TWM568301U - Gas-water separator structure of water pump - Google Patents
Gas-water separator structure of water pump Download PDFInfo
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Abstract
本創作係有關於一種抽水機之氣水分離器構造,其主要設有一外殼體,所述外殼體上方覆合一上蓋,下方具有通道連結水泵腔體,並於所述外殼體內部設有一浮筒,而所述上蓋上設有一氣密調整組及一真空破除器,所述氣密調整組一端連結真空泵,另一端連結一槓桿組,而所述槓桿組對應連結帶動所述浮筒;藉此,當於真空泵啟動後氣水分離器中的氣體,由外殼體通道流經外殼體與浮筒之間的間隙,並往氣密調整組端抽出,使其達到極限真空的狀態,且於此狀態下運轉,不會產生反覆抽取大氣而使浮筒碰撞的缺失,可大幅提升浮筒壽命,並可避免潤滑油受水氣液化與油品氣化作用。The present invention relates to a gas-water separator structure of a water pump, which is mainly provided with an outer casing body, an outer cover is covered on the outer casing body, a passage connecting water pump cavity is arranged below, and a buoy is arranged inside the outer casing body. The upper cover is provided with an airtight adjustment group and a vacuum breaker, the airtight adjustment group is connected to the vacuum pump at one end, and the lever group is coupled to the other end, and the lever group is coupled to drive the buoy; After the vacuum pump is started, the gas in the gas-water separator flows through the gap between the outer casing and the pontoon through the outer casing passage, and is taken out to the airtight adjustment group end to reach the ultimate vacuum state, and is operated in this state. There is no possibility of repeatedly extracting the atmosphere and causing the collision of the pontoon, which can greatly improve the life of the pontoon and prevent the lubricating oil from being liquefied by water and gas and gasified by oil.
Description
本創作係有關於一種抽水機之氣水分離器構造,尤指一種可達極限真空功效的氣水分離器構造為其創作應用者。This creation is about a gas-water separator construction of a water pump, especially a gas-water separator constructed to achieve ultimate vacuum efficiency.
按,一般的抽水機用於緊急排洪、抽取地下污水或大樓地下室緊急抽水等,抽水機具有高機動性且無需外接電源,故常用於急難救助;然而,當發生地區性的積水,或於挖掘隧道、埋管等工程時,也會以抽水機將積水由工程現場等積水處抽出,藉此使積水消退而讓工程能夠繼續順利進行,或者使低窪地區的積水能夠順利消退。According to the general pumping machine for emergency flood discharge, underground sewage extraction or emergency pumping in the basement of the building, the pump is highly maneuverable and does not require external power supply, so it is often used for emergency rescue; however, when regional water accumulation occurs, or tunnels are excavated In the case of buried pipes, etc., the water will be pumped out from the accumulated water at the project site, so that the water can be recirculated and the project can continue smoothly, or the water in the low-lying areas can be smoothly eliminated.
然而,「使泵浦殼內注入足夠的水量」為泵浦正常運轉的首要條件,但因郊區或緊急排洪等環境因素,讓泵浦操作者無法每次都能先完成注入足夠水的步驟,故透過真空輔助系統達成注給需求的功能,便油然而生。當水位低於陸地導致難以取水,便是真空引水的好時機;當使用真空泵浦作為真空引水裝置時, 若無法適當斷開真空泵與抽水機之腔體連接通路,會因為真空泵持續使真空度上升,因而讓水可越過抽水機腔體高度而進入真空泵,進而導致真空泵腔體的損壞。為避免此情況的發生,須於真空泵入口處前設置輔助裝置-氣水分離器,藉由氣水分離器能自主斷開真空泵與抽水機之空氣迴路,避免抽水機腔體內之真空度持續上升,而使水進入真空泵。However, “injecting enough water into the pump casing” is the primary condition for normal pump operation, but due to environmental factors such as suburban or emergency flooding, the pump operator cannot complete the steps of injecting sufficient water every time. Therefore, the function of injecting demand into the vacuum assisted system is born. When the water level is lower than the land, it is difficult to take water, which is a good time for vacuum water diversion; when vacuum pumping is used as the vacuum water diversion device, if the vacuum pump and the pump body connection path cannot be properly disconnected, the vacuum pump will continue to increase the vacuum degree. Thus, the water can enter the vacuum pump across the height of the pumping chamber, thereby causing damage to the vacuum pump chamber. In order to avoid this, an auxiliary device-gas water separator must be installed in front of the inlet of the vacuum pump. The gas water separator can automatically disconnect the air circuit of the vacuum pump and the pump to avoid the vacuum in the pump chamber continuously rising. Bring water into the vacuum pump.
