A decoloration device for aminobutyric acid zymotic fluid decoloration purification

文档序号:819415 发布日期:2021-03-30 浏览:46次 中文

阅读说明:本技术 一种用于氨基丁酸发酵液脱色纯化的脱色装置 (A decoloration device for aminobutyric acid zymotic fluid decoloration purification ) 是由 梁承� 陈成 邹林君 吴宁 邹仕刚 闭革林 吴志雄 于 2020-11-10 设计创作,主要内容包括:本发明涉及发酵过滤领域,具体公开了一种用于氨基丁酸发酵液脱色纯化的脱色装置,包括内部划分为三层的壳体、若干布置在壳体中层的脱色管、填充各根脱色管的过滤物、水浴模块和进出液口,水浴模块通过水浴方式加热位于壳体中层的各根脱色管,需要过滤的液体从壳体的上层经过各根脱色管流至壳体的下层,其中过滤物包括活性炭和NH2-UiO-66。本方案通过水浴方式能够稳定脱色过程的温度,降低外界环境的干扰,提高分离提纯的稳定性、效率和品质;脱色管采用可拆卸方式安装,方便更换方便维护装置;脱色管内填充了新型的混合物,同时给出了最佳的混合比例,既能提高脱色率,又能降低损失率。(The invention relates to the field of fermentation and filtration, and particularly discloses a decoloring device for decoloring and purifying aminobutyric acid fermentation liquor, which comprises a shell, a plurality of decoloring pipes, a filter, a water bath module and a liquid inlet and outlet, wherein the shell is internally divided into three layers, the decoloring pipes are arranged on the middle layer of the shell, the filter fills each decoloring pipe, the water bath module heats each decoloring pipe on the middle layer of the shell in a water bath mode, liquid to be filtered flows to the lower layer of the shell from the upper layer of the shell through each decoloring pipe, and the filter comprises activated carbon and NH 2-UiO-66. The scheme can stabilize the temperature in the decoloring process in a water bath mode, reduce the interference of the external environment and improve the stability, efficiency and quality of separation and purification; the decolorizing tube is detachably mounted, so that the device is convenient to replace and maintain; the decoloring pipe is filled with a novel mixture, and the optimal mixing proportion is given, so that the decoloring rate can be improved, and the loss rate can be reduced.)

1. A decoloration device for decoloration and purification of aminobutyric acid fermentation liquid is characterized by comprising:

the shell is of a revolving body structure, two partition plates which are respectively positioned at different heights are arranged in the shell, the two partition plates divide the interior of the shell into an upper layer space, a middle layer space and a lower layer space, a liquid inlet communicated with the upper layer is formed in the top of the shell, and a liquid outlet communicated with the lower layer is formed in the bottom of the shell;

the decolorizing tubes are made of heat-conducting materials and are uniformly distributed in the middle layer of the shell, the head and the tail ends of the decolorizing tubes are connected with the upper partition plate and the lower partition plate, the upper layer and the lower layer in the shell are communicated through the decolorizing tubes, the middle layer of the shell is not communicated with the upper layer and the lower layer, and the filter substances filled in the decolorizing tubes comprise activated carbon and NH 2-UiO-66;

the water bath module comprises a heating unit and a control panel, a water inlet and a water outlet of the water bath module are respectively communicated with different positions of the middle layer of the shell, and the water bath module is arranged on the middle layer of the shell to form a water bath circulation for heating the decolorizing tube.

2. The decoloring apparatus according to claim 1, wherein: the main pipeline of the liquid outlet is sequentially provided with a liquid pump and branch pipelines, the outlet of the branch pipeline is folded back to the liquid inlet of the shell, and part or all of the liquid outlet is folded back to the shell through the branch pipeline for re-filtering.

