阅读说明：本技术 双氟磺酰亚胺锂的制备方法及进料装置 (Preparation method and feeding device of lithium bis (fluorosulfonyl) imide ) 是由 王晓东 徐煜 韩航飞 陈华勇 郑伟建 于 2021-04-07 设计创作，主要内容包括：本发明公开了双氟磺酰亚胺锂的制备方法及进料装置,包括如下步骤：a、在反应釜中加入二氯亚砜；b、将氨基磺酸和氯磺酸在二氯亚砜中反应生成双氯磺酸亚胺；c、在反应釜的进料口中加入无水氟化氢进行氟化,得到双氟磺酰亚胺锂；d、对反应釜进行侧向分体清洗。本发明制备双氟磺酰亚胺锂和二氯亚砜加入处于两个区域进行,可避免二氯亚砜对人体的灼伤,而且二氯亚砜加入过程处于一定高度,便于设置防护装置,提高安全性和可靠性。具体反应生成双氯磺酸亚胺过程中,反应釜稳定性极高,保证了收集双氟磺酰亚胺锂的流畅性。对反应釜进行侧向分体清洗,方便对上筒体和下筒体进行拆装,适当增加清洗空间,便于对上筒体和下筒体进行清洗。(The invention discloses a preparation method and a feeding device of lithium bis (fluorosulfonyl) imide, which comprises the following steps: a. adding thionyl chloride into a reaction kettle; b. reacting sulfamic acid and chlorosulfonic acid in thionyl chloride to generate dichlorosulfonic acid imine; c. adding anhydrous hydrogen fluoride into a feed inlet of a reaction kettle for fluorination to obtain lithium bis (fluorosulfonyl) imide; d. and (4) laterally cleaning the reaction kettle in a split manner. The preparation of the lithium bis (fluorosulfonyl) imide and the addition of the thionyl chloride are carried out in two areas, so that the thionyl chloride can be prevented from burning a human body, and the addition process of the thionyl chloride is at a certain height, so that a protection device is convenient to arrange, and the safety and the reliability are improved. In the process of generating the bis (chlorosulfonyl) imide through the specific reaction, the stability of the reaction kettle is extremely high, and the fluency of collecting the bis (fluorosulfonyl) imide lithium is ensured. The reaction kettle is laterally and separately cleaned, the upper barrel and the lower barrel are conveniently disassembled and assembled, the cleaning space is properly increased, and the upper barrel and the lower barrel are conveniently cleaned.)

1. The preparation method of the lithium bis (fluorosulfonyl) imide is characterized by comprising the following steps:

a. adding thionyl chloride into a reaction kettle:

(1) the bottom of a reaction kettle is vertically arranged on a movable plate on a movable support through a fixed bolt, the reaction kettle comprises an upper barrel and a lower barrel, the upper barrel and the lower barrel are fixedly connected through a mounting bolt, two sections of positioning plates are welded on the outer side of the upper barrel, the movable plate moves on the movable support in a directional mode, then the positioning bolts on the positioning plates are screwed upwards, the bottom of the positioning bolts does not penetrate through the positioning plates, then the reaction kettle is controlled to move towards the direction of a feeding device through a lead screw motor arranged at the bottom of the movable support, the reaction kettle is arranged below the feeding device, the feeding device is fixed on the movable support through the mounting support, and the positioning plates on the two sides of the reaction kettle are tightly attached to the mounting support at;

(2) controlling a material pipe in the feeding device to descend so that the material pipe is communicated with a feeding pipe of the reaction kettle, then introducing thionyl chloride in the storage tank into the material pipe of the feeding device, and enabling the thionyl chloride to enter the reaction kettle through the material pipe and the feeding pipe of the reaction kettle;

b. reacting sulfamic acid and chlorosulfonic acid in thionyl chloride to produce bischlorosulfonimide:

(1) when the introduction of thionyl chloride in the reaction kettle is finished, stopping the introduction of thionyl chloride in the storage tank, controlling a material pipe in the feeding device to ascend to enable the material pipe to be separated from a feeding pipe of the reaction kettle, installing a driving motor on a movable support at the moment, fixedly connecting a turnover plate with the driving motor, supporting the turnover plate on the movable support, installing an L-shaped limiting plate on the movable support, controlling the reaction kettle to move away from the feeding device through a lead screw motor installed at the bottom of the movable support, screwing positioning bolts on the positioning plates when one positioning plate corresponds to the turnover plate up and down and the other positioning plate corresponds to the limiting plate up and down, screwing one positioning bolt between the other positioning plate and the turnover plate, and screwing the other positioning bolt between the other positioning plate and the limiting plate;

(2) adding sulfamic acid and chlorosulfonic acid into a feed inlet of a reaction kettle, and reacting the sulfamic acid and the chlorosulfonic acid in thionyl chloride to generate dichlorosulfoimine;

c. adding anhydrous hydrogen fluoride into a feed port of a reaction kettle for fluorination to obtain the lithium bis (fluorosulfonyl) imide, and collecting the lithium bis (fluorosulfonyl) imide through a discharge pipe of the reaction kettle;

d. and (3) laterally cleaning the reaction kettle in a split manner: demolish the discharging pipe from reation kettle's bottom department, unscrew the fixing bolt between reation kettle and the movable plate again, then driving motor control returning face plate clockwise rotation 90, make the reation kettle level set up, support reation kettle's last barrel again, then unscrew the construction bolt between last barrel and the lower barrel, demolish barrel down, wash barrel in the washing tank down, adopt the water pipe to spray the washing to the inside of last barrel again, then clean the inside of last barrel, after the washing is accomplished, dry last barrel and lower barrel again, after the drying is accomplished, pass through construction bolt with last barrel and fix to last barrel, then reversal driving motor, driving motor control returning face plate anticlockwise rotation 90, make reation kettle vertical setting, then install the discharging pipe in reation kettle's bottom department.

2. The method for producing lithium bis (fluorosulfonyl) imide according to claim 1, wherein: in the step b, heating reflux operation is carried out on the reaction kettle, and the temperature is controlled to be 50-140 ℃.

3. The method for producing lithium bis (fluorosulfonyl) imide according to claim 1, wherein: the movable support is provided with two sliding holes, T-shaped movable plates are adopted, the movable plates are arranged in the sliding holes, a connecting plate is welded between the two movable plates, a lead screw nut connected with a lead screw motor is fixed on the bottom surface of the connecting plate, the connecting plate is provided with a through hole, and the discharging pipe penetrates through the through hole.

4. The method for producing lithium bis (fluorosulfonyl) imide according to claim 1, wherein: in the step d, the upper barrel body is supported by the two-point supporting device, the two-point supporting device comprises a bottom plate, a first supporting plate and a second supporting plate, the first supporting plate is welded on the top surface of the bottom plate, the second supporting plate is welded on the side surface of the first supporting plate, the bottom plate is fixed at the bottom of the movable support by fastening screws, the positioning plate below the bottom plate is supported by the first supporting plate, and meanwhile, the outer side of the upper barrel body is supported by the second supporting plate.

5. The feeding device for the preparation method of lithium bis (fluorosulfonyl) imide according to claim 1, characterized in that: including casing and connecting pipe, the installing support welding is in the casing with between the movable support, the connecting pipe with material pipe intercommunication, the bottom of connecting pipe is used for the intercommunication the inlet pipe, the material pipe is worn out the top of casing, the inside of casing is equipped with the slide rail, the outside of connecting pipe is equipped with the slider, the slider is in reciprocate in the slide rail, the inside fixedly connected with cylinder of casing, the cylinder drive is connected the connecting pipe.

6. The feeding device according to claim 5, wherein: at least two connecting pipes are adopted, the connecting pipes are provided with fixing plates, and every two adjacent fixing plates are fixedly connected through a connecting bolt.

7. The feeding device according to claim 6, wherein: the outer side of the connecting pipe is welded with limiting bulges which are distributed up and down, a limiting groove is formed between the two limiting bulges which are distributed up and down, and the bottom of the air cylinder is fixedly connected with a clamping plate which is limited in the limiting groove.

