CN1122043C - Electromagnetized plant protein and its preparing process - Google Patents

Electromagnetized plant protein and its preparing process Download PDF

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Publication number
CN1122043C
CN1122043C CN 98125644 CN98125644A CN1122043C CN 1122043 C CN1122043 C CN 1122043C CN 98125644 CN98125644 CN 98125644 CN 98125644 A CN98125644 A CN 98125644A CN 1122043 C CN1122043 C CN 1122043C
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protein
electromagnetic
plant protein
plant
material
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CN 98125644
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CN1239102A (en
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李建军
曲直
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李建军
曲直
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Abstract

一种电磁化植物蛋白及其制备方法和用途。 An electromagnetic plant protein and its preparation method and application. 从甜菜中提取蛋白体,经高强电磁场进行交换式反应后,将甜菜蛋白体中官能团的分子形成在蛋白体中分子氢键鳖合环光化学反应,产生鳖合环状物质。 Proteins were extracted from sugar beet material, the reaction was carried switched high strength electromagnetic fields, beet proteosome molecule a functional group formed hydrogen bonds in the protein molecule photochemical reactions rings turtle, turtle together to produce a cyclic material. 电磁化植物蛋白对波长200nm-300nm之间的高能紫外光具有强烈吸收作用,可将波长较短的高能光,转变为波长较长的低能光,以低热能释放。 Electromagnetic plant protein having high-energy ultraviolet wavelength between 200nm-300nm strong absorption, the wavelength may be shorter high-energy light, longer wavelength into light of low energy, low heat release. 可应用于灭火,也可适用于植物蛋白的应用研究。 Fire can be applied, it is applicable to the application of plant proteins.

Description

电磁化植物蛋白及其制备方法 Electromagnetic plant protein and preparation method

技术领域 FIELD

:本发明属于生物化学和分子生物学领域,尤其是一种植物蛋白及其制备方法。 : The present invention belongs to the field of molecular biology and biochemistry, and in particular a plant protein preparation.

背景技术 Background technique

:天然植物蛋白在生物学、营养学、食品添加剂、饲料添加剂和植物蛋白灭火剂等方面均有广泛应用。 : Natural plant proteins are widely used in biology, nutrition, food additives, feed additives and vegetable proteins fire extinguishing agent aspects. 但将植物蛋白磁化、改性后的应用研究很少,目前尚未发现用磁化后的植物蛋白作应用研究的报导。 But the vegetable protein magnetization, application of the modified very little research has not yet reported the application of plant protein for use after the magnetization found. 目前国内外对植物蛋白停留在提取粗蛋白直接应用在医药保健品、食品添加剂、饲料添加剂和植物蛋白灭火剂等方面,没有做植物蛋白的深层次应用研究和化学结构测定。 At home and abroad to stay in the vegetable protein extract crude protein directly applied in medicine and health products, food additives, feed additives and vegetable proteins terms of fire extinguishing agent, do not plant protein-depth research and application of chemical structure determination.

发明内容 SUMMARY

:本发明的是提供一种磁化改性的植物蛋白,改变甜菜蛋白的化学结构,使磁化后的植物蛋白能吸收能量从而用于灭火。 : The present invention is to provide a modified vegetable protein magnetization, altering the chemical structure of the beet proteins, plant protein so magnetized so as to absorb energy for extinguishing.

本发明的电磁化植物蛋白,为甜菜蛋白,含有氢键鰲合环结构,含有如下的化学结构(R=-CnH2n+1) Electromagnetic plant protein of the invention, the protein is a sugar beet, hydrogen containing chelate ring structure, containing the following chemical structure (R = -CnH2n + 1) 制备该电磁化植物蛋白的方法,其步骤为:(1)提炼植物蛋白体;(2)活化和膨化植物蛋白体;(3)将膨化后的植物蛋白体送入电磁化机管道中进行磁化。 The method of preparing an electromagnetic vegetable protein, comprising the steps of: (1) refined plant protein material; (2) activation and extruded vegetable protein material; (3) the plant protein material into the puffing machine of the solenoid magnetization conduit .

