TWM523826U - Filter for air conditioner - Google Patents
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- TWM523826U TWM523826U TW105203757U TW105203757U TWM523826U TW M523826 U TWM523826 U TW M523826U TW 105203757 U TW105203757 U TW 105203757U TW 105203757 U TW105203757 U TW 105203757U TW M523826 U TWM523826 U TW M523826U
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Description
本創作係關於一種用於空調裝置之濾網,特別關於一種含有遠紅外線材料之用於空調裝置之濾網。The present invention relates to a screen for an air conditioner, and more particularly to a screen for an air conditioner comprising a far infrared material.
空調裝置是一種應用熱力學原理來改變環境溫度的裝置。其應用範圍廣泛,包括:應用於居家或公共環境的冷暖氣機及冰箱,以及工商業上所使用的冷凍貨櫃及大型冷藏庫等方面。An air conditioning unit is a device that applies thermodynamic principles to change the ambient temperature. It can be used in a wide range of applications, including: air conditioners and refrigerators for home or public use, as well as refrigerated containers and large refrigerators used in industrial and commercial applications.
為改善空調裝置的熱交換效率,通常會在該空調裝置的進氣口安裝濾網,其主要作用係過濾空氣中的懸浮粒子,藉此避免因懸浮粒子附著於散熱片上而降低了熱交換效率,並同時達成淨化空氣的功能。In order to improve the heat exchange efficiency of the air conditioner, a filter screen is usually installed at the air inlet of the air conditioner, and its main function is to filter the suspended particles in the air, thereby avoiding the heat exchange efficiency being lowered due to the adhesion of the suspended particles to the heat sink. And at the same time achieve the function of purifying the air.
然而,傳統之濾網必須時常加以清洗或更換。若濾網過度阻塞,將導致空調裝置的進氣量減少,因此降低熱交換效率,增加電力的耗損。However, conventional screens must be cleaned or replaced from time to time. If the filter is excessively blocked, the intake air amount of the air conditioner will be reduced, thereby reducing the heat exchange efficiency and increasing the power consumption.
因此,有必要提供一種新穎之用於空調裝置之濾網,來改善傳統濾網的缺陷。Therefore, it is necessary to provide a novel screen for an air conditioner to improve the defects of the conventional screen.
為改善上述傳統之用於空調裝置之濾網的缺陷,本創作係提拱一種新穎之用於空調裝置之濾網。In order to improve the above-mentioned conventional defects of the filter screen for an air conditioner, the present invention proposes a novel filter screen for an air conditioner.
為達上述目的及其他目的,本創作之一種用於空調裝置之濾網,包含: 一板體,該板體的厚度係介於2~3 mm之間,其上具有複數個穿透該板體的圓形孔洞,每一圓形孔洞的平均孔徑係介於3~9 mm之間,任意二個圓形孔洞的軸心間的最近距離係介於10.5~13.5 mm之間; 其中,該板體係含有遠紅外線材料。For the above purposes and other purposes, a filter for an air conditioning apparatus of the present invention comprises: a plate body having a thickness of between 2 and 3 mm, having a plurality of penetrating plates thereon The circular hole of the body, the average aperture of each circular hole is between 3 and 9 mm, and the closest distance between the axes of any two circular holes is between 10.5 and 13.5 mm; The board system contains far infrared materials.
上述之濾網,其中該遠紅外線材料可包含: 60~70 %的SiO 2; 17~23 %的Al 2O 3; 2 %的Na 2O 3; 5 %的K 2O; 2.50 %的MgO; 4.50 %的ZnO;以及 1 %的B 2O 3。 The above filter screen, wherein the far-infrared material may comprise: 60-70% SiO 2 ; 17-23% Al 2 O 3 ; 2% Na 2 O 3 ; 5% K 2 O; 2.50% MgO ; 4.50% ZnO; and 1% B 2 O 3 .
上述之濾網,其中該板體可包含: 25 %的遠紅外線材料;以及 75 % 的基材。The above filter screen, wherein the plate body may comprise: 25 % far infrared material; and 75 % substrate.
上述之濾網,其中該基材可選自由聚乙烯、聚丙烯、聚苯乙烯、聚氯乙烯、聚碳酸酯、聚乳酸及聚對苯二甲酸乙二酯所組成之群組。The above filter screen, wherein the substrate is selected from the group consisting of polyethylene, polypropylene, polystyrene, polyvinyl chloride, polycarbonate, polylactic acid and polyethylene terephthalate.
上述之濾網,其中該板體可進一步含有負離子材料。The above filter screen, wherein the plate body may further contain an anion material.
上述之濾網,其中該負離子材料可選自由TiO 2、Fe 2O 3及CaO所組成之群組。 The above filter screen, wherein the negative ion material is selected from the group consisting of TiO 2 , Fe 2 O 3 and CaO.
上述之濾網,其可進一步包含: 奈米銀,其係塗佈於該板體的表面,形成一奈米銀塗層。The above filter screen may further comprise: nano silver coated on the surface of the plate to form a nano silver coating.
上述之濾網,其中該等圓形孔洞之孔徑可自該板體之一面逐漸朝該板體的另一面縮小。In the above filter screen, the aperture of the circular holes can be gradually reduced from one side of the plate body toward the other side of the plate body.
上述之濾網,其中該等圓形孔洞之孔壁與該板體的一面間可形成一圓角。In the above filter screen, a hole is formed between the hole wall of the circular hole and one side of the plate body.
上述之濾網,其可進一步包含: 複數個卡榫,其係位於該板體之邊緣,用以將該濾網與另一濾網銜接。The filter screen described above may further comprise: a plurality of cassettes located at an edge of the plate for engaging the filter screen with another filter screen.
本創作之一種用於空調裝置之濾網可應用於居家或公共環境的冷暖氣機及冰箱,以及工商業上所使用的冷凍貨櫃及大型冷藏庫等方面,可達成增加熱交換效率,減少電力的耗損的功效。The filter screen for an air conditioner can be applied to a heating and cooling machine and a refrigerator in a home or public environment, as well as a refrigerated container and a large refrigerator used in industrial and commercial fields, thereby achieving an increase in heat exchange efficiency and a reduction in electric power. The effect of wear and tear.
為充分瞭解本創作之目的、特徵及功效,茲藉由下述具體之實施例,並配合所附之圖式,對本創作做一詳細說明,說明如後:In order to fully understand the purpose, features and effects of this creation, the following specific examples, together with the attached drawings, provide a detailed description of the creation, as explained below:
本創作之一種用於空調裝置之濾網,包含: 一板體,該板體的厚度係介於2~3 mm之間,其上具有複數個穿透該板體的圓形孔洞,每一圓形孔洞的平均孔徑係介於3~9 mm之間,任意二個圓形孔洞的軸心間的最近距離係介於10.5~13.5 mm之間; 其中,該板體係含有遠紅外線材料。The invention relates to a filter for an air conditioner, comprising: a plate body having a thickness of between 2 and 3 mm, having a plurality of circular holes penetrating the plate body, each of The average hole diameter of the circular hole is between 3 and 9 mm, and the closest distance between the axes of any two circular holes is between 10.5 and 13.5 mm. The plate system contains far infrared rays.
高效遠紅外線輻射是由日本認證中心所發現的(JISQ17025‧ISO/IEC17025)。遠紅外線的特定波長(4~14 μm)被稱之為「培養射線」,可促進植物生長。培養射線被認為是可與水分子產生共鳴的。Efficient far-infrared radiation was discovered by the Japan Certification Center (JISQ17025‧ISO/IEC17025). The specific wavelength of the far infrared ray (4~14 μm) is called "culture ray" and can promote plant growth. The cultured rays are thought to resonate with water molecules.
