KR102398149B1 - Ejector for transferring cathode material of lithium secondary battery and denseveyor included the same - Google Patents

Abstract

The present invention relates to an ejector for transporting a cathode material of a lithium secondary battery and a denseveyor including the same. The ejector for transporting a cathode material of a lithium secondary battery comprises: an ejector body becoming tapered downwards from above, having a straight body structure, and coupled to a material transport tank positioned above to be used; a material transport discharge pipe extended from the lower end of the ejector body in a flue structure to transport and discharge a cathode material transported downwards from above to the outside; an air supply pipe fixed and coupled to the outer circumferential surface of the ejector body, and having an air inlet; one or more first air supply nozzles connected to the air supply pipe; and second air supply nozzles provided in the middle or on the upper end of the outer circumferential surface of the ejector body to communicate with the inside, arranged in a number corresponding to the first air supply nozzles, and connected such that the transport flow of air reaches the inside of the ejector body. According to the present invention, the flow of a cathode material for a lithium secondary battery is improved to prevent the cathode material from being accumulated or lumped in the ejector, thereby preventing a dead zone caused by fixation of the cathode material and greatly increasing the transport efficiency of the cathode material.

Description

EJECTOR FOR TRANSFERRING CATHODE MATERIAL OF LITHIUM SECONDARY BATTERY AND DENSEVEYOR INCLUDED THE SAME

The present invention relates to an ejector for transferring a cathode material for a lithium secondary battery and a densorveyer including the same, and more particularly, to a lithium secondary battery capable of greatly increasing the transfer efficiency by improving the flowability of a cathode material for a secondary battery. It relates to an ejector for transferring a cathode material and a densorveyer including the same.

In general, a lithium secondary battery includes a cathode material, and the cathode material is one of the components of the secondary battery and determines the capacity and average voltage of the lithium secondary battery.

The basic type of such a cathode material is LCO (lithium cobalt oxide), which is the most used in small secondary batteries and is the most used cathode material for electric vehicle batteries. for example.

In addition, as an essential material for the cathode material, lithium hydroxide (LiOH) or lithium carbonate (LiCO ₃ ) is used together. Lithium hydroxide is mainly used in high-performance electric vehicle batteries, and lithium carbonate is mainly used in notebook and mobile phone batteries. .

The cathode material of lithium hydroxide (LiOH) or lithium carbonate has the advantage of being easy to synthesize with nickel, which increases battery capacity.

In addition, current cathode materials for lithium secondary batteries are manufactured through processes such as firing using raw materials such as NCM (nickel cobalt manganese), NCA (nickel cobalt aluminum), lithium hydroxide (LiOH), and lithium carbonate (LiCO ₃ ). .

On the other hand, the cathode material for lithium secondary batteries, that is, NCM (nickel cobalt manganese), NCA (nickel cobalt aluminum), lithium hydroxide (LiOH), lithium carbonate (LiCO ₃ ), etc. A transfer device such as a transfer machine is used.

In this way, a pneumatic transporter (denseveyor) used to transport cathode materials for lithium secondary batteries, such as NCM (nickel cobalt manganese), NCA (nickel cobalt aluminum), lithium hydroxide (LiOH), and lithium carbonate (LiCO ₃ ) is a configuration that is supported and coupled on a fixed frame and installed upright, a raw material transport tank is provided on the upper side so that the cathode material raw material is input and is transported in the downward direction, and is positioned and coupled to the lower side of the raw material transport tank to transport and discharge the cathode material raw material An ejector is provided to support the

However, in the conventionally used pneumatic transporter for transporting cathode material for lithium secondary batteries, due to structural disadvantages on the ejector side located at the bottom, cathode material raw materials cannot be smoothly transferred and discharged and accumulated, such as in the dead zone ( There was a problem that a dead zone) occurred. This not only becomes an obstacle to the production of cathode materials for lithium secondary batteries, but also causes industrial and economic losses because the entire production line may be stopped due to a disruption in the transport and supply of cathode materials.

In addition, the conventional pneumatic feeder-side ejector has a curved structure to ensure the flow of cathode material raw material, and due to the inner protruding structure of the air supply pipe connected to the lower end, the cathode material material is smoothly transferred It is not discharged and accumulates, causing problems.