其抽水機的氣水分離結構大致上如公告第M299231號一種抽水機之氣水分離機,其係設有:一氣水分離機本體,於該氣水分離機本體內的底側設有一第一氣室,於第一氣室的底部向下穿設有一抽氣孔,該抽氣孔於該氣水分離機本體的底面形成一抽氣接口,於第一氣室的上方設有一第二氣室,第二氣室與第一氣室之間設有一底孔,第二氣室的頂部對應該抽氣孔而於該氣水分離機的頂面穿設有一頂孔,於第一氣室的一側設有一第三氣室,第三氣室的頂部分別與第二氣室以及第一氣室的頂部之間穿設有一第一流道以及一第二流道,並且第三氣室的頂部向外穿設有一抽氣流道,該抽氣流道於該氣水分離機本體的表面形成一真空泵接口;一浮筒,該浮筒係柱狀浮塊並容設於第一氣室內;一連動啓閉閥裝置,其包括一單向閥及一連動啓閉件,其中單向閥係設於該底孔處,該連動啓閉件垂直穿設於該單向閥且底端對應該浮筒而朝第一氣室內延伸,該連動啓閉件的頂端用於將頂孔開關而設於該頂孔處;一單向閥裝置,該單向閥裝置係固設於第三氣室與第一氣室之間的第二流道處。The gas-water separation structure of the water pump is substantially the same as the gas-water separator of the water pump of the publication No. M299231, which is provided with a gas-water separator body, and a first gas chamber is arranged on the bottom side of the gas-water separator body. a suction hole is formed in the bottom of the first air chamber, and a suction port is formed on the bottom surface of the gas water separator body, and a second air chamber is disposed above the first air chamber. A bottom hole is defined between the air chamber and the first air chamber, and a top hole of the second air chamber corresponds to the air suction hole, and a top hole is formed on the top surface of the gas water separator, and one side is disposed on one side of the first air chamber a third air chamber, a first flow passage and a second flow passage are respectively disposed between the top of the third air chamber and the top of the second air chamber and the first air chamber, and the top of the third air chamber is outwardly disposed. a pumping air passage, the pumping air passage forming a vacuum pump interface on the surface of the gas water separator body; a buoy tube, the column type floating block is accommodated in the first gas chamber; and a linkage opening and closing valve device The utility model comprises a one-way valve and a linkage opening and closing member, wherein the one-way valve is arranged at the bottom a hole opening portion, the interlocking opening and closing member is vertically disposed on the one-way valve and the bottom end is corresponding to the float tube and extends toward the first air chamber, and the top end of the interlocking opening and closing member is configured to set the top hole switch at the top hole A one-way valve device is fixed at a second flow path between the third air chamber and the first air chamber.
上述真空泵浦在抽氣時,其空氣在氣水分離機的流動路徑可分成四個流程:1.空氣由氣水分離器底部抽氣孔進入第一氣室。2.進入後的空氣會繞過浮筒,往連動啓閉閥裝置的連動啓閉件孔位處穿過,進入氣水分離器的上筒部之第二氣室。3.進入第二氣室後,繼續流往側邊的第三氣室。由於第三氣室可分成左/中/右三處,其中中間受到單向閥裝置密封,僅左右兩處相通,故空氣會往第三氣室左邊[第二流道]流到右邊[抽氣流道]。4.流到第三氣室右邊[抽氣流道]後,最後往真空泵接口邁進,便可流出氣水分離器。當真空泵浦之真空度足夠時,水泵腔體浦腔內的液體便會進入氣水分離器內,因而將浮筒推高。浮筒上升一方面帶動連動啓閉閥裝置的下閥塞密封阻隔液體進入第二氣室,達成避免水進入真空泵浦內的目的外,一方面同時讓連動啓閉閥裝置的連動啓閉件也一併推開上方的第一球塞。When the above vacuum pump is pumping, the flow path of the air in the gas water separator can be divided into four processes: 1. The air enters the first air chamber from the bottom air suction hole of the gas water separator. 2. The air after entering will bypass the pontoon and pass through the hole of the interlocking opening and closing device of the interlocking opening and closing valve device to enter the second air chamber of the upper cylinder portion of the gas water separator. 3. After entering the second air chamber, continue to the third air chamber on the side. Since the third air chamber can be divided into three parts of left/medium/right, wherein the middle is sealed by the one-way valve device, only the left and right sides are connected, so the air flows to the left side of the third air chamber [second flow path] to the right side. Airflow channel]. 4. After flowing to the right of the third chamber [extraction channel], and finally moving toward the vacuum pump port, the gas-water separator can be discharged. When the vacuum of the vacuum pump is sufficient, the liquid in the pump chamber will enter the gas water separator, thus pushing the float high. On the one hand, the rising of the float cylinder drives the lower valve plug of the interlocking opening and closing valve device to block the liquid from entering the second air chamber, thereby achieving the purpose of avoiding the entry of water into the vacuum pump, and simultaneously, the interlocking opening and closing member of the interlocking opening and closing valve device is also And push the first ball plug above.
當上方第一球塞被連動啓閉閥裝置的連動啓閉件推開後,因環境空氣進入第二氣室,使第二氣室壓力回升。由於第二氣室與第三氣室左邊[第二流道]連通,故第三氣室之壓力也連帶回升。此時,因第三氣室中間受到單向閥裝置的阻隔仍保持真空。當第三氣室下方之回升壓力足夠大時,便可使單向閥裝置透過氣壓差作用而上升,讓空氣可對浮筒所在的空間充壓,而使氣壓將推升浮筒的水退回水泵腔體浦腔體內,進而讓浮筒回到原始位置。因此,只要真空泵浦持續運轉,此過程便會循環動作。由於運作過程受到連動啓閉閥裝置持續破除真空狀態,會使得真空泵浦除了無法滿足維持低功耗與低潤滑油溫外,還會使真空泵浦受反覆吸取大氣的影響,此影響具有下列缺陷:When the upper first ball plug is pushed open by the interlocking opening and closing member of the interlocking opening and closing valve device, the second air chamber pressure is raised due to the ambient air entering the second air chamber. Since the second air chamber is in communication with the left side [second flow path] of the third air chamber, the pressure of the third air chamber is also brought back. At this time, the vacuum is maintained because the third chamber is blocked by the check valve device. When the rebound pressure below the third air chamber is sufficiently large, the check valve device can be raised by the air pressure difference, so that the air can pressurize the space in which the float is located, and the air pressure will push the water of the lift tank back to the pump chamber. Inside the body cavity, the float is returned to its original position. Therefore, as long as the vacuum pump continues to operate, the process will cycle. Since the operation process is continuously interrupted by the interlocking valve device, the vacuum pump will not only satisfy the low power consumption and low lubricating oil temperature, but also cause the vacuum pump to be absorbed by the atmosphere. This effect has the following defects:
(1)浮筒壽命短-因連動啓閉閥裝置於循環過程須反覆與浮筒碰撞,使得接觸位置常常需要承受衝擊,而較易出現疲勞破壞的問題。(1) The life of the pontoon is short - because the interlocking opening and closing valve device must repeatedly collide with the pontoon during the circulation process, the contact position often needs to withstand the impact, and the fatigue damage is more likely to occur.