3. The decoloring apparatus according to claim 2, wherein: the decolorization tube is a straight tube, when the tube body of the decolorization tube passes through the upper and lower two clapboards, the upper and lower layers of clapboards are provided with press covers through bolts at the positions where the decolorization tube passes through, the middle of each press cover is provided with a through hole which avoids the inner hole of the decolorization tube, and the upper and lower press covers clamp and seal the corresponding decolorization tube between the two clapboards.

4. The decoloring apparatus according to claim 3, wherein: the top of casing is equipped with release valve, moisturizing mouth, first temperature sensor and first liquid level observation window, the middle level of casing is equipped with second temperature sensor and second liquid level observation window.

5. The decoloring apparatus according to claim 1, wherein: in the decolorizing tube, the ratio of the activated carbon to NH2-UiO-66 is 9: 0.5-1.5.

6. The decoloring apparatus according to claim 5, wherein: the filtering material filling height of the decolorizing tube is 2/3-3/4 of the length of the decolorizing tube.

7. The decoloring apparatus according to claim 6, wherein: the water bath module provides a water bath temperature of 25-35 ℃ for the middle layer of the shell.

8. The decoloring apparatus according to claim 7, wherein: the height-diameter ratio of the decolorizing tube is 15-20: 1.

9. The decoloring apparatus according to claim 8, wherein: the diameter of the decolorizing tube is 1-3 cm.

10. The decoloring apparatus according to claim 9, wherein: the distance between the axis lines of two adjacent decolorizing tubes is 3-5 cm.

Technical Field

The invention belongs to the technical field of fermentation and filtration, and particularly relates to a decoloring device for decoloring and purifying aminobutyric acid fermentation liquor.

Background

Aminobutyric acid is a non-protein natural amino acid widely existing in the nature, is the most important inhibitory neurotransmitter in the central nervous system of mammals, and has a regulating effect on various functions of the body, such as various physiological functions of reducing blood pressure, treating epilepsy, resisting aging, improving brain activity, improving climacteric syndrome and the like. Therefore, the aminobutyric acid is used as a novel functional factor and has wide application in the fields of medicine, food, health care, chemical industry, agriculture and the like.

At present, the preparation process of the aminobutyric acid is mainly divided into a chemical method and a biological method, wherein the biological method comprises a plant enrichment method and a microbial fermentation method, the safety of chemically synthesized aminobutyric acid is poor, and the content of the plant-enriched aminobutyric acid is not high, so that the production of the aminobutyric acid by microbial fermentation has a very good development prospect. However, the fermentation process is only one of the processes, and the fermented aminobutyric acid fermentation liquor is often required to be purified. The subsequent decolorization is an important unit of operation for the purification of the aminobutyric acid.

The activated carbon has the advantages of large specific surface area, high adsorption capacity, cheapness, stability and the like, and is widely used for decoloring aminobutyric acid fermentation liquor. The activated carbon as a process for decoloring aminobutyric acid has the following disadvantages:

1. aminobutyric acid in the fermentation liquor is adsorbed at the same time, so that the loss rate is high; 2. the device is sensitive to temperature, so that the device needs to be decolorized at a proper constant temperature, and the reported decolorization and purification device for the aminobutyric acid fermentation liquor rarely carries out condition control, particularly does not control the temperature, is easily interfered by the ambient temperature, and causes poor separation and purification effect and low efficiency.

Disclosure of Invention

The invention aims to provide a decoloring device for decoloring and purifying aminobutyric acid fermentation liquor, which reduces the loss rate of the aminobutyric acid in the decoloring process of the aminobutyric acid fermentation liquor and improves the purifying effect of the aminobutyric acid fermentation liquor.

