TWM648474U - High-efficiency microbubble-based oxygen dissolution apparatus - Google Patents
High-efficiency microbubble-based oxygen dissolution apparatus Download PDFInfo
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- TWM648474U TWM648474U TW112205061U TW112205061U TWM648474U TW M648474 U TWM648474 U TW M648474U TW 112205061 U TW112205061 U TW 112205061U TW 112205061 U TW112205061 U TW 112205061U TW M648474 U TWM648474 U TW M648474U
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- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 title claims abstract description 95
- 239000001301 oxygen Substances 0.000 title claims abstract description 95
- 229910052760 oxygen Inorganic materials 0.000 title claims abstract description 95
- 238000004090 dissolution Methods 0.000 title abstract 2
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 123
- 241000251468 Actinopterygii Species 0.000 claims abstract description 66
- 230000007246 mechanism Effects 0.000 claims abstract description 31
- 230000000694 effects Effects 0.000 claims abstract description 20
- 238000002347 injection Methods 0.000 claims description 19
- 239000007924 injection Substances 0.000 claims description 19
- 238000000034 method Methods 0.000 claims description 19
- 238000007667 floating Methods 0.000 claims description 14
- 230000009471 action Effects 0.000 claims description 10
- 239000007789 gas Substances 0.000 claims description 8
- 230000008569 process Effects 0.000 claims description 7
- 238000005086 pumping Methods 0.000 claims description 5
- 239000007921 spray Substances 0.000 claims description 5
- 230000008859 change Effects 0.000 claims description 4
- 230000009977 dual effect Effects 0.000 claims description 2
- 239000003570 air Substances 0.000 abstract 2
- 239000012080 ambient air Substances 0.000 abstract 2
- 238000010586 diagram Methods 0.000 description 8
- 238000009395 breeding Methods 0.000 description 6
- 230000001488 breeding effect Effects 0.000 description 6
- 238000009360 aquaculture Methods 0.000 description 4
- 244000144974 aquaculture Species 0.000 description 4
- 238000005276 aerator Methods 0.000 description 2
- 238000006243 chemical reaction Methods 0.000 description 2
- 238000005516 engineering process Methods 0.000 description 2
- 230000006870 function Effects 0.000 description 2
- 230000006872 improvement Effects 0.000 description 2
- 238000006213 oxygenation reaction Methods 0.000 description 2
- 208000035240 Disease Resistance Diseases 0.000 description 1
- 238000000889 atomisation Methods 0.000 description 1
- 238000010009 beating Methods 0.000 description 1
- 230000008901 benefit Effects 0.000 description 1
- 230000005540 biological transmission Effects 0.000 description 1
- 230000006835 compression Effects 0.000 description 1
- 238000007906 compression Methods 0.000 description 1
- 230000036541 health Effects 0.000 description 1
- 239000003595 mist Substances 0.000 description 1
- 238000010248 power generation Methods 0.000 description 1
- 230000004044 response Effects 0.000 description 1
- 239000010865 sewage Substances 0.000 description 1
- 239000007858 starting material Substances 0.000 description 1
- 230000004083 survival effect Effects 0.000 description 1
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02W—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
- Y02W10/00—Technologies for wastewater treatment
- Y02W10/10—Biological treatment of water, waste water, or sewage
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Abstract
Description
本創作係有關於高效率微氣泡溶氧設備,尤指一種魚塭打水機改善深水區域之溶氧量為主所開發之高效率微氣泡溶氧設備。This creation is about high-efficiency micro-bubble oxygen-dissolving equipment, especially a high-efficiency micro-bubble oxygen-dissolving equipment developed mainly by using a fish pump to improve the amount of dissolved oxygen in deep water areas.