本創作係利用該濾網之板體上之具有特定形狀、平均孔徑大小及軸心間的最近距離的圓形孔洞,以及該板體係含有遠紅外線材料,可放出遠紅外線的特性,使得透過該濾網進出空調設備的氣體分子能夠藉由該濾網分餾,進而使氣體分子能夠更為均勻地散落在空調設備的散熱片上,增加氣體分子與散熱片的接觸面積,藉此提升該空調設備的熱交換效能。經分餾的空氣分子可有效地交換熱能,使空氣可更快達到預設溫度。此外,還可以減輕溫度不均的狀況。因此,可減少空調裝置之壓縮機的運行時間,進而達成節省能量耗損之功效。The creation system utilizes a circular hole having a specific shape, an average pore size and a closest distance between the axes on the plate body of the filter, and the plate system contains a far-infrared material, which can emit the characteristics of far infrared rays, so that the The gas molecules of the filter entering and leaving the air-conditioning device can be fractionated by the filter, so that the gas molecules can be more evenly scattered on the heat sink of the air-conditioning device, and the contact area between the gas molecules and the heat sink is increased, thereby improving the air-conditioning device. Heat exchange efficiency. The fractionated air molecules exchange heat efficiently, allowing air to reach preset temperatures faster. In addition, it can also reduce the temperature unevenness. Therefore, the running time of the compressor of the air conditioner can be reduced, thereby achieving the effect of saving energy consumption.
其中,該板體之長度及寬度並未特別限制,本創作所屬技術領域中具有通常知識者可進行適當之調整。The length and width of the plate body are not particularly limited, and those skilled in the art to which the present invention pertains may make appropriate adjustments.
其中,每一圓形孔洞的平均孔徑及任意二個圓形孔洞的軸心間的最近距離並未特別限制,其尺寸只要在上述範圍之內,即可達成節省能量耗損之功效。較佳地,任意二個圓形孔洞的邊緣間的最近距離係介於1~3 mm之間,藉此使任意二個圓形孔洞之間仍存在足夠的板體結構,以支持該濾網。在本創作的一態樣中,一圓形孔洞可具有一致的孔徑,此時,平均孔徑可為該圓形孔洞於該板體之任一面所測得之孔徑。在本創作的另一態樣中,一圓形孔洞之孔徑可自該板體之一面逐漸朝該板體的另一面縮小,使該圓形孔洞於該板體之二面分別具有不同的孔徑,此時,平均孔徑係指該圓形孔洞之孔徑的平均值。The average aperture of each circular hole and the closest distance between the axes of any two circular holes are not particularly limited, and the size of the circular hole is within the above range, thereby achieving the effect of saving energy consumption. Preferably, the closest distance between the edges of any two circular holes is between 1 and 3 mm, so that there is still enough plate structure between any two circular holes to support the filter. . In one aspect of the present invention, a circular aperture can have a uniform aperture, and in this case, the average aperture can be the aperture measured by the circular aperture on either side of the plate. In another aspect of the present invention, the aperture of a circular hole can be gradually reduced from one side of the plate toward the other side of the plate, so that the circular hole has different apertures on both sides of the plate. In this case, the average pore size refers to the average value of the pore diameter of the circular pore.
其中,該板體所含有遠紅外線材料並未特別限制,可使用任何習知之能夠有效發射遠紅外線輻射的材料。較佳地,該遠紅外線材料係係包含: 60~70 %的SiO 2; 17~23 %的Al 2O 3; 2 %的Na 2O 3; 5 %的K 2O; 2.50 %的MgO; 4.50 %的ZnO;以及 1 %的B 2O 3。 Among them, the far-infrared material contained in the plate body is not particularly limited, and any conventional material capable of efficiently emitting far-infrared radiation can be used. Preferably, the far-infrared material system comprises: 60-70% SiO 2 ; 17-23% Al 2 O 3 ; 2% Na 2 O 3 ; 5% K 2 O; 2.50% MgO; 4.50% ZnO; and 1% B 2 O 3 .
其中,該遠紅外線材料在該板體中所佔的比例並未特別限制,本創作所屬技術領域中具有通常知識者可進行適當之調整。較佳地,該板體係包含: 25 %的遠紅外線材料;以及 75 % 的基材。The proportion of the far-infrared material in the plate body is not particularly limited, and those skilled in the art can make appropriate adjustments. Preferably, the panel system comprises: 25 % far infrared material; and 75 % substrate.
其中,該基材所使用材料並未特別限制,例如:可使用任何習知之熱固性聚合物或熱塑性聚合物。較佳地,該基材係選自由聚乙烯、聚丙烯、聚苯乙烯、聚氯乙烯、聚碳酸酯、聚乳酸及聚對苯二甲酸乙二酯所組成之群組。The material used for the substrate is not particularly limited, and for example, any conventional thermosetting polymer or thermoplastic polymer can be used. Preferably, the substrate is selected from the group consisting of polyethylene, polypropylene, polystyrene, polyvinyl chloride, polycarbonate, polylactic acid, and polyethylene terephthalate.
實施例Example 11
圖1係為本創作實施例1之用於空調裝置之濾網的正面視圖;以及圖2係為本創作實施例1之用於空調裝置之濾網的背面視圖。如圖1及圖2所示,實施例1之濾網10係包含一板體11,該板體11上具有複數個穿透該板體11的圓形孔洞12,其中該等圓形孔洞12所佔的面積係為該板體的45~55%。實施例1之濾網10在該板體11之相鄰的二邊,進一步包含複數個公卡榫13,用以與另一濾網之母卡榫銜接。實施例1之濾網10在該板體11之另外相鄰的二邊,進一步包含複數個母卡榫14,用以與另一濾網之公卡榫銜接。1 is a front view of a screen for an air conditioner of the first embodiment; and FIG. 2 is a rear view of the screen for an air conditioner of the first embodiment. As shown in FIG. 1 and FIG. 2, the screen 10 of the first embodiment includes a plate body 11 having a plurality of circular holes 12 penetrating the plate body 11, wherein the circular holes 12 are formed. The area occupied is 45 to 55% of the plate. The filter screen 10 of the first embodiment further includes a plurality of male cassettes 13 on the two adjacent sides of the board body 11 for engaging with the female card holder of the other filter screen. The screen 10 of the first embodiment further includes a plurality of female cassettes 14 on the other adjacent sides of the board body 11 for engaging with the male cassettes of the other screen.
圖3係為本創作實施例1之用於空調裝置之濾網的上視圖;圖4係為沿圖3之A-A切面的剖面圖;以及圖5係為沿圖3之B-B切面的剖面圖。在圖3中,實施例1之板體11的長度L及寬度W皆為300 mm。公卡榫13突出該板體11的距離D1係為6.5 mm,該公卡榫13之直徑R1係為9 mm。母卡榫14則具有對應該公卡榫13之尺寸。在圖4中,實施例1之板體11的厚度T1係為3 mm。在圖5中,公卡榫13之厚度T2係為1.5 mm,母卡榫14之深度S1係為1.5 mm,彼此對應。3 is a top view of the screen for the air conditioner of the first embodiment; FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3; and FIG. 5 is a cross-sectional view taken along line B-B of FIG. In Fig. 3, the length L and the width W of the plate body 11 of the first embodiment are 300 mm. The male click 13 protrudes from the plate 11 by a distance D1 of 6.5 mm, and the male snap 13 has a diameter R1 of 9 mm. The female cassette 14 has the size corresponding to the male cassette 13 . In Fig. 4, the thickness T1 of the plate body 11 of the embodiment 1 is 3 mm. In Fig. 5, the thickness T2 of the male click 13 is 1.5 mm, and the depth S1 of the female click 14 is 1.5 mm, which corresponds to each other.
圖6係為本創作實施例1之用於空調裝置之濾網的放大側視圖。在圖6中,該圓形孔洞12之孔徑R2係為9 mm,二個圓形孔洞12的軸心15間的最近距離D2係為12 mm。Fig. 6 is an enlarged side elevational view of the screen for the air conditioning apparatus of the first embodiment. In Fig. 6, the circular hole 12 has an aperture R2 of 9 mm, and the closest distance D2 between the axial centers 15 of the two circular holes 12 is 12 mm.
