CN111254056A

CN111254056A - Deep sea biogeochemical in-situ experimental device

Info

Publication number: CN111254056A
Application number: CN202010118292.4A
Authority: CN
Inventors: 张健; 杜梦然; 杨晨光; 吴邦春; 柳双权; 彭晓彤
Original assignee: Institute of Deep Sea Science and Engineering of CAS
Current assignee: Institute of Deep Sea Science and Engineering of CAS
Priority date: 2020-02-26
Filing date: 2020-02-26
Publication date: 2020-06-09
Anticipated expiration: 2040-02-26
Also published as: CN111254056B

Abstract

According to the deep sea biological geochemistry in-situ experimental device provided by the invention, when the seawater pump rotates forwards, the inlet of the culture cavity sucks in-situ environmental seawater, the outlet discharges deionized water, when the seawater pump rotates backwards, the inlet of the culture cavity discharges in-situ environmental seawater, and the outlet sucks in-situ seawater; the deep sea biogeochemistry in-situ experiment device adopts one-time sample injection and grouping to carry out parallel experiments, avoids the defect of error caused by repeated sample injection in the past for carrying out the parallel experiments, and ensures that all the parallel experiments are carried out under the same sample.

Description

Deep sea biogeochemical in-situ experimental device

Technical Field

The invention relates to marine organism geochemistry, in particular to a deep sea organism geochemistry in-situ experimental device.

Background

The geochemical process of marine organisms becomes the most critical system for controlling the material circulation of a marine system in the sea, and the research on the geochemical process of the marine organisms becomes the core of the earth science. Meanwhile, microorganisms play an indispensable role in the geochemical cycle of the marine organisms, are the drivers of the material cycle, ensure that various elements and materials in the nature can be recycled, and if the marine organism geochemical in-situ culture experiment can be developed, the microorganism samples participating in the reaction can be effectively stored, so that more comprehensive data support and basis can be provided for disclosing the geochemical cycle mechanism of the marine organisms; meanwhile, if a plurality of groups of parallel experiments can be synchronously developed according to the time gradient, the reliability and the scientificity of data can be greatly improved, so that the land experiment underwater is really realized, and a powerful technical support is provided for the geochemical process research of marine organisms.

Disclosure of Invention

Therefore, there is a need to provide a deep-sea biogeochemical in-situ experiment apparatus capable of synchronously developing multiple sets of parallel biogeochemical in-situ experiments according to time gradients.

In order to achieve the purpose, the invention adopts the following technical scheme:

the deep sea biological geochemistry in-situ experimental device comprises a culture cavity, a sea water pump connected with the culture cavity, six-way valves, tracer bags, culture bags, three-channel peristaltic pumps and parallel test groups, wherein the parallel test groups comprise filters and sample bags, the number of the tracer bags is three, the number of the culture bags is three, the number of the parallel test groups is three, any one of the parallel test groups comprises three filters and three corresponding sample bags, and the experimental device comprises:

when the seawater pump rotates forwards, the inlet of the culture cavity sucks in the seawater in the normal environment, the outlet of the culture cavity discharges deionized water, when the seawater pump rotates backwards, the inlet of the culture cavity discharges the seawater in the normal environment, and the outlet sucks in the seawater in the normal environment;

the inlet of the culture cavity is also connected with the six-way valve, any inlet of the six-way valve is correspondingly connected with one tracer bag, any outlet of the six-way valve is correspondingly connected with one culture bag, all the culture bags are also connected with the three-channel peristaltic pump, the three-channel peristaltic pump is also connected with a stationary liquid bag, and the three-channel peristaltic pump is connected with three parallel test groups.

In some preferred embodiments, the middle of the culture chamber comprises a piston of PC material, which enables sealing of both ends of the culture chamber.

In some preferred embodiments, the inlet of the culture chamber is connected to a two-way solenoid valve, and the in-situ environmental seawater enters the culture chamber through the two-way solenoid valve.

In some preferred embodiments, a two-way solenoid valve is disposed between the inlet of the six-way valve and the tracer bag, and the microbial fixing liquid in the tracer bag can enter the inlet of the six-way valve through the two-way solenoid valve.

In some preferred embodiments, a two-way solenoid valve is provided between any one of the culture bags and the outlet of the corresponding six-way valve.