按,台灣屬於海島型地形,四面環海之特殊環境造就台灣經濟可觀之養殖業,在陸上養殖業中,養殖池水之魚塭含氧量之高低對於池內魚類健康、存活率及飼料換肉率之影響極大;當池水之含氧量越高,魚兒越健康且抗病力越高,因而可大幅提高養殖利潤。According to reports, Taiwan has an island-type terrain, and the special environment surrounded by the sea has created Taiwan's economically significant aquaculture industry. In the land-based aquaculture industry, the oxygen content of fish ponds in the aquaculture pond water has a significant impact on the health, survival rate and feed conversion rate of the fish in the pond. The impact is huge; when the oxygen content of the pond water is higher, the fish are healthier and have higher disease resistance, which can greatly increase the profits of breeding.
其目前在魚塭中水中溶氧量所提供之方式如下所列:The methods currently used to provide dissolved oxygen in fish pond water are as follows:
1.打水車:其中有業者開發出中華民國新型專利M279182號其係在於當啟動馬達運轉時,同步使驅動斜齒輪轉動以驅動嚙接的從動斜齒輪及齒輪轉軸轉動,即可帶動水車的打水葉進行打水動作,而且可以小馬力之馬達即可帶動兩嚙接之驅動斜齒輪及從動斜齒輪運轉水車,但上述結構僅能針對池水表面進行溶氧量改善,深層水池中溶氧量並未增加,而且葉片式拍打不僅造成噪音影響水中生物生長環境,且拍打速度過大時則容易傷害水中生物,造成不必要之損失,另外此種方式需要大電壓由岸邊提供,不僅危險而且容易受到停電之困擾。1. Water tanker: Among them, some industry players have developed a new patent of the Republic of China No. M279182, which is that when the starter motor is running, the driving helical gear is rotated synchronously to drive the engaged driven helical gear and the gear shaft to rotate, which can drive the water tanker. The water pumping blade performs the water pumping action, and a small horsepower motor can drive the two meshing driving helical gears and the driven helical gear to run the water wheel. However, the above structure can only improve the dissolved oxygen content on the surface of the pool water, and the dissolved oxygen in the deep pool water can be improved. The amount of oxygen has not increased, and the blade-type flapping not only causes noise that affects the growth environment of aquatic organisms, but also easily harms aquatic organisms when the flapping speed is too high, causing unnecessary losses. In addition, this method requires a large voltage to be provided by the shore, which is not only dangerous. And are prone to power outages.
2.風車裝置:另有業者開發出中華民國新型專利141439號之一種高效能打氣風車裝置,該主要係由一扇葉受風單元,一空氣壓縮單元,及一尾翼定向單元等所構成,其該技術係以簡易構造之葉片將風力充份納入,以使發揮運轉功能,並推動後方壓縮機將空氣壓縮儲存,以提供氣缸壓將空氣壓縮並打入水中提高魚塭中的氧氣密度,其上述風力發電會因季節性或是風力大小推動產生之能量不穩定,容易產生供氧斷斷續續之狀況而導致氧氣密度不均勻之問題。2. Windmill device: Another industry has developed a high-efficiency air-inflating windmill device according to the new patent number 141439 of the Republic of China. It is mainly composed of a fan blade wind receiving unit, an air compression unit, and a tail fin directional unit. This technology uses blades with a simple structure to fully incorporate the wind force to achieve operational functions and drive the rear compressor to compress and store the air to provide cylinder pressure to compress the air and pump it into the water to increase the oxygen density in the fish ponds. The energy generated by the above-mentioned wind power generation is unstable due to seasonality or wind strength, and it is easy to cause intermittent oxygen supply, resulting in uneven oxygen density.
3.沉水式:另一有業者開發中華民國新型專利194375號之一種水質處理用沉水式增壓給氧機,利用上大下小的中空倒錐狀增壓吸氣管,配合旋轉機連動的增壓吸氣機構,產生強勁空氣吸進力,達到充分的空氣與水的混合而注入水中,但此方式外葉片拍打魚池仍會產生巨大聲響而影響魚類生存空間。3. Submersible type: Another industry developer has developed a submersible type pressurized oxygen feeder for water quality treatment, as shown in the new patent number 194375 of the Republic of China. It uses a hollow inverted cone-shaped pressurized suction pipe with a large top and a small bottom, and cooperates with a rotating machine. The linked supercharged air suction mechanism generates strong air suction force to achieve sufficient mixing of air and water and injects it into the water. However, in this method, the blades beating the fish pond will still produce a huge sound and affect the living space of the fish.
