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Photon energy ceramic powder and preparation method thereof

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Publication number
CN101062861A
CN101062861A CN 200610060493 CN200610060493A CN101062861A CN 101062861 A CN101062861 A CN 101062861A CN 200610060493 CN200610060493 CN 200610060493 CN 200610060493 A CN200610060493 A CN 200610060493A CN 101062861 A CN101062861 A CN 101062861A
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photon
energy
radiation
ceramic
electromagnetic
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CN 200610060493
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Chinese (zh)
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阙山财
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阙山财
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Abstract

The invention discloses a photon energy ceramic powder and preparing method, which comprises the following steps: allocating mass percent with 10%-15% clay, 10%-25% phyllite, 40%-50% tourmaline, 5%-10% potash feldspar, 5%-10% albite, 5%-10% schreyerite ore and 5%-10% copper oxide; getting the product. This photon energy ceramic powder can transfer harmful electromagnetic radiation to far-infrared electromagnetic radiation, which provides a electronic component to absorb electromagnetic radiation.

Description

光子能量陶瓷粉及其制备方法 Photon energy ceramic powder and preparation method

技术领域 FIELD

本发明是有关于一种光子能量陶瓷粉及其制备方法,特别是指一种具有可将热能及有害于人体的电磁辐射吸收,并转换成对人体有益的远红外波的陶瓷粉。 The present invention relates to a photon energy of ceramic powder and its preparation method, especially to a thermal energy and having a harmful electromagnetic radiation absorbing body, and translate into beneficial far-infrared ceramic powder wave.

背景技术 Background technique

一般电机设备或电子设备均具有许多电子零组件,而当该电机或电子设备在运作时,其电子零组件就会产生热能和电磁辐射。 Motors or electronic device typically has a number of electronic components, and when the operation of electrical or electronic equipment, electronic components which will produce heat and electromagnetic radiation.

电子零组件所产生的热能会使其温度升高而影响该电机或电子设备的效能,进而会使电机或电子设备因温度过高而导致有当机的情形发生,因此,电子零组件所产生的热能必须有效的发散才不致于影响其工作效能。 Heat generated by electronic components will raise the temperature of the machine or affect the performance of the electronic device, the electronic device further causes the motor or due to high temperatures resulting in a crash situation occurs, therefore, the generated electronic components heat must be effective and avoid divergence affecting the efficacy.

如图1所示,就现有电子元件7的散热方式而言,其大抵使用一散热鳍片组8,紧靠在该电子元件7上,该电子元件7所产生的热能被传导至该散热鳍片组8,再利用风对流的方式而将该散热鳍片组8上所聚积的热能带走。 1, prior to cooling mode electronic element 7, the use of which is probably a fin assembly 8, abuts against the electronic component 7, the heat generated by the electronic component 7 is conducted to the heat sink fin assembly 8, and then the heat sink fins 8 on the accumulated heat away using air convection.

此外,电子零组件在运作时不但会产生热量亦会产生电磁辐射波,该电磁辐射波不但会影响其他邻近电子零组件的寿命,也会对人体的健康有害。 In addition, electronic components not only the heat generated during the operation will produce electromagnetic radiation, the electromagnetic radiation will not only affect the life of other nearby electronic components, will be harmful to human health.

如图2所示,现有的用于电子元件7的电磁辐射处理方式,是为使用一包覆金属9包覆该产生电磁辐射的电子元件7,用以遮蔽该电子元件7所产生的电磁辐射。 , The conventional electromagnetic radiation treatment for an electronic component 7 in FIG. 2, electronic components 7 to 9 using a metal cladding covering the generated electromagnetic radiation, electromagnetic shielding for the electronic component generated 7 radiation.

于是,本发明人有感上述问题的可改善,乃潜心研究并配合学理的运用,而提出一种设计合理且有效改善上述问题的本发明。 Thus, the present inventors have felt the above problems can be improved, is the experience and research to apply theoretical, while the present invention has reasonable design and improve these issues.

发明内容 SUMMARY

本发明的主要目的在于提供一种光子能量陶瓷粉及其制备方法,该光子能量陶瓷粉具有将热能及有害于人体的电磁辐射吸收,并转换成对人体有益的远红外波。 The main object of the present invention is to provide a photon energy of ceramic powder and a preparation method, the ceramic powder having a photon energy and thermal energy are harmful to the human body of electromagnetic radiation absorption, and translate into beneficial far-infrared waves.