In some preferred embodiments, a three-way electromagnetic valve and a two-way electromagnetic valve are arranged between any culture bag and the three-way peristaltic pump from top to bottom in sequence.

In some preferred embodiments, a four-way joint is connected to the third channel of any one of the three-way solenoid valves, and the four-way joint is connected with the stationary liquid bag.

In some preferred embodiments, any of the parallel test sets further comprises a four-way connector, three of the filters connected to the four-way connector, and a two-way solenoid valve disposed between the filters and the sample bags.

In some preferred embodiments, the two-way solenoid valve is capable of switching on and off the flow path, the three-way solenoid valve is capable of selecting and switching among two-in one-out flow paths, and the four-way joint is capable of realizing one fluid medium flow path of one rotation and three rotation and one rotation.

The invention adopts the technical scheme that the method has the advantages that:

according to the deep sea biological geochemistry in-situ experimental device provided by the invention, when the seawater pump rotates forwards, the inlet of the culture cavity sucks in-situ environmental seawater, and the outlet discharges deionized water; the deep sea biological geochemistry in-situ experiment device provided by the invention adopts a mode of once sample injection and then grouping to carry out parallel experiments, avoids the defects that in the prior art, the samples are repeatedly injected for a plurality of times for carrying out the parallel experiments, and the errors exist due to environmental changes, and ensures that all the parallel experiments are carried out under the same sample.

In addition, the deep-sea biological geochemistry in-situ experimental device provided by the invention realizes that a sample participates in a reaction in an in-situ environment, and finally, the experiment termination and the sample fixation storage are carried out in situ, reactants, reaction products and isotope tracers which are cultured are remained most truly, and a microorganism sample which is fixed in situ is kept, so that a precious sample is provided for the subsequent marine biological geochemical cycle mechanism research, and the experimental result distortion caused by environmental changes such as temperature, pressure and the like in the sample culture process of the traditional land laboratory and the higher pollution risk in the sample culture and transfer processes of the land laboratory are avoided.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a deep-sea biogeochemical in-situ experiment apparatus provided in an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

Referring to fig. 1, a schematic structural diagram of an in-situ experimental apparatus for deep sea biogeochemistry is provided, which includes: the device comprises a culture cavity 110, a seawater pump 120 connected with the culture cavity 110, a six-way valve 130, three tracer bags 140, three culture bags 150, a three-way peristaltic pump 160, a filter 170 and three sample bags 180, wherein the inlet of the culture cavity 110 is also connected with the six-way valve 130, any inlet of the six-way valve 130 is correspondingly connected with one tracer bag 140, any outlet of the six-way valve 130 is correspondingly connected with one culture bag 150, all the culture bags 150 are also connected with the three-way peristaltic pump 160, the three-way peristaltic pump 160 is also connected with a fixed liquid bag 170, the three-way peristaltic pump 160 is connected with three parallel test groups 190, and any parallel test group 190 comprises three filters 210 and the sample bags 220 correspondingly arranged with the filters 210.

The structure of each component and the connection relationship thereof are described in detail below.

Specifically, the culture cavity 110 is a PC material culture cavity with a piston in the middle, the culture cavity 110 can precisely determine the volume of seawater in the in-situ environment with high accuracy, the volume accuracy is better than 1%, and the piston is arranged in the middle and an O-ring is adopted to realize sealing at two ends.

It can be understood that the high-precision sample injection is carried out by adopting the culture cavity 110 with fixed volume, the sample injection volume precision is greatly improved, and the defect that the traditional quantitative control mode is completed by controlling the working time of a pump, and the rotating speed of a pump motor is influenced by additional resistance under different water pressures, so that the sample injection precision of a sample is greatly influenced is overcome.

Specifically, the seawater pump 120 is a seawater pump capable of moving in two directions, and is configured to drive a piston of the culture chamber 110 to move, when the seawater pump 120 rotates forward, the inlet of the culture chamber 110 sucks in the in-situ environmental seawater, and the outlet discharges the deionized water, and when the seawater pump 120 rotates backward, the inlet of the culture chamber 110 discharges the in-situ environmental seawater, and the outlet sucks in the in-situ seawater.

In some preferred embodiments, the inlet of the culture chamber 110 is connected to a two-way electromagnetic valve 111, and since the two-way electromagnetic valve 111 can be used to open and close a flow path, when the two-way electromagnetic valve 111 is opened, the in-situ environmental seawater can enter the culture chamber 110 through the two-way electromagnetic valve 111.