4.沈水馬達:在有業者開發中華民國新型專利M313423號之一種沈水馬達增壓溶氧泵浦,係為沈水馬達泵浦結構之改良,主要結構乃包括由沈水馬達、軸封座、空氣吸管座、附於中空內軸的圓柱狀鼠籠式之軸流風葉、螺旋式排氣風葉、以及附於外軸的軸槳葉輪所組成,其特徵在於將水面上之空氣透過該創作之強力抽氣馬達而直接灌入水中,而外界設置之葉片擾動魚池內池水而產生水流,使空氣與水混合而增加含氧量,但此方式仍需要大電壓才可驅動馬達運轉而造成耗電問題。4. Submersible motor: A submersible motor pressurized dissolved oxygen pump has been developed by the industry under the new patent number M313423 of the Republic of China. It is an improvement of the submersible motor pump structure. The main structure includes a submersible motor, a shaft seal seat, and an air suction pipe. It consists of a base, a cylindrical squirrel-cage axial flow fan blade attached to the hollow inner shaft, a spiral exhaust fan blade, and a shaft propeller impeller attached to the outer shaft. It is characterized by the strong suction of the air on the water surface through the creation. The air motor is directly poured into the water, and the external blades disturb the water in the fish pond to generate water flow, which mixes the air and water and increases the oxygen content. However, this method still requires a large voltage to drive the motor and causes power consumption problems.
5. 移動式綠能:中華民國新型專利M461318號之移動式綠能魚塭增氧機,透過抽水馬達將魚塭池水抽離水面並噴向空中,而霧化噴嘴之設計使噴出之池水以霧化方式噴向空中以增加水與空氣之接觸面積而提高水之含氧量,同時落下之水霧可降落於太陽能板上以降低太陽能板表面溫度,提高太陽能板之轉換效率之,另有設計一動力馬達可提供使用者透過無線電方式控制本創作移動至指定位置進行增氧行為,但上述結構僅能針對池水表面進行溶氧量改善,深層水池中溶氧量並未增加,且太陽能板如天氣不佳時移動式綠能魚塭增氧機無法執行提高含氧量以及移動行為問題。5. Mobile green energy: The mobile green energy fish pond aerator of the new patent number M461318 of the Republic of China uses a pumping motor to pump the fish pond water out of the water and spray it into the air. The design of the atomizing nozzle makes the sprayed pond water The atomization method is sprayed into the air to increase the contact area between water and air and increase the oxygen content of the water. At the same time, the falling water mist can land on the solar panel to reduce the surface temperature of the solar panel and improve the conversion efficiency of the solar panel. A power motor is designed to allow users to control the creation via radio to move to a designated location for oxygenation. However, the above structure can only improve the dissolved oxygen level on the surface of the pool water. The amount of dissolved oxygen in the deep pool has not increased, and the solar panel For example, when the weather is bad, the mobile green energy fish aerator cannot increase the oxygen content and there are problems with mobile behavior.