为达成上述目的,本发明提供一种光子能量陶瓷粉,包括一粘土,其占重量比的10%至15%;一千枚岩,其占重量比的10%至25%;一电气石,其占重量比的40%至50%;一钾长石,其占重量比的5%至10%;一钠长石,其占重量比的5%至10%;一钒钛矿石,其占重量比的5%至10%;以及一氧化铜,其占重量比的5%至10%。 To achieve the above object, the present invention provides a ceramic powder photon energy, including a clay, which accounts for 10-15% by weight; and one thousand rock, which accounts for 10-25% by weight; and a tourmaline, which accounts for 40-50% by weight; and a feldspar which 5% to 10% by weight; and a albite, which accounts for a weight ratio of 5-10%; V a titanium ore, which accounts the weight ratio of from 5 to 10%; and a copper oxide, which is 5% to 10% by weight of.

为达成上述目的,本发明另提供一种光子能量陶瓷粉的制备方法,其包括下列步骤:依重量百分比取黏土10%至15%、千枚岩10%至25%、电气石40%至50%、钾长石5%至10%、钠长石5%至10%、钒钛矿石5%至10%、氧化铜5%至10%以及DK2001取10%;将粘土、千枚岩、电气石、钾长石、钠长石及钒钛矿石粉碎过350目筛出;将上述原料放入制丸机内以DK2001均匀喷洒制丸机滚动制丸,至3到8毫米的球体;将上述球体干燥,至含水量小于5%;将干燥后的球体放入烧结炉烧结成瓷;以及将烧结后的球体放入粉碎机加工成500至2000目的粉体。 To achieve the above object, the present invention further provides a process for preparing ceramic powders photon energy, comprising the steps of: taking the percentage by weight 10-15% clay, phyllite 10 to 25%, 50 to 40% tourmaline %, 5-10% potassium feldspar, albite 5 to 10%, vanadium ores 5-10% copper oxide and 5-10% DK2001 take 10%; clay, phyllite, electrical , potassium feldspar, albite, and vanadium ores sifted through a 350 mesh sieve; DK2001 to the above raw materials uniformly sprayed into the pelletizer pill rolling the pelletizer, to 3-8 mm spheres; above sphere dried to a moisture content less than 5%; sphere dried ceramic sintered into a sintering furnace; and spherical sintered into a shredder 500-2000 object processed into powder.

为了能更进一步了解本发明为达成既定目的所采取的技术、方法及功效,请参阅以下有关本发明的详细说明、附图,相信本发明的目的、特征与特点,当可由此得一深入且具体的了解,然而所附图式与附件仅提供参考与说明用,并非用来对本发明加以限制者。 In order to further understanding of the present invention to achieve the intended purpose of the technique employed, the method and effects, please refer to the following detailed description of the invention, drawings, believe objects, features and characteristics of the present invention can thus be obtained when a deep and specifically understood. However, the drawings and annex reference and illustration only, not intended to limit the present invention's.

附图说明 BRIEF DESCRIPTION

图1是现有散热装置的示意图。 1 is a schematic of the conventional heat dissipation device.

图2是现有隔绝电磁辐射装置的示意图。 FIG 2 is a schematic view of the conventional insulating means electromagnetic radiation.

图3是本发明光子能量陶瓷粉使用状态的第一实施例的立体图。 3 is a perspective view of a first embodiment of the photon energy of the ceramic powder embodiment of the present invention use state.

图4是本发明光子能量陶瓷粉使用状态的第二实施例的立体图。 FIG 4 is a perspective view of a second embodiment of the photon energy of the ceramic powder embodiment of the present invention use state.

图5是本发明光子能量陶瓷粉制备方法的步骤流程图。 FIG 5 is a ceramic powder prepared in step photon energy process flowchart of the present invention.

具体实施方式 detailed description

本发明提供一种光子能量陶瓷粉,包括一粘土、一千枚岩、一电气石、一钾长石、一钠长石、一钒钛矿石,以及一氧化铜。 The present invention provides a ceramic powder photon energy, including a clay, rock one thousand, tourmaline, a potash feldspar, albite a, a titanium ore vanadium, and a copper oxide.