In order to achieve the above object, the present invention provides a decoloring apparatus for decoloring and purifying a aminobutyric acid fermentation broth, comprising: the shell is of a revolving body structure, two partition plates which are respectively positioned at different heights are arranged in the shell, the two partition plates divide the interior of the shell into an upper layer space, a middle layer space and a lower layer space, a liquid inlet communicated with the upper layer is formed in the top of the shell, and a liquid outlet communicated with the lower layer is formed in the bottom of the shell; the decolorizing tubes are made of heat-conducting materials and are uniformly distributed in the middle layer of the shell, the head and the tail ends of the decolorizing tubes are connected with the upper partition plate and the lower partition plate, the upper layer and the lower layer in the shell are communicated through the decolorizing tubes, the middle layer of the shell is not communicated with the upper layer and the lower layer, and the filter substances filled in the decolorizing tubes comprise activated carbon and NH 2-UiO-66; the water bath module comprises a heating unit and a control panel, a water inlet and a water outlet of the water bath module are respectively communicated with different positions of the middle layer of the shell, and the water bath module is arranged on the middle layer of the shell to form a water bath circulation for heating the decolorizing tube.

As an improvement of the scheme, a liquid pump and branch pipelines are sequentially arranged on a main pipeline of the liquid outlet, an outlet of each branch pipeline returns back to the liquid inlet of the shell, and part or all of liquid of the liquid outlet returns back to the shell through the branch pipelines for re-filtering.

As an improvement of the above scheme, the decolorizing tube is a straight tube, after the tube body of the decolorizing tube passes through the upper and lower two separating plates, the upper and lower layers of separating plates are provided with a gland through bolts at the positions passed by the decolorizing tube, the middle of the gland is provided with a through hole avoiding the inner hole of the decolorizing tube, and the upper and lower two glands clamp and seal the corresponding decolorizing tube between the two separating plates.

As the improvement of above-mentioned scheme, the top of casing is equipped with release valve, moisturizing mouth, first temperature sensor and first liquid level observation window, the middle level of casing is equipped with second temperature sensor and second liquid level observation window.

As an improvement of the scheme, the ratio of the activated carbon to the NH2-UiO-66 in the decoloration tube is 9: 0.5-1.5.

As an improvement of the scheme, the filter filling height of the decolorizing tube is 2/3-3/4 of the length of the decolorizing tube.

As an improvement of the scheme, the water bath module provides the water bath temperature for the middle layer of the shell to be 25-35 ℃.

As an improvement of the scheme, the height-diameter ratio of the decolorizing tube is 15-20: 1.

As an improvement of the scheme, the diameter of the decolorizing tube is 1-3 cm.

As an improvement of the scheme, the distance between the axes of two adjacent decolorizing tubes is 3-5 cm.

The invention has the following beneficial effects: 1. the scheme can stabilize the temperature in the decoloring process in a water bath mode, reduce the interference of the external environment and improve the stability, efficiency and quality of separation and purification; 2. the decolorizing tube is detachably mounted, so that the device is convenient to replace and maintain; 3. the decoloring pipe is filled with a novel mixture, and the optimal mixing proportion is given, so that the decoloring rate can be improved, and the loss rate can be reduced.

Drawings

FIG. 1 is a structural view of a decoloring apparatus according to an embodiment;

FIG. 2 is a block diagram of the ends of a decolorization tube according to an exemplary embodiment.

Description of reference numerals: 10. a housing; 111. an upper partition plate; 112. a lower partition plate; 12. a gas release valve; 13. a liquid inlet; 14. a liquid discharge port; 15. a main pipeline; 21. a decolorizing tube; 22. a gland; 30. a water bath module; 31. a water inlet; 32. and a water outlet.

Detailed Description

The following detailed description of the present invention is provided in conjunction with the accompanying drawings, but it should be understood that the scope of the present invention is not limited to the specific embodiments.

Referring to fig. 1 and 2, the invention discloses a decoloring device for decoloring and purifying aminobutyric acid fermentation liquor. The decoloring device includes a housing 10 and a water bath module 30, viewed from the outside; the inner side of the casing 10 is of a revolving structure, and the outer side of the casing 10 is not strictly required, and may be of a revolving structure together with the inner side of the casing 10. Two partition plates respectively positioned at different heights are arranged inside the shell 10, and the two partition plates temporarily divide the inner space of the shell 10 into an upper layer, a middle layer and a lower layer which are not communicated with each other; for the sake of convenience of reference, the partition located at the upper layer is referred to as an upper partition 111, and the partition located at the lower layer is referred to as a lower partition 112. Because the inside of the shell 10 is a revolving body, correspondingly, the upper and lower partition plates are both disc structures. The top of the shell 10 is provided with a liquid inlet 13 communicated with the upper layer, and the bottom of the shell 10 is provided with a liquid outlet 14 communicated with the lower layer.