針對以上開發新的改良結構,另有其他業者同樣有開發出中有關水質處理(如:污水處理、水產養殖等)所使用的水中浴氧機具種類甚多,諸如已知的技術文獻中:公告第056594號「浮動循環廣角輸氣水車」、公告第066928號「湧流式揚水車」、公告第163849號「養殖場水車泵浦之改良結構)、公告第177992號「養殖用打水車之新型結構」、公告第189930號「養殖用供氧打水車之新型結構」、公告第228051號「兼具排水功能之養殖供氧打水車結構」、公告第342599號「養殖用之水車結構」…等等,但同樣無法達到本創作所要達到之提高魚塭內高效率大範圍區域增加魚塭內之氧氣與淨化水質為主之效果者。In response to the above-mentioned new improved structures, other industries have also developed many types of water bath oxygen equipment used in water quality treatment (such as sewage treatment, aquaculture, etc.), such as in the known technical documents: Announcement Announcement No. 056594 "Floating circulation wide-angle gas transmission water truck", Announcement No. 066928 "Gush type water pump", Announcement No. 163849 "Improved structure of water truck pump for breeding farms", Announcement No. 177992 "New structure of water pump for breeding ", Announcement No. 189930 "New Structure of Oxygen Supply and Water Truck for Breeding", Announcement No. 228051 "Structure of Oxygen Supply and Water Truck for Breeding with Drainage Function", Announcement No. 342599 "Structure of Water Truck for Breeding"...etc. , but it is also unable to achieve the main effect of improving the efficiency of the fish farm, increasing the oxygen in the fish farm and purifying the water quality in a large area, which is what this invention aims to achieve.
本創作人有鑑於習知打水馬達有上述缺點,是以乃思及創作的意念,經多方探討與試作樣品試驗,及多次修正改良後,遂推出本創作。 本創作提供一種高效率微氣泡溶氧設備,其包含: 一馬達; 一管架體,該管架體係組設於該馬達上;以及 至少一高效率溶氧產生機構,該高效率溶氧產生機構內係可產生文氏管效應與螺旋增壓動作之結構,其該馬達設置於一魚塭內,藉由該馬達引導魚塭內水後配合而帶動流動水依序通過管架體內後,進入該高效率溶氧產生機構空間內,並配合該高效率溶氧產生機構內文氏管效應與螺旋增壓的雙加壓方式,將外界空氣得被負壓吸入打碎形成更小微氣泡溶於流動水後在引導入魚塭內水中。 In view of the above-mentioned shortcomings of conventional water-fetching motors, the creator of the invention thought about the idea of creation. After many discussions and prototype tests, as well as many revisions and improvements, he came up with this creation. This creation provides a high-efficiency microbubble dissolved oxygen equipment, which includes: a motor; A pipe frame body, the pipe frame system is assembled on the motor; and At least one high-efficiency dissolved oxygen generation mechanism. The high-efficiency dissolved oxygen generation mechanism has a structure that can produce a venturi effect and a spiral boosting action. The motor is installed in a fish tank, and the motor is used to guide the inside of the fish tank. The water then cooperates to drive the flowing water through the pipe frame body in sequence, and then enters the space of the high-efficiency dissolved oxygen generation mechanism, and cooperates with the dual pressurization method of the Venturi effect and spiral boosting in the high-efficiency dissolved oxygen generation mechanism. The outside air is sucked in and broken by negative pressure to form smaller micro-bubbles, which are dissolved in the flowing water and then introduced into the water inside the fish pond.
本創作高效率微氣泡溶氧設備主要目的,為達到魚塭內高效率大範圍區域增加魚塭內之氧氣與淨化水質為主之效果者。The main purpose of this high-efficiency microbubble dissolved oxygen equipment is to achieve the main effects of increasing oxygen in the fish pond and purifying the water quality in a large area with high efficiency.
以下茲配合本創作較佳實施例之圖式進一步說明如下,以期能使熟悉本創作相關技術之人士,得依本說明書之陳述據以實施。 The following is a further description of the preferred embodiments of the invention in conjunction with the drawings, in order to enable those who are familiar with the technology related to the invention to implement the invention in accordance with the statements in this specification.
