CN207557168U - It is a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis - Google Patents
It is a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis Download PDFInfo
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- CN207557168U CN207557168U CN201721615924.8U CN201721615924U CN207557168U CN 207557168 U CN207557168 U CN 207557168U CN 201721615924 U CN201721615924 U CN 201721615924U CN 207557168 U CN207557168 U CN 207557168U
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Abstract
It is provided by the utility model a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, monitoring device including the probe tube extending into reaction kettle interior reagent and for monitoring oxygen content in the sample of the probe tube taking-up, and the cooling device of the temperature for reducing the sample is provided between the probe tube and the monitoring device.The utility model it is a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, the oxygen content in reaction kettle in reagent can be monitored in real time, improve monitoring efficiency.
Description
Technical field
The utility model is related to lithium electricity multicomponent material technologies of preparing, are used to monitor multicomponent material more particularly, to one kind
The system of oxygen content during precursor synthesis.
Background technology
Lithium ion battery has many advantages, such as high-energy, long-life, low stain, be widely used in collection, computer, it is electronic from
The multiple fields such as driving, electric vehicle, national defence.And positive electrode directly determines the performance of final lithium ion battery.For making
The multicomponent material of standby battery has that high power capacity, reversible specific capacity are big, while have higher security performance, and price is also relatively
It is low.And it is preferable with the compatibility of electrolyte, cycle performance is excellent, therefore is widely used in every field.
In recent years, the advantage of multicomponent material was fully played, and became the object that battery material producer pursues;
At the same time, as polynary battery material is in the extensive use of new-energy automobile industry, multicomponent material presoma also proposed
Higher requirement, the security performance of multicomponent material presoma are stood in the breach.
In the building-up process of multicomponent material presoma, especially in booting initial reaction phase, it is easy to because of the band of oxygen
Enter and aoxidized, and the primary particle for influencing presoma is formed and pattern, and serious puzzlement is caused to the synthesis of presoma.
When being detected to oxygen content, otherwise detection temperature requirement, can cause detection device fragile less than 45 DEG C
Wait harmful effects.And the reaction temperature for synthesizing multicomponent material presoma at present is mostly higher than 50 DEG C.Therefore it must be taken from reaction kettle
Sample, addition flow cell starts to detect after sample is cooled to the temperature range of oxygen analyser requirement.The detection method has hysteresis quality;
A small amount of oxygen can be introduced again by being placed after sample takes out simultaneously, so as to influence the judgement to legitimate reading;How effectively to monitor
Oxygen content in reaction kettle, targetedly takes measures, it appears very important.
Utility model content
The utility model offer is a kind of to be overcome the above problem or solves the above problems at least partly more for monitoring
The system of oxygen content in first material precursor building-up process, to solve during multicomponent material precursor synthesis, oxygen contains in reaction kettle
The monitoring of amount is not in time, monitoring efficiency is low, accuracy is not high and reaction kettle in the inefficient skill of Control for Oxygen Content in reagent
Art problem.
One side according to the present utility model is provided and a kind of is contained for oxygen during monitoring multicomponent material precursor synthesis
The system of amount, including the probe tube extending into reaction kettle interior reagent and for monitoring in the sample that the probe tube takes out
The monitoring device of oxygen content, and be provided between the reaction kettle and the monitoring device for reducing the temperature of the sample
Cooling device, one end of the cooling device is connected with the probe tube, the other end of the cooling device and the monitoring
Device is connected.
Further, the cooling device includes the solution pool for being loaded with coolant, and infusion is provided in the solution pool
Pipeline, the infusion pipeline are immersed in coolant, and one end of the infusion pipeline is connected with probe tube, the woven hose
The other end on road is connected with the monitoring device.
Further, the infusion pipeline is spirality pipeline.
Further, the end that the probe tube is located on the outside of reaction kettle is provided with the peristaltic pump for extracting sample.
Further, the monitoring device includes for monitoring in sample the sensor of oxygen content and for dynamically storing up
The flow cell of storage sample product;The infusion pipeline is connected with the flow cell, and the sensor is inserted into the sample in the flow cell
In.
Further, what the bottom of the flow cell was provided with sample in discharge flow pond is opened and closed leakage fluid dram.
Further, the bottom of the flow cell is the revolving body of variable cross-section.