提炼植物蛋白体是从甜菜中提取蛋白体原液,用现有工业蛋白萃取设备提炼甜菜中蛋白体,用180#过滤筛筛选作为磁化蛋白体原料。 Refined vegetable protein material is extracted from sugar beet body protein stock solution, extracted beet proteosome protein by conventional industrial extraction equipment, filtered with 180 mesh filter # magnetization protein raw material.

活化和膨化植物蛋白体是将提练的蛋白体溶于蒸馏水中,加入氟表面活性剂倒入反应釜中预混20分钟,然后倒入高压反应釜中在0.4MP-0.6MP和45℃-65℃之间反应;反应釜转速15-20转/分,反应时间为40分钟;将反应后的蛋白液用180#过滤筛筛选。 Activation and extruded vegetable protein material is a material extraction of proteins dissolved in distilled water, was added fluorine surfactant premix was poured into the kettle for 20 minutes, then poured into the autoclave and 0.4MP-0.6MP 45 ℃ - the reaction between 65 deg.] C; 15-20 kettle speed rev / min, the reaction time was 40 minutes; the protein solution after the reaction was filtered with a # 180 mesh filter.

将膨化后的植物蛋白体以900-1000克/分的流量送入电磁化机管道中,进行360度方向间歇磁化,磁场强度为18000-22000高斯。 The vegetable protein material to flow after puffing 900-1000 g / min into an electromagnetic machine of the pipeline, 360 the magnetization direction intermittently, 18000-22000 Gauss magnetic field intensity.

所述磁场分为五段,每段三个磁极,磁化方向相同,段与段之间距离为2000毫米,段与段之间中心点强屏蔽到5高斯以下。 The field is divided into five sections, each section three poles of the same magnetization direction, the distance between paragraphs is 2000 mm, the center point between paragraphs strong shield to 5 gauss or less.

由于植物蛋白体被高强磁化后,所形成氢键鰲合环可起到光化学作用。 Since the plant protein material is magnetized high strength, the hydrogen bonded chelate ring formed may serve photochemistry. 根据爱因斯坦光化学定律,每一个光子只能活化一个分子,同一分子在同一瞬间只能吸收一个光子。 According to Einstein's law of photochemical, each photon can only be activated a molecule, at the same moment the same molecule can only absorb a photon. 分子吸收一个光子后,电子发生乐向高能级位的跃迁,发生电子跃迁的分子被称为激发态分子。 After molecule absorbs a photon, electron transition occurs in energy level bit music, electronic transitions molecules excited state is referred to. 吸收和能理等于两定态的能量之差。 And can manage the absorption of energy equal to the difference between two stationary states. 激发态的分子寿命很短,约为10-7-10-9秒左右。 Molecular excited state lifetime is short, is about 10-7-10-9 sec. 激发态分子释放能量后回到基态。 After releasing energy excited state to the ground state. 这些准稳定的激发态分子向其他分子转移能量和产生自由基、离子能等活性物质,从而发生光化学反应。 These metastable excited state energy transfer to other molecules and produce free radicals, ions and other active substances can thereby photochemical reaction.