In some preferred embodiments, a two-way solenoid valve 111 is disposed between the inlet of the six-way valve 130 and the tracer bag 140, and the microbial fixing fluid in the tracer bag 140 can enter the inlet of the six-way valve 130 through the two-way solenoid valve 111.

It will be appreciated that six-way valve 130 may select between "one in, multiple out" or "multiple in, one out" flow paths.

Referring to fig. 1 again, the port 0 in the six-way valve 130 is used as a common port and connected to the culture chamber 110 as a total inlet or a total outlet, the port 0 can be communicated with any one of the ports 1-6, the port 1 is connected to the tracer bag 1, the port 2 is connected to the tracer bag 2 140, the port 3 is connected to the tracer bag 3 140, the port 4 is connected to the culture bag 3, the port 5 is connected to the culture bag 2, and the port 6 is connected to the culture bag 1 150.

Further, the volume of the culture bag 150 is 1/3 of the volume of the culture chamber 110.

In some preferred embodiments, a two-way solenoid valve 111 is disposed between any one of the culture bags 150 and the corresponding outlet of the six-way valve 130, and the liquid in the outlet of the six-way valve 130 can enter the culture bag 150 through the two-way solenoid valve 111.

In some preferred embodiments, a three-way solenoid valve 112 and a two-way solenoid valve 111 are sequentially disposed between any one of the culture bags 150 and the three-way peristaltic pump 160 from top to bottom, and the liquid in any one of the culture bags 150 can enter the three-way peristaltic pump 160 through the three-way solenoid valve 112 and the two-way solenoid valve 111.

It can be understood that because a plurality of groups of parallel contrast experiments can be synchronously developed according to the time gradient, the time consistency of the parallel experiments is ensured by adopting the multi-channel peristaltic pump, and the reliability of the experimental results is greatly improved.

It will be appreciated that the three-way solenoid valve 112 can be selected and switched between a "two-in one-out" type flow path, where A-B is connected when not energized, A-C is connected when energized, and A-B is normally connected when not energized.

Further, a third channel of any one of the three-way solenoid valves 112 is connected to a four-way joint 113, and the four-way joint 113 is connected to the stationary liquid bag 170.

It will be appreciated that the four-way junction 113 may implement "three-for-three" or "three-for-one" of the same fluid medium; under the action of the four-way joint 113, the liquid in the fixed liquid bag 170 can realize three times per turn.

In some preferred embodiments, the two-way solenoid valve 111 is further disposed between the four-way joint 113 and the stationary liquid bag 170.

Any one of the parallel test sets 190 further comprises a four-way joint 113, three filters 210 connected to the four-way joint 113, and a two-way solenoid valve 111 disposed between the filters 210 and the sample bag 220.

For ease of illustration, one of the parallel test sets 190 includes three filters 210, designated as F11, F12, F13; and the like, wherein another of the parallel test sets 190 comprises three filters 210, which are designated as F21, F22, F33(F31, F32, F33).

It will be appreciated that the seawater incubated through the three-channel peristaltic pump 160 to complete the incubation to include the tracer is filtered through the filter 210 having a 0.2 μm filter membrane, such that the microbial sample and the seawater sample are separated, thereby stopping the biogeochemical reaction occurring in the seawater, leaving the microbes on the filter membrane, and the filtered seawater sample in the sample bag 220.

The deep-sea biological geochemistry in-situ experimental device provided by the invention can realize that a sample participates in a reaction in an in-situ environment, and finally, the experiment termination and the sample fixation storage are carried out in situ, reactants, reaction products and isotope tracers which are cultured are truly reserved, and a microorganism sample which is fixed in situ is kept, so that a precious sample is provided for the subsequent marine biological geochemistry circulation mechanism research, the experimental result distortion caused by environmental changes such as temperature, pressure and the like in the sample culture process of the traditional land laboratory is avoided, and the higher pollution risk in the sample culture and transfer processes of the land laboratory is avoided.

The deep sea biological geochemical in-situ experiment device provided by the invention adopts a mode of carrying out parallel experiments by one-time sample introduction and grouping, avoids the defects that the sample is repeatedly introduced for a plurality of times for carrying out the parallel experiments and has errors due to environmental changes in the prior art, and ensures that all the parallel experiments are carried out under the same sample.