Preferably, the top of the casing 10 is provided with an air release valve 12, a water replenishing port, a first temperature sensor and a first liquid level observation window, and the middle layer of the casing 10 is provided with a second temperature sensor and a second liquid level observation window.

A plurality of decolorizing tubes 21 are uniformly arranged in the shell 10, namely between the upper partition plate 111 and the lower partition plate 112, and the decolorizing tubes 21 can be selected from straight round tubes or bent and spiral round tubes (so as to increase the filtering path of the liquid, prolong the retention time of the liquid and enhance the filtering effect). The decolorizing tube 21 is made of heat conducting material. The upper and lower ends of each of the decoloring tubes 21 are connected to an upper partition 111 and a lower partition 112, respectively, and the upper and lower layers inside the casing 10 are communicated with each other through each of the decoloring tubes 21. The liquid to be filtered can flow in the upper and lower layer spaces but can not enter the middle layer. The filtering material filled in the decolorizing tube 21 comprises activated carbon and NH 2-UiO-66.

The water bath module 30 includes a heating unit and a control panel, a heat medium (e.g., water) is introduced into the middle space of the housing 10, the heat medium fills the middle space and is drawn by the water bath module 30 to flow, and the heating unit (e.g., an electric heating tube) heats the heat medium flowing in and then discharges the heat medium to adjust the middle space of the housing 10. When the liquid (supernatant from the fermentation liquid after centrifugation to remove the bacterial cells) flows from the upper layer to the lower layer of the casing 10, the liquid is heated by the heat medium in the middle layer. In order to improve the circulation effect, the water inlet 31 and the water outlet of the water bath module 30 are symmetrically arranged diagonally, that is, the water inlet 31 is arranged at 0 ° and close to the upper partition 111, and the water outlet is arranged at 180 ° and close to the lower partition 112.

Specifically referring to fig. 2, an interruption drawing method is adopted, after the tube body of the decolorizing tube 21 passes through the upper and lower two separating plates, the upper and lower layers of separating plates are provided with a gland 22 through bolts at the positions passed by the decolorizing tube 21, the middle of the gland 22 is provided with a through hole avoiding the inner hole of the decolorizing tube 21, the through hole of the gland 22 is equal to two smooth planes of the inner diameter of the decolorizing tube 21, and the upper and lower two glands 22 clamp and seal the corresponding decolorizing tube 21 between the two separating plates. The gland 22 is simultaneously attached to the side surface of the partition plate and the end surface of the decolorizing tube 21, and a sealing ring is added at the attachment position to improve the sealing effect.

A liquid pump and branch pipes are sequentially arranged on the main pipe 15 of the liquid discharge port 14, the outlet of the branch pipe is returned back to the liquid inlet 13 of the shell 10, and part or all of the liquid discharge port 14 is returned back to the shell 10 through the branch pipe for re-filtering. In fig. 1, it can be seen that the branch pipes and the original liquid inlet pipe are communicated with the upper layer of the shell 10, but are in different positions. Valves are arranged on the liquid inlet 13, the liquid outlet and other pipelines. When temporary sampling is needed, a tee joint is added on the main pipeline 15, and the last port of the tee joint is used as a sampling port.

The housing 10 includes upper and lower parts which can be separated from each other, and when the device is assembled, the upper partition 111, the decoloring tube 21 and the lower partition 112 are first manufactured as a whole, and then are put into the housing 10 together, and finally the other part of the housing 10 is covered.