Technical Field

The invention belongs to the technical field of lithium ion battery material preparation, and particularly relates to a preparation method and a feeding device of lithium bis (fluorosulfonyl) imide.

Background

In the prior art, lithium ion batteries are widely used in electronic products, electric vehicles, and energy storage devices due to their high energy density. Therefore, lithium ion battery products are generally required to have excellent performance such as high capacity, long life, high power factor, and safety. Specifically, the electrolytes with different compositions in the lithium ion battery cause differences in performance of the lithium ion battery to a great extent, and particularly, the problems of the lithium ion battery, such as service life and self-discharge, are significantly affected by high and low temperature use environments, decomposition and side reactions of the electrolytes. Therefore, attempts have been made to improve the above-mentioned problems of the battery by adding various additives to the electrolyte.

The lithium bis (fluorosulfonyl) imide has the characteristics of high temperature resistance and excellent low-temperature performance, has the advantages of good stability in water, environmental friendliness and the like, is widely applied to the electrolyte of a lithium ion battery, can effectively reduce the high-low temperature resistance of an SEI layer formed on the surface of an electrode at a low temperature, and reduces the capacity loss of the lithium ion battery in the placing process, thereby providing a high-capacity battery and improving the electrochemical performance of the battery.

China Special interest 2020.04.24 discloses a patent invention named as a preparation method of lithium bis (fluorosulfonyl) imide and lithium bis (fluorosulfonyl) imide (application number: CN202010330602.9), which adopts easily available thionyl chloride, chlorosulfonic acid and sulfamic acid as raw materials. The hazards of thionyl chloride are: after being inhaled, orally taken or absorbed through skin, the thionyl chloride is harmful to human bodies, has strong corrosiveness and strong irritation, and can cause burn of human bodies, so that how to safely and reliably introduce the thionyl chloride into the reaction kettle is a technical problem to be solved by the technical personnel in the field.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a preparation method and a feeding device of lithium bis (fluorosulfonyl) imide. In the process of generating the bis (chlorosulfonyl) imide through the specific reaction, the stability of the reaction kettle is extremely high, and the fluency of collecting the bis (fluorosulfonyl) imide lithium is ensured. Carry out the side direction components of a whole that can function independently washing to reation kettle, conveniently carry out the dismouting to last barrel and lower barrel, suitably increase the washing space, be convenient for wash last barrel and lower barrel for reation kettle is inside to keep clean.

In order to solve the technical problems, the invention adopts the following technical scheme:

the preparation method of the lithium bis (fluorosulfonyl) imide adopts thionyl chloride, sulfamic acid and chlorosulfonic acid as raw materials, and the thionyl chloride is added in the largest amount, so that the thionyl chloride is preferentially introduced into a reaction kettle considering that the thionyl chloride has strong corrosivity and strong irritation and can cause the damage of human burns.

The method is characterized by comprising the following steps:

a. adding thionyl chloride into a reaction kettle:

(1) the bottom of the reaction kettle is vertically installed on the movable plate on the movable support through the fixing bolt, the reaction kettle comprises an upper barrel body and a lower barrel body, and the upper barrel body and the lower barrel body are fixedly connected through the mounting bolt, so that the upper barrel body and the lower barrel body are designed in a split type. Two sections of positioning plates are welded on the outer side of the upper barrel, and the moving plate moves on the moving support in a directional mode. And then the positioning bolt on the positioning plate is screwed upwards, so that the bottom of the positioning bolt does not penetrate out of the positioning plate, and the reaction kettle is prevented from being touched between the positioning bolt and the movable support in the moving process. Then the screw motor installed at the bottom of the movable support controls the reaction kettle to move towards the direction of the feeding device, the screw motor controls the screw nut to do directional reciprocating motion on the screw rod, the screw nut is connected with the movable plate, so that the reaction kettle is arranged below the feeding device, thionyl chloride is led into the reaction kettle at a certain height, the feeding device is fixed on the movable support through the mounting support, and the positioning plates on the two sides of the reaction kettle are tightly attached to the mounting support.