首先,請配合參閱第一圖至第八圖所示,本創作高效率微氣泡溶氧設備,其包含:首先,如第一圖至第十四圖所示,本創作為一種高效率微氣泡溶氧設備,其包含:一馬達10,該馬達10係為高壓供氣防水之馬達10,該馬達10設有一馬達本體11供一圓形框之底架12組設,另該馬達本體11上另設有圓形的接口部111;一管架體20,該管架體20係設有一圓柱狀的垂直主管路21、一圓柱狀的橫向主管路22、四L形之彎管23以及兩蓋體24,該垂直主管路21一端連結固定於該馬達10的馬達本體11之接口部111,另一端係連接於橫向主管路22一端,該彎管23係間隔的設置該管架體20的橫向主管路22,另該橫向主管路22兩自由端係供該兩蓋體24密閉蓋設,使橫向主管路22內形成一密閉之空間;四高效率溶氧產生機構30,該各高效率溶氧產生機構30設置該管架體20的橫向主管路22的彎管23上,其高效率溶氧產生機構30係設有一體成形的高效率溶氧噴射管體31與一具撓性弧形之第一進氣彎管32,該高效率溶氧噴射管體31係設有一第一接合端311、一第二接合端312以及一
噴射出水端313,其該第一接合端311係設置於該管架體20的橫向主管路22的彎管23,其該第一接合端311內係設為文氏管結構之斷面變化孔徑,其該第一接合端311係依序設有一第一孔徑3111、一第二孔徑3112以及一第三孔徑3113,其中第一孔徑3111以及一第三孔徑3113直徑大於第二孔徑3112,另該第二接合端312係設靠近於第一接合端311的第三孔徑3113處,其該第二接合端312係供第一進氣彎管32結合設置,其第二接合端312內係設有一氣柱板3121,且於該氣柱板3121靠近第三孔徑3113係設有一集氣槽3122,另該噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131,其螺旋紋凹槽3131延伸連結至第一接合端311的第三孔徑3113位置,該第一進氣彎管32係設置有一第一端部321以及一第二端部322,該第一端部321係設置於第二接合端312,另該第二端部322係連通外界提供空氣進入於內。
First of all, please refer to Figures 1 to 8, the high-efficiency microbubble dissolved oxygen equipment of this invention includes: First, as shown in Figures 1 to 14, this invention is a high-efficiency microbubble Dissolved oxygen equipment, which includes: a
另請參考第六圖至第八圖為高效率微氣泡溶氧設備於魚塭內使用狀態示意圖,其中依序進行程序為以下方式:第一為抽水程序:該其馬達10之馬達本體11設置於魚塭內底部中水區域,藉由該馬達10的馬達本體11增壓由底架12處抽取魚塭內的水;第二為導引程序:由該馬達10的接口部111而帶動引導水流依序流動至該管架體20垂直主管路21及橫向主管路22及兩蓋體24處,因各蓋體24使內部流動管路為密閉空間,故抽取魚塭內的水流使該朝向該各彎管23後,在各別進入高效率溶氧噴射管體31;第三為第一次加壓程序:該第一進氣彎管32之第二端部322係連通外界提供空氣依序進入該第一進氣彎管32之第一端部321後至該第二接合端312的氣柱板3121的36細小孔徑進行空氣分割加壓打碎形成微氣泡後,
並將第一次加壓成微氣泡引導至集氣槽3122內;第四為第二次加壓程序:為其水流會依序經由該高效率溶氧噴射管體31的第一接合端311內的第一孔徑3111、第二孔徑3112以及一第三孔徑3113,因該第一孔徑3111以及一第三孔徑3113直徑大於第二孔徑3112不同截面積設計產生文氏管效應,進而使流動的水產生加壓形成第二次加壓速度變化後,將集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成更小微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓動作;第五為魚塭內高效增氧程序:該集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成更小微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓後,使得被負壓吸入打碎形成更小微氣泡溶於流動的水中後高壓引至魚塭內,進而達到魚塭內高效率大範圍區域增加魚塭內之氧氣與淨化水質為主之效果者。
Please also refer to Figures 6 to 8, which are schematic diagrams of the use of high-efficiency microbubble oxygen-dissolving equipment in fish ponds. The sequential procedures are as follows: The first is the water pumping procedure: the
另請參考第九圖為高效率微氣泡溶氧設備於魚塭內使用狀態示意圖,其中該馬達10的底架12係設置於一四方形的水底框架A後並置放魚塭內底部深水區域,該其馬達10之馬達本體11設置於魚塭內底部中水區域,藉由該馬達10的馬達本體11增壓由底架12處抽取魚塭內的水,並由該馬達10的接口部111而帶動水流依序流動至該管架體20垂直主管路21及橫向主管路22及兩蓋體24處,因各蓋體24使內部流動管路為密閉空間,故抽取魚塭內的水流使該朝向該各彎管23後,在各別進入高效率溶氧噴射管體31,該第一進氣彎管32之第二端部322係連通外界提供負壓空氣依序吸入該第一進氣彎管32之第一端部321後至該第二接合端312的氣柱板3121的36細小