(2)大氣水分對潤滑油的影響-當真空泵的潤滑油溫只要小於120℃,在油潤滑片式真空泵之運轉過程的壓縮段,幾乎會把吸入空氣裡的水蒸氣壓成液態水,進而導致汙染潤滑油。若空氣濕度越高,影響更加劇烈。故當設備應用於防洪救災的豪雨季節,將使潤滑油僅能做為耗材使用,以避免滑片潤滑不佳,使功耗與磨耗加劇。(2) Influence of atmospheric moisture on lubricating oil - When the temperature of the lubricating oil of the vacuum pump is less than 120 °C, the water vapor in the inhaled air will be pressed into liquid water in the compression section of the oil-lubricated vacuum pump. Causes contamination of the lubricant. If the air humidity is higher, the impact is more severe. Therefore, when the equipment is used in the rainy season of flood control and disaster relief, the lubricating oil can only be used as a consumable material to avoid poor lubrication of the sliding vane and increase power consumption and wear.
(3)潤滑油無法成為耐久使用的影響-前述提及反覆吸氣的過程會使得潤滑油遭受水氣得液化汙染,迫使潤滑油壽命減短,但反覆吸氣還會造成一個更為嚴重的影響;因油潤滑片式真空泵有壓縮氣體的運作過程,此過程能以熱力學的絕熱壓縮視之,即柴油引擎的點火機制,透過壓縮氣體造成氣體溫升。若是無法使真空泵長期運轉於極限真空,便會迫使真空泵持續壓縮氣體,造成整機與油溫皆上升,壓縮過程的溫度上升會導致潤化油從液體變成氣體,若真空泵無法運轉於極限真空,表示該泵仍要排氣,此時,若無法有效地將氣化後的潤滑油冷凝為液體,便會讓氣化後的潤滑油隨著空氣排出,一方面汙染環境,一方面加速潤滑油的消耗。(3) Lubricating oil can not be affected by durable use - the aforementioned process of re-inhalation will cause the lubricating oil to be liquefied and contaminated by water vapor, forcing the life of the lubricating oil to be shortened, but the repeated inhalation will also cause a more serious Impact; Because the oil-lubricated chip vacuum pump has the operation process of compressed gas, this process can be viewed by thermodynamic adiabatic compression, that is, the ignition mechanism of the diesel engine, and the temperature rise of the gas is caused by the compressed gas. If the vacuum pump cannot be operated for a long time in the ultimate vacuum, the vacuum pump will be forced to continue to compress the gas, causing the whole machine and the oil temperature to rise. The temperature rise during the compression process will cause the moisturizing oil to change from liquid to gas. If the vacuum pump cannot operate at the ultimate vacuum, It means that the pump still needs to be vented. At this time, if the vaporized lubricating oil cannot be effectively condensed into a liquid, the vaporized lubricating oil will be discharged along with the air, which on the one hand pollutes the environment and accelerates the lubricating oil on the one hand. Consumption.
綜上所述,傳統抽水機之氣水分離機設計仍有待改良,以解決真空泵受反覆吸取大氣的影響與缺失問題;緣是,創作人有鑑於此,秉持多年該相關行業之豐富設計開發及實際製作經驗,針對現有之結構及缺失予以研究改良,提供一種抽水機之氣水分離器構造,以期達到更佳實用價值性之目的者。In summary, the design of the gas-water separator of the traditional water pump still needs to be improved to solve the problem of the vacuum pump being affected by the re-absorption of the atmosphere. The reason is that the creators have been in charge of the rich design and development of the relevant industries for many years. Production experience, research and improvement of existing structures and defects, and provide a gas-water separator structure of the water pump, in order to achieve better practical value.
本創作之主要目的在於提供一種抽水機之氣水分離器構造,尤其是指一種可達極限真空功效的氣水分離器構造為目的者。The main purpose of this creation is to provide a gas-water separator structure for a water pump, especially for a gas-water separator structure that achieves ultimate vacuum efficiency.
本創作抽水機之氣水分離器構造之主要目的與功效,係由以下具體技術手段所達成:The main purpose and effect of the gas-water separator construction of the present water pump are achieved by the following specific technical means:
其主要設有一外殼體,所述外殼體上方覆合一上蓋,下方具有通道連結水泵腔體,並於所述外殼體內部設有一浮筒,而所述上蓋上設有一氣密調整組及一真空破除器,所述氣密調整組一端連結真空泵,另一端連結一槓桿組,而所述槓桿組對應連結帶動所述浮筒;藉此,當於真空泵啟動後氣水分離器中的氣體,由外殼體通道流經外殼體與浮筒之間的間隙,並往氣密調整組端抽出,使其達到極限真空的狀態,且於此狀態下運轉,不會產生反覆抽取大氣而使浮筒碰撞的缺失,可大幅提升浮筒壽命,並可避免潤滑油受水氣液化與油品氣化作用。The utility model is mainly provided with an outer casing body. The outer casing body is covered with an upper cover, the lower portion has a passage connecting water pump cavity, and a buoy is arranged inside the outer casing, and the upper cover is provided with an airtight adjustment group and a vacuum. a breaker, the airtight adjustment group is connected to the vacuum pump at one end, and the lever group is coupled to the other end, and the lever group is coupled to drive the buoy; thereby, the gas in the gas water separator after the vacuum pump is started, by the outer casing The body passage flows through the gap between the outer casing and the pontoon, and is withdrawn to the end of the airtight adjustment group to reach the state of the ultimate vacuum, and operates in this state, and there is no possibility of reversing the atmosphere and causing the collision of the pontoon. The life of the float can be greatly improved, and the lubricating oil can be prevented from being liquefied by water and gas and gasified by oil.