Example 2

The invention provides an experimental method of a deep sea biogeochemical in-situ experimental device, which comprises the following steps:

step S110: the method for cleaning the culture cavity specifically comprises the following steps:

step S111: the seawater pump 120 rotates forward, the left side of the culture chamber 110 sucks in the in-situ environmental seawater, and the right side discharges the deionized water.

Step S112: the seawater pump 120 is reversed, the left side of the culture cavity 110 discharges the in-situ environmental seawater, and the right side sucks the in-situ seawater;

step S113: the above steps are repeated to make the background environment in the culture chamber 110 highly consistent with the in situ seawater environment.

It can be understood that, since the inlet of the culture chamber is connected with the two-way solenoid valve 111, the in-situ environmental seawater can enter the culture chamber through the two-way solenoid valve when the two-way solenoid valve 111 is opened.

Step S120: the sample injection of seawater and tracer comprises the following steps:

step S121: the seawater pump 120 rotates forwards, the inlet of the culture cavity 110 sucks in the seawater in the normal environment, and when the volume of the sucked seawater in the normal environment is 1/4 of the culture cavity, the seawater pump 120 is stopped, and the inlet of the culture cavity is closed;

step S122: adjusting the rotation position of the six-way valve 230 to connect the first port of the six-way valve 230 with the corresponding tracer bag, and activating the seawater pump 120 to allow the corresponding tracer bag liquid to enter the culture chamber 110;

step S123: repeating the above steps to allow the liquid of other tracer bags to enter the culture chamber 110;

step S124: the seawater pump 120 rotates forward, the inlet of the culture chamber 110 sucks in the in-situ environment seawater again, so that the whole culture chamber 110 is filled with the culture seawater, the seawater pump 120 is stopped, and the inlet of the culture chamber 110 is closed.

It can be understood that, since the inlet of the culture chamber 110 is connected with the two-way electromagnetic valve 111, the in-situ environmental seawater can enter the culture chamber through the two-way electromagnetic valve when the two-way electromagnetic valve 111 is opened; a two-way electromagnetic valve is disposed between the inlet of the six-way valve 230 and the tracer bag 140, and the microorganism fixing liquid in the tracer bag 140 can enter the inlet of the six-way valve 230 through the two-way electromagnetic valve.

Step S130: the parallel separation of samples comprises the following steps:

step S131: the inlet of one of the culture bags 150 is opened, the seawater pump 120 is reversed, the culture seawater in the culture cavity 110 is filled into the culture bag until the volume of the culture seawater is 1/3, the inlet of the culture bag is closed, and the seawater pump is closed.

Step S132: the above steps are repeated, and the seawater for culture in the culture chamber 110 is filled into other culture bags.

It can be understood that, in the second stage of sample injection of seawater and tracer, the precise sample injection is completed by the culture chamber 110 with a fixed volume, and the concentration value is used as the calculation basis of all culture samples, so that in the parallel sample separation stage, it can be considered that the fluid medium with the same concentration is separated, and the sample injection volume control is completed by controlling the seawater pump to perform the same working time.

Step S140: the sample is filtered and stored, and the method comprises the following steps:

step S141: simultaneously opening the outlets of the three culture bags, and simultaneously opening the outlets of the filters F11, F21 and F31, starting a three-channel peristaltic pump, and completing sampling of the sample 1/3 volume of the culture bag;

it can be understood that, when passing through the 0.2 μm filter membrane of the filter, the microorganisms are filtered on the filter membrane, and the sample is stored in the sample bag, since the liquid in the sample bag does not contain the microorganisms, the biogeochemical test performed by the participation of the microorganisms is terminated, and the preservation of three parallel sample seawater samples at the time of T0 is realized;

step S142: simultaneously opening the outlets of the three culture bags, and simultaneously opening the outlets of the F12, F22 and F32 filters, starting a three-channel peristaltic pump, completing sampling and filtering of the culture bag sample 1/3 volume, and completing storage of three parallel sample seawater samples at the T1 moment;

step S143: simultaneously opening the outlets of the three culture bags, and simultaneously opening the outlets of the F13, F23 and F33 filters, starting a three-channel peristaltic pump, completing sampling and filtering of the culture bag sample 1/3 volume, and completing storage of three parallel sample seawater samples at the T2 moment;