實施例1之濾網的板體係包含:25 %的遠紅外線材料;以及75 % 的聚丙烯。其中,該遠紅外線材料係包含:60~70 %的SiO 2;17~23 %的Al 2O 3;2 %的Na 2O 3;5 %的K 2O;2.50 %的MgO;4.50 %的ZnO;以及1 %的B 2O 3。 The panel system of the screen of Example 1 contained: 25% far infrared material; and 75% polypropylene. Wherein, the far-infrared material comprises: 60-70% SiO 2 ; 17-23% Al 2 O 3 ; 2% Na 2 O 3 ; 5% K 2 O; 2.50% MgO; 4.50% ZnO; and 1% B 2 O 3 .
實施例1之用於空調裝置之濾網,可裝設與空調設備的室外機及室內機的入風口及出風口,藉此過濾進出該空調設備的空氣。The screen for the air conditioner of the first embodiment can be installed with the air inlet and the air outlet of the outdoor unit and the indoor unit of the air conditioner, thereby filtering the air entering and leaving the air conditioner.
測試例Test case 11
測試例1係針對實施例1的濾網進行測試,藉此了解實施例1之具有圓形孔洞的濾網對於空調裝置之熱交換效率及電力的耗損程度的影響,以及佐證本創作之用於空調裝置之濾網的功效。Test Example 1 was tested on the screen of Example 1, whereby the influence of the screen having the circular hole of Example 1 on the heat exchange efficiency and the degree of power loss of the air conditioner was ascertained, and the use of the present invention was confirmed. The efficiency of the filter screen of the air conditioning unit.
測試例1係測試在安裝實施例1之具有圓形孔洞的濾網的前後,冷凍機用電量的改變情形。於測試之第1~6天(未安裝),該冷凍機係在未安裝實施例1之具有圓形孔洞的濾網的情況下運作。於測試之第7天(安裝當日),係將實施例1之具有圓形孔洞的濾網安裝於冷凍機之室外機及室內機的出風口及入風口上。於測試之第8~21天(安裝後),該冷凍機係在安裝實施例1之具有圓形孔洞的濾網的情況下運作。Test Example 1 was a test for changing the amount of electricity used by the refrigerator before and after the installation of the screen having the circular holes of Example 1. On the first to sixth days of the test (not installed), the freezer was operated without the filter of the first embodiment having the circular hole. On the seventh day of the test (on the day of installation), the filter having the circular hole of the first embodiment was attached to the air outlet and the air inlet of the outdoor unit and the indoor unit of the refrigerator. On the 8th to 21st days of the test (after installation), the freezer was operated with the filter screen of Example 1 having a circular hole.
於測試期間,紀錄該冷凍機的用電度數,以計算未安裝及安裝後的日最高用電量、日最低用電量及平均日用電量,並藉由未安裝及安裝後的平均日用電量來計算節能率。同時,亦記錄測試期間的氣溫、最高氣溫及降水量。During the test period, record the electricity consumption of the freezer to calculate the maximum daily electricity consumption, daily minimum electricity consumption and average daily electricity consumption after installation and installation, and by the average date after installation and installation. Use electricity to calculate the energy saving rate. At the same time, the temperature, maximum temperature and precipitation during the test were also recorded.
測試例1之測試結果係如下列表1所示: 表1 <TABLE border="1" borderColor="#000000" width="_0001"><TBODY><tr><td><b>狀態</b></td><td><b>日期</b></td><td><b>用電度數</b></td><td><b>日最高用電量</b></td><td><b>日最低用電量</b></td><td><b>平均日用電量</b></td><td><b>節能率</b></td><td><b>氣溫</b></td><td><b>最高氣溫</b></td><td><b>降水量</b></td></tr><tr><td> 未安裝 </td><td> 2015/12/29 </td><td> 90.3 </td><td> 103.90 </td><td> 89.30 </td><td> 95.96 </td><td> 36.10% </td><td> 17.4 </td><td> 20.0 </td><td> 0.0 </td></tr><tr><td> 2015/12/30 </td><td> 89.3 </td><td> 16.2 </td><td> 17.2 </td><td> 1.0 </td></tr><tr><td> 2015/12/31 </td><td> 92.5 </td><td> 16.3 </td><td> 17.0 </td><td> 0.0 </td></tr><tr><td> 2016/1/1 </td><td> 96.0 </td><td> 19.1 </td><td> 22.6 </td><td> 0.0 </td></tr><tr><td> 2016/1/2 </td><td> 103.7 </td><td> 18.7 </td><td> 20.1 </td><td> 0.0 </td></tr><tr><td> 2016/1/3 </td><td> 103.9 </td><td> 19.1 </td><td> 20.2 </td><td> 15.5 </td></tr><tr><td> 安裝當日 </td><td> 2016/1/4 </td><td> 91.5 </td><td></td><td></td><td></td><td> 20.4 </td><td> 23.3 </td><td> 0.5 </td></tr><tr><td> 安裝後 </td><td> 2016/1/5 </td><td> 64.4 </td><td> 67.26 </td><td> 56.30 </td><td> 61.33 </td><td> 20.7 </td><td> 24.0 </td><td> 0.5 </td></tr><tr><td> 2016/1/6 </td><td> 62.5 </td><td> 18.5 </td><td> 20.2 </td><td> 34.0 </td></tr><tr><td> 2016/1/7 </td><td> 59.3 </td><td> 18.0 </td><td> 19.6 </td><td> 0.0 </td></tr><tr><td> 2016/1/8 </td><td> 58.8 </td><td> 16.9 </td><td> 18.0 </td><td> 6.0 </td></tr><tr><td> 2016/1/9 </td><td> 58.5 </td><td> 17.2 </td><td> 20.3 </td><td> 0.0 </td></tr><tr><td> 2016/1/10 </td><td> 62.8 </td><td> 18.5 </td><td> 23.1 </td><td> 0.0 </td></tr><tr><td> 2016/1/11 </td><td> 59.4 </td><td> 17.1 </td><td> 19.0 </td><td> 32.8 </td></tr><tr><td> 2016/1/12 </td><td> 64.0 </td><td> 16.0 </td><td> 17.6 </td><td> 6.5 </td></tr><tr><td> 2016/1/13 </td><td> 56.3 </td><td> 14.3 </td><td> 15.0 </td><td> 4.0 </td></tr><tr><td> 2016/1/14 </td><td> 56.8 </td><td> 14.6 </td><td> 15.6 </td><td> 0.0 </td></tr><tr><td> 2016/1/15 </td><td> 59.5 </td><td> 15.5 </td><td> 16.8 </td><td> 2.0 </td></tr><tr><td> 2016/1/16 </td><td> 67.3 </td><td> 18.2 </td><td> 21.5 </td><td> 0.5 </td></tr><tr><td> 2016/1/17 </td><td> 67.1 </td><td> 16.9 </td><td> 19.0 </td><td> 40.0 </td></tr><tr><td> 2016/1/18 </td><td> 62.0 </td><td> 14.9 </td><td> 17.7 </td><td> 0.0 </td></tr></TBODY></TABLE>The test results of Test Example 1 are shown in Table 1 below: Table 1 <TABLE border="1" borderColor="#000000" width="_0001"><TBODY><tr><td><b>Status</b></td><td><b>Date</b> ></td><td><b>Power consumption</b></td><td><b>Day maximum power consumption</b></td><td><b>Day minimum Battery</b></td><td><b>Average daily electricity</b></td><td><b>Energy saving rate</b></td><td><b >Temperature</b></td><td><b>Maximum temperature</b></td><td><b>Precipitation</b></td></tr><tr>< Td> not installed</td><td> 2015/12/29 </td><td> 90.3 </td><td> 103.90 </td><td> 89.30 </td><td> 95.96 </ Td><td> 36.10% </td><td> 17.4 </td><td> 20.0 </td><td> 0.0 </td></tr><tr><td> 2015/12/30 </td><td> 89.3 </td><td> 16.2 </td><td> 17.2 </td><td> 1.0 </td></tr><tr><td> 2015/12/ 31 </td><td> 92.5 </td><td> 16.3 </td><td> 17.0 </td><td> 0.0 </td></tr><tr><td> 2016/1 /1 </td><td> 96.0 </td><td> 19.1 </td><td> 22.6 </td><td> 0.0 </td></tr><tr><td> 2016/ 1/2 </td><td> 103.7 </td><td> 18.7 </td><td> 20.1 </td><td> 0.0 </td></tr><tr><td> 2016 /1/3 </td><td> 103.9 </td><td> 19.1 </td><td> 20.2 </td><td> 15.5 </td></tr><tr><td> The day of installation </td><td> 2016/1/ 4 </td><td> 91.5 </td><td></td><td></td><td></td><td> 20.4 </td><td> 23.3 </td> <td> 0.5 </td></tr><tr><td> After installation</td><td> 2016/1/5 </td><td> 64.4 </td><td> 67.26 </ Td><td> 56.30 </td><td> 61.33 </td><td> 20.7 </td><td> 24.0 </td><td> 0.5 </td></tr><tr>< Td> 2016/1/6 </td><td> 62.5 </td><td> 18.5 </td><td> 20.2 </td><td> 34.0 </td></tr><tr> <td> 2016/1/7 </td><td> 59.3 </td><td> 18.0 </td><td> 19.6 </td><td> 0.0 </td></tr><tr ><td> 2016/1/8 </td><td> 58.8 </td><td> 16.9 </td><td> 18.0 </td><td> 6.0 </td></tr>< Tr><td> 2016/1/9 </td><td> 58.5 </td><td> 17.2 </td><td> 20.3 </td><td> 0.0 </td></tr> <tr><td> 2016/1/10 </td><td> 62.8 </td><td> 18.5 </td><td> 23.1 </td><td> 0.0 </td></tr ><tr><td> 2016/1/11 </td><td> 59.4 </td><td> 17.1 </td><td> 19.0 </td><td> 32.8 </td></ Tr><tr><td> 2016/1/12 </td><td> 64.0 </td><td> 16.0 </td><td> 17.6 </td><td> 6.5 </td>< /tr><tr><td> 2016/1/13 </td><td> 56.3 </td><td> 14.3 </td><td> 15.0 </td><td> 4.0 </td> </tr><tr><td> 2016/1/14 </td><td> 56.8 </td><td> 1 4.6 </td><td> 15.6 </td><td> 0.0 </td></tr><tr><td> 2016/1/15 </td><td> 59.5 </td><td > 15.5 </td><td> 16.8 </td><td> 2.0 </td></tr><tr><td> 2016/1/16 </td><td> 67.3 </td>< Td> 18.2 </td><td> 21.5 </td><td> 0.5 </td></tr><tr><td> 2016/1/17 </td><td> 67.1 </td> <td> 16.9 </td><td> 19.0 </td><td> 40.0 </td></tr><tr><td> 2016/1/18 </td><td> 62.0 </td ><td> 14.9 </td><td> 17.7 </td><td> 0.0 </td></tr></TBODY></TABLE>
如表1所示,在未安裝實施例1之具有圓形孔洞的濾網的情況下,該冷凍機的平均日用電量係為95.96度,相對而言,在安裝實施例1之具有圓形孔洞的濾網的情況下,該冷凍機的平均日用電量係減少為61.33度,經安裝後該冷凍機的平均日用電量係減少了36.10%,即節能率係達36.10%。由此可見,實施例1之具有圓形孔洞的濾網可有效地提升該空調設備的熱交換效能,藉此減少用電量,以獲得節能、省電之功效。As shown in Table 1, in the case where the screen having the circular hole of Example 1 was not installed, the average daily electricity consumption of the refrigerator was 95.96 degrees, and relatively speaking, it was round in the mounting example 1. In the case of a mesh with a hole, the average daily electricity consumption of the refrigerator is reduced to 61.33 degrees. After installation, the average daily electricity consumption of the refrigerator is reduced by 36.10%, that is, the energy saving rate is 36.10%. It can be seen that the filter screen with the circular hole of Embodiment 1 can effectively improve the heat exchange performance of the air conditioner, thereby reducing the power consumption to obtain the energy saving and power saving effects.
比較例Comparative example 11
為比較濾網上之孔洞的形狀對於空調裝置之熱交換效率及電力的耗損程度的影響,另製備比較例1之濾網,並進行下述測試例2之測試作為對照。比較例1之濾網大致上與實施例1之濾網相同,同樣含有遠紅外線材料,但比較例1之濾網的板體上係具有複數個六角形孔洞,形成一蜂巢狀的濾網。比較例1之濾網中該等六角形孔洞所佔的面積係為該板體的60%,略大於實施例1。In order to compare the influence of the shape of the pores on the sieve on the heat exchange efficiency of the air-conditioning apparatus and the degree of power loss, the sieve of Comparative Example 1 was prepared, and the test of Test Example 2 described below was carried out as a control. The screen of Comparative Example 1 was substantially the same as the screen of Example 1, and also contained a far-infrared material. However, the screen of the filter of Comparative Example 1 had a plurality of hexagonal holes to form a honeycomb-shaped screen. The area occupied by the hexagonal holes in the screen of Comparative Example 1 was 60% of the plate body, which was slightly larger than that of Example 1.
測試例Test case 22
測試例2係針對比較例1的濾網進行測試,藉此了解比較例1之具有六角形孔洞的濾網對於空調裝置之熱交換效率及電力的耗損程度的影響。Test Example 2 was tested on the screen of Comparative Example 1, whereby the influence of the screen having the hexagonal holes of Comparative Example 1 on the heat exchange efficiency and the degree of power loss of the air conditioner was known.
測試例2係在萊爾富新莊店的3台一對一分離式空調機組上進行測試。該等空調機組的使用情況係為24小時不間斷地運作。Test Example 2 was tested on three one-to-one split air conditioning units in the Lairfu Xinzhuang store. The use of these air conditioning units is 24 hours of continuous operation.
測試例2係測試在安裝比較例1之具有六角形孔洞的濾網的前後,該等空調機組用電量的改變情形。於測試之第1~15天(未安裝),該等空調機組係在未安裝比較例1之具有六角形孔洞的濾網的情況下運作。於測試之第16天(安裝當日)的下午,係將比較例1之具有六角形孔洞的濾網安裝於該等空調機組的室外機迴風處及室內機迴風處。於測試之第17~30天(安裝後),該等空調機組係在安裝比較例1之具有六角形孔洞的濾網的情況下運作。Test Example 2 tests the change in the amount of electricity used by the air conditioner units before and after the installation of the screen having the hexagonal holes of Comparative Example 1. On the 1st to 15th days of the test (not installed), the air conditioning units were operated without the filter screen of the first embodiment having the hexagonal holes. On the afternoon of the 16th day of the test (the day of installation), the filter with hexagonal holes of Comparative Example 1 was installed in the return air of the outdoor unit of the air conditioning unit and the return air of the indoor unit. On the 17th to 30th day of the test (after installation), the air conditioning units were operated with the screen of the hexagonal hole of Comparative Example 1 installed.
於測試期間,紀錄該等空調機組的用電度數。同時,亦記錄測試期間的日均溫,日均溫數據來源係為台灣中央氣象局台北地區每日平均溫度統計紀錄。During the test period, the power consumption of the air conditioning units was recorded. At the same time, the daily average temperature during the test period was also recorded. The daily average temperature data is the daily average temperature record of the Taipei Central Meteorological Bureau in Taipei.