(2) The reaction kettle horizontally reciprocates under the control of the screw motor, and in order to enable the feeding pipe and the material pipe of the reaction kettle to be mutually matched and communicated, the material pipe moves up and down. And controlling the material pipe in the feeding device to descend so that the material pipe is communicated with a feeding pipe of the reaction kettle, then introducing thionyl chloride in the storage tank into the material pipe of the feeding device, and enabling the thionyl chloride to enter the reaction kettle through the material pipe and the feeding pipe of the reaction kettle.

b. Reacting sulfamic acid and chlorosulfonic acid in thionyl chloride to produce bischlorosulfonimide:

(1) when the introduction of thionyl chloride in the reaction kettle is finished, the introduction of thionyl chloride in the storage tank is stopped, the material pipe in the feeding device is controlled to ascend, so that the material pipe is separated from the feeding pipe of the reaction kettle, the driving motor is installed on the movable support at the moment and fixedly connected with the turnover plate, the turnover plate is supported on the movable support, the movable support is provided with an L-shaped limiting plate, then the reaction kettle is controlled to move away from the feeding device through a lead screw motor installed at the bottom of the movable support, when one of the positioning plates corresponds to the turnover plate up and down and the other one corresponds to the limiting plate up and down, the positioning bolts on the positioning plates are screwed, so that one of the positioning bolts is screwed between one of the positioning plates and the turnover plate, the other positioning bolt is screwed between the other positioning plate and the limiting plate, and under the connecting action of the, the reaction kettle is fixed on the turnover plate and the limiting plate, and the stability of the reaction in the reaction kettle is improved.

(2) Adding sulfamic acid and chlorosulfonic acid into a feed inlet of a reaction kettle, and reacting the sulfamic acid and the chlorosulfonic acid in thionyl chloride to generate dichlorosulfoimine.

c. Adding anhydrous hydrogen fluoride into a feed inlet of the reaction kettle for fluorination to obtain the lithium bis (fluorosulfonyl) imide, and collecting the lithium bis (fluorosulfonyl) imide through a discharge pipe of the reaction kettle.

d. And (3) laterally cleaning the reaction kettle in a split manner: and dismantling the discharge pipe from the bottom of the reaction kettle, and screwing out the fixing bolt between the reaction kettle and the movable plate to separate the reaction kettle from the movable plate. Then driving motor control returning face plate clockwise rotation 90 for reation kettle level sets up, supports reation kettle's last barrel again, then twists out the construction bolt between last barrel and the lower barrel, demolishs the lower barrel, can adopt the bracket to shift out lower barrel level. And cleaning the lower barrel in a cleaning tank, spraying and cleaning the inside of the upper barrel by adopting a water pipe, and wiping the inside of the upper barrel. In carrying out the side direction components of a whole that can function independently cleaning process to reation kettle, go up the barrel and set up agitating unit and motor, consequently wash last barrel on moving movable support, carry out spacing fixed to last barrel simultaneously, and then make reation kettle fix a position and set for position department at moving movable support, avoid the reation kettle after the washing can't be used for the preparation of bifluoro sulfonyl imide lithium next time. After the cleaning is finished, the upper barrel body and the lower barrel body are dried, after the drying is finished, the upper barrel body is fixed to the upper barrel body through the mounting bolt, then the driving motor is reversed, the driving motor controls the turnover plate to rotate 90 degrees anticlockwise, so that the reaction kettle is vertically arranged, and then the discharging pipe is arranged at the bottom of the reaction kettle.

Further, in the step b, heating reflux operation is carried out on the reaction kettle, and the temperature is controlled to be 50-140 ℃.

Further, the movable support is provided with two sliding holes, T-shaped movable plates are adopted, the movable plates are installed in the sliding holes, a connecting plate is welded between the two movable plates, a lead screw nut connected with a lead screw motor is fixed on the bottom surface of the connecting plate, the connecting plate is provided with a through hole, and a discharging pipe penetrates through the through hole, so that the movable plates can directionally move on the movable support at the same time.

