CN215640707U - Measuring device for gas production rate of silicon-based negative electrode slurry - Google Patents

Abstract

The embodiment of the utility model relates to a device for measuring the gas production rate of silicon-based cathode slurry, which comprises: the device comprises a weighing platform, a container containing liquid, a lifting appliance, a containing bag containing silicon-based cathode slurry, a temperature control module for monitoring and adjusting the temperature of the liquid in the container and a data monitoring and processing module for calculating the gas production rate; the container is arranged above the weighing platform; the lifting appliance is arranged above the container; the containing bag is suspended by a hanger and is immersed in the liquid in the container; the temperature control module comprises a temperature measuring part and a temperature adjusting component; the temperature adjusting component is arranged outside the container; the temperature measuring piece extends into the liquid in the container; the data monitoring processing module is electrically connected with the weighing platform. The device for measuring the gas production rate of the silicon-based cathode slurry improves the measurement sensitivity.

Description

Measuring device for gas production rate of silicon-based negative electrode slurry

Technical Field

The utility model relates to the technical field of battery material detection, in particular to a device for measuring the gas production rate of silicon-based negative electrode slurry.

Background

High capacity silicon-based anode materials have been successfully used in commercial applications, such as nano silicon carbon anode materials and silicon monoxide carbon anode materials. With the development of high-capacity silicon-based negative electrode materials, means such as surface modification and element doping are widely used for improving material performance, and especially, the pre-lithiation technology is more remarkable in improving the first effect and the energy density of a battery. However, surface modification and element doping techniques are often accompanied by unstable factors, such as surface alkalinity and incomplete coating, which result in exposure of nano-silicon and gas generation due to reaction of hydroxyl ions. In the prior art, the gas production rate of the silicon electrode material is mostly measured by calculating the weight difference before and after gas production, and the change of the gas production rate in the gas production process cannot be inspected, so that the reaction intensity of the silicon electrode material slurry at a certain moment cannot be judged.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model aims to provide a device for measuring the gas production rate of silicon-based cathode slurry, which can monitor the gas production rate of the silicon-based cathode slurry in real time, improve the measurement sensitivity, further disclose the gas production mechanism and make effective measures for inhibiting the gas production reaction.

In view of the above, the present invention provides a device for measuring a gas generation rate of a silicon-based anode slurry, the device comprising: the device comprises a weighing platform, a container containing liquid, a lifting appliance, a containing bag containing silicon-based cathode slurry, a temperature control module for monitoring and adjusting the temperature of the liquid in the container and a data monitoring and processing module for calculating the gas production rate;

the container is arranged above the weighing platform;

the spreader is disposed above the container;

the containing bag is suspended by the hanger and is immersed in the liquid of the container;

the temperature control module comprises a temperature measuring part and a temperature adjusting component; the temperature regulating assembly is arranged outside the container; the temperature measuring piece extends into the liquid in the container;

the data monitoring and processing module is electrically connected with the weighing platform.

Preferably, the temperature adjustment assembly includes: the water circulation device comprises a circulating water pipe, a water supply unit and a control unit;

the circulating water pipe is surrounded on the outer side of the container;

the water supply unit is connected with the circulating water pipe;

the control unit is respectively connected with the temperature measuring part and the water supply unit.

Further preferably, the circulating water pipe comprises a water inlet and a water outlet; the water inlet is connected with the water supply unit.

Still further preferably, when the circulating water pipe is spiral, the water inlet is arranged at the lower end of the circulating water pipe; the water outlet is arranged at the upper end of the circulating water pipe;

when the circulating water pipe is a plurality of annular pipes arranged in parallel, the water inlet and the water outlet are respectively arranged at two ends of each annular pipe.

Preferably, the measuring device further comprises a pH measuring module;

the pH measuring module is positioned on the weighing platform, and a probe of the pH measuring module is immersed in the containing bag.

Preferably, the measuring device further comprises a platform and a fixing rod;

the platform is arranged below the weighing platform;

the fixed rod is positioned on one side of the platform and comprises a vertical rod, a first extension rod, a second extension rod and a third extension rod, wherein the first extension rod is arranged on the vertical rod and used for fixing the lifting appliance, the second extension rod is used for fixing the temperature measuring part, and the third extension rod is used for fixing the temperature adjusting component.