測試例2之測試結果係如下列表2所示: 表2 <TABLE border="1" borderColor="#000000" width="_0002"><TBODY><tr><td><b>狀態</b></td><td><b>日期</b></td><td><b>主機一</b><b>(kWh)</b></td><td><b>主機二</b><b>(kWh)</b></td><td><b>主機三</b><b>(kWh)</b></td><td><b>用電總和</b><b>(kWh)</b></td><td><b>日均溫</b><b>(</b><b>℃</b><b>)</b></td></tr><tr><td> 未安裝 </td><td> 5月24日 </td><td> 24.2 </td><td> 12.5 </td><td> 0 </td><td> 36.7 </td><td> 24.3 </td></tr><tr><td> 5月25日 </td><td> 24.7 </td><td> 12.4 </td><td> 0 </td><td> 37.1 </td><td> 23.6 </td></tr><tr><td> 5月26日 </td><td> 20.4 </td><td> 12.1 </td><td> 0 </td><td> 32.5 </td><td> 23.4 </td></tr><tr><td> 5月27日 </td><td> 28.9 </td><td> 15.5 </td><td> 0 </td><td> 44.4 </td><td> 26.8 </td></tr><tr><td> 5月28日 </td><td> 32.6 </td><td> 23.4 </td><td> 0 </td><td> 56 </td><td> 30 </td></tr><tr><td> 5月29日 </td><td> 33.1 </td><td> 32.6 </td><td> 2.6 </td><td> 68.3 </td><td> 30.9 </td></tr><tr><td> 5月30日 </td><td> 39.8 </td><td> 31 </td><td> 6.2 </td><td> 77 </td><td> 31 </td></tr><tr><td> 5月31日 </td><td> 37.5 </td><td> 23.9 </td><td> 5.8 </td><td> 67.2 </td><td> 28.2 </td></tr><tr><td> 6月1日 </td><td> 35.9 </td><td> 23.7 </td><td> 5.9 </td><td> 65.5 </td><td> 28.5 </td></tr><tr><td> 6月2日 </td><td> 29.2 </td><td> 29.8 </td><td> 5.4 </td><td> 64.4 </td><td> 29.6 </td></tr><tr><td> 6月3日 </td><td> 36.7 </td><td> 28.3 </td><td> 5 </td><td> 70 </td><td> 30.2 </td></tr><tr><td> 6月4日 </td><td> 35.6 </td><td> 25.1 </td><td> 5.2 </td><td> 65.9 </td><td> 28.4 </td></tr><tr><td> 6月5日 </td><td> 35.5 </td><td> 29.1 </td><td> 5.1 </td><td> 69.7 </td><td> 30.3 </td></tr><tr><td> 6月6日 </td><td> 34.4 </td><td> 23.1 </td><td> 5.6 </td><td> 63.1 </td><td> 26.7 </td></tr><tr><td> 6月7日 </td><td> 28.2 </td><td> 24.1 </td><td> 5.9 </td><td> 58.2 </td><td> 27.2 </td></tr><tr><td> 安裝當日 </td><td> 6月8日 </td><td> 36.3 </td><td> 25.1 </td><td> 5.8 </td><td> 67.2 </td><td> 29.5 </td></tr><tr><td> 安裝後 </td><td> 6月9日 </td><td> 41.2 </td><td> 26.8 </td><td> 5.4 </td><td> 73.4 </td><td> 30.4 </td></tr><tr><td> 6月10日 </td><td> 7.6 </td><td> 33.6 </td><td> 5.2 </td><td> 46.4 </td><td> 31.1 </td></tr><tr><td> 6月11日 </td><td> 42.2 </td><td> 31.5 </td><td> 4.8 </td><td> 78.5 </td><td> 31.7 </td></tr><tr><td> 6月12日 </td><td> 37.5 </td><td> 35.8 </td><td> 4.8 </td><td> 78.1 </td><td> 30.7 </td></tr><tr><td> 6月13日 </td><td> 33.1 </td><td> 30 </td><td> 5.2 </td><td> 68.3 </td><td> 29.2 </td></tr><tr><td> 6月14日 </td><td> 29.7 </td><td> 26.5 </td><td> 5.1 </td><td> 61.3 </td><td> 28.1 </td></tr><tr><td> 6月15日 </td><td> 39.6 </td><td> 23 </td><td> 4.9 </td><td> 67.5 </td><td> 29.2 </td></tr><tr><td> 6月16日 </td><td> 40.1 </td><td> 32.1 </td><td> 5.2 </td><td> 77.4 </td><td> 30.8 </td></tr><tr><td> 6月17日 </td><td> 35.9 </td><td> 40.8 </td><td> 5 </td><td> 81.7 </td><td> 31.6 </td></tr><tr><td> 6月18日 </td><td> 33.9 </td><td> 38.2 </td><td> 5 </td><td> 77.1 </td><td> 31.5 </td></tr><tr><td> 6月19日 </td><td> 37.3 </td><td> 31.3 </td><td> 4.3 </td><td> 72.9 </td><td> 30.9 </td></tr><tr><td> 6月20日 </td><td> 23 </td><td> 35.3 </td><td> 4.1 </td><td> 62.4 </td><td> 30.1 </td></tr><tr><td> 6月21日 </td><td> 35.7 </td><td> 26.1 </td><td> 4.4 </td><td> 66.2 </td><td> 29.1 </td></tr><tr><td> 6月22日 </td><td> 33.6 </td><td> 25.6 </td><td> 4.2 </td><td> 63.4 </td><td> 29.3 </td></tr></TBODY></TABLE>The test results of Test Example 2 are shown in Table 2 below: Table 2 <TABLE border="1" borderColor="#000000" width="_0002"><TBODY><tr><td><b>Status</b></td><td><b>Date</b> ></td><td><b>Host one</b><b>(kWh)</b></td><td><b>Host two</b><b>(kWh)< /b></td><td><b>Host 3</b><b>(kWh)</b></td><td><b>Power Usage</b><b>( kWh)</b></td><td><b>Day Average Temperature</b><b>(</b><b>°C</b><b>)</b></td ></tr><tr><td> not installed</td><td> May 24th </td><td> 24.2 </td><td> 12.5 </td><td> 0 </ Td><td> 36.7 </td><td> 24.3 </td></tr><tr><td> May 25th </td><td> 24.7 </td><td> 12.4 </ Td><td> 0 </td><td> 37.1 </td><td> 23.6 </td></tr><tr><td> May 26th </td><td> 20.4 </ Td><td> 12.1 </td><td> 0 </td><td> 32.5 </td><td> 23.4 </td></tr><tr><td> May 27th </ Td><td> 28.9 </td><td> 15.5 </td><td> 0 </td><td> 44.4 </td><td> 26.8 </td></tr><tr>< Td> May 28th </td><td> 32.6 </td><td> 23.4 </td><td> 0 </td><td> 56 </td><td> 30 </td> </tr><tr><td> May 29th </td><td> 33.1 </td><td> 32.6 </td><td> 2.6 </td><td> 68.3 </td> <td> 30.9 </td></tr><tr><td> May 30th </td><td> 39.8 </td><td> 31 </td><td> 6.2 </td><td> 77 </td><td> 31 </td></tr><tr><td> May 31st</td><td> 37.5 </td><td> 23.9 </td><td> 5.8 </td><td> 67.2 </td><td> 28.2 </td></tr><tr><td> June 1st </td><td> 35.9 </td><td> 23.7 </td><td> 5.9 </td><td> 65.5 </td><td> 28.5 </td></tr><tr><td> June 2 </td><td> 29.2 </td><td> 29.8 </td><td> 5.4 </td><td> 64.4 </td><td> 29.6 </td></tr><tr ><td> June 3rd </td><td> 36.7 </td><td> 28.3 </td><td> 5 </td><td> 70 </td><td> 30.2 </ Td></tr><tr><td> June 4th </td><td> 35.6 </td><td> 25.1 </td><td> 5.2 </td><td> 65.9 </ Td><td> 28.4 </td></tr><tr><td> June 5th </td><td> 35.5 </td><td> 29.1 </td><td> 5.1 </ Td><td> 69.7 </td><td> 30.3 </td></tr><tr><td> June 6th </td><td> 34.4 </td><td> 23.1 </ Td><td> 5.6 </td><td> 63.1 </td><td> 26.7 </td></tr><tr><td> June 7th </td><td> 28.2 </ Td><td> 24.1 </td><td> 5.9 </td><td> 58.2 </td><td> 27.2 </td></tr><tr><td> Installation Day</td> <td> June 8th </td><td> 36.3 </td><td> 25.1 </td><td> 5.8 </td><td> 67.2 </td><td> 29.5 </td ></tr><tr><td> After installation</td>< Td> June 9 </td><td> 41.2 </td><td> 26.8 </td><td> 5.4 </td><td> 73.4 </td><td> 30.4 </td> </tr><tr><td> June 10th </td><td> 7.6 </td><td> 33.6 </td><td> 5.2 </td><td> 46.4 </td> <td> 31.1 </td></tr><tr><td> June 11th </td><td> 42.2 </td><td> 31.5 </td><td> 4.8 </td> <td> 78.5 </td><td> 31.7 </td></tr><tr><td> June 12th </td><td> 37.5 </td><td> 35.8 </td> <td> 4.8 </td><td> 78.1 </td><td> 30.7 </td></tr><tr><td> June 13th </td><td> 33.1 </td> <td> 30 </td><td> 5.2 </td><td> 68.3 </td><td> 29.2 </td></tr><tr><td> June 14 </td> <td> 29.7 </td><td> 26.5 </td><td> 5.1 </td><td> 61.3 </td><td> 28.1 </td></tr><tr><td> June 15th </td><td> 39.6 </td><td> 23 </td><td> 4.9 </td><td> 67.5 </td><td> 29.2 </td></ Tr><tr><td> June 16th </td><td> 40.1 </td><td> 32.1 </td><td> 5.2 </td><td> 77.4 </td><td > 30.8 </td></tr><tr><td> June 17th </td><td> 35.9 </td><td> 40.8 </td><td> 5 </td><td > 81.7 </td><td> 31.6 </td></tr><tr><td> June 18th </td><td> 33.9 </td><td> 38.2 </td><td > 5 </td><td> 77.1 </td><td> 31.5 </td></tr><tr><td> June 19th </td><td> 37.3 </td><td> 31.3 </td><td> 4.3 </td><td> 72.9 </td><td> 30.9 </td></tr><tr><td> June 20th </td><td> 23 </td><td> 35.3 </td><td> 4.1 </td><td> 62.4 </td><td> 30.1 </td></tr><tr><td> June 21st</td><td> 35.7 </td><td> 26.1 </td><td> 4.4 </td><td> 66.2 </td><td> 29.1 </td></tr><tr><td> June 22nd</td><td> 33.6 </td><td> 25.6 </td><td> 4.2 </td><td> 63.4 </td><td> 29.3 </td></tr></TBODY></TABLE>