Furthermore, in the step d, in consideration of the weight problem of the reaction kettle, the upper cylinder is supported by using a two-point supporting device, the two-point supporting device comprises a bottom plate, a first supporting plate and a second supporting plate, the first supporting plate is welded on the top surface of the bottom plate, the second supporting plate is welded on the side surface of the first supporting plate, the bottom plate is fixed at the bottom of the movable support by using fastening screws, the positioning plate below the bottom plate is supported by using the first supporting plate, and the outer side of the upper cylinder is supported by using the second supporting plate. The upper barrel is limited in supporting position, the lower positioning plate is supported by the first supporting plate to indirectly support the upper barrel, the second supporting plate supports the outer side of the upper barrel to directly support the upper barrel, and the technical problem that the supporting position of the upper barrel is limited is solved.

The feeding device for the preparation method of the lithium bis (fluorosulfonyl) imide is characterized in that: the material pipe is made of soft materials and can adapt to the change of the upper position and the lower position of the connecting pipe. The bottom of connecting pipe is used for communicateing the inlet pipe, and the top of casing is worn out to the material pipe, and the inside of casing is equipped with the slide rail, and the outside of connecting pipe is equipped with the slider, and the slider reciprocates in the slide rail, the inside fixedly connected with cylinder of casing, cylinder drive connection connecting pipe. Through cylinder control connection pipe, because the connecting pipe location is in the inside of casing for the connecting pipe reciprocates in the casing is inside, when the connecting pipe moves down, makes connecting pipe and inlet pipe match the intercommunication each other, and then makes intercommunication between material pipe, connecting pipe and the inlet pipe, controls certain velocity of flow, can let in thionyl chloride to reation kettle in.

Further, at least two connecting pipes are adopted, the connecting pipes are provided with fixing plates, and the two adjacent fixing plates are fixedly connected through connecting bolts, so that the connecting pipes are fixedly connected.

Furthermore, the outside welding of connecting pipe has spacing arch that distributes from top to bottom, forms the spacing groove between two spacing archs that distribute from top to bottom, and the bottom fixedly connected with chucking plate of cylinder, chucking plate are spacing in the spacing groove. Make the cylinder can control many connecting pipes and remove the same distance simultaneously, improve the accurate nature that connecting pipe and inlet pipe are connected.

Due to the adoption of the technical scheme, the invention has the following beneficial effects:

1. according to the invention, the screw motor arranged at the bottom of the movable support controls the reaction kettle to move towards the feeding device, the screw motor controls the screw nut to do directional reciprocating motion on the screw, the screw nut is connected with the movable plate, so that the reaction kettle is arranged below the feeding device, thionyl chloride is led into the reaction kettle at a certain height, a protection device is convenient to arrange, the safety and the reliability are improved, the feeding device is fixed on the movable support through the mounting support, and the positioning plates at two sides of the reaction kettle are tightly attached to the mounting support.

2. Through lead screw motor antiport for reation kettle returns initial position, reacts, makes preparation difluoride sulfonyl imide lithium like this and thionyl chloride add to be in two regions go on, and then makes the region that thionyl chloride added keep away from operating personnel, avoids thionyl chloride to the burn of human body.

3. According to the invention, one positioning plate corresponds to the turnover plate up and down, when the other positioning plate corresponds to the limiting plate up and down, the positioning bolts on the positioning plates are screwed, so that one positioning bolt is screwed between one positioning plate and the turnover plate, the other positioning bolt is screwed between the other positioning plate and the limiting plate, and the reaction kettle is fixed on the turnover plate and the limiting plate through the connection effect of the positioning bolts, so that the reaction stability in the reaction kettle is improved.