孔徑進行空氣分割加壓打碎形成微氣泡後,並將第一次加壓成微氣泡引導至集氣槽3122內,為其水流會依序經由該高效率溶氧噴射管體31的第一接合端311內的第一孔徑3111、第二孔徑3112以及一第三孔徑3113,因該第一孔徑3111以及一第三孔徑3113直徑大於第二孔徑3112不同截面積設計產生文氏管效應,進而使流動的水產生加壓形成第二次加壓速度變化後,將集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成更小微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓動作,該集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成更小微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓後,使得被負壓吸入打碎形成更小微氣泡溶於流動的水中後高壓引至魚塭內底部深水區域,進而達到魚塭內底部深水區域增加氧氣與淨化水質為主之效果者。
Please also refer to Figure 9, which is a schematic diagram of the use of high-efficiency microbubble dissolved oxygen equipment in fish ponds. The
另請參考第十圖及第十一圖為高效率溶氧產生機構另一實施例立體圖,該高效率溶氧產生機構30係設有一圓柱狀的接頭33、一圓柱狀的柱體34以及一快速接頭35,該接頭33內具有不同內徑之截面積設計並具有一內螺牙的第一端331以及一第二端332,其該第一端331係螺設於該管架體20之彎管23一端處,另第二端332係螺設於柱體34一端,該柱體34係設有具一外螺牙之螺鎖部341、一具有內螺牙之穿孔部342以及一噴射出水端343,該柱體34之螺鎖部341與該接頭33的第二端332鎖設固定,另該穿孔部342係供快速接頭35螺鎖固定於上,另該噴射出水端343內係設有設有複數交錯左右螺旋紋凹槽,藉由上述組合係提供高效率溶氧產生機構輕易生產與組合運用效果者。
Please also refer to Figures 10 and 11, which are perspective views of another embodiment of a high-efficiency dissolved oxygen generation mechanism. The high-efficiency dissolved
另請參考第十二圖至第十三圖為另一高效率微氣泡溶氧設備實施例於魚塭水面上使用狀態,其請參考第十二圖為高效率微氣泡溶氧設備係設置於浮板架體40上,其該浮板架體40係設有兩浮板41以及一框架42,該馬達10為齒輪泵,該馬達10的馬達本體11係設置於該框架42內,其該管架體20係設置於該兩浮板41底部位於魚塭內,藉由該馬達10的馬達本體11增壓由底架12處管路抽取魚塭內的水,並由該馬達10的接口部111而帶動水流依序流動至該管架體20內部後,在各別進入高效率溶氧噴射管體31,該第一進氣彎管32之第二端部322係連通外界提供負壓空氣依序吸入該第一進氣彎管32之第一端部321後至該第二接合端312的氣柱板3121的36細小孔徑進行空氣分割加壓打碎形成微氣泡後,並將第一次加壓成微氣泡引導至集氣槽3122內,其水流會依序經由該高效率溶氧噴射管體31的第一接合端311內的第一孔徑3111、第二孔徑3112以及一第三孔徑3113,因該第一孔徑3111以及一第三孔徑3113直徑大於第二孔徑3112不同截面積設計產生文氏管效應,進而使流動的水產生加壓形成第二次加壓速度變化後,將集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成更小微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓動作,該集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成更小微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓後,使得被負壓吸入打碎形成更小微氣泡溶於流動的水中後高壓引至魚塭內,進而達到魚塭內高效率大範圍區域增加魚塭內之氧氣與淨化水質,並藉由浮板架體40達到能夠於魚塭移動進而達到大範圍之溶氧量效率增加為主效果者;請參考第十三圖及第十四圖,其中一高效率溶氧產生機構30係直接設置
於該馬達10的馬達本體11的接口部111上的管架體20,藉由該馬達10的馬達本體11設置於該浮板架體40並藉由馬達本體11增壓由底架12結合一管體處抽取魚塭內的水,並由該馬達10的接口部111至管架體20而帶動流動至高效率溶氧噴射管體31,進入高效率溶氧噴射管體31,該第一進氣彎管32之第二端部322係連通外界提供負壓空氣依序吸入該第一進氣彎管32之第一端部321後至該第二接合端312的氣柱板3121的36細小孔徑進行空氣分割加壓打碎形成微氣泡後,並將第一次加壓成微氣泡引導至集氣槽3122內,其水流會依序經由該高效率溶氧噴射管體31的第一接合端311內的第一孔徑3111、第二孔徑3112以及一第三孔徑3113,因該第一孔徑3111以及一第三孔徑3113直徑大於第二孔徑3112不同截面積設計產生文氏管效應,進而使流動的水產生加壓形成第二次加壓速度變化後,將集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成更小微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓動作,該集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓後,使得被負壓吸入打碎形成更小微氣泡溶於流動的水中後高壓引至魚塭內,進而達到魚塭內高效率大範圍區域增加為主效果者。