選擇日均溫相近之日期,對照未安裝及安裝後的用電量來計算節能率,其結果係如下列表3及表4所示。5月24日至5月29日及6月10日因有部分主機關機,造成比較基準不同,故不列入比較。此外,6月8日為安裝當日,亦不列入數據比較。 表3 <TABLE border="1" borderColor="#000000" width="_0003"><TBODY><tr><td><b>狀態</b></td><td><b>日期</b></td><td><b>空調總用電(kWh)</b></td><td><b>日均溫</b><b>(</b><b>℃)</b></td><td><b>用電差異(kWh)</b></td><td><b>節能率</b></td></tr><tr><td> 未安裝 </td><td> 5月30日 </td><td> 77 </td><td> 31 </td><td> 4.1 </td><td> 5.32% </td></tr><tr><td> 安裝後 </td><td> 6月19日 </td><td> 72.9 </td><td> 30.9 </td></tr><tr><td> 未安裝 </td><td> 5月31日 </td><td> 67.2 </td><td> 28.2 </td><td> 5.9 </td><td> 8.78% </td></tr><tr><td> 安裝後 </td><td> 6月14日 </td><td> 61.3 </td><td> 28.1 </td></tr><tr><td> 未安裝 </td><td> 6月3日 </td><td> 70 </td><td> 30.2 </td><td> 7.6 </td><td> 10.86% </td></tr><tr><td> 安裝後 </td><td> 6月20日 </td><td> 62.4 </td><td> 30.1 </td></tr><tr><td></td><td></td><td><b>平均節能率</b></td><td></td><td></td><td><b>8.32%</b></td></tr></TBODY></TABLE>表4 <TABLE border="1" borderColor="#000000" width="85%"><TBODY><tr><td><b>狀態</b></td><td><b>日期</b></td><td><b>空調總用電(kWh)</b></td><td><b>日均溫</b><b>(</b><b>℃)</b></td><td><b>用電差異(kWh)</b></td><td><b>節能率</b></td></tr><tr><td> 未安裝 </td><td> 5月29日 </td><td> 68.3 </td><td> 30.9 </td><td> -9.8 </td><td> -14.30% </td></tr><tr><td> 安裝後 </td><td> 6月12日 </td><td> 78.1 </td><td> 30.7 </td></tr><tr><td> 未安裝 </td><td> 6月2日 </td><td> 64.4 </td><td> 29.6 </td><td> -3.9 </td><td> -6.10% </td></tr><tr><td> 安裝後 </td><td> 6月13日 </td><td> 68.3 </td><td> 29.2 </td></tr><tr><td> 未安裝 </td><td> 6月5日 </td><td> 69.7 </td><td> 30.3 </td><td> -3.7 </td><td> -5.30% </td></tr><tr><td> 安裝後 </td><td> 6月9日 </td><td> 73.4 </td><td> 30.4 </td></tr><tr><td></td><td></td><td><b>平均節能率</b></td><td></td><td></td><td><b>-8.60%</b></td></tr></TBODY></TABLE>The date of the average daily temperature is selected, and the energy saving rate is calculated against the power consumption after installation and installation. The results are shown in Tables 3 and 4 below. From May 24th to May 29th and June 10th, some of the mainframes were shut down, resulting in different benchmarks, so they are not included in the comparison. In addition, June 8 is the date of installation and is not included in the data comparison. table 3 <TABLE border="1" borderColor="#000000" width="_0003"><TBODY><tr><td><b>Status</b></td><td><b>Date</b> ></td><td><b>Air conditioning total electricity consumption (kWh)</b></td><td><b>day average temperature</b><b>(</b><b> °C)</b></td><td><b>Power consumption difference (kWh)</b></td><td><b>energy saving rate</b></td></tr> <tr><td> not installed</td><td> May 30th</td><td> 77 </td><td> 31 </td><td> 4.1 </td><td> 5.32% </td></tr><tr><td> After installation</td><td> June 19th </td><td> 72.9 </td><td> 30.9 </td>< /tr><tr><td> Not Installed</td><td> May 31st</td><td> 67.2 </td><td> 28.2 </td><td> 5.9 </td> <td> 8.78% </td></tr><tr><td> After installation</td><td> June 14th </td><td> 61.3 </td><td> 28.1 </ Td></tr><tr><td> not installed</td><td> June 3rd</td><td> 70 </td><td> 30.2 </td><td> 7.6 < /td><td> 10.86% </td></tr><tr><td> After installation</td><td> June 20th</td><td> 62.4 </td><td> 30.1 </td></tr><tr><td></td><td></td><td><b>average energy saving rate</b></td><td></td> <td></td><td><b>8.32%</b></td></tr></TBODY></TABLE> Table 4 <TABLE border="1" borderColor="#000000" width="85%"><TBODY><tr><td><b>Status</b></td><td><b>Date</ b></td><td><b>Air conditioning total electricity consumption (kWh)</b></td><td><b>day average temperature</b><b>(</b><b >°C)</b></td><td><b>Power consumption difference (kWh)</b></td><td><b>energy saving rate</b></td></tr ><tr><td> Not Installed</td><td> May 29th</td><td> 68.3 </td><td> 30.9 </td><td> -9.8 </td>< Td> -14.30% </td></tr><tr><td> After installation</td><td> June 12th </td><td> 78.1 </td><td> 30.7 </ Td></tr><tr><td> not installed</td><td> June 2nd</td><td> 64.4 </td><td> 29.6 </td><td> -3.9 </td><td> -6.10% </td></tr><tr><td> After installation</td><td> June 13th </td><td> 68.3 </td>< Td> 29.2 </td></tr><tr><td> not installed</td><td> June 5th </td><td> 69.7 </td><td> 30.3 </td> <td> -3.7 </td><td> -5.30% </td></tr><tr><td> After installation</td><td> June 9th </td><td> 73.4 </td><td> 30.4 </td></tr><tr><td></td><td></td><td><b>average energy saving rate</b></td> <td></td><td></td><td><b>-8.60%</b></td></tr></TBODY></TABLE>
在表3的3組對照數據中,安裝後的空調總用電量皆低於未安裝的空調總用電量,平均節能率係為8.32%。然而,在表4的3組對照數據中,安裝後的空調總用電量皆高於未安裝的空調總用電量,平均節能率係為-8.60%。綜合上述表3及表4的對照結果,可了解比較例1之具有六角形孔洞的濾網並無法有效地降低用電量。In the three sets of control data in Table 3, the total electricity consumption of the installed air conditioners is lower than the total installed electricity consumption of the air conditioners, and the average energy saving rate is 8.32%. However, in the three sets of control data in Table 4, the total power consumption of the air conditioner after installation is higher than the total power consumption of the unmounted air conditioner, and the average energy saving rate is -8.60%. Based on the comparison results of Tables 3 and 4 above, it can be understood that the screen having the hexagonal holes of Comparative Example 1 cannot effectively reduce the amount of electricity used.