In the embodiment, the preferable water bath heating temperature is 25-35 ℃, the height-diameter ratio of the decolorizing tubes 21 is 15-20:1, the diameter of the decolorizing tubes 21 is 1-3cm, the axial distance between two adjacent decolorizing tubes 21 is 3-5cm, and the filter filling height of the decolorizing tubes 21 is 2/3-3/4 of the length of the decolorizing tubes 21. In the decolorizing tube 21, the ratio of the activated carbon to NH2-UiO-66 is 9: 0.5-1.5.

Example 1, the mixing ratio of activated carbon in the decolorizing tube 21 to NH2-UiO-66 was 9: 0.5.

comparative example 1-1, other parameters were substantially the same as in example 1, and activated carbon was equally mass-packed in the decolorizing tube 21.

Comparative examples 1-2, otherwise essentially identical to example 1, were filled with NH2-UiO-66 in the decolorizing tube 21 in an equal mass.

Example 2, the other parameters were substantially the same as in example 1, and the mixing ratio of activated carbon in the decolorizing tube 21 to NH2-UiO-66 was 9: 1.

example 3, the other parameters were substantially the same as in example 1, and the mixing ratio of activated carbon in the decolorizing tube 21 to NH2-UiO-66 was 9: 1.5.

and (3) decolorization rate determination: taking a small amount of sample through one port of the tee joint, taking deionized water as a contrast, respectively measuring the light absorption values before and after decolorization under the wavelength of 420nm, and calculating the average value after 3 times of parallel measurement. The determination formula is as follows: decolorization ratio = (absorbance before decolorization-absorbance after decolorization)/absorbance before decolorization.

And (3) loss rate determination: 1. determining the content of aminobutyric acid in the fermentation broth before and after decolorization by referring to a method for detecting aminobutyric acid in 5.2 in standard QB/T4587-2013, and replacing aminobutyric acid powder with the aminobutyric acid fermentation broth as a sample; 2. the total mass of the sample before and after decolorization was weighed. The determination formula is as follows: loss rate = (content of aminobutyric acid before decoloring-content of aminobutyric acid before decoloring)/content of aminobutyric acid before decoloring.

From the experimental results, the decolorization ratio of example 1 was 93% and the loss ratio was 4.1%; the decolorization rate of example 2 was 97% and the loss rate was 3.4%; the decolorization ratio of example 3 was 94% and the loss ratio was 3.1%; the decolorization ratio of comparative example 1-1 was 81%, and the loss ratio was 20.5%; the decolorization ratio of comparative examples 1 and 2 was 48% and the loss ratio was 2.3%.

From the experimental results, it is known that the ratio of activated carbon to the mixture of NH2-UiO-66 is 9:0.5,9: 1,9: under the condition of 1.5, the loss rate of the aminobutyric acid in the decoloring process is respectively 4.1%, 3.4% and 3.1%, the loss rate of the aminobutyric acid in the decoloring process is 20.5% only by using activated carbon, and the loss rate of the aminobutyric acid in the decoloring process by using NH2-UiO-66 is 2.3%; under the condition of ensuring the decoloring effect, after the weight synthesis, the ratio of the activated carbon to the NH2-UiO-66 is better within the range of 9: 0.5-1.5.

The invention has the following beneficial effects: 1. the scheme can stabilize the temperature in the decoloring process in a water bath mode, reduce the interference of the external environment and improve the stability, efficiency and quality of separation and purification; 2. the decolorizing tube 21 is detachably mounted, so that the device is convenient to replace and maintain; 3. the decoloring pipe 21 is filled with a novel mixture, and an optimal mixing ratio is provided, so that the decoloring rate can be improved, and the loss rate can be reduced.

The foregoing descriptions of specific exemplary embodiments of the present invention have been presented for purposes of illustration and description. It is not intended to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. The exemplary embodiments were chosen and described in order to explain certain principles of the invention and its practical application to enable one skilled in the art to make and use various exemplary embodiments of the invention and various alternatives and modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims and their equivalents.

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