Please also refer to Figures 12 to 13 for another example of high-efficiency micro-bubble oxygen-dissolving equipment being used on the surface of the fish pond. Please refer to Figure 12 for another example of high-efficiency micro-bubble oxygen-dissolved equipment installed on the water surface. The floating
由上述具體實施例之結構,可得到下述之效益:本創作高效率微氣泡溶氧設備,其該第一進氣彎管32之第二端部322係連通外界提供負壓空氣依序吸入該第一進氣彎管32之第一端部321後至該第二接合端312的氣柱板3121的36細小孔徑進行空氣分割加壓打碎形成微氣泡後,並將第一次加壓成微氣泡引導至集氣槽3122內,為其水流
會依序經由該高效率溶氧噴射管體31的第一接合端311內的第一孔徑3111、第二孔徑3112以及一第三孔徑3113,因該第一孔徑3111以及一第三孔徑3113直徑大於第二孔徑3112不同截面積設計產生文氏管效應,進而使流動的水產生加壓形成第二次加壓速度變化後,將集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成更小微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓動作,該集氣槽3122內微氣泡引導加壓速度帶動被負壓吸入打碎形成更小微氣泡朝向噴射出水端313內係設有複數交錯左右螺旋紋凹槽3131產生螺旋增壓後,形成雙加壓的方式將被負壓吸入打碎形成更小微氣泡溶於流動的水中後高壓引至魚塭內,進而達到魚塭內高效率大範圍區域增加魚塭內之氧氣與淨化水質為主之效果者。
From the structure of the above specific embodiment, the following benefits can be obtained: In this high-efficiency microbubble oxygen-dissolving equipment, the
本創作高效率微氣泡溶氧設備,其中該馬達10的底架12係設置於一四方形的水底框架A後並置放魚塭內底部深水區域,進而達到魚塭內底部深水區域增加氧氣與淨化水質為主之效果者。
This invention creates a high-efficiency micro-bubble dissolved oxygen equipment, in which the
本創作高效率微氣泡溶氧設備,其中藉由浮板架體40達到能夠於魚塭移動進而達到大範圍之溶氧量效率增加為主效果者。
This invention creates a high-efficiency micro-bubble oxygen-dissolving equipment, in which the floating
10:馬達 10: Motor
11:馬達本體 11:Motor body
111:接口部 111:Interface Department
12:底架 12: Bottom frame
20:管架體 20: Pipe frame body
21:垂直主管路 21:Vertical main pipeline
22:橫向主管路 22: Lateral main pipeline
23:彎管 23:Bend pipe
24:蓋體 24: Cover
30:高效率溶氧產生機構 30: High-efficiency dissolved oxygen generation mechanism
31:高效率溶氧噴射管體 31: High efficiency dissolved oxygen injection pipe body
311:第一接合端 311: first joint end
312:第二接合端 312: Second joint end
3121:氣柱板 3121:Air column plate
3122:集氣槽 3122:Gas collecting tank
313:噴射出水端 313: Jet water end
3131:螺旋紋凹槽 3131: Spiral groove
32:第一進氣彎管 32:First air intake elbow
321:第一端部 321: first end
322:第二端部 322:Second end
33:接頭 33:Connector
331:第一端 331:First end
332:第二端 332:Second end
34:柱體 34: Cylinder
341:螺鎖部 341:Screw lock part
342:穿孔部 342: Perforation part
343:噴射出水端 343: Jet water end
35:快速接頭 35:Quick connector
40:浮板架體 40: Floating board frame
41:浮板 41:Floating board
42:框架 42:Frame
A:水底框架 A: Underwater frame