對照測試例1及測試例2的測試結果,可了解相較於比較例1之具有六角形孔洞的濾網,實施例1之具有圓形孔洞的濾網,藉由特殊的孔洞形狀以及特定之孔洞所佔板體的面積,可達成優異的節能效果。Comparing the test results of Test Example 1 and Test Example 2, it is understood that the screen having the hexagonal holes of Comparative Example 1 has the mesh having the circular holes of Embodiment 1, by the special hole shape and the specific shape. The area occupied by the holes can achieve excellent energy saving effects.
實施例Example 22
實施例2之用於空調裝置之濾網大致上與實施例1相同,二者的差異僅在於圓形孔洞的細部結構,以及板體之材料。The screen for the air conditioner of Embodiment 2 is substantially the same as that of Embodiment 1, and the difference between them is only the detailed structure of the circular hole, and the material of the plate.
在圓形孔洞的細部結構方面,圖7係為本創作實施例2之用於空調裝置之濾網的放大側視圖。在圖7中,實施例2之板體11的厚度T1係為3 mm。圓形孔洞12之孔徑係自該板體11之一面逐漸朝該板體11的另一面縮小,於板體11之一面孔徑R3係為9 mm,於板體11之另一面孔徑R4係為8.48 mm,圓形孔洞12之平均孔徑係為8.74 mm,二個圓形孔洞12的軸心間的最近距離D2係為12 mm,孔壁16之斜面與圓形孔洞12之軸心之間的角度A1係為5°。In the detailed structure of the circular hole, Fig. 7 is an enlarged side view of the screen for the air conditioner of the second embodiment. In Fig. 7, the thickness T1 of the plate body 11 of the second embodiment is 3 mm. The aperture of the circular hole 12 is gradually reduced from the surface of the plate body 11 toward the other surface of the plate body 11. The aperture R3 of the plate body 11 is 9 mm, and the aperture R4 of the plate body 11 is 8.48. Mm, the average hole diameter of the circular hole 12 is 8.74 mm, and the closest distance D2 between the axes of the two circular holes 12 is 12 mm, and the angle between the inclined surface of the hole wall 16 and the axis of the circular hole 12 The A1 system is 5°.
實施例2之用於空調裝置之濾網,可裝設與空調設備的室外機及室內機的入風口及出風口,藉此過濾進出該空調設備的空氣。於裝設實施例2之濾網時,較佳係使氣流沿著圖7所示之方向F流動,藉由圓形孔洞之孔徑係自該板體之一面逐漸朝該板體的另一面縮小之特點,使該氣流能更為集中地進出該空調設備,可進一步提升該空調設備的熱交換效能,藉此達成進一步減少用電量,以獲得節能、省電之功效。The screen for the air conditioner of the second embodiment can be installed with the air inlet and the air outlet of the outdoor unit and the indoor unit of the air conditioner, thereby filtering the air entering and leaving the air conditioner. When the screen of Embodiment 2 is installed, it is preferred that the air flow flows in the direction F shown in FIG. 7, and the aperture of the circular hole gradually decreases from one surface of the plate toward the other side of the plate. The utility model enables the airflow to enter and exit the air conditioner more intensively, thereby further improving the heat exchange performance of the air conditioner, thereby achieving further reduction of power consumption to obtain energy saving and power saving effects.
在板體之材料方面,實施例2之濾網的板體係包含:20 %的遠紅外線材料;75 % 的聚丙烯;以及5 %的負離子材料。其中,該遠紅外線材料係包含:60~70 %的SiO 2;17~23 %的Al 2O 3;2 %的Na 2O 3;5 %的K 2O;2.50 %的MgO;4.50 %的ZnO;以及1 %的B 2O 3;其中,該負離子材料係為TiO 2。 In terms of the material of the plate, the plate system of the sieve of Example 2 comprises: 20% far infrared material; 75% polypropylene; and 5% negative ion material. Wherein, the far-infrared material comprises: 60-70% SiO 2 ; 17-23% Al 2 O 3 ; 2% Na 2 O 3 ; 5% K 2 O; 2.50% MgO; 4.50% ZnO; and 1% B 2 O 3 ; wherein the negative ion material is TiO 2 .
實施例2之濾網藉由負離子材料的添加,可進一步提升該空調設備的熱交換效能,藉此達成進一步減少用電量,以獲得節能、省電之功效。The filter of the second embodiment can further improve the heat exchange performance of the air conditioner by adding the negative ion material, thereby achieving further reduction of power consumption to obtain energy saving and power saving effects.
實施例Example 33
實施例3之用於空調裝置之濾網大致上與實施例1相同,二者的差異僅在於圓形孔洞的細部結構,以及實施例3之濾網係進一步包含塗佈於板體表面的奈米銀。The screen for the air conditioner of Embodiment 3 is substantially the same as that of Embodiment 1, and the difference is only in the detailed structure of the circular hole, and the screen system of Embodiment 3 further includes the Nai coated on the surface of the board. Rice silver.