The beneficial effects of the utility model are mainly as follows:
(1) probe tube is extend into reaction kettle, and cooling device is set between reaction kettle and monitoring device, can be realized
To the real time monitoring of oxygen content in reaction kettle, it can avoid introducing oxygen or other impurities into sample or reagent, improve prison
Control efficiency and monitoring accuracy;
(2) cooling device uses and is submerged into spiral element line structure in coolant, simple in structure, and cooling effect is good
It is good;
(3) monitoring device is further ensured that using flow cell and the matched structure of sensor in dynamic monitoring reaction kettle
The instantaneity and accuracy of oxygen content in reagent.
Description of the drawings
Fig. 1 is monitors oxygen content during multicomponent material precursor synthesis according to one kind in the utility model embodiment
System structure diagram;
Fig. 2 is monitors oxygen content during multicomponent material precursor synthesis according to one kind in the utility model embodiment
System cooling device structure diagram.
Specific embodiment
With reference to the accompanying drawings and examples, specific embodiment of the present utility model is described in further detail.Below
Embodiment is used to illustrate the utility model, but be not intended to limit the scope of the present invention.
It is shown in Figure 1, it is a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, including sampling
Pipe 2, cooling device 4 and monitoring device 5.One end of probe tube 1 extend into the inside of reaction kettle 1, and extend into inside reaction kettle 1
In the mix reagent for participating in reaction, for extracting reagent as sample, to monitor the oxygen content in sample.Monitoring device 5 is used
Analysis is detected in the sample extracted to probe tube 2, to obtain the oxygen content situation in sample, and then analyzes reaction kettle 1
The oxygen content of middle reagent, so as to be monitored to the oxygen content during multicomponent material precursor synthesis.
Cooling device 4 is set between reaction kettle 1 and monitoring device 5, and one end of cooling device 4 is connected with probe tube 2, cold
But the other end of device 4 is connected with monitoring device 5.Cooling device 4 is used to carry out cooling treatment to the sample that probe tube 2 extracts,
The damage of monitoring device 5 is caused to avoid the directly measurement high temp samples of monitoring device 5.
Since during multicomponent material presoma is synthesized, the reagent in reaction kettle 1 is usually in the temperature higher than 50 DEG C
Under the conditions of react, the temperature of sample extracted by probe tube 2 is higher, be not suitable for monitoring device 5 directly it is measured.If
It places after sample is taken out, is measured again after sample cooling, it not only can there are certain hysteresis qualitys, it is also possible to environment can be introduced
In oxygen and influence monitor accuracy.
Therefore, cooling device 4 is set between monitoring device 5 and probe tube 2, and the sample extracted by probe tube 2 is direct
It is detected after 4 cooling treatment of cooling device, then through monitoring device 5 to analyze the oxygen content in sample, and then in reaction kettle 1
Oxygen content in reagent is monitored.Using between monitoring device 5 and probe tube 2 set cooling device 4 structure, not only
The promptness of detection oxygen content can be improved, to realize the real time monitoring to oxygen content, additionally it is possible to avoid being introduced into environment
Oxygen, improve analysis and monitoring accuracy.
Specifically, when structure inside reaction kettle 1 is stretched into one end using probe tube 2, probe tube 2 and reaction kettle 1 can be made
Position fix, and processing is sealed to the position of contact to the outer wall and reaction kettle 1 of probe tube 2.Probe tube 2 is extracting sample
During product and during entire monitoring, reaction kettle 1 all in sealing state, the oxygen that will not be introduced into environment or its
His impurity generates harmful effect to avoid to the reaction of reagent in reaction kettle 1.
Shown in Figure 2 in another specific embodiment, cooling device 4 includes infusion pipeline 42 and contains to cool down
The solution pool 41 of liquid, infusion pipeline 42 are immersed in the coolant contained in solution pool 41.Also, one end of infusion pipeline 42 with
Probe tube 2 is connected, and the other end of infusion pipeline 42 is connected to monitoring device 5.Specifically, coolant can be used water or contain second
Aqueous solution of glycol etc., as long as can achieve the effect that cool.
It is conveyed into infusion pipeline 42 by the sample extracted in probe tube 2, monitoring is delivered to via infusion pipeline 42
Device 5 is detected sample analysis by monitoring device 5.Sample via in infusion pipeline 42 by when, by infusion pipeline 42 outside
The coolant of side carries out cooling treatment to the sample flowed through in infusion pipeline 42, then is transported to the temperature of the sample of monitoring device 5
It spends relatively low, directly sample can in real time be detected by monitoring device 5.