该粘土占重量比的10%至15%。 The clay comprises 10-15% by weight.

该千枚岩占重量比的10%至25%。 The phyllite accounts for 10-25% by weight.

该电气石占重量比的40%至50%。 The tourmaline accounting for 40-50% by weight.

该钾长石占重量比的5%至10%。 The Feldspar 5% to 10% by weight of.

该钠长石占重量比的5%至10%。 The albite 5% to 10% by weight of.

该钒钛矿石占重量比的5%至10%。 The vanadium ores 5% to 10% by weight of.

该氧化铜占重量比的5%至10%。 The copper oxide 5% to 10% by weight of.

及本发明光子能量陶瓷粉的制备方法,请参阅图5,包括下列步骤:1、依重量百分比取黏土10%至15%、千枚岩10%至25%、电气石40%至50%、钾长石5%至10%、钠长石5%至10%、钒钛矿石5%至10%、氧化铜5%至10%以及DK2001取10%(S100);该氧化铜为工业级,且该粘土含水量为25%,该DK2001为有机粘合剂,且由重量百分比的酒精10%至30%、硬脂酸丁脂5%至10%、聚乙烯醇30%至50%、乙基苯基乙二醇5%至10%以及甘油5%至10%组成;2、将粘土、千枚岩、电气石、钾长石、钠长石及钒钛矿石粉碎过筛筛出(S102); And photon energy for producing a ceramic powder according to the present invention, see Figure 5, comprising the following steps: 1, by taking the weight percentage from 10 to 15 percent clay, phyllite 10-25%, 40-50% tourmaline, 5-10% potash feldspar, albite 5 to 10%, vanadium ores 5-10% copper oxide and 5-10% DK2001 taking 10% (S100); the technical grade cupric oxide, the clay and water content of 25%, the organic binder is DK2001, and alcohol, by weight percent 10-30%, butylstearate 5-10%, polyvinyl alcohol 30-50%, b phenyl ethylene glycol and 5-10% glycerol 5-10% composition; 2, clay, phyllite, tourmaline, potassium feldspar, albite, and vanadium ores pulverized sieved sieved out (S102 );

3、将上述原料放入制丸机内以DK2001均匀喷洒制丸机滚动制丸,至3到8毫米的球体(S104);4、将上述球体干燥,至含水量小于5%(S106);5、将干燥后的球体放入烧结炉烧结成瓷(S108);其烧结温度大于等于1100℃;6、将烧结后的球体放入粉碎机加工成500至2000目的粉体(S110)。 3, the raw material into the pellet mill to uniformly sprayed DK2001 scrolling pill Pill, to 3-8 mm spheres (S104); 4, the above-described spherical dried to a moisture content of less than 5% (S106); 5, the spheres after drying into a sintering furnace to sinter porcelain (S108); the sintering temperature is higher than 1100 ℃; 6, the sintered spheres into a shredder processed into powder 500-2000 object (S110).

本发明光子能量陶瓷粉可为陶瓷经由气流的气旋所粉碎加工而成的一种高能量粉体材料,该光子能量陶瓷粉为一种能量转换的载体,该光子能量陶瓷粉对于热、光、电、和磁有良好的匹配吸收功效。 Ceramic powder of the present invention, the photon energy can be a high-energy ceramic powder material is processed via a cyclonic airflow pulverized, the photon energy conversion ceramic powder as a carrier of energy, photon energy of the ceramic powder to heat, light, electrical, magnetic and have a good match absorption effect. 该光子能量陶瓷粉能够吸收热、光、电、和磁的能量,以形成该光子能量陶瓷粉本身的电子跃迁所需的能量,并转换成为2至18微波米的电磁辐射,以发射出去,且该电磁辐射的发射率可为0.93。 The ceramic powder can be absorbed photon energy is thermal energy, light, electricity, magnetism, and so as to form the photon energy required energy electronic transitions ceramic powder itself, and converted into electromagnetic radiation of 2-18 micro Bomi to emit out, and the emission of electromagnetic radiation may be 0.93.