In addition, in addition to the problems caused by the structural arrangement design of the ejector itself provided on the side of the conventional pneumatic transporter, the physical properties of the cathode material itself are additional factors causing problems in the prior art, such as lithium hydroxide (LiOH) or Cathode materials for lithium secondary batteries such as NCM (nickel cobalt manganese) and NCA (nickel cobalt aluminum), including lithium carbonate (LiCO ₃ ), are crystalline materials and have agglomeration properties, so they have poor flowability. That is, due to the coexistence of the physical properties of the cathode material and the structural problems of the ejector itself, a phenomenon in which the cathode material accumulates and solidifies in the dead zone within the ejector is occurring.

In addition, in the conventional pneumatic transfer machine, the ejector is manufactured by a casting method for ease of manufacture, but has a disadvantage in that it is not economical due to a large manufacturing cost.

On the other hand, when examining the prior art literature, it was not easy to find applications and disclosed technologies in relation to the ejector for transferring the cathode material of a lithium secondary battery and the densorveyer (pneumatic transfer machine) including the same, and only domestic registered patents Reference may be made to “a material transport device for secondary batteries” disclosed in No. 10-2071713 and “a device and method for high-capacity precision transport of slurry for secondary batteries” disclosed in Korean Patent Registration No. 10-2207830, but these are proposed below. It can be said that the technology of the present invention has a difference in technical configuration and method.

Republic of Korea Patent Publication No. 10-2071713 Republic of Korea Patent Publication No. 10-2207830

The present invention has been devised in consideration of and solving the problems of the prior art, and an ejector for transferring a cathode material for a lithium secondary battery, which can greatly increase the transfer efficiency by improving the flowability of a cathode material for a lithium secondary battery, and the same An object of the present invention is to provide a densurveyor that includes.

The present invention provides an ejector for transferring a cathode material of a lithium secondary battery capable of preventing accumulation and aggregation of cathode material in the ejector and preventing a dead zone from being formed due to fixation, and a densuvier including the same. There is a purpose.

An object of the present invention is to provide an ejector for transferring a cathode material of a lithium secondary battery capable of reducing manufacturing costs by improving a manufacturing method compared to the prior art, and a densuvier including the same.

The ejector for transferring the cathode material of a lithium secondary battery according to the present invention for achieving the above object is tapered from the upper side to the lower side, has a straight body structure, and is used in combination with a flow tank located at the upper side ejector body for; a raw material transfer and discharge pipe extending to the lower end of the ejector body in a communication structure and transferring and discharging the cathode material transferred from the upper part to the lower part to the outside; an air supply pipe fixedly coupled to the outer circumferential surface of the ejector body and having an air inlet; a first air supply nozzle provided with one or more connections on the air supply pipe; A second air supply nozzle provided in communication with the inside in the upper or middle portion of the outer circumferential surface of the ejector body and connected to a plurality of channels corresponding to the first air supply nozzle and connected to the inside of the ejector body so that the transport flow of air is made into the interior of the ejector body; characterized by including.

Here, the air supply pipe is formed in a circular shape to enable easy and fast supply of a cover and air around the outer peripheral surface of the ejector body; The first air supply nozzle is spaced apart from two or more multiples in the opposite direction of the raw material transport and discharge pipe with respect to the center of the air supply pipe side, and two or more multiples are spaced in the direction in which the raw material transport and discharge pipe is located. , it may be configured to arrange a larger number in the direction opposite to the raw material transfer and discharge pipe than the direction in which the raw material transfer and discharge pipe is located.

Here, the first air booster pipe fixedly coupled to the lower end of the ejector body to supply air toward the raw material transport and discharge pipe from the opposite side where the raw material transport and discharge pipe is located; may be configured to further include.

Here, the ejector body is provided integrally with a flange portion having a fastening hole on the upper outer surface extending outward, and a second air booster tube is connected to one side of the flange portion to supply air to the inside. An air gap for guiding the air supply in the inner downward direction of the ejector body together with the flange part on the raw material transport tank side that is matched and coupled by forming a chamfering inclined part on the upper end of the inner surface of the flange part having the air supply path. It may be a configuration to form.