物质在燃烧过程中不断发出高能量光量子,这些光是子的波长比较短,能量比较高。 Substance continuously emitted during combustion of high energy photons, whose wavelengths are relatively short sub-light, relatively high energy. 根据这一原理,被高强磁化过程中植物蛋白体官能团分子形成氢键鰲合环,和光激发官能团物质,可以有选择的强烈吸收某一波长段光量子,氢键鰲合环中的电子发生跃迁,成为激发态,电子所吸收的高能量以更长波长再辐射,高能于是转变成低能,电子回到基态,释放了能量的电子不再会影响燃烧反应。 According to this principle, is formed of high strength magnetization process plant-functional molecules proteosome hydrogen chelating ring, and photoexcitation functional materials, there can be selected a strong absorption of a wavelength band of light quantum, hydrogen bonding chelation ring electrons transition, an excited state, high-energy electrons at a longer wavelength absorbed by reradiation, then converted into low-energy high-energy, electron to the ground state, releasing energy electrons no longer affect the combustion reaction. 这些带有光激发官能团物质,极大地增加蛋白体热溶。 These functional materials with excitation light, greatly increase the body protein thermosol. 所以分子内的氢键鰲合环吸收光量子,吸入的能量切断了氢键鰲合环,伴随这一过程,把有害的波长较短的高能量光转变为波长较长的低能光,以低能释放,这一过程周而复始,因此植物蛋白体中官能团分子内形成氢键越强,能吸收的能量也越高。 Therefore, hydrogen in the chelate ring molecules absorb photons, the energy drawn off the hydrogen chelate ring, with this process, the shorter the wavelength of harmful high energy light into longer wavelength light of low energy, low energy release , this process again and again, so the higher the hydrogen bonds formed absorb the energy of the higher-functional molecules in the endosomes plant protein.

附图说明 BRIEF DESCRIPTION

:图1蛋白分子中形成氢键鰲合环的光吸收性示意图图2光的波长和能量关系图图3光化学反应示意图实施方案:首先选择北纬33度以南生长的甜菜,从中提取蛋白体原液,用现有工业蛋白萃取设备提炼甜菜中蛋白体,用180#过滤筛筛选作为磁化蛋白体粗料。 : FIG. 1 protein molecule forming a schematic view of a light-absorbing chelate ring hydrogen wavelength and energy diagram of FIG. 2 light photochemical reaction schematic of an embodiment 3: Beet first selected 33 degrees south latitude growth, body protein liquid extract , sugar beet extract protein body proteins existing industrial extraction equipment, filtered with 180 mesh filter # magnetization crude protein thereof. 将上述提炼的蛋白体400-500克溶于1000克蒸馏水中,加入氟表面活性剂120克,调整PH值为7.6,倒入反应釜中预混20分钟,搅拌转速15-20转/分;然后倒入高压反应釜中在0.4MP-0.6MP和45℃-65℃之间进行高压和高温反应;反应釜转速15-20转/分,反应时间为40分钟;将反应后的蛋白液用180#过滤筛筛选,此时环境温度控制在40℃-50℃,使蛋白体内分子氨基酸和磷酸脂类物质完全处于活跃和膨化形态。 The proteins of the above refined 400-500 g dissolved in 1000 grams of distilled water, was added 120 grams fluorine surfactant, adjust PH value of 7.6, the premix was poured into the kettle for 20 minutes, stirring speed 15-20 rev / min; then poured into the autoclave high pressure and high temperature reaction between 0.4MP-0.6MP and 45 ℃ -65 ℃; kettle speed 15-20 rev / min, the reaction time was 40 minutes; the protein solution after the reaction with # 180 filter screen filter, this time at controlled temperature 40 ℃ -50 ℃, so that amino acids and protein molecules in vivo phosphorylation of lipids in active and fully expanded form.

将膨化后的植物蛋白体用加压泵以900-1000克/分的流量送入电磁化机管道中,经过五段均布高磁场,进行360度方向间歇磁化,每段三个磁级,磁场强度为18000-22000高斯,磁化方向相同,段与段之间距离为2000毫米,段与段之间中心点场强屏蔽到5高斯以下。 The vegetable protein material after puffing using the pressure pump at a flow rate 900-1000 g / min into an electromagnetic machine of the pipe, uniformly distributed through the five sections of high magnetic field, intermittently magnetization directions 360 degrees, each magnetic three stages, 18000-22000 Gauss magnetic field intensity is the same magnetization direction, the distance between paragraphs is 2000 mm, the center point between paragraphs 5 to field shield gauss or less.

