Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Infrared energy-saving material and preparation method thereof
The invention discloses an infrared energy-saving material, which is prepared from the following components: 30-40% of thermoplastic elastomer powder, 25-35% of negative ion powder, 30-40% of far infrared ceramic powder and 8-15% of kaolin. The negative ion powder, far-infrared ceramic powder and kaolin are wrapped after thermoplastic elastomer powder is melted into colloid at high temperature. The preparation method comprises the following steps: firstly, uniformly mixing the negative ion powder, the far infrared ceramic powder and the kaolin in parts by weight in a mixer; adding thermoplastic elastomer powder into a granulator, mixing with the mixed thermoplastic elastomer powder, heating, extruding and fusing into colloidal particles through granulator equipment, adhering the thermoplastic elastomer powder, the thermoplastic elastomer powder and the colloidal particles into a mixed material, and molding into the infrared energy-saving material through injection molding equipment. The energy-saving material can release negative ions and far infrared rays at the same time, the release amount of the negative ions exceeds 65000/cm<3>, the air quality of outlet air of air conditioning equipment is improved, the convective heat exchange efficiency of the air conditioning equipment is improved, and energy consumption is reduced.
本发明公开了一种红外节能材料,由以下组份组成:热塑弹性体粉末30‑40%、负离子粉25‑35%、远红外陶瓷粉30‑40%,及高岭土8‑15%;负离子粉、远红外陶瓷粉和高岭土,由热塑弹性体粉末高温熔成胶质后进行包裹。其制备方法如下:首先按重量份将负离子粉、远红外陶瓷粉和高岭土三者在混料机中均匀混合;之后在造粒机中加入热塑弹性体粉末和混合后的三者混合,之后通过造粒机设备加热挤出融合成胶质颗粒,使三者与热塑弹性体粉末粘连成一混合材料,之后通过注塑成型设备成型为所述的红外节能材料。本发明的节能材料能够同时释放负离子和远红外线,负离子的释放量超过65000个/cm,提高了空调设备出风空气质量,又提高了空调设备对流热交换效率,降低能耗。
Infrared energy-saving material and preparation method thereof
The invention discloses an infrared energy-saving material, which is prepared from the following components: 30-40% of thermoplastic elastomer powder, 25-35% of negative ion powder, 30-40% of far infrared ceramic powder and 8-15% of kaolin. The negative ion powder, far-infrared ceramic powder and kaolin are wrapped after thermoplastic elastomer powder is melted into colloid at high temperature. The preparation method comprises the following steps: firstly, uniformly mixing the negative ion powder, the far infrared ceramic powder and the kaolin in parts by weight in a mixer; adding thermoplastic elastomer powder into a granulator, mixing with the mixed thermoplastic elastomer powder, heating, extruding and fusing into colloidal particles through granulator equipment, adhering the thermoplastic elastomer powder, the thermoplastic elastomer powder and the colloidal particles into a mixed material, and molding into the infrared energy-saving material through injection molding equipment. The energy-saving material can release negative ions and far infrared rays at the same time, the release amount of the negative ions exceeds 65000/cm<3>, the air quality of outlet air of air conditioning equipment is improved, the convective heat exchange efficiency of the air conditioning equipment is improved, and energy consumption is reduced.
本发明公开了一种红外节能材料,由以下组份组成:热塑弹性体粉末30‑40%、负离子粉25‑35%、远红外陶瓷粉30‑40%,及高岭土8‑15%;负离子粉、远红外陶瓷粉和高岭土,由热塑弹性体粉末高温熔成胶质后进行包裹。其制备方法如下:首先按重量份将负离子粉、远红外陶瓷粉和高岭土三者在混料机中均匀混合;之后在造粒机中加入热塑弹性体粉末和混合后的三者混合,之后通过造粒机设备加热挤出融合成胶质颗粒,使三者与热塑弹性体粉末粘连成一混合材料,之后通过注塑成型设备成型为所述的红外节能材料。本发明的节能材料能够同时释放负离子和远红外线,负离子的释放量超过65000个/cm,提高了空调设备出风空气质量,又提高了空调设备对流热交换效率,降低能耗。
Infrared energy-saving material and preparation method thereof
一种红外节能材料及其制备方法
CHENG RULIN (Autor:in) / WEI MINGKANG (Autor:in)
10.07.2020
Patent
Elektronische Ressource
Chinesisch
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