Here, the second air supply nozzle may be configured to be arranged in a downwardly inclined structure to supply air toward the inner downward direction of the ejector body.

Here, the ejector body may have a configuration manufactured by a can-making manufacturing method using laser processing.

In addition, in order to achieve the above object, the denser bearing including the ejector for transferring the cathode material of the lithium secondary battery according to the present invention is supported and installed on the frame and installed upright, and the cathode material is input and transferred in the downward direction a raw material transport tank provided to form the; It includes; an ejector that is fastened and fixed while being positioned at the lower side of the raw material transfer tank, and is provided to transfer and discharge the cathode material through air supply, wherein the ejector has the technical configuration described above. It is characterized in that it is configured in any one of the ejectors for transferring the cathode material.

Here, the raw material transport tank is a body tapering in the downward direction, the flange portion for fastening with the ejector is integrally provided at the lower edge, and is connected to supply air inward from the side of the upper end; an air pulse valve connected to the upper end of the raw material transfer tank and outputting a pulse when air is supplied to the raw material transfer tank and outputting it in an inward direction; A pressure transmitter connected to the upper end of the raw material transfer tank to amplify the pressure according to the pressure signal in the raw material transfer tank or to handle signal-to-noise ratio signal processing and to be used for electronic control when air is supplied; may include a configuration .

Here, the air to prevent adhesion to the inner surface of the raw material transfer tank during supply and transfer of the cathode material by providing air vibration by being installed at one place on the lower end side of the raw material transfer tank or at two places opposite to each other It may be configured to further include a knocker (air knocker).

According to the present invention, it is possible to provide an ejector for transferring a cathode material for a lithium secondary battery, which can greatly increase the transfer efficiency by improving the flowability of a cathode material for a lithium secondary battery, and a densorveyer including the same.

According to the present invention, it is possible to prevent the positive electrode material from accumulating and aggregating inside the ejector through the improvement of the air supply structure as well as the internal structure improvement on the ejector body side, so it is possible to very effectively prevent the occurrence of a dead zone due to sticking. In addition, it is possible to provide an ejector for transferring a cathode material of a lithium secondary battery capable of greatly increasing the transfer efficiency of a cathode material, and a densorveyer including the same.

According to the present invention, it is possible to reduce the manufacturing cost by improving the ejector-side manufacturing method compared to the conventional one, and to realize the ease of installing additional parts, an ejector for transferring the cathode material of a lithium secondary battery, and a densuvier including the same can provide

1 is a block diagram illustrating a densorveyer including an ejector for transferring a cathode material of a lithium secondary battery according to an embodiment of the present invention.
2 is a block diagram illustrating an ejector for transferring a cathode material of a lithium secondary battery according to an embodiment of the present invention.
Figure 3 is a detailed view showing the portion "A" of Figure 2 in the present invention.
4 is a plan view showing the main part of the air supply side in the ejector for transferring the cathode material of the lithium secondary battery according to the embodiment of the present invention.

Preferred embodiments of the present invention will be described with reference to the accompanying drawings as follows, and through such detailed description, it will be possible to better understand the purpose and configuration of the present invention and its features.

Among the terms used in the present invention, 'densorveyer' is a device for performing pneumatic transport of cathode material raw materials, and may be defined as 'pneumatic transporter'.

As shown in Figs. 1 to 4, the denser carrier 1 including an ejector for transferring a cathode material of a lithium secondary battery according to an embodiment of the present invention includes a raw material transfer tank 100 and an ejector 200 coupled thereto. It consists of a composition comprising

The raw material transport tank 100 is a component that is supported and coupled to the fixed frame 101 and installed upright, and is provided so that the cathode material is fed and transported in the downward direction.

In this case, the cathode material may be NCM (nickel cobalt manganese), NCA (nickel cobalt aluminum), lithium hydroxide (LiOH), lithium carbonate (LiCO ₃ ), or the like.

The raw material transfer tank 100 is provided with a tapered body 110 of upper and lower narrow that tapers toward the lower side for smooth supply and transfer of cathode material, and an ejector 200 and an ejector 200 at the lower edge. The flange portion 120 for fastening extends outward and is integrally provided, and the air inlet pipe 102 is connected to supply air in the inward direction from one side of the upper end.