step S144: after the time gradient sampling of the three parallel samples is completed, switching the samples in the sample bags to microorganism fixing liquid in a fixing liquid bag, simultaneously opening the outlets of the three culture bags, and simultaneously opening the outlets of F11, F21 and F31 filters, starting a three-channel peristaltic pump, injecting a trace of fixing liquid into the F11, F21 and F31 filters, and completing the fixation of microorganisms attached to filter membranes of the F11, F21 and F31 filters;

step S145: opening three electromagnetic valves at the outlet of the culture bag, opening the outlets of the F12, F22 and F32 filters at the same time, starting a three-channel peristaltic pump, and injecting a trace amount of stationary liquid into the F12, F22 and F32 filters to complete the immobilization of microorganisms attached to the filter membranes of the F12, F22 and F32 filters;

step S145: and opening the outlets of the three culture bags, opening the outlets of the F13, the F23 and the F33 filters at the same time, starting a three-channel peristaltic pump, and injecting a trace amount of fixing liquid into the F13, the F23 and the F33 filters to complete the fixation of microorganisms attached to the filter membranes of the F13, the F23 and the F33 filters.

It can be understood that, because a two-way electromagnetic valve is arranged between any one of the culture bags and the outlet of the corresponding six-way valve, a three-way electromagnetic valve and a two-way electromagnetic valve are sequentially arranged between any one of the culture bags and the three-way peristaltic pump from top to bottom, the third channel of any one of the three-way electromagnetic valves is connected with a four-way joint, the four-way joint is connected with the fixed liquid bag, and the outflow or closing of liquid in the corresponding reagent bag is realized by opening or closing each electromagnetic valve.

The deep sea biological geochemical in-situ experiment method provided by the invention adopts a mode of carrying out parallel experiments by one-time sample introduction and grouping, avoids the defects that the sample is repeatedly introduced for a plurality of times for carrying out the parallel experiments and has errors due to environmental changes in the prior art, and ensures that all the parallel experiments are carried out under the same sample.

In addition, the deep-sea biological geochemistry in-situ experiment method provided by the invention realizes that the sample participates in the reaction in the in-situ environment, and finally the experiment termination and the sample fixed storage are carried out in situ, so that the reactants, the reaction products and the isotope tracers which are cultured and the microorganism sample which is fixed in situ are kept most truly, precious samples are provided for the subsequent marine biological geochemical cycle mechanism research, the distortion of the experiment result caused by the environmental changes of temperature, pressure and the like in the sample culture process of the traditional land laboratory is avoided, and the higher pollution risk in the sample culture and transfer processes of the land laboratory is avoided.

The present invention will be described in detail with reference to specific examples.

1. Preparation before laying

(1) The culture cavity and the pipeline are filled with deionized water;

(2) the tracer bag 1.2.3 is pre-filled with three tracers with target volumes and concentrations, and the fixing liquid bag is pre-filled with microorganism fixing liquid with target volumes and concentrations;

(3) all the culture bags and the sample bags are empty;

2. laying on sea

After the preparation work for placement is finished, the instrument carries a manned submersible vehicle or an ROV or other carrying platform, is placed at the seabed target position, and is used for in-situ experiment.

3. Cleaning culture cavity

(1) Opening an electromagnetic valve at the inlet of the culture cavity, rotating a seawater pump forwards, sucking in-situ environment seawater on the left side of a piston of the culture cavity, and discharging deionized water on the right side;

(2) the seawater pump rotates reversely, the left side of the piston of the culture cavity discharges the seawater in the original environment, and the right side sucks the seawater in the original environment;

(3) the operation is repeated for 4 times to ensure that the background environment in the culture cavity is highly consistent with the in-situ seawater environment.

4. Sample introduction of seawater and tracer

(1) Opening an electromagnetic valve at the inlet of the culture cavity, positively rotating a seawater pump, feeding a seawater sample with about 1/4 volume, stopping the seawater pump, and closing the electromagnetic valve at the inlet of the culture cavity;

(2) the six-way valve is rotated to adjust the No. 0 port and the No. 1 port connected with the tracer 1, the tracer switch valve 1 is opened, the seawater pump is started, and the tracer 1 is injected into the culture cavity;

(3) after the sample introduction of the tracer 1 is finished, the sample introduction processes of other two tracers are consistent with the sample introduction processes, the position of the rotary valve is adjusted, and the corresponding channel switch electromagnetic valve is opened;