The structure of cooling device 4 is simple, but can realize the good result to sample cooling treatment.Meanwhile sampled pipe 2
The sample extracted is directly conveyed into infusion pipeline 42 after cooling treatment, i.e., by monitoring device 5 be detected analysis namely
It is that sample flows in pipeline to convey and be cooled, whole process carries out in the environment of closing, can effectively avoid environment
The introducing of middle oxygen, not only increases treatment effeciency, also improves monitoring accuracy.
In another specific embodiment, infusion pipeline 42 is spirality pipeline.The woven hose being submerged into coolant
Road 42 uses spirality pipeline, increases the length that infusion pipeline 42 is submerged into coolant.Sample flows in infusion pipeline 42
When dynamic, the path of sample flow can be increased, extend sample and interact and the time of cooled processing with coolant, so as to
The temperature of sample is effectively reduced, in order to which monitoring device 5 is in time detected sample analysis, improves the instantaneity of monitoring.
In another specific embodiment, the end that probe tube 2 is located on the outside of reaction kettle is provided with peristaltic pump 3.It is compacted
Dynamic pump 3 improves sampling efficiency for probe tube 2 to be coordinated to extract sample from reaction kettle 1 automatically.It is filled using peristaltic pump 3 and cooling
4 matched structures are put, can realize the at-once monitor to sample size in reagent in reaction kettle 1.
In another specific embodiment, include sensing for testing and analyzing the monitoring device 5 of oxygen content in sample
Device and flow cell.The measurement end of sensor is submerged into the sample in flow cell, for being examined to the oxygen content in sample
Survey analysis;The sample that flow cell is extracted for interim or dynamic storing by probe tube 2, so that sensor is to the oxygen in sample
Content is detected analysis.
Specifically, one end of infusion pipeline 42 is connected with flow cell.The sample that probe tube 2 is obtained out of reaction kettle 1 is through defeated
Liquid pipeline 42 is transported in flow cell, and measurement of oxygen content is carried out by the sensor being inserted into flow cell.
Specifically, monitoring device 5 can realize the sample extracted to reaction kettle 1 using the flow cell of dynamic storing sample
The dynamic monitoring process of product.Meanwhile using flow cell and the matched structure of sensor, it is applied not only to the device of detection and analysis
It is simple in structure, moreover, it can realize dynamic monitoring in real time.
Specifically, monitoring device 5 further includes the display screen 51 being connected with sensor.Sensor is detected sample analysis
Afterwards, what detection structure can be immediately shows on display screen 51, to improve the convenience of monitoring.
In another specific embodiment, what the bottom of flow cell was provided with sample in discharge flow pond is opened and closed drain
Mouthful.The bottom that leakage fluid dram is arranged on flow cell can be opened and closed, convenient for being completely exhausted out flow cell to the sample for having been subjected to detection, in favor of
Detection to oxygen content in sample.
When being detected to the sample in flow cell, leakage fluid dram closing can be opened and closed.When the sample detection in flow cell is complete
Bi Hou can be opened and closed leakage fluid dram opening, the sample in flow cell be discharged, in order to the detection to next group sample.Alternatively,
The openings of sizes of leakage fluid dram can be opened and closed to control the flow regime of sample in flow cell by adjusting, so as to measure dynamic stream
Oxygen content in dynamic sample.
Specifically, the sensor for measuring oxygen content in sample uses dissolved oxygen sensor.The electrode of dissolved oxygen sensor
Outside be coated with allow dissolved gas by diaphragm, electrode and electrolyte is enable to be separated with measured liquid, it is only molten
Solve gas-permeable overlay film.Therefore protect sensor, can prevent electrolyte escape and prevent foreign substance immersion and
Cause to pollute and poison.
In another specific embodiment, the bottom of the flow cell is the revolving body of variable cross-section.Specifically, flow cell
For the revolving body of variable cross-section, and direction from top to bottom, the area in section are gradually reduced, and the bottom for making flow cell is tool downwards
There is the structure at certain angle of inclination, convenient for the discharge of sample in flow cell.
In another specific embodiment, in practical measurement process, the oxygen content regulation and control in reaction kettle 1 in reagent
The amount of nitrogen is passed through into reaction kettle 1.Specifically, nitrogen can be passed through by regulating and controlling into reaction kettle 1 by being passed through the amount of nitrogen
Flow and time are controlled.