At this time, the flange portion 110 is provided to match the flange portion 211 on the ejector 200 side and connect the second air booster tube 270 to one side thereof to form an air supply path so that air can be supplied to the inside. do.

A fastening hole is formed in the flange part 110 to be matched with the flange part 211 on the ejector 200 side and used for fastening using a fastening member such as a bolt.

In addition, the raw material transfer tank 100 includes a configuration in which an air pulse valve 130 is connected to the upper end, and a pulse is output when air is supplied to the raw material transfer tank 100 through the air pulse valve 130 . It plays a role of exporting in the inward direction.

In addition, the raw material transfer tank 100 includes a configuration in which a pressure transmitter 140 is connected to the upper end, and the pressure is amplified according to the pressure signal in the raw material transfer tank 100 through the pressure transmitter 140 . This is to handle signal processing to improve the signal-to-noise ratio or to perform electronic control more efficiently when air is supplied.

Here, the raw material transfer tank 100 includes a configuration for installing a pressure sensor.

In addition, the raw material transfer tank 100 includes an air knocker 150 for providing air vibration by being mounted at one place on the lower end side or two places opposite to each other.

This is to prevent the cathode material from adhering to the inner surface of the raw material transfer tank 100 when the cathode material is supplied and transferred through the air knocker 150 .

The ejector 200 is a component that is fastened and fixed while being positioned at the lower side of the raw material transfer tank 100 described above, and is provided to more easily and smoothly transfer and discharge the cathode material through air supply.

In this way, the ejector 200 for use for transferring the cathode material of the lithium secondary battery and for use in connection with the raw material transfer tank 100 is shown in FIGS. 1 to 4, the ejector body 210, the raw material It includes a transfer discharge pipe 220 , an air supply pipe 230 , a first air supply nozzle 240 , and a second air supply nozzle 240 .

The ejector body 210 is tapered from the upper side to the lower side, has a straight body structure, and is configured for use in combination with the raw material transfer tank 100 located at the upper side.

A flange portion 211 having a fastening hole at the upper end of the ejector body 210 is integrally provided to extend outwardly, and a bolt or the like is fastened in a state matched with the flange portion 120 on the raw material transport tank 100 side. It is provided to fasten through the member.

At this time, an air supply path is formed by connecting a second air booster tube 270 to one side of the flange portion 210 to supply air to the inside, and the inner surface of the flange portion 211 having the air supply path is provided. An air gap 201 for guiding the supply of air in the inner downward direction of the ejector body 210 together with the flange portion 120 on the side of the raw material transfer tank 100 that is matched and coupled to the chamfering machine inclined portion 211a at the upper end. It is desirable to have a configuration that forms a

Here, the air gap 201 formed through the mutual coupling structure of the flange part 120 on the raw material transport tank 100 side and the flange part 211 on the ejector body 210 side is the rear surface of the raw material transport and discharge pipe 220 . It is preferable to form on the side. That is, it is formed to cover the point where the dead zone is generated in the conventional ejector side, and to supply air downward for the efficiency of raw material transfer.

The ejector body 210 has a configuration manufactured by a can-making manufacturing method using laser processing differently from the prior art, and through this, not only can the manufacturing cost be reduced, but also the advantage of facilitating the installation of additional parts can be provided.

The raw material transport and discharge pipe 220 extends to the lower end of the ejector body 210 in a communication structure and is configured to transport and discharge the cathode material transferred from the upper part to the lower side to the outside.

The air supply pipe 230 is fixedly coupled in a horizontally arranged state on the outer circumferential surface of the ejector body 210 , and has an air inlet 231 .

At this time, it is preferable that the air supply pipe 230 has a circular shape around the outer circumferential surface of the ejector body 210 to enable easy and quick supply of the cover and air.

As shown in FIG. 3 , the first air supply nozzle 240 is installed in a configuration in which one or more connections are provided on the air supply pipe 230 .

At this time, the first air supply nozzle 240 is spaced apart from two or more in the opposite direction of the raw material transport and discharge pipe 220 with respect to the center of the air supply pipe 230 side, and the raw material transport and discharge pipe 220 . It is preferable to arrange a plurality of two or more at intervals in the direction in which this is located, but to arrange a larger number in the opposite direction of the raw material transfer and discharge pipe 220 than the direction in which the raw material transfer and discharge pipe 220 is located.