本創作抽水機之氣水分離器構造的較佳實施例,其中於所述上蓋上設有一真空破除器,所述真空破除器對應設置於所述氣密調整組一側,並位於所述槓桿組的上方,所述槓桿組藉所述浮筒上升而啟動所述真空破除器,令外部空氣進入所述外殼體內部空間,讓所述浮筒下降並連動所述槓桿組,使所述活塞組脫離上蓋,使真空泵接續抽取水泵腔體端的空氣者。A preferred embodiment of the gas-water separator structure of the present invention is characterized in that a vacuum breaker is disposed on the upper cover, and the vacuum breaker is disposed on one side of the airtight adjustment group and located in the lever group. Above, the lever group starts the vacuum breaker by rising the buoy, allowing outside air to enter the inner space of the outer casing, lowering the buoy and interlocking the lever group to disengage the piston assembly from the upper cover , so that the vacuum pump continues to extract the air from the pump cavity end.
本創作抽水機之氣水分離器構造的較佳實施例,其中所述槓桿組包含一連桿,所述連桿具有一固定於所述外殼體內部的支點,其一端連結於所述浮筒,另一端設有一連動件,所述連動件連結所述活塞組之主桿。A preferred embodiment of the gas-water separator structure of the present invention, wherein the lever set includes a link having a fulcrum fixed to the inside of the outer casing, one end of which is coupled to the pontoon, and One end is provided with a linkage, and the linkage links the main pole of the piston set.
本創作抽水機之氣水分離器構造的較佳實施例,其中所述彈性件為採用兩階段進位彈簧。A preferred embodiment of the gas-water separator construction of the present water pump, wherein the elastic member is a two-stage carry spring.
為令本創作所運用之技術內容、創作目的及其達成之功效有更完整且清楚的揭露,茲於下詳細說明之,並請一併參閱所揭之圖式及圖號:In order to make the technical content, creative purpose and the effect achieved by this creation more complete and clear, please elaborate below, and please refer to the drawings and drawings:
於本創作技術特徵說明之前,係先了解氣水分離器設計的主要功能性及欲達成的理想目的與功效;然而,氣水分離器的設計,其主要目的是為了使水泵浦腔內之液體與氣體分離,因此氣水分離器的設計有兩大方向需要考慮:Before the description of the technical characteristics of this creation, it is first to understand the main functions of the gas-water separator design and the ideal purpose and effect to be achieved; however, the design of the gas-water separator is mainly for the purpose of making the pump cavity The liquid is separated from the gas, so the design of the gas-water separator has two main directions to consider:
1.從真空泵運轉功率面解析-真空泵的入口應盡量保持極限真空,且極限真空度越高越好。請參閱附件1所示,真空泵設計的文獻資料圖表,可以看出不論在哪種潤滑油溫下,真空泵的運轉功率跟入口壓力有很大關係,當入口越接近常壓或極限真空,功率越低,故當真空泵的入口可以保持在極限真空時,除了可以讓運轉功耗較低外,還可以帶來其他好處。1. From the vacuum pump running power surface analysis - the inlet of the vacuum pump should try to maintain the ultimate vacuum, and the higher the ultimate vacuum, the better. Please refer to the literature chart of the vacuum pump design shown in Appendix 1. It can be seen that the operating power of the vacuum pump has a great relationship with the inlet pressure regardless of the temperature of the lubricating oil. When the inlet is closer to the normal pressure or the ultimate vacuum, the power is higher. Low, so when the vacuum pump inlet can be kept at the ultimate vacuum, in addition to the lower operating power consumption, it can bring other benefits.
2.從真空泵入口壓力設計氣水分離器-控制潤滑油溫度,即是在控制油的黏滯性,當溫度恰當時,油的黏滯性可形成好的邊界潤滑,使滑片處於最佳潤滑,因而降低磨耗並延長壽命。然而,真空泵入口越接近常壓或接近極限真空時,潤滑油溫皆可達成最低的極值;因此,為了能以機械方式控制油品的溫度,若是能讓真空泵處於極限真空狀態運轉,則可確認油溫的降溫需求裕度,就能計算合適散熱模組,而不需要設計複雜的變頻散熱系統。2. Design the gas-water separator from the inlet pressure of the vacuum pump - control the temperature of the lubricating oil, that is, control the viscosity of the oil. When the temperature is right, the viscosity of the oil can form a good boundary lubrication, so that the sliding piece is in the best condition. Lubrication, thus reducing wear and extending life. However, the closer the vacuum pump inlet is to normal pressure or close to the ultimate vacuum, the minimum temperature can be reached by the temperature of the lubricating oil; therefore, in order to mechanically control the temperature of the oil, if the vacuum pump can be operated under the limit vacuum state, By confirming the cooling demand margin of the oil temperature, it is possible to calculate a suitable heat dissipation module without designing a complicated variable frequency heat dissipation system.