4. In the process of laterally cleaning the reaction kettle in a split manner, the stirring device and the motor are arranged on the upper cylinder, so that the upper cylinder is cleaned on the movable support, and meanwhile, the upper cylinder is limited and fixed, and the reaction kettle is positioned at the set position of the movable support, so that the problem that the cleaned reaction kettle cannot be used for preparing the next lithium bis (fluorosulfonyl) imide is avoided. After the cleaning is finished, the upper barrel body and the lower barrel body are dried, after the drying is finished, the upper barrel body is fixed to the upper barrel body through the mounting bolt, then the driving motor is reversed, the driving motor controls the turnover plate to rotate 90 degrees anticlockwise, so that the reaction kettle is vertically arranged, and then the discharging pipe is arranged at the bottom of the reaction kettle.

Drawings

The invention will be further described with reference to the accompanying drawings in which:

FIG. 1 is a schematic diagram of the structure of the present invention when thionyl chloride is added to a reaction vessel;

FIG. 2 is a schematic diagram of the structure of the present invention in the reaction to produce bischlorosulfonimide;

FIG. 3 is a schematic structural view of the present invention in a state of lateral split cleaning of a reaction vessel;

FIG. 4 is a schematic structural diagram of the moving plate moving on the moving rack in the present invention;

FIG. 5 is a schematic view of the structure of a reaction vessel in the present invention;

FIG. 6 is a schematic structural view of the two-point support device of the present invention;

FIG. 7 is a schematic view showing the inside structure of a feeding apparatus according to the present invention;

fig. 8 is a schematic structural view of the housing of the present invention.

In the figure, 1-a reaction kettle; 2-fixing the bolt; 3-moving the support; 4, mounting the cylinder; 5-lower cylinder body; 6, positioning a plate; 7-positioning bolts; 8-a feeding device; 9-a screw motor; 10-a material pipe; 11-feed pipe; 12-a limiting plate; 13-turning over the board; 14-a drive motor; 15-a feed inlet; 16-a housing; 17-mounting a bracket; 18-a connecting plate; 19-a through hole; 20-a feed screw nut; 21-a sliding hole; 22-moving the plate; 23-a screw rod; 24-a base plate; 25-a first support plate; 26-a second support plate; 27-a discharge pipe; 28-connecting pipe; 29-a slide block; 30-limiting protrusions; 31-a limiting groove; 32-a clamping plate; 33-a cylinder; 34-a fixed plate; 35-a two-point support device; 36-sliding rail.

Detailed Description

As shown in fig. 1 to 8, in the method for preparing lithium bis (fluorosulfonyl) imide according to the present invention, thionyl chloride, sulfamic acid and chlorosulfonic acid are used as raw materials, and because thionyl chloride is added in the largest amount, and considering that thionyl chloride has strong corrosivity and strong irritation, and can cause the damage of human body burn, thionyl chloride is preferably introduced into a reaction kettle.

The preparation method of the lithium bis (fluorosulfonyl) imide comprises the following steps:

a. thionyl chloride was added to reaction vessel 1:

(1) the bottom of the reaction kettle 1 is vertically arranged on a movable plate 22 on a movable bracket 3 through a fixed bolt 2. The moving support 3 is provided with two sliding holes 21, T-shaped moving plates 22 are adopted, the moving plates 22 are installed in the sliding holes 21, a connecting plate 18 is welded between the two moving plates 22, a lead screw nut 20 connected with a lead screw motor 9 is fixed on the bottom surface of the connecting plate 18, and the connecting plate 18 is provided with a through hole 19, so that the moving plates 22 can simultaneously move directionally on the moving support 3.

Reaction kettle 1 includes barrel 4 and barrel 5 down, goes up barrel 4 and barrel 5 down and passes through construction bolt fixed connection for go up barrel 4 and the split type design of barrel 5 down, discharging pipe 27 that barrel 5 bottom is connected down passes through-hole 19. Two sections of positioning plates 6 are welded on the outer side of the upper barrel 4, and the moving plate 22 moves on the moving support 3 in a directional mode. And then the positioning bolt 7 on the positioning plate 6 is screwed upwards, so that the bottom of the positioning bolt 7 does not penetrate out of the positioning plate 6, and the reaction kettle 1 is prevented from being touched between the positioning bolt 7 and the movable support 3 in the moving process. Then lead screw motor 9 through the installation of movable support 3 bottom controls reation kettle 1 and removes towards the feed arrangement direction, lead screw motor 9 control screw-nut 20 directional reciprocating motion on lead screw 23, screw-nut 20 and movable plate 22 are connected for reation kettle 1 sets up the below at feed arrangement 8, make thionyl chloride be in the take the altitude and let in reation kettle 1 in, this feed arrangement 8 is fixed on movable support 3 through installing support 17, the locating plate 6 of reation kettle 1 both sides is hugged closely on installing support 17 this moment.