(4) opening an electromagnetic valve at the inlet of the culture cavity, positively rotating the seawater pump to finish the residual seawater sample of about 3/4 volumes, stopping the seawater pump, and closing the electromagnetic valve at the inlet of the culture cavity;

5. parallel separation of samples

In the second stage, when the seawater and the tracer are injected, the accurate sample injection of the sample is completed by the culture cavity with a fixed volume, and the concentration value is used as the calculation basis of all culture samples, so that in the parallel separation stage of the sample, the fluid medium with the same concentration can be considered to be separated, and the sample injection volume control can be completed by controlling the seawater pump to perform the same working time.

(1) Opening an inlet switch valve of the No. 1 culture bag, reversely rotating the seawater pump, injecting the cultured seawater into the No. 1 culture bag, wherein the volume is about 1/3 culture cavity volume, closing the inlet switch valve of the No. 1 culture bag after the culture bag is completely cultured, and closing the seawater pump;

(2) opening an inlet switch valve of the No. 2 culture bag, reversing a seawater pump, injecting cultured seawater into the No. 2 culture bag, wherein the volume of the cultured seawater is about 1/3 culture cavity volume, and closing the inlet switch valve of the No. 2 culture bag after the culture bag is completely cultured;

(3) opening an inlet switch valve of the No. 3 culture bag, reversing a seawater pump, injecting cultured seawater into the No. 3 culture bag, culturing the volume of the culture cavity of 1/3, and closing the inlet switch valve of the No. 3 culture bag after the culture is completed;

6. filtering and storing sample

(1) After the culture samples in the culture cavity are transferred to 3 culture bags, immediately sampling at T0 time to serve as a calculation zero point, wherein the process comprises the steps of simultaneously opening electromagnetic valves at the outlets of No. 1, No. 2 and No. 3 culture bags, simultaneously opening electromagnetic valves at the outlets of F11, F21 and F31 filters, starting a three-channel peristaltic pump, completing sampling of 1/3 volume of the culture bag samples, filtering microorganisms on the filter membrane when the microorganisms pass through the 0.2 mu m filter membrane of the filter, storing the samples in the sample bags, and terminating the biological geochemical test performed by the microorganisms due to the fact that liquid in the sample bags does not contain the microorganisms, so that the storage of seawater samples of three parallel samples at T0 time is realized;

(2) at the time of T2, opening the electromagnetic valves of the outlets of the culture bags No. 1, No. 2 and No. 3 at the same time, opening the electromagnetic valves of the outlets of the filters F12, F22 and F32 at the same time, starting a three-channel peristaltic pump, completing the volume sampling and filtering of the culture bag samples 1/3, and completing the storage of three parallel sample seawater samples at the time of T1;

(3) at the time of T3, opening the electromagnetic valves of the outlets of the culture bags No. 1, No. 2 and No. 3 at the same time, opening the electromagnetic valves of the outlets of the filters F13, F23 and F33 at the same time, starting a three-channel peristaltic pump, completing the volume sampling and filtering of the culture bag samples 1/3, and completing the storage of three parallel sample seawater samples at the time of T2;

(4) after the time gradient sampling of three parallel samples is completed, 3 three-way electromagnetic valves at the outlets of 3 culture bags are switched to an A-C state from an A-B state, an input medium of the three-way valve is switched to microorganism stationary liquid in a No. 4 microorganism stationary liquid bag from a sample in the sample bag, the outlet electromagnetic valves of No. 1, No. 2 and No. 3 culture bags are opened at the same time, the outlet electromagnetic valves of F11, F21 and F31 filters are opened at the same time, a three-way peristaltic pump is started, a trace amount of stationary liquid is injected into the F11, F21 and F31 filters, and the fixation of microorganisms attached to filter membranes of the F11, F21 and F31 filters is completed;

(5) the three-way electromagnetic valve is kept in an A-C state, the outlet electromagnetic valves of No. 1, No. 2 and No. 3 culture bags are opened at the same time, the outlet electromagnetic valves of F12, F22 and F32 filters are opened at the same time, a three-channel peristaltic pump is started, and a trace amount of stationary liquid is injected into the F12, F22 and F32 filters to complete the fixation of microorganisms attached to the filter membranes of the F12, F22 and F32 filters;