For example, as shown in FIG. 3 , in the direction opposite to the raw material transfer and discharge pipe 220 with respect to the center of the air supply pipe 230 side, four are spaced apart, and the raw material transfer and discharge pipe 220 is located in the direction It may be a configuration in which two are spaced on the side, and it will be apparent that modifications or variations can be made without being limited to these examples in particular.

Here, through the arrangement of the first air supply nozzle 240 as described above, it is possible to more easily cover the point where the dead zone is generated on the conventional ejector side, and the cathode material raw material transferred by air cleaning It can provide the advantage of preventing aggregation and fixation of

The second air supply nozzle 250 is provided in communication with the inside at the upper end or the middle part of the outer peripheral surface of the ejector body 210, and is disposed in a number corresponding to the first air supply nozzle 240, and the flow of air is It is configured to be connected to the inside of the ejector body 210 .

The second air supply nozzle 250 is preferably arranged in a downwardly inclined structure to supply air toward the inner downward direction of the ejector body 210 .

Here, the first air supply nozzle 240 and the second air supply nozzle 250 may be connected through a connection hose or a connection pipe.

In addition, in the present invention, the first air booster pipe 260 communicates with the lower end of the ejector body 210 so as to supply air toward the raw material transport and discharge pipe 220 from the opposite side where the raw material transport and discharge pipe 220 is located. It may include a configuration for fixing the coupling.

In this case, the first air booster tube 260 is preferably connected so that the connecting end thereof does not protrude from the inner surface of the ejector body 210 .

In addition, in the present invention, a second air booster pipe 270 is included. When the raw material transport tank 100 side flange part 120 and the ejector body 210 side flange part 211 are matched to one side when fastening, one side is included. It is connected to the air supply path formed in the cavity and is provided to additionally supply air from the upper end of the ejector body 210 .

Here, the air supply pipe 230 and the first air booster pipe 260 and the second air booster pipe 270 connected to supply air to the inside of the ejector body 210 are each air Although it may be configured to supply air through the tank, it may be more preferable to configure it to be distributed and connected in one air tank 202 for structural design and efficiency thereof.

Here, the air inlet pipe 102 connected to one side of the upper end of the raw material transfer tank 100 may also have a configuration in which it is distributed and connected from one air tank 202 .

Here, the air tank 202 may be an air header unit for distributing and supplying air.

That is, in the ejector 200 for transferring the cathode material of a lithium secondary battery according to the present invention having the above-described configuration, the ejector body 210 of a straight body tapered in a can-making method is constituted, and thus the air supply pipe 230 ) and the first air supply nozzle 240 and the second air supply nozzle 250 are matched and connected by implementing a system for supplying air from the upper part to the lower part of the ejector body 210 side. It is possible to increase the cleaning efficiency in the ejector body 210 through air supply, so it is possible to eliminate the dead zone generated inside the conventional ejector, and to remove and improve the aggregation or sticking phenomenon of the cathode material, and compared to the existing method. It is possible to provide the advantage of greatly increasing the transfer efficiency of the cathode material raw material.

In addition, in the present invention, since air is also supplied toward the raw material transfer and discharge tube 220 through the first air booster tube 260, it is possible to eliminate the clogging phenomenon during transfer and discharge of the cathode material, and the second air booster tube 270 and Since air is supplied from the upper side of the ejector body 210 even through the matching configuration of the air gap 201 , it is possible to prevent and improve the phenomenon that the cathode material is accumulated and clogged in the ejector body 210 , compared to the existing method. It is possible to provide the advantage of greatly increasing the transfer efficiency of the cathode material raw material.

The embodiments described above are merely illustrative of preferred embodiments of the present invention and are not limited to these embodiments, and various modifications and variations by those skilled in the art within the technical spirit and claims of the present invention It will be said that this can be done, and it will be said that it falls within the scope of the technical rights of the present invention.