Specifically, the oxygen content in reaction kettle 1 in reagent is monitored by above system, i.e. probe tube 2 is from reaction
Sample is extracted in kettle 1, and the sample of extraction is delivered to monitoring device 5 after 4 cooling treatment of cooling device, by monitoring device 5
Analysis is detected to the oxygen content in sample.When the oxygen content in sample is excessively high, nitrogen is passed through into reaction kettle 1.
At the same time, sample is extracted in the slave reaction kettle 1 of probe tube 2 continuously or intermittently, and be delivered to monitoring device 5 into
Row monitoring analysis.Until the oxygen content in the sample extracted stops being passed through nitrogen into reaction kettle 1 less than threshold limit value
Gas.
In this way, it can not only effectively ensure that the oxygen content in reaction kettle 1 in reagent is low, not interfere with anti-
The quality of reagent reaction products obtained therefrom in kettle 1 is answered, meanwhile, the dosage of nitrogen can be reduced, avoids into reaction kettle 1 leading to always
Enter nitrogen.So as to reduce cost, and ensure product quality.
In another specifically embodiment, when the oxygen content in reagent in reaction kettle 1 is excessively high, by reaction kettle
Nitrogen is passed through in 1, to reduce the oxygen content in reaction kettle 1 in reagent.While nitrogen is passed through into reaction kettle 1, may be used also
To add reducing agent into reaction kettle 1, to avoid in reaction kettle 1 reagent aoxidized or reduced reagent by oxygenation efficiency.Specifically
Ground, the reducing agent added into reaction kettle 1 can be the substances such as hydrazine hydrate.
It is understood that reduce the oxygen content in reaction kettle 1 in reagent, nitrogen can be passed through into reaction kettle 1
Protection;The reducing agents such as hydrazine hydrate can also be added while nitrogen is passed through, are contained with reducing the oxygen in reaction kettle 1 in reagent
Amount.
The utility model it is a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, probe tube 2
One end extend into inside reaction kettle 1 to extract sample, the sample extracted is directly transported after 4 cooling treatment of cooling device
To monitoring device 5, the oxygen content in sample is tested and analyzed by monitoring device 5;According to the oxygen content detected, i.e.,
When the adjusting nitrogen amount being passed through into reaction kettle 1 or the nitrogen and the amount of reducing agent that are passed through simultaneously.Using the system and side
Method can carry out real-time monitoring and regulation, to improve product quality to the oxygen content in reagent in reaction kettle.
Finally, the method for the utility model is only preferable embodiment, is not intended to limit the protection of the utility model
Range.Within the spirit and principle of the utility model, any modification, equivalent replacement, improvement and so on should be included in
Within the scope of protection of the utility model.
Claims (7)
- It is 1. a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, which is characterized in that including extending into Probe tube in reaction kettle interior reagent and the monitoring device for monitoring oxygen content in the sample of the probe tube taking-up, And the cooling device of the temperature for reducing the sample is provided between the reaction kettle and the monitoring device, the cooling One end of device is connected with the probe tube, and the other end of the cooling device is connected with the monitoring device.
- 2. it is as described in claim 1 a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, it is special Sign is that the cooling device includes the solution pool for being loaded with coolant, and infusion pipeline is provided in the solution pool, described defeated Liquid pipeline is immersed in coolant, and one end of the infusion pipeline is connected with probe tube, the other end of the infusion pipeline It is connected with the monitoring device.
- 3. it is as claimed in claim 2 a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, it is special Sign is that the infusion pipeline is spirality pipeline.
- 4. it is as described in claim 1 a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, it is special Sign is that the end that the probe tube is located on the outside of reaction kettle is provided with the peristaltic pump for extracting sample.
- 5. it is as claimed in claim 2 a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, it is special Sign is that the monitoring device includes monitoring the sensor of oxygen content and the stream for dynamic storing sample in sample Dynamic pond;The infusion pipeline is connected with the flow cell, and the sensor is inserted into the sample in the flow cell.
- 6. it is as claimed in claim 5 a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, it is special Sign is, what the bottom of the flow cell was provided with sample in discharge flow pond is opened and closed leakage fluid dram.
- 7. it is as claimed in claim 5 a kind of for monitoring the system of oxygen content during multicomponent material precursor synthesis, it is special Sign is that the bottom of the flow cell is the revolving body of variable cross-section.
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