(6) the three-way electromagnetic valve is kept in an A-C state, the outlet electromagnetic valves of No. 1, No. 2 and No. 3 culture bags are opened at the same time, the outlet electromagnetic valves of F13, F23 and F33 filters are opened at the same time, a three-channel peristaltic pump is started, and a trace amount of stationary liquid is injected into the F13, F23 and F33 filters to complete the fixation of microorganisms attached to the filter membranes of the F13, F23 and F33 filters;

7. the instrument is recovered and the sample is stored,

(1) after the experiment is completed, the instrument is recovered by the manned submersible vehicle or the ROV and is recovered to a mother ship laboratory along with the manned submersible vehicle or the ROV;

(2) in a laboratory, taking down the sample bags and replacing the sample bags with adsorption columns in sequence, and storing the sample bags in a refrigerator for subsequent analysis;

(3) replacing a No. 4 microorganism stationary liquid bag with large-volume deionized water, switching a three-way electromagnetic valve to an A-C state, simultaneously opening outlet electromagnetic valves of No. 1, No. 2 and No. 3 culture bags, and simultaneously opening outlet electromagnetic valves of F11, F21 and F31 filters, starting a three-channel peristaltic pump, leaching the F11, F21 and F31 filters by using the deionized water, injecting stationary liquid containing a microorganism sample onto an adsorption column, so that the microorganism is adsorbed on the adsorption column, and after leaching is completed, storing 3 adsorption columns into a refrigerator for subsequent analysis;

(4) carrying out microorganism sample extraction operation on three filters of F12, F22 and F32;

(5) and performing microorganism sample extraction operation on the three filters of F13, F23 and F33.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

Of course, the cathode material of the deep sea biogeochemical in-situ experimental device of the invention can also have various changes and modifications, and is not limited to the specific structure of the above embodiment. In conclusion, the scope of the present invention should include those changes or substitutions and modifications which are obvious to those of ordinary skill in the art.

Claims

1. The deep sea biogeochemical in-situ experiment device is characterized by comprising a culture cavity, a seawater pump, a six-way valve, tracer bags, culture bags, three-way peristaltic pumps and parallel test groups, wherein the seawater pump, the six-way valve, the tracer bags, the culture bags, the three-way peristaltic pumps and the parallel test groups are connected with the culture cavity, the parallel test groups comprise three filters and three sample bags, any one of the three filter groups and the three corresponding sample bags are arranged in the parallel test group, and the device comprises:

2. The deep-sea biogeochemical in-situ experiment device as claimed in claim 1, wherein the middle of the culture cavity comprises a piston made of PC material, and sealing at two ends of the culture cavity can be realized.

3. The deep sea biogeochemical in-situ experiment device according to claim 2, wherein a two-way solenoid valve is connected to the inlet of the culture chamber, and the in-situ environmental seawater enters the culture chamber through the two-way solenoid valve.

4. The deep sea biogeochemical in-situ experiment device as claimed in claim 3, wherein a two-way electromagnetic valve is arranged between the inlet of the six-way valve and the tracer bag, and the microorganism fixing liquid in the tracer bag can enter the inlet of the six-way valve through the two-way electromagnetic valve.

5. The deep-sea biogeochemical in-situ experiment device as claimed in claim 4, wherein a two-way solenoid valve is arranged between any one of the culture bags and the outlet of the corresponding six-way valve.

6. The deep-sea biogeochemical in-situ experiment device as claimed in claim 5, wherein a three-way electromagnetic valve and a two-way electromagnetic valve are arranged between any one culture bag and the three-channel peristaltic pump from top to bottom in sequence.

7. The deep-sea biogeochemical in-situ experiment device as claimed in claim 6, wherein a fourth joint is connected to the third channel of any one of the three-way solenoid valves, and the four-way joint is connected with the fixed liquid bag.

8. The deep-sea biogeochemical in-situ experiment device according to claim 7, wherein any one of the parallel test sets further comprises a four-way joint, three filters connected with the four-way joint, and a two-way solenoid valve arranged between the filters and the sample bags.

9. The in-situ experimental apparatus for deep sea biogeochemistry according to claim 8, wherein the two-way solenoid valve is capable of realizing the on-off of a flow path, the three-way solenoid valve is capable of selecting and switching among a two-in one-out flow path, and the four-way joint is capable of realizing a three-in-one or a three-in-one flow path of the same fluid medium.