1: Densurveyor 100: Raw material transfer tank
101: fixed frame 102: air inlet pipe
110: tapered body 120: flange portion
130: air pulse valve 140: pressure transmitter
150: air knocker 200: ejector
201: air gap 202: air tank
210: ejector body 211: flange portion
220: raw material transfer and discharge pipe 230: air supply pipe
240: first air supply nozzle 250: second air supply nozzle
260: first air booster tube 270: second air booster tube

Claims (9)

an ejector body that is tapered from the upper side to the lower side, has a straight body structure, and is used in combination with a raw material transport tank located at the upper side;
a raw material transfer/discharge pipe extending to the lower end of the ejector body in a communication structure and transferring and discharging the cathode material transferred from the upper part to the lower part to the outside;
an air supply pipe fixedly coupled to the outer circumferential surface of the ejector body and having an air inlet;
a first air supply nozzle provided with one or more connections on the air supply pipe;
a second air supply nozzle provided in communication with the inside at an upper end or a middle portion of an outer peripheral surface of the ejector body and connected to a plurality of channels corresponding to the first air supply nozzle and connected to the inside of the ejector body so that the transport flow of air is made; includes,
The air supply pipe,
a cover around the outer circumferential surface of the ejector body and made in a circular shape to enable easy and fast supply of air;
The first air supply nozzle,
Spaced apart two or more multiples in the opposite direction of the raw material transport and discharge pipe with respect to the center of the air supply pipe side, and spaced apart two or more multiples in the direction in which the raw material transport and discharge pipe is located, where the raw material transport and discharge pipe is located An ejector for transferring a cathode material of a lithium secondary battery, characterized in that a larger number is arranged in the direction opposite to the raw material transfer and discharge pipe than the direction. delete The method of claim 1,
a first air booster pipe fixedly coupled to the lower end of the ejector body to supply air toward the raw material transport and discharge pipe from the opposite side where the raw material transport and discharge pipe is located; An ejector for transferring the cathode material of a lithium secondary battery, characterized in that it further comprises a. The method of claim 1,
The ejector body is
A flange portion having a fastening hole at the upper end is provided integrally by extending outwardly,
A second air booster pipe is connected to one side of the flange part to form an air supply path so that air can be supplied to the inside. The ejector for transferring the cathode material of a lithium secondary battery, characterized in that it forms an air gap for guiding the air supply in the inner downward direction of the ejector body together with the flange portion on the transfer tank side. The method of claim 1,
The second air supply nozzle,
An ejector for transferring a cathode material of a lithium secondary battery, characterized in that it is arranged in a downwardly inclined structure to supply air toward the inner lower side of the ejector body. The method of claim 1,
The ejector body is
An ejector for transferring the cathode material of a lithium secondary battery, characterized in that it is manufactured by a canning manufacturing method using laser processing. In the density surveyor used to transport the cathode material of a lithium secondary battery,
a raw material transfer tank which is supported and installed on a fixed frame and installed upright, and is provided so that the cathode material is fed in and transferred in a downward direction;
an ejector that is fastened and fixed while being located at the lower side of the raw material transfer tank, and is provided to transfer and discharge the cathode material through air supply; includes,
The ejector is
A denser for transferring a cathode material of a lithium secondary battery, characterized in that it is an ejector for transferring a cathode material of a lithium secondary battery having the configuration according to any one of claims 1 to 6. 8. The method of claim 7,
The raw material transport tank is a body tapering toward the lower side, a flange portion for fastening with the ejector is integrally provided at a lower edge thereof, and is connected to supply air in an inward direction from a side surface of the upper end;
an air pulse valve connected to the upper end of the raw material transfer tank to output a pulse when supplying air to the raw material transfer tank and output it in an inward direction;
a pressure transmitter connected to the upper end of the raw material transfer tank to amplify the pressure according to the pressure signal in the raw material transfer tank or to handle signal-to-noise ratio signal processing and to be used for electronic control when air is supplied; Densurveyor for transferring the cathode material of a lithium secondary battery, characterized in that it comprises a. 8. The method of claim 7,
An air knocker (air) to prevent adhesion to the inner surface of the raw material transfer tank when supplying and transferring the cathode material by providing air vibration by being installed at one place on the lower end side of the raw material transfer tank or two places opposite to each other knocker); Densurveyor for transferring the cathode material of a lithium secondary battery, characterized in that it further comprises a.

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