本創作依據氣水分離器設計的兩大方向進行研發創作而出,為令本創作所運用之技術內容、創作目的及其達成之功效有更完整且清楚的揭露,茲於下詳細說明之,並請一併參閱所揭之圖式及圖號:This creation is based on the two major directions of gas-water separator design. It is a complete and clear disclosure of the technical content, creative purpose and effect achieved by this creation. Please also refer to the drawings and drawings:
首先,請參閱第一~三圖所示,為本創作之抽水機之氣水分離器構造立體分解、組合外觀及剖視示意圖,其包含有:First of all, please refer to the first to third figures, which is a three-dimensional decomposition, combined appearance and cross-sectional schematic view of the gas-water separator structure of the water pump of the present invention, which includes:
一外殼體(1),係設有內部空間(11),於所述內部空間(11)底部設有通道(12)連結一水泵腔體;An outer casing (1) is provided with an inner space (11), and a passage (12) is connected to a pump cavity at the bottom of the inner space (11);
一浮筒(2),係對應容置於所述外殼體(1)之內部空間(11);a pontoon (2) corresponding to the inner space (11) of the outer casing (1);
一上蓋(3),係對應覆合於所述外殼體(1)之開口端,且所述上蓋(3)端面設有連通所述外殼體(1)之內部空間(11)的第一、第二階梯孔(31)、(32),所述第一階梯孔(31)內設有氣密環(33);An upper cover (3) correspondingly covers the open end of the outer casing (1), and the end surface of the upper cover (3) is provided with a first space connecting the inner space (11) of the outer casing (1), a second stepped hole (31), (32), wherein the first stepped hole (31) is provided with a gas tight ring (33);
一氣密調整組(4),係對應組設於所述上蓋(3)第一階梯孔(31)處,包含有一活塞外筒(41)及活塞組(42),所述活塞外筒(41)鎖固於所述上蓋(3),且所述活塞外筒(41)與一真空泵連結,而所述活塞組(42)包含一活塞內筒(421)、一設置於所述活塞內筒(421)內部的活塞體(422),所述活塞體(422)連結一主桿(423),並於所述主桿(423)外部套設有彈性件(424),所述彈性件(424)抵靠於所述活塞體(422)與所述活塞內筒(421)之間,所述主桿(423)穿組通過所述第一階梯孔(31),並能帶動所述活塞體(422)於所述活塞內筒(421)內部活動位移,及帶動所述活塞內筒(421)相對脫離或密合抵掣於所述第一階梯孔(31);An airtight adjustment group (4) is correspondingly disposed at the first stepped hole (31) of the upper cover (3), and includes a piston outer cylinder (41) and a piston group (42), and the piston outer cylinder (41) Locking the upper cover (3), and the piston outer cylinder (41) is coupled to a vacuum pump, and the piston group (42) includes a piston inner cylinder (421) and a piston inner cylinder (421) an inner piston body (422), the piston body (422) is coupled to a main rod (423), and an elastic member (424) is disposed outside the main rod (423), the elastic member ( 424) abutting between the piston body (422) and the inner cylinder (421), the main rod (423) passes through the first stepped hole (31) and can drive the piston The body (422) is movably displaced inside the piston inner cylinder (421), and drives the piston inner cylinder (421) to relatively disengage or close against the first stepped hole (31);
一槓桿組(5),係設有一固定的支點(51),且一端連結所述浮筒(2),另一端連結所述活塞組(42),以帶動所述活塞組(42)與所述浮筒(2)改變相對位置;所述槓桿組(5)包含一連桿(52),所述連桿(52)具有一固定於所述外殼體(1)內部的支點(51),其一端連結於所述浮筒(2),另一端設有一連動件(53),所述連動件(53)連結所述活塞組(42)之主桿(423);a lever set (5) is provided with a fixed fulcrum (51), one end of which is coupled to the pontoon (2), and the other end is coupled to the piston set (42) to drive the piston set (42) with the The pontoon (2) changes the relative position; the lever set (5) includes a link (52) having a fulcrum (51) fixed to the inside of the outer casing (1), one end of which Attached to the pontoon (2), the other end is provided with a linkage (53), the linkage (53) is coupled to the main rod (423) of the piston set (42);
一真空破除器(6),係設置在所述第二階梯孔(32)處,其包含有一球座(61),所述球座(61)嵌組於所述第二階梯孔(32)內,並設有一氣流通道(611),所述氣流通道(611)連結一容槽(612),所述容槽(612)設有一氣音球(62),且所述氣流通道(611)連通所述第二階梯孔(32),並設有一活動桿(63),所述活動桿(63)位於所述槓桿組(5)上方,且能於所述氣流通道(611)與所述第二階梯孔(32)間活動位移。a vacuum breaker (6) is disposed at the second stepped hole (32), and includes a ball seat (61), the ball seat (61) being embedded in the second stepped hole (32) An air flow channel (611) is disposed, the air flow channel (611) is coupled to a cavity (612), the cavity (612) is provided with an air ball (62), and the air flow channel (611) Connecting the second stepped hole (32), and is provided with a movable rod (63), the movable rod (63) is located above the lever set (5), and is capable of the air flow passage (611) and the Active displacement between the second stepped holes (32).
於實際操作時,請參閱第一~五圖所示,當真空泵剛開始執行真空作業時,空氣從水泵腔體端流入該氣水分離器底部的通道(12),再經浮筒(2)與外殼體(1)之間的間隙進入槓桿組(5)與上蓋(3)之第一階梯孔(31)間隙,並通過活塞組(42)與活塞外筒(41)間隙後,即可離開氣水分離器並流入真空泵之吸入側[空氣流動如第一圖中的箭頭標示路徑],於真空泵讓空氣經由箭頭路徑流動後,便可逐漸使水泵腔體內之真空度上升。In actual operation, please refer to the first to fifth figures. When the vacuum pump is just beginning to perform the vacuum operation, the air flows from the pump chamber end into the channel (12) at the bottom of the gas-water separator, and then through the pontoon (2). The gap between the outer casings (1) enters the gap between the lever group (5) and the first stepped hole (31) of the upper cover (3), and after leaving the piston outer casing (41) through the piston group (42), it can leave The gas-water separator flows into the suction side of the vacuum pump [air flow as indicated by the arrow in the first figure], and after the vacuum pump allows air to flow through the arrow path, the vacuum in the pump chamber can be gradually increased.