在圓形孔洞的細部結構方面,圖8係為本創作實施例3之用於空調裝置之濾網的放大側視圖。在圖8中,實施例3之板體11的厚度T1係為3 mm。圓形孔洞12之孔徑係自該板體11之一面逐漸朝該板體11的另一面縮小,且圓形孔洞12之孔壁16與板體11的一面間係形成一圓角17。於圓角17與板體11之一面的交接處,孔徑R5係為10.83 mm,於該圓角與孔壁的交接處,孔徑R6係為8.84 mm,於板體11之另一面孔徑R7係為8.48 mm,圓形孔洞12之平均孔徑大約為9 mm。二個圓形孔洞12的軸心間的最近距離D2係為12 mm,孔壁16之斜面與圓形孔洞12之軸心之間的角度A1係為5°。In the detailed structure of the circular hole, Fig. 8 is an enlarged side view of the screen for the air conditioner of the third embodiment. In Fig. 8, the thickness T1 of the plate body 11 of the embodiment 3 is 3 mm. The aperture of the circular hole 12 is gradually reduced from one surface of the plate body 11 toward the other surface of the plate body 11, and a hole 17 is formed between the hole wall 16 of the circular hole 12 and one side of the plate body 11. At the intersection of the fillet 17 and one of the faces of the plate 11, the aperture R5 is 10.83 mm. At the intersection of the fillet and the hole wall, the aperture R6 is 8.84 mm, and the aperture R7 on the other side of the plate 11 is At 8.48 mm, the circular bore 12 has an average pore size of approximately 9 mm. The closest distance D2 between the axes of the two circular holes 12 is 12 mm, and the angle A1 between the inclined surface of the hole wall 16 and the axis of the circular hole 12 is 5°.
實施例3之用於空調裝置之濾網,可裝設與空調設備的室外機及室內機的入風口及出風口,藉此過濾進出該空調設備的空氣。於裝設實施例3之濾網時,較佳係使氣流沿著圖8所示之方向F流動,藉由圓形孔洞之孔壁與該板體的一面間係形成一圓角特點,使該氣流能更為平順地進出該空調設備,可進一步提升該空調設備的熱交換效能,藉此達成進一步減少用電量,以獲得節能、省電之功效。The screen for the air conditioner of the third embodiment can be installed with the air inlet and the air outlet of the outdoor unit and the indoor unit of the air conditioner, thereby filtering the air entering and leaving the air conditioner. When the filter screen of Embodiment 3 is installed, it is preferred that the air flow flows in the direction F shown in FIG. 8 , and the hole wall of the circular hole and the one side of the plate body form a rounded feature. The airflow can enter and exit the air conditioner more smoothly, and the heat exchange performance of the air conditioner can be further improved, thereby further reducing the power consumption to obtain energy saving and power saving effects.
在板體之材料方面,實施例3之濾網的板體係包含:25 %的遠紅外線材料;以及75 % 的聚丙烯。實施例3的濾網,進一步包含塗佈於板體表面的奈米銀,形成一奈米銀塗層。該奈米銀塗層之重量係為該板體重量的5%。In terms of the material of the plate, the plate system of the sieve of Example 3 comprises: 25% far infrared material; and 75% polypropylene. The screen of Example 3 further comprising nano silver coated on the surface of the plate to form a nano silver coating. The weight of the nano silver coating is 5% by weight of the board.
實施例3之濾網進一步包含塗佈於板體表面的奈米銀,可藉由奈米銀的抗菌能力及空調裝置所帶動的空氣循環,來充分達成淨化空氣的效果。The screen of Example 3 further comprises nano silver coated on the surface of the plate body, and the effect of purifying the air can be fully achieved by the antibacterial ability of the nano silver and the air circulation by the air conditioner.
本創作在上文中已以較佳實施例揭露,然熟習本項技術者應理解的是,該實施例僅用於描繪本創作,而不應解讀為限制本創作之範圍。應注意的是,舉凡與該實施例等效之變化與置換,均應設為涵蓋於本創作之範疇內。因此,本創作之保護範圍當以申請專利範圍所界定者為準。The present invention has been disclosed in the above preferred embodiments, and it should be understood by those skilled in the art that the present invention is only intended to depict the present invention and should not be construed as limiting the scope of the present invention. It should be noted that variations and permutations equivalent to those of the embodiments are intended to be included within the scope of the present invention. Therefore, the scope of protection of this creation is subject to the definition of the scope of patent application.
10‧‧‧濾網
11‧‧‧板體
12‧‧‧圓形孔洞
13‧‧‧公卡榫
14‧‧‧母卡榫
15‧‧‧軸心
16‧‧‧孔壁
17‧‧‧圓角
L1‧‧‧長度
W1‧‧‧寬度
T1‧‧‧厚度
S1‧‧‧深度
D1‧‧‧距離
D2‧‧‧距離
R1‧‧‧直徑
R2‧‧‧孔徑
R3‧‧‧孔徑
R4‧‧‧孔徑
R5‧‧‧孔徑
R6‧‧‧孔徑
R7‧‧‧孔徑
F‧‧‧方向10‧‧‧ Filter
11‧‧‧ board
12‧‧‧Circular holes
13‧‧‧ Public Card
14‧‧‧ mother card
15‧‧‧Axis
16‧‧‧ hole wall
17‧‧‧ fillet
L1‧‧‧ length
W1‧‧‧Width
T1‧‧‧ thickness
S1‧‧ depth
D1‧‧‧ distance
D2‧‧‧ distance
R1‧‧‧ diameter
R2‧‧‧ aperture
R3‧‧‧ aperture
R4‧‧‧ aperture
R5‧‧‧ aperture
R6‧‧‧ aperture
R7‧‧‧ aperture
F‧‧‧ directions
[圖1]係為本創作實施例1之用於空調裝置之濾網的正面視圖 [圖2]係為本創作實施例1之用於空調裝置之濾網的背面視圖 [圖3]係為本創作實施例1之用於空調裝置之濾網的上視圖 [圖4]係為沿圖3之A-A切面的剖面圖 [圖5]係為沿圖3之B-B切面的剖面圖 [圖6]係為本創作實施例1之用於空調裝置之濾網的放大側視圖 [圖7]係為本創作實施例2之用於空調裝置之濾網的放大側視圖 [圖8]係為本創作實施例3之用於空調裝置之濾網的放大側視圖1 is a front view of a screen for an air conditioner according to the first embodiment of the present invention. FIG. 2 is a rear view of the screen for an air conditioner according to the first embodiment [FIG. 3]. The top view of the screen for the air conditioner of the first embodiment of the present invention [Fig. 4] is a cross-sectional view taken along line AA of Fig. 3 [Fig. 5] is a sectional view taken along line BB of Fig. 3 [Fig. 6] An enlarged side view of the screen for the air conditioner of the first embodiment of the present invention [Fig. 7] is an enlarged side view of the screen for the air conditioner of the second embodiment [Fig. 8] Magnified side view of the screen for the air conditioner of Embodiment 3
10‧‧‧濾網 10‧‧‧ Filter
11‧‧‧板體 11‧‧‧ board
12‧‧‧圓形孔洞 12‧‧‧Circular holes
13‧‧‧公卡榫 13‧‧‧ Public Card
14‧‧‧母卡榫 14‧‧‧ mother card
Claims (10)
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| TW105203757U TWM523826U (en) | 2016-03-18 | 2016-03-18 | Filter for air conditioner |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| TW105203757U TWM523826U (en) | 2016-03-18 | 2016-03-18 | Filter for air conditioner |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| TWM523826U true TWM523826U (en) | 2016-06-11 |
Family
ID=56757239
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| TW105203757U TWM523826U (en) | 2016-03-18 | 2016-03-18 | Filter for air conditioner |
Country Status (1)
| Country | Link |
|---|---|
| TW (1) | TWM523826U (en) |
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN107166572A (en) * | 2017-05-16 | 2017-09-15 | 成都振中电气有限公司 | A kind of filter for solar airconditioning |
| TWI781425B (en) * | 2019-07-25 | 2022-10-21 | 日商王子控股股份有限公司 | Deodorizing structure and housing |
-
2016
- 2016-03-18 TW TW105203757U patent/TWM523826U/en not_active IP Right Cessation
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN107166572A (en) * | 2017-05-16 | 2017-09-15 | 成都振中电气有限公司 | A kind of filter for solar airconditioning |
| TWI781425B (en) * | 2019-07-25 | 2022-10-21 | 日商王子控股股份有限公司 | Deodorizing structure and housing |
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| Date | Code | Title | Description |
|---|---|---|---|
| MM4K | Annulment or lapse of a utility model due to non-payment of fees |