Further preferably, the vertical rod is arranged perpendicular to the platform; the first extension bar, the second extension bar and the third extension bar are arranged in parallel to the platform.

Preferably, the detection head of the temperature measuring piece is positioned 1/2-2/3 below the liquid level of the container; the hanger is a flexible wire.

Preferably, the distance from the bottom end of the spreader to the liquid level of the container is no less than 1/3.

Preferably, the containing bag comprises an aluminum-plastic film package and an air bag; the air bag is communicated with the aluminum-plastic film package.

Compared with the prior art, the method has the following beneficial effects:

according to the device for measuring the gas production rate of the silicon-based negative electrode slurry, the weighing platform is adopted, the tension does not need to be measured, and the measurement sensitivity is improved; in addition, this application is still through setting up temperature control module, can real-time measurement temperature and adjust, has solved the liquid temperature's in the container that silicon-based negative pole thick liquids are brought because of the exothermic change of producing gas to lead to arousing the inaccurate problem of data measurement that buoyancy change brought after the liquid density change.

Drawings

Fig. 1 is a schematic structural diagram of a device for measuring a gas production rate of a silicon-based anode slurry according to an embodiment of the present invention;

fig. 2 is a partial structural cross-sectional view of a device for measuring a gas production rate of a silicon-based anode slurry according to an embodiment of the present invention.

Detailed Description

The technical solution of the present invention will be further described in detail with reference to the following embodiments. The following examples are merely illustrative and explanatory of the present invention and should not be construed as limiting the scope of the utility model. All the technologies realized based on the above-mentioned contents of the present invention are covered in the protection scope of the present invention.

The test methods described in the following examples are all conventional methods unless otherwise specified; the reagents and materials, unless otherwise indicated, are commercially available.

Fig. 1 is a schematic structural diagram of a device for measuring a gas production rate of a silicon-based anode slurry according to an embodiment of the present invention; fig. 2 is a partial structural cross-sectional view of a device for measuring a gas production rate of a silicon-based anode slurry according to an embodiment of the present invention. With reference to fig. 1 and fig. 2, the present invention provides a device for measuring gas production rate of silicon-based negative electrode slurry, including: the device comprises a platform 1, a fixed rod 2, a lifting appliance 3, a weighing platform 4, a container 5, a containing bag 6, a temperature control module 7, a pH measuring module 8 and a data monitoring and processing module 9.

The platform 1 is the supporting and fixing structure of the measuring device.

The fixing rod 2 is arranged at one side of the platform 1. The fixing lever 2 includes: a vertical rod 20, a first extension rod 21, a second extension rod 22 and a third extension rod 23. The first extension bar 21, the second extension bar 22 and the third extension bar 23 are arranged on the vertical bar 20 in sequence from top to bottom. As an alternative, the vertical bars 20 are arranged perpendicular to the platform 1. The first, second and third projecting bars 21, 22, 23 are arranged parallel to the platform 1.

The spreader 3 is fixed to the first projecting bar 21. In an alternative, the spreader 3 may be a flexible wire. The bottom end of the spreader 3 is at a distance from the liquid level of the container 5 of not less than 1/3, the purpose of which is to allow the bag 6 to be completely submerged below the liquid level.

The weighing station 4 is a weight measuring module of the measuring device. The weighing station 4 is arranged above the platform 1. The weighing station 4 may be embodied as a high-precision high-sensitivity balance.

The container 5 contains liquid which can provide buoyancy conditions for the reaction of the silicon-based anode slurry. In fig. 1 and 2, the liquid level of the liquid is shown by a dotted line.

The containing bag 6 is a space for reaction of the silicon-based cathode slurry, and the volume of the containing bag can be changed. In a preferred embodiment, the bag 6 comprises an aluminum-plastic film package 61 and an air bag 62. The aluminum-plastic film package 61 is mainly used for containing silicon-based negative electrode slurry. The air bag 62 is communicated with the aluminum-plastic film package 61, when the silicon-based negative electrode slurry in the aluminum-plastic film package 61 reacts to generate gas, the gas can enter the air bag 62, and the phenomenon that the slurry leaks out due to volume expansion and breakage of the aluminum-plastic film package 61 is avoided.