當浮筒(2)沒有受到浮力上升時,其槓桿組(5)可讓活塞組(42)保持不與上蓋(3)之第一階梯孔(31)處的氣密環(33)貼合,以避免空氣迴路阻斷;續,當真空泵讓水泵腔體端的真空度足夠時,會使水泵腔體端的水進入氣水分離器,並推動浮筒(2)上升,於浮筒(2)上升後,會透過槓桿組(5)的連桿(52)運動,讓連桿(52)以支點(51)為圓心定位而旋動,連結帶動另一端的連動件(53),使連動件(53)帶動活塞組(42)之主桿(423)往下活動位移,使氣密調整組(4)中的活塞組(42)被往下拉動,當於水位足夠高時[即浮筒(2)上升到一適當位置],其下拉幅度可使活塞組(42)抵靠於第一階梯孔(31)處,並與氣密環(33)貼合,開始阻斷空氣迴路。進一步阻斷空氣迴路需要考慮氣密設計,即活塞組(42)與氣密環(33)的貼合力量;此部分本創作透過彈性件(424)採用兩階段進位彈簧的作用,使其活塞組(42)能緊密抵靠氣密環(33)而貼合,以下說明之。When the pontoon (2) is not subjected to buoyancy rise, its lever group (5) allows the piston set (42) to remain attached to the airtight ring (33) at the first stepped hole (31) of the upper cover (3). To avoid air circuit blockage; continued, when the vacuum pump makes the vacuum at the pump chamber end sufficient, the water at the pump chamber end will enter the gas water separator and push the float (2) up. After the float (2) rises, Through the movement of the connecting rod (52) of the lever group (5), the connecting rod (52) is rotated with the fulcrum (51) as a center, and the connecting member (53) that drives the other end is connected to make the linking member (53) Driving the main rod (423) of the piston group (42) to move downward, so that the piston group (42) in the airtight adjustment group (4) is pulled downward, when the water level is high enough [ie, the float (2) rises To a suitable position], the pull-down amplitude allows the piston set (42) to abut against the first stepped bore (31) and fits against the airtight ring (33) to begin blocking the air circuit. Further blocking the air circuit requires consideration of the airtight design, that is, the bonding force of the piston group (42) and the airtight ring (33); this part of the present work uses the two-stage carry spring to make the piston through the elastic member (424). The group (42) can be closely fitted against the airtight ring (33), as explained below.
當活塞組(42)與氣密環(33)的貼合力量不足時,表示真空度會持續上升[即持續抽真空],讓水繼續推動浮筒(2);此時,槓桿組(5)會讓活塞組(42)開始產生如第五圖的分離現象,其目的便是讓彈性件(424)[為採兩階段進位彈簧]執行第一階段進位壓縮,讓活塞組(42)能對氣密環(33)有更多的貼合力,以確實將空氣迴路斷開。待空氣迴路確實斷開後,浮筒(2)所在的空間便維持原始壓力,而氣密調整組(4)之活塞組(42)所在空間即可繼續往極限真空邁進。然而,由於活塞組(42)並無任何破除真空的機制影響,故不會反覆吸取大氣,也能維持極限真空的運作條件。When the bonding force of the piston group (42) and the airtight ring (33) is insufficient, it means that the vacuum will continue to rise [ie, continuous vacuuming], so that the water continues to push the pontoon (2); at this time, the lever group (5) The piston set (42) will begin to produce the separation phenomenon as shown in the fifth figure, the purpose of which is to allow the elastic member (424) [for the two-stage carry spring] to perform the first stage carry compression, so that the piston set (42) can The airtight ring (33) has more adhesion to actually disconnect the air circuit. After the air circuit is indeed disconnected, the space in which the pontoon (2) is located maintains the original pressure, and the space in which the piston group (42) of the airtight adjustment group (4) is located can continue to move toward the ultimate vacuum. However, since the piston group (42) does not have any mechanism to break the vacuum, it does not repeatedly absorb the atmosphere, and can maintain the operating conditions of the ultimate vacuum.
而在上述的動作過程,設置於上蓋(3)第二階梯孔(32)處的真空破除器(6)係保持氣音球(62)位於球座(61)容槽(612)內並抵掣遮蔽氣流通道(611),讓氣水分離器內部於真空泵運作時可逐漸將氣體抽出完成氣水分離的動作。In the above operation process, the vacuum breaker (6) disposed at the second stepped hole (32) of the upper cover (3) holds the air ball (62) in the socket (612) of the ball seat (61) and abuts掣The airflow channel (611) is shielded so that the inside of the gas water separator can gradually extract the gas to complete the gas-water separation action when the vacuum pump operates.