(2) The reaction kettle 1 horizontally reciprocates under the control of the screw motor 9, and in order to enable the feeding pipe 11 and the material pipe 10 of the reaction kettle 1 to be mutually matched and communicated, the material pipe 10 vertically moves. And controlling a material pipe 10 in the feeding device 8 to descend, so that the material pipe 10 is communicated with a feeding pipe 11 of the reaction kettle 1, then introducing thionyl chloride in the storage tank into the material pipe 10 of the feeding device 8, and allowing the thionyl chloride to enter the reaction kettle 1 through the material pipe 10 and the feeding pipe 11 of the reaction kettle 1.

b. Reacting sulfamic acid and chlorosulfonic acid in thionyl chloride to produce bischlorosulfonimide:

(1) after thionyl chloride among reation kettle 1 lets in the completion, thionyl chloride among the stop storage tank lets in, material pipe 10 among the controlling feed arrangement 8 rises again, make material pipe 10 and reation kettle 1's inlet pipe 11 throw off, install driving motor 14 on the removal support 3 this moment, driving motor 14 fixed connection returning face plate 13, returning face plate 13 supports on removing support 3, it is the limiting plate 12 of L shape to install on removing support 3, limiting plate 12 and returning face plate 13 can adapt to reation kettle upset and installation on removing support 3. Then through the lead screw motor 9 control reation kettle 1 of the installation of movable support 3 bottom keep away from 8 directions removals of feed arrangement, correspond from top to bottom as one of them locating plate 6 and returning face plate 13, when another locating plate 6 corresponds from top to bottom with limiting plate 12, twist positioning bolt 7 on the locating plate 6, make one of them positioning bolt 7 screw in between one of them locating plate 6 and returning face plate 13, another positioning bolt 7 screws in between another locating plate 6 and limiting plate 12, through positioning bolt 7's linkage effect, make reation kettle 1 fix on returning face plate 13 and limiting plate 12, increase the stability of reaction in reation kettle 1.

(2) Sulfamic acid and chlorosulfonic acid are added into a feed inlet 15 of the reaction kettle 1, and the sulfamic acid and the chlorosulfonic acid react in thionyl chloride to generate dichlorosulfimide. Heating reflux operation is carried out on the reaction kettle 1, and the temperature is controlled to be 50-140 ℃.

c. Anhydrous hydrogen fluoride is added into a feed port 15 of the reaction kettle 1 for fluorination to obtain the lithium bis (fluorosulfonyl) imide, and the lithium bis (fluorosulfonyl) imide is collected through a discharge pipe 27 of the reaction kettle 1.

d. And (3) laterally cleaning the reaction kettle 1 in a split manner: the discharging pipe 27 is removed from the bottom of the reaction kettle 1, and then the fixing bolt 2 between the reaction kettle 1 and the moving plate 22 is screwed out, so that the reaction kettle 1 and the moving plate 22 are separated. Then the driving motor 14 controls the turnover plate 13 to rotate 90 degrees clockwise, so that the reaction kettle 1 is horizontally arranged, the upper barrel 4 of the reaction kettle 1 is supported, the mounting bolt between the upper barrel 4 and the lower barrel 5 is screwed out, the lower barrel 5 is dismounted, and the lower barrel 5 can be horizontally moved out by adopting a bracket. The lower cylinder 5 is cleaned in a cleaning tank, the inside of the upper cylinder 4 is sprayed and cleaned by a water pipe, and then the inside of the upper cylinder 4 is wiped. In carrying out the side direction components of a whole that can function independently cleaning process to reation kettle 1, go up barrel 4 and set up agitating unit and motor, consequently will go up barrel 4 and wash on moving movable support 3, carry out spacing fixed to last barrel 4 simultaneously, and then make reation kettle 1 fix a position and set for position department at moving movable support 3, avoid reation kettle 1 after the washing can't be used for the preparation of difluoro sulfonyl imide lithium next time. After the cleaning is finished, the upper barrel body 4 and the lower barrel body 5 are dried, after the drying is finished, the upper barrel body 4 is fixed on the upper barrel body 4 through a mounting bolt, then the driving motor 14 is reversed, the driving motor 14 controls the turnover plate 13 to rotate 90 degrees anticlockwise, so that the reaction kettle 1 is vertically arranged, and then the discharging pipe 27 is mounted at the bottom of the reaction kettle 1.