The temperature control module 7 comprises a temperature measuring member 71 and a temperature adjusting assembly 72.

The temperature measuring member 71 may be a thermometer. The temperature measuring element 71 projects into the liquid in the container 5, the temperature measuring element 71 preferably being inserted vertically into the liquid. In order to ensure the accuracy of temperature measurement, the temperature measuring part 71 is suspended and fixed by the second extension bar 22. In a preferred example, the detection head of the temperature measuring part 71 is located 1/2-2/3 below the liquid level of the container 5.

The temperature adjusting component 72 can provide a constant temperature condition for the reaction of the silicon-based cathode slurry, and the phenomenon that the density of liquid in the container 5 is changed due to the change of temperature in the gas production process, so that the buoyancy and the gravity are changed, and the measurement is inaccurate is avoided. The temperature regulating assembly 72 is disposed outside the container 5.

The temperature adjustment assembly 72 may specifically include: a circulating water pipe 721, a water supply unit 722, and a control unit 723.

The circulating water pipe 721 is wound around the outside of the container 5 and fixed by the third protruding rod 23. The circulation water pipe 721 includes a water inlet and a water outlet. The water inlet is connected with a water supply unit 722. The circulating water pipe 721 may include, but is not limited to, the following two:

in the mode a, when the circulating water pipe 721 is spiral, the water inlet is arranged at the lower end of the circulating water pipe 721; the water outlet is provided at the upper end of the circulation water pipe 721.

Mode B, when the water circulation pipe 721 is a plurality of annular pipes arranged in parallel, the water inlet and the water outlet are respectively provided at both ends of each annular pipe.

The control unit 723 is connected with the temperature measuring part 71 and the water supply unit 722 respectively, can read the measured value of the temperature measuring part 71 in real time, and can indirectly adjust the temperature of the liquid in the container 5 by controlling the temperature of the water supply unit 722, thereby avoiding the error of data measurement caused by the change of the liquid temperature in the reaction process and improving the measurement precision.

The pH measuring module 8 is used for detecting the change of pH in the gas production process of the silicon-based negative electrode slurry. The pH measuring module 8 is positioned on the weighing platform 4, and the probe of the pH measuring module 8 is immersed in the containing bag 6.

The data monitoring and processing module 9 can record and calculate the measurement data of the silicon-based negative electrode slurry in the gas production process to obtain the gas production rate. The data monitoring and processing module 9 is respectively and electrically connected with the weighing platform 4 and the pH measuring module 8.

The components of the device for measuring the gas production rate of the silicon-based anode slurry and the connection relationship among the components are described above, and the use principle of the device is described below.

(1) The water supply unit 722, the control unit 723 and the temperature measuring member 71 are turned on. A preset temperature, for example 25 ℃, is set by the control unit 723;

(2) filling the container 5 with a liquid, such as water or ethanol, etc., and opening the pH measuring module 8 and the weighing station 4;

(3) opening the data monitoring processing module 9;

(4) filling the silicon-based negative electrode slurry to be tested into the aluminum-plastic film package 61 of the containing bag 6, and exhausting the gas in the air bag 62;

(5) fixing the bottom end of the hanger 3 on the containing bag 6, and placing the containing bag 6 below the liquid level of the container 5;

(6) the data monitoring and processing module 9 records the measurement data of the pH value measurement module 8 and the weighing platform 4 and draws a pH value-time curve and a gas production rate-time curve;

calculating the gas production Vx according to formula (I):

Vx＝(m_x2-m_x1)*g/ρ_T… … … … formula (I)

Calculating the gas production rate according to formula (II):

k_v＝d(V_x2-V_x1)/d(t₂-t₁) … … … … formula (II)

Wherein Vx is the silicon-based negative electrode slurry at delta t (t)₂-t₁) Gas production over time;

m_x1is t₁The weight of the aluminum-plastic film package 61 filled with the silicon-based cathode slurry completely immersed in the liquid is read by the weighing platform 4;

m_x2is t₂The weight of the aluminum-plastic film package 61 filled with the silicon-based cathode slurry at the moment when the aluminum-plastic film package is completely immersed in the liquid is read by the weighing platform 4;