第一圖係本創作立體圖。 第二圖係本創作之立體分解圖。 第三圖係本創作之剖視示意圖。 第四圖係本創作之高效率溶氧產生機構剖視示意圖。 第五圖係本創作之高效率溶氧產生機構剖視示意圖。 第六圖係本創作於魚塭內使用狀態示意圖。 第七圖係本創作於魚塭深水處使用狀態剖視示意圖。 第八圖係本創作於魚塭深水處使用狀態立體動作示意圖。 第九圖係本創作於魚塭深水處高效率微氣泡溶氧使用狀態示意圖。 第十圖係本創作於高效率溶氧產生機構另一實施例立體圖。 第十一圖係本創作高效率溶氧產生機構另一實施例立體分解圖。 第十二圖係本創作另一實施例於魚塭水面上使用狀態示意圖。 第十三圖係本創作再另一實施例於魚塭水面上使用狀態示意圖。The first picture is a three-dimensional view of this creation. The second picture is a three-dimensional exploded view of this creation. The third picture is a schematic cross-sectional view of this creation. The fourth picture is a schematic cross-sectional view of the high-efficiency dissolved oxygen generating mechanism of this invention. The fifth figure is a schematic cross-sectional view of the high-efficiency dissolved oxygen generating mechanism of this invention. The sixth picture is a schematic diagram of the usage state of this creation in the fish farm. The seventh picture is a schematic cross-sectional view of this creation in use in deep water. The eighth picture is a schematic diagram of the three-dimensional action of this creation when it is used in deep water. The ninth picture is a schematic diagram of the use of high-efficiency microbubble dissolved oxygen created in the deep water of Yushan. The tenth figure is a perspective view of another embodiment of the high-efficiency dissolved oxygen generating mechanism of the present invention. Figure 11 is an exploded three-dimensional view of another embodiment of the high-efficiency dissolved oxygen generating mechanism of the present invention. The twelfth picture is a schematic diagram of another embodiment of the invention being used on the water surface of the fish pond. Figure 13 is a schematic diagram of another embodiment of the present invention being used on the surface of the fish pond.
第十四圖係本創作再一另一實施例於魚塭水面上使用狀態示意圖。 Figure 14 is a schematic diagram of another embodiment of the present invention being used on the surface of the fish pond.
20:管架體 20: Pipe frame body
23:彎管 23:Bend pipe
30:高效率溶氧產生機構 30: High-efficiency dissolved oxygen generation mechanism
31:高效率溶氧噴射管體 31: High efficiency dissolved oxygen injection pipe body
311:第一接合端 311: first joint end
3111:第一孔徑 3111: First aperture
3112:第二孔徑 3112: Second aperture
3113:第三孔徑 3113:Third aperture
312:第二接合端 312: Second joint end
3121:氣柱板 3121:Air column plate
3122:集氣槽 3122:Gas collecting tank
313:噴射出水端 313: Jet water end
3131:螺旋紋凹槽 3131: Spiral groove
32:第一進氣彎管 32:First air intake elbow
321:第一端部 321: first end
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