该2至18微波米的电磁辐射能够作用于含有氢键的双原子和多原子分子的物体,以引起该物体的分子运动,从而产生温热效应。 The electromagnetic radiation is 2-18 micro Bomi capable of acting on the object and diatomic hydrogen-containing polyatomic molecules to induce molecular movement of the object, thereby generating thermal effects.

该2至18微波米的电磁辐射不是一种热介质,而是能够被该物体所吸收而产生作用的一种热效应。 The electromagnetic micro Bomi 2-18 radiant heat is not a medium, but can be to produce a thermal effect and the absorption of the object. 换言之,该物体产生热能与否,是取决于该物体是否吸收该2至18微波米的电磁辐射。 In other words, the object to generate thermal energy or not, depending on whether the object is absorbing the electromagnetic radiation of 2-18 micro Bomi.

如图3所示,该光子能量陶瓷粉1被制成涂料后涂抹于一导热基板2上,该导热基板2将热量由发热源传导至该光子能量陶瓷粉1,该光子能量陶瓷粉1直接将该热量吸收,兼以将邻近电子元件所发出的电磁辐射吸收后,将该热量与该电磁辐射转换为不被金属材料所吸收的2至18微波米的电磁辐射,而以光量子的形式散掉,或转为远红外电磁辐射,藉此提供一散热功效,并提供一吸收电磁辐射功效,且该远红外电磁辐射进一步有益于人体。 3, the photon energy of the ceramic powder 1 is made to apply a coating to a metal substrate 2, the substrate 2 is thermally conduct heat from the heat source to the photon energy of a ceramic powder, the ceramic powder 1 photon energy directly the heat absorption, and to the absorption of electromagnetic radiation emitted by electronic components adjacent to, the heat of the electromagnetic radiation into electromagnetic radiation 2-18 micro Bomi is not absorbed by the metal material, and scattered photons to form off, or turned into a far-infrared electromagnetic radiation, thereby providing a cooling effect and provide a infrared electromagnetic radiation absorbing electromagnetic radiation effect, and that is far more beneficial to the body.

如图4所示,为本发明光子能量陶瓷粉的第二实施例,该光子能量陶瓷粉1被制成涂料后直接涂抹于该电子元件3之上,直接吸收该电子元件3所散发出的热量以及电磁辐射,如此将能更快、更有效率的达到散热与吸收电磁辐射的功效。 4, a second embodiment of the present invention, the photon energy of the ceramic powder, the ceramic powder 1 photon energy is directly applied to the coating formed on the electronic component 3, the electronic component 3 directly absorbed exudes heat and electromagnetic radiation, so it will be faster, more efficient and achieve cooling effect absorption of electromagnetic radiation.

以上所述仅为本发明的较佳可行实施例,非因此即局限本发明的专利保护范围,故举凡运用本发明说明书及附图内容所作的等效技术变化,均同理皆包含在本发明的保护范围内。 The above are only preferred embodiments of the present invention are possible, i.e. non thus limited the scope of protection of the present invention, it is covered the use of the specification and drawings of the present invention taken equivalent technical changes are included in the present invention are empathy within the scope of protection.

Claims (9)