V_x1is t₁The volume of the aluminum plastic film package 61 filled with the silicon-based cathode slurry completely immersed in the liquid at the moment;

V_x2is t₂The volume of the aluminum-plastic film package 61 filled with the silicon-based negative electrode slurry when the film package is completely immersed in the liquid at that time;

ρ_Tis the density of the liquid in the container 5 at a temperature T, T being a preset temperature;

the relationship between the gas production rate and the pH value in a certain time period can be obtained from the pH value-time curve and the gas production rate-time curve.

According to the device for measuring the gas production rate of the silicon-based negative electrode slurry, the weighing platform is adopted, the tension does not need to be measured, and the measurement sensitivity is improved; in addition, this application is still through setting up temperature control module, can real-time measurement temperature and adjust, has solved the liquid temperature's in the container that silicon-based negative pole thick liquids are brought because of the exothermic change of producing gas to lead to arousing the inaccurate problem of data measurement that buoyancy change brought after the liquid density change.

The above-mentioned embodiments are intended to illustrate the objects, technical solutions and advantages of the present invention in further detail, and it should be understood that the above-mentioned embodiments are merely exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (10)

1. A measuring device for gas production rate of silicon-based negative electrode slurry is characterized by comprising: the device comprises a weighing platform, a container containing liquid, a lifting appliance, a containing bag containing silicon-based cathode slurry, a temperature control module for monitoring and adjusting the temperature of the liquid in the container and a data monitoring and processing module for calculating the gas production rate;

the container is arranged above the weighing platform;

the spreader is disposed above the container;

the containing bag is suspended by the hanger and is immersed in the liquid of the container;

the temperature control module comprises a temperature measuring part and a temperature adjusting component; the temperature regulating assembly is arranged outside the container; the temperature measuring piece extends into the liquid in the container;

the data monitoring and processing module is electrically connected with the weighing platform.

2. The measurement device of claim 1, wherein the temperature adjustment assembly comprises: the water circulation device comprises a circulating water pipe, a water supply unit and a control unit;

the circulating water pipe is surrounded on the outer side of the container;

the water supply unit is connected with the circulating water pipe;

the control unit is respectively connected with the temperature measuring part and the water supply unit.

3. The measuring device of claim 2, wherein the circulating water pipe comprises a water inlet and a water outlet; the water inlet is connected with the water supply unit.

4. A measuring device according to claim 3, wherein the water inlet is provided at a lower end of the water circulation pipe when the water circulation pipe is helical; the water outlet is arranged at the upper end of the circulating water pipe;

when the circulating water pipe is a plurality of annular pipes arranged in parallel, the water inlet and the water outlet are respectively arranged at two ends of each annular pipe.

5. The measurement device of claim 1, further comprising a pH measurement module;

the pH measuring module is positioned on the weighing platform, and a probe of the pH measuring module is immersed in the containing bag.

6. The measurement device of claim 1, further comprising a platform and a fixation bar;

the platform is arranged below the weighing platform;

the fixed rod is positioned on one side of the platform and comprises a vertical rod, a first extension rod, a second extension rod and a third extension rod, wherein the first extension rod is arranged on the vertical rod and used for fixing the lifting appliance, the second extension rod is used for fixing the temperature measuring part, and the third extension rod is used for fixing the temperature adjusting component.

7. A measuring device as claimed in claim 6, characterized in that the vertical bars are arranged perpendicular to the platform; the first extension bar, the second extension bar and the third extension bar are arranged in parallel to the platform.

8. The measuring device according to claim 1 or 6, wherein the detection head of the temperature measuring part is located 1/2-2/3 below the liquid level of the container; the hanger is a flexible wire.

9. The measuring device of claim 1, wherein the bottom end of the spreader is no less than 1/3 of the liquid level of the container.

10. A measuring device as claimed in claim 1, wherein the containing bag comprises an aluminium-plastic film pack and an air bag; the air bag is communicated with the aluminum-plastic film package.

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