In consideration of the weight of the reaction vessel 1, the present invention supports the upper cylinder 4 using the two-point type supporting device 35, the two-point type supporting device 35 includes a bottom plate 24, a first supporting plate 25 and a second supporting plate 26, the first supporting plate 25 is welded on the top surface of the bottom plate 24, the second supporting plate 26 is welded on the side surface of the first supporting plate 25, the bottom plate 24 is fixed at the bottom of the movable bracket 3 using fastening screws, the positioning plate 6 positioned below is supported using the first supporting plate 25, and the outer side of the upper cylinder 4 is supported using the second supporting plate 26. The supporting position of the upper barrel 4 is limited, the first supporting plate 25 is adopted to support the positioning plate 6 which is positioned below the upper barrel 4, the upper barrel 4 is indirectly supported, the second supporting plate 26 supports the outer side of the upper barrel 4, the upper barrel 4 is directly supported, and the technical problem that the supporting position of the upper barrel 4 is limited is solved.

The feeding device for the preparation method of the lithium bis (fluorosulfonyl) imide comprises a shell 16 and a connecting pipe 28, wherein a mounting support 17 is welded between the shell 16 and a moving support 3, the connecting pipe 28 is communicated with a material pipe 10, and the material pipe 10 is made of a soft material and can adapt to the change of the upper position and the lower position of the connecting pipe 28. The bottom of the connecting pipe 28 is used for communicating with the feeding pipe 11, and the material pipe 10 penetrates out of the top of the shell 16. The housing 16 is provided with a slide rail 36 inside, the connecting pipe 28 is provided with a slide block 29 outside, the slide block 29 moves up and down in the slide rail 36, the housing 16 is fixedly connected with an air cylinder 33 inside, and the air cylinder 33 is connected with the connecting pipe 28 in a driving way. Through cylinder 33 control connecting pipe 28, because connecting pipe 28 is fixed a position in the inside of casing 16 for connecting pipe 28 reciprocates in casing 16 inside, when connecting pipe 28 moves down, make connecting pipe 28 and inlet pipe 11 match the intercommunication each other, and then make and communicate between material pipe 10, connecting pipe 28 and the inlet pipe 11, control certain velocity of flow, can let in thionyl chloride to reation kettle 1.

At least two connecting pipes 28 are adopted, the connecting pipes 28 are provided with fixing plates 34, and two adjacent fixing plates 34 are fixedly connected through connecting bolts, so that the connecting pipes 28 are fixedly connected. Limiting bulges 30 distributed up and down are welded on the outer side of the connecting pipe 28, a limiting groove 31 is formed between the two limiting bulges 30 distributed up and down, a clamping plate 32 is fixedly connected to the bottom of the air cylinder 33, and the clamping plate 32 is limited in the limiting groove 31. The air cylinder 33 can control the connecting pipes 28 to move the same distance at the same time, and the connecting accuracy of the connecting pipes 28 and the feeding pipes 11 is improved.

The above is only a specific embodiment of the present invention, but the technical features of the present invention are not limited thereto. Any simple changes, equivalent substitutions or modifications made based on the present invention to solve the same technical problems and achieve the same technical effects are within the scope of the present invention.