進一步當氣密環(33)發生氣密不良的現象[如疲乏、龜裂…],導致活塞組(42)無法透過彈性件(424)[為採兩階段進位彈簧]強制斷開空氣迴路,會使真空泵能持續對浮筒(2)所在內部空間(11)提高真空度,讓水繼續上升推高浮筒(2),進而讓彈性件(424)[為採兩階段進位彈簧]執行第二階段進位壓縮。然而,在此時因浮筒(2)逐漸升高,進而讓槓桿組(5)之連桿(52)接觸到真空破除器(6),讓真空破除器(6)中的活動桿(63)將機械式警示氣音球(62)推離球座(61)容槽(612),使氣流通道(611)與外部環境連通,進而達成真空破除,讓環境空氣由氣流通道(611)經第二階梯孔(32)進入氣水分離器的外殼體(1)內,將水退至水泵腔體的浦腔體內。Further, when the airtight ring (33) is in a poor airtight state [such as fatigue, cracking, ...], the piston group (42) cannot forcibly open the air circuit through the elastic member (424) [for the two-stage carry spring]. The vacuum pump can continue to increase the vacuum in the internal space (11) of the pontoon (2), allowing the water to continue to rise and push up the pontoon (2), thereby allowing the elastic member (424) to perform the second stage [for the two-stage carry spring] Carry compression. However, at this time, the pontoon (2) is gradually raised, and the link (52) of the lever group (5) is brought into contact with the vacuum breaker (6), and the movable rod (63) in the vacuum breaker (6) is allowed. Pushing the mechanical warning air ball (62) away from the ball seat (61) slot (612), so that the air flow channel (611) communicates with the external environment, thereby achieving vacuum breaking, allowing the ambient air to pass through the air flow channel (611). The two stepped holes (32) enter the outer casing (1) of the gas water separator, and the water is retracted into the pump chamber of the water pump chamber.
上述動作因外部環境空氣透過機械式警示氣音球(62)與球座(61)的間隙流入會產生氣音外,氣音球(62)也會移動,讓設備操作員可以用聽覺與視覺進行雙重判斷氣密環(33)是否損壞;而上述的警示效果,並無須使用任何電子儀器檢測,具有結構簡單可靠的功效。The above action is caused by the external ambient air passing through the gap between the mechanical warning air ball (62) and the ball seat (61), and the air sound ball (62) is also moved, so that the equipment operator can use the hearing and the vision. Double judgment is made whether the airtight ring (33) is damaged; and the above warning effect does not need to be detected by any electronic instrument, and has the advantages of simple and reliable structure.
綜上述,維持真空泵入口壓力於極限真空的條件才是真空泵正確的使用方式,且經研究結果也顯示維持極限真空的條件暨能有利於溫控,也能在不使用離合器的條件下讓真空泵運轉於最低能耗,因此,氣水分離器的合理設計,須讓水充滿水泵浦腔體後,即可自動切斷空氣流動迴路,除了阻隔水進入真空泵外,又使真空泵於最佳狀態運轉。In summary, maintaining the vacuum pump inlet pressure at the ultimate vacuum is the correct way to use the vacuum pump, and the results of the study also show that maintaining the ultimate vacuum condition can be beneficial to temperature control, and can also operate the vacuum pump without using a clutch. At the lowest energy consumption, the rational design of the gas-water separator requires that the water fills the pump cavity to automatically cut off the air flow circuit, except that the barrier water enters the vacuum pump and the vacuum pump operates in an optimal state. .
然而前述之實施例或圖式並非限定本創作之產品態樣、結構或使用方式,任何所屬技術領域中具有通常知識者之適當變化或修飾,皆應視為不脫離本創作之專利範疇。However, the above-described embodiments or drawings are not intended to limit the product, the structure, or the use of the present invention. Any changes or modifications of the ordinary skill in the art should be considered as not departing from the scope of the invention.
藉由以上所述,本創作結構之組成與使用實施說明可知,本創作與現有結構相較之下,具有下列優點:By the above, the composition and use description of the authoring structure can be seen that this creation has the following advantages compared with the existing structure:
1.本創作抽水機之氣水分離器構造,藉由於極限狀態運轉的真空泵運作下,與傳統現有氣水分離器相較具有下列差異、優點及功效:1. The gas-water separator structure of the present water pump has the following differences, advantages and effects compared with the conventional air-water separators operated by the vacuum pump operating in the limit state:
(A)因無須反覆抽取大氣,可避免潤滑油受水氣液化與油品氣化作用,僅作為耗材使用,舉如傳統氣水分離器運作72小時潤滑油箱內的油會耗盡,而本創作氣水分離器實際累積運轉504小時後,潤滑油箱的油量依舊很充足,故採用本創作氣水分離器可使相同容量的潤滑油品由耗盡改為更換,進而對環境保護有明確優點與功效;(A) Because it is not necessary to repeatedly extract the atmosphere, the lubricating oil can be prevented from being liquefied by water and gas and vaporized by oil. It can only be used as a consumable. For example, if the traditional gas-water separator is operated for 72 hours, the oil in the lubricating oil tank will be exhausted. After the actual accumulated operation of the gas-water separator for 504 hours, the oil volume of the lubricating oil tank is still sufficient. Therefore, the gas-water separator of the present invention can be used to change the lubricating oil of the same capacity from exhaustion to replacement, thereby clearing the environmental protection. Advantages and effects;
(B)不論傳統或本創作氣水分離器皆會配置一個真空計量測腔內真空度,由於傳統現有的氣水分離器會有反覆吸氣的過程,會導致真空計指針忽大忽小,無法穩定於某一值,故會導致真空計內的膜片或彈簧反覆壓縮,因而提早使其老化,然而,本創作氣水分離器因為可維持極限真空,故無此方面影響。(B) Regardless of whether the conventional or the original gas-water separator is equipped with a vacuum measuring chamber vacuum, the conventional gas-water separator will have a process of re-inhalation, which will cause the gauge to suddenly become small and small. It cannot be stabilized at a certain value, so the diaphragm or spring in the vacuum gauge is reversely compressed, so that it is aged early. However, the gas-water separator of the present invention has no such influence because it can maintain the ultimate vacuum.
