the fifth base ground G of the fifth transistor Q5 to turn on the fifth transistor Q5. At this time, the main power VDD energizes the oscillating circuit 162 and the high voltage ignition circuit 164 via the turned-on fifth transistor Q5 to enable the corresponding igniter element 18 to perform high voltage discharge ignition of the furnace port. Referring back to the first figure, when the ignition switch SW is triggered to stop, the capacitor C1 performs discharge 'discharge time TD=R3x C1. During this discharge time TD'. The second transistor Q2, the third transistor Q3, and the fourth transistor Q4 remain in the on state, and the main power VDD continues to energize the solenoid valve 10 to maintain the corresponding furnace opening. Gas circulation. Through the discharge operation of the capacitor C1, the main power VDD can be maintained to energize the solenoid valve 10 for a period of time. Therefore, the user does not need to continuously trigger the ignition switch SW during the ignition operation, and the gas supply to the furnace port is not It will be interrupted as a result. In addition, during the discharge time TD, the second transistor Q2, the third transistor Q3, and the fourth transistor Q4 remain in an on state, and the fifth transistor Q5 is also kept turned on. At this time, the main power VDD continues to be continued. High Pressure > The igniter 16 is energized to allow the corresponding ignition element 18 to continuously ignite the furnace port. In this way, the discharge operation of the capacitor C1, that is, * can maintain the main power VDD to energize the high-voltage igniter 16 for a period of time, so that the user does not need to continuously trigger the ignition switch SW during the ignition operation, and the ignition operation is not performed. It will be interrupted as a result. Before the end of the discharge operation of the capacitor C1, the thermocouple 12 has been warmed by the flame generated by the furnace mouth to an appropriate working temperature. At this time, the coil L of the solenoid valve 10 obtains the auxiliary electric power Vs from the thermocouple 12 to ignite the furnace mouth. The gas remains in a state of circulation. Therefore, when the discharge of the capacitor C1 is completed, the magnetic attraction force of the solenoid valve 10 10 M348205 has been changed by the auxiliary power Vs, so that the furnace gas is still kept in circulation. When the user reaches the m, the ignition operation is performed immediately. In the case of thermocouples, the user does not need to continuously trigger the ignition switch SW, that is, the required power, to avoid the problem of triggering = failure of the ignition switch between the fire switch (4), and creating & Please refer to the second picture. The second picture is the operation of the creation::=Thinking. In the operation of the gas appliance ignition control device 1 of this creation, after the trigger and start, the main power, with the second and second look: the capacitor The established voltage is used to maintain the second body, the third transistor, the third transistor Q4, and the fifth transistor: 5, for a period of time, and then the main power _ to the solenoid valve i. The flow firer 16 that turns on the gas of the gas burner is kept energized for automatic ignition (Si〇2). The H ignition is detected by two (4) through two electric two-hearts to determine whether the flame is: skin ignition ( S104) 'If the flame has not been ignited, then within one: , continuously open the circulation plate of the gas with gas at the mouth of the gas (S102), if at the end of the discharge time TD (si〇^ is not ignited, stop the ignition action and the gas of the gas burner (S1 〇 7 }. Conversely, if the flame points to glow / melon (S106). After step S106, it is judged that the automatic ignition action is to enter the shutdown, then stop the electricity two: No = machine state (clear, furnace gas Circulation (S109). In order to shut down the gas appliance, the creation does not need to manually trigger the ignition switch with 11 M348205, so that the ignition operation can be convenient for a while. The hair has greatly improved the effect that the operation cannot be ignited, and the fire material is pre-empted by the overflow of the power. When it is extinguished, it still has the function of preventing gas from being fired. However, as described above, this is only a detailed description of the present. In the specific example of one of the buckets, and the best one, you can use the β 田 。 。 。 。 。 。 。 。 技 技 技 技 技 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易 易The following patents in this case
【圖式簡單說明】 第一圖為本創作實施例的電路示意圖。 第二圖為本創作操作流程示意圖。 【主要元件符號說明】BRIEF DESCRIPTION OF THE DRAWINGS The first figure is a circuit diagram of an embodiment of the present invention. The second picture is a schematic diagram of the creative operation process. [Main component symbol description]
燃氟具點火控制裝置1 點火開關sw 電磁閥10 熱電偶12 點火控制電路14 高壓點火器16 點火元件18 線圈L 輔助電力Vs 主要電力VDD 震盪電路162 高壓點火電路164 12Fluorine ignition control device 1 ignition switch sw solenoid valve 10 thermocouple 12 ignition control circuit 14 high voltage igniter 16 ignition element 18 coil L auxiliary power Vs main power VDD oscillating circuit 162 high voltage ignition circuit 164 12