经过反复五段磁化反应就可使得蛋白中的分子形成氢键鰲合环植物蛋白体,用蛋白质分子仪测定烷基酚乙氧基聚合物,其化学结构如下: After repeated five sections can be magnetized such that the reaction to form hydrogen bonds in the protein molecule chelating ring plant protein material, an alkyl phenol ethoxylate polymers measuring instrument protein molecule, its chemical structure is as follows:

Claims (3)

1.一种制备电磁化植物蛋白的方法,其步骤为:(1)提炼植物蛋白体;从甜菜中提取蛋白体原液,用现有工业蛋白萃取设备提炼甜菜中蛋白体,用180#目过滤筛筛选作为磁化蛋白体原料;(2)活化和膨化植物蛋白体;将提练的蛋白体溶于蒸馏水中,加入氟表面活性剂倒入反应釜中预混20分钟,然后倒入高压反应釜中在0.4MP-0.6MP和45℃-65℃之间反应;反应釜转速15-20转/分,反应时间为40分钟;将反应后的蛋白液用180#过滤筛筛选;(3)将膨化后的植物蛋白体送入电磁化机管道中进行磁化;将膨化后的植物蛋白体以900-1000克/分的流量送入电磁化机管道中,进行360度方向间歇磁化,磁场强度为18000-22000高斯。 An electromagnetic method of preparing plant protein, comprising the steps of: (1) refined plant protein material; extracting protein from the liquid body beet, sugar beet extract proteosome protein by conventional industrial extraction equipment, filtered through a # 180 mesh screen for a screening magnetization protein raw material; (2) activation and puffing the vegetable protein material; extraction of the proteosome dissolved in distilled water, was added fluorine surfactant premix was poured into the kettle for 20 minutes, then poured into an autoclave in between 0.4MP-0.6MP and 45 ℃ -65 ℃ reactor; reactor speed 15-20 rev / min, the reaction time was 40 minutes; the protein solution after the reaction was filtered with a # 180 mesh filter; (3) plant protein material into the puffing machine of the solenoid magnetization conduit; vegetable protein material after puffing at a flow rate 900-1000 g / min into an electromagnetic machine of the pipeline, 360 the magnetization direction intermittently, the magnetic field strength is 18000-22000 gauss.
2.如权利要求2所述的制备电磁化植物蛋白的方法,其特征在于所述磁场分为五段,每段三个磁极,磁化方向相同,段与段之间距离为200毫米,段与段之间中心点场强屏蔽到5高斯以下。 The method of preparing an electromagnetic plant protein as claimed in claim 2, wherein said field is divided into five segments, each three poles, the same magnetization direction, the distance between paragraphs 200 mm, segment field shield between the center point of the segment to the 5 gauss or less.
3.一种按照权利要求1所述方法制得的电磁化植物蛋白,为甜菜蛋白,含有氢键鰲合环结构,含有如下的化学结构: 3. A method of claim 1 prepared electromagnetic plant protein according to claim sugarbeet proteins, chelate ring structures containing hydrogen, comprising the following chemical structure:
CN 98125644 1998-12-23 1998-12-23 Electromagnetized plant protein and its preparing process CN1122043C (en)

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CN103041539A (en) * 2010-05-23 2013-04-17 杜志刚 Multi-electron conductive material extinguishing agent
CN103041533A (en) * 2010-05-23 2013-04-17 杜志刚 Multi-electron conductive material extinguishing agent

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5656429A (en) * 1994-10-03 1997-08-12 Adelman; Lonnie W. Polynucleotide and protein analysis method using magnetizable moieties
CN1195481A (en) * 1997-10-27 1998-10-14 高国勤 Method for preparing magnetized drink and food
US5981297A (en) * 1997-02-05 1999-11-09 The United States Of America As Represented By The Secretary Of The Navy Biosensor using magnetically-detected label

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5656429A (en) * 1994-10-03 1997-08-12 Adelman; Lonnie W. Polynucleotide and protein analysis method using magnetizable moieties
US5981297A (en) * 1997-02-05 1999-11-09 The United States Of America As Represented By The Secretary Of The Navy Biosensor using magnetically-detected label
CN1195481A (en) * 1997-10-27 1998-10-14 高国勤 Method for preparing magnetized drink and food

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