1.一种光子能量陶瓷粉,其特征在于,包括:一粘土,其占重量比的10%至15%;一千枚岩,其占重量比的10%至25%;一电气石,其占重量比的40%至50%;一钾长石,其占重量比的5%至10%;一钠长石,其占重量比的5%至10%;一钒钛矿石,其占重量比的5%至10%;以及一氧化铜,其占重量比的5%至10%。 A photon energy ceramic powder, characterized by comprising: a clay which accounts for 10-15% by weight; and one thousand rock, which accounts for 10-25% by weight; and a tourmaline, which accounting for the weight ratio of 40-50 percent; a feldspar which 5% to 10% by weight; and a albite, which accounts for a weight ratio of 5-10%; V a titanium ore, which accounts weight ratio from 5 to 10%; and a copper oxide, which is 5% to 10% by weight of.
2.如权利要求1所述的光子能量陶瓷粉,其特征在于,该光子能量陶瓷粉进一步包含DK2001。 The photon energy of the ceramic powder as claimed in claim 1, wherein the ceramic powder further comprises a photon energy DK2001.
3.如权利要求2所述的光子能量陶瓷粉,其特征在于,该DK2001为有机粘合剂。 The photon energy of the ceramic powder as claimed in claim 2, wherein the binder is an organic DK2001.
4.如权利要求1所述的光子能量陶瓷粉,其特征在于,该氧化铜为工业级。 4. The photon energy of the ceramic powder as claimed in claim 1, wherein the copper oxide industrial grade.
5.如权利要求1所述的光子能量陶瓷粉,其特征在于,该粘土含水量为25%。 The photon energy of the ceramic powder as claimed in claim 1, wherein the water content of 25% clay.
6.如权利要求1所述的光子能量陶瓷粉,其特征在于,该光子能量陶瓷粉粉体大小为500至2000目不等。 The photon energy of the ceramic powder as claimed in claim 1, wherein the photon energy of another on the ceramic body sizes ranging from 500 to 2000 mesh.
7.一种光子能量陶瓷粉的制备方法,其特征在于,包括下列步骤:依重量百分比取黏土10%至15%、千枚岩10%至25%、电气石40%至50%、钾长石5%至10%、钠长石5%至10%、钒钛矿石5%至10%、氧化铜5%至10%以及DK2001取10%;将粘土、千枚岩、电气石、钾长石、钠长石及钒钛矿石粉碎过筛筛出;将上述原料放入制丸机内以DK2001均匀喷洒制丸机滚动制丸,至3到8毫米的球体;将上述球体干燥,至含水量小于5%;将干燥后的球体放入烧结炉烧结成瓷;以及将烧结后的球体放入粉碎机加工成500至2000目的粉体。 A method for preparing ceramic powders photon energy, characterized by comprising the steps of: taking the percentage by weight 10-15% clay, phyllite 10-25%, 40-50% tourmaline, K-feldspar stone 5-10%, albite 5 to 10%, vanadium ores from 5 to 10%, copper oxide, 5 to 10% and 10% take DK2001; clay, phyllite, tourmaline, K-feldspar stone, albite pulverized and sieved vanadium ores sieved; DK2001 to the above raw materials uniformly sprayed into the pelletizer pill rolling the pelletizer, to 3-8 mm spheres; dried spherical above, to a solution of water is less than 5%; sphere dried ceramic sintered into a sintering furnace; and spherical sintered into a shredder 500-2000 object processed into powder.
8.如权利要求7所述的光子能量陶瓷粉的制备方法,其特征在于,该烧结步骤采用烧结温度大于等于1100℃。 8. A method for preparing ceramic powders of the photon energy as claimed in claim 7, wherein the sintering step employs a sintering temperature is higher than 1100 ℃.
9.如权利要求7所述的光子能量陶瓷粉的制备方法,其特征在于,该DK2001由重量百分比的酒精10%至30%、硬脂酸丁脂5%至10%、聚乙烯醇30%至50%、乙基苯基乙二醇5%至10%以及甘油5%至10%组成。 Photon energy for producing a ceramic powder according to claim 7, characterized in that the DK2001 alcohol, by weight percent 10-30%, butylstearate 5-10% polyvinyl alcohol 30% to 50%, ethylphenyl glycol 5-10% and 5-10% glycerol composition.
CN 200610060493 2006-04-26 2006-04-26 Photon energy ceramic powder and preparation method thereof CN101062861A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101913849A (en) * 2010-09-04 2010-12-15 淄博博纳科技发展有限公司 Heat-resistant ceramic for kitchen ware
US20120270034A1 (en) * 2008-08-13 2012-10-25 San-Teng Chueh Heat-dissipating structure
CN105344021A (en) * 2015-11-07 2016-02-24 德化均能手造陶瓷有限公司 Optical wafer for activating blood and dredging collaterals

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20120270034A1 (en) * 2008-08-13 2012-10-25 San-Teng Chueh Heat-dissipating structure
CN101913849A (en) * 2010-09-04 2010-12-15 淄博博纳科技发展有限公司 Heat-resistant ceramic for kitchen ware
CN105344021A (en) * 2015-11-07 2016-02-24 德化均能手造陶瓷有限公司 Optical wafer for activating blood and dredging collaterals

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