(C)本創作氣水分離器可讓真空泵運轉於極限真空,因此可讓真空泵運轉於最低功率,與傳統現有氣水分離器相比,節能比率範圍約為5~20%。(C) The created gas-water separator allows the vacuum pump to operate at the ultimate vacuum, thus allowing the vacuum pump to operate at the lowest power. Compared with the conventional gas-water separator, the energy-saving ratio ranges from 5 to 20%.
(D)傳統現有氣水分離器的反覆抽取過程,會破壞抽水機入口壓力值的恆定,連帶使得抽水機的輸出壓力也會變動,而使抽水機較易出現喘振的狀況,使機組振動與穩定度較差;本創作氣水分離器因恆定於極限真空,故不會出現上述狀況。(D) The traditional extraction process of the existing gas-water separator will destroy the constant inlet pressure value of the pump, and the output pressure of the pump will also change, which makes the pumper more prone to surge and the vibration and stability of the unit. Poor; the creation of the gas-water separator is not constant because of the constant vacuum, so the above situation does not occur.
(E)本創作抽水機之氣水分離器構造,同上述,由於降低浮筒碰撞次數,可大幅提升浮筒壽命。(E) The gas-water separator structure of the present water pump, as described above, can greatly increase the life of the pontoon by reducing the number of pontoon collisions.
2.本創作抽水機之氣水分離器構造,藉由結構簡單的設計,使其能達到有效減少機體重量與體積的功效。2. The gas-water separator structure of the water pump of the present invention can achieve the effect of effectively reducing the weight and volume of the body by a simple structure design.
3.本創作抽水機之氣水分離器構造,藉以透過機械式警示氣音,讓設備操作員可以用聽覺與視覺進行雙重判斷氣密環是否損壞,而上述的警示效果,並無須使用任何電子儀器檢測,具有結構簡單可靠的功效。3. The gas-water separator structure of the water pump is designed to allow the operator of the equipment to use both the hearing and the vision to determine whether the airtight ring is damaged by the mechanical warning sound. The above warning effect does not require any electronic equipment. Detection, with a simple and reliable structure.
綜上所述,本創作實施例確能達到所預期之使用功效,又其所揭露之具體構造,不僅未曾見諸於同類產品中,亦未曾公開於申請前,誠已完全符合專利法之規定與要求,爰依法提出新型專利之申請,懇請惠予審查,並賜准專利,則實感德便。In summary, the present embodiment can achieve the expected use efficiency, and the specific structure disclosed therein has not been seen in similar products, nor has it been disclosed before the application, and has fully complied with the provisions of the Patent Law. And the request, the application for a new type of patent in accordance with the law, please forgive the review, and grant the patent, it is really sensible.
本創作:This creation:
(1)‧‧‧外殼體(1) ‧‧‧ outer casing
(11)‧‧‧內部空間(11)‧‧‧Internal space
(12)‧‧‧通道(12) ‧‧‧ channels
(2)‧‧‧浮筒(2) ‧ ‧ 浮
(3)‧‧‧上蓋(3) ‧ ‧ upper cover
(31)‧‧‧第一階梯孔(31)‧‧‧First stepped hole
(32)‧‧‧第二階梯孔(32)‧‧‧Second stepped hole
(33)‧‧‧氣密環(33) ‧ ‧ airtight ring
(4)‧‧‧氣密調整組(4) ‧ ‧ airtight adjustment group
(41)‧‧‧活塞外筒(41) ‧‧‧Piston outer cylinder
(42)‧‧‧活塞組(42) ‧‧‧Piston Set
(421)‧‧‧活塞內筒(421)‧‧‧Piston inner cylinder
(422)‧‧‧活塞體(422)‧‧‧ piston body
(423)‧‧‧主桿(423)‧‧‧ main pole
(424)‧‧‧彈性件(424)‧‧‧Flexible parts
(5)‧‧‧槓桿組(5) ‧‧‧Leverage group
(51)‧‧‧支點(51) ‧ ‧ fulcrum
(52)‧‧‧連桿(52)‧‧‧ linkage
(53)‧‧‧連動件(53)‧‧‧ linkages
(6)‧‧‧真空破除器(6) ‧‧‧vacuum breaker
(61)‧‧‧球座(61) ‧‧‧ tee
(611)‧‧‧氣流通道(611) ‧‧‧Air passage
(612)‧‧‧容槽(612) ‧‧‧ 容容
(62)‧‧‧氣音球(62) ‧ ‧ air ball
(63)‧‧‧活動桿(63) ‧‧‧ activity pole
第一圖:本創作之立體分解示意圖。The first picture: a three-dimensional exploded view of the creation.
第二圖:本創作之組合外觀示意圖。The second picture: a schematic view of the combination of the creation.
第三圖:本創作之剖視示意圖。The third picture: a schematic cross-sectional view of the creation.
第四圖:本創作之剖視動作示意圖一。The fourth picture: a schematic diagram of the cross-sectional action of this creation.
第五圖:本創作之剖視動作示意圖二。Figure 5: Schematic diagram of the cross-sectional action of this creation.
附件1:真空泵設計的文獻資料圖表。Annex 1: A literature chart of the vacuum pump design.
Claims (5)
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI655371B (en) * | 2018-07-02 | 2019-04-01 | 祥昇機電工業有限公司 | Steam separator structure of water pump |
TWI779909B (en) * | 2021-10-27 | 2022-10-01 | 祥昇機電工業有限公司 | Sealing element for fluid channel |
-
2018
- 2018-07-02 TW TW107208950U patent/TWM568301U/en unknown
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI655371B (en) * | 2018-07-02 | 2019-04-01 | 祥昇機電工業有限公司 | Steam separator structure of water pump |
TWI779909B (en) * | 2021-10-27 | 2022-10-01 | 祥昇機電工業有限公司 | Sealing element for fluid channel |
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