KR20140072723A - ultrasonic homogenizing apparatus and method of mixing anode material for lithium secondary battery using the same - Google Patents

Abstract

The present invention relates to an ultrasonic homogenizing device and a method for mixing anode materials for a lithium secondary battery using the same. The device includes a mixing container which is open on the top and has an accommodation space for accommodating materials to be treated, at least one ultrasonic horn which is mounted on the outside of the mixing container to apply ultrasonic waves to the mixing container, and a stirrer which is installed inside the mixing container to rotate a rotary blade. According to the ultrasonic homogenizing device and the method for mixing anode materials for a lithium secondary battery using the same, the homogenizing speed of heterogeneous materials can be improved.

Description

[0001] The present invention relates to an ultrasonic homogenizing apparatus and a method of mixing a cathode material of a lithium ion battery using the same,

The present invention relates to an ultrasonic homogenizer and a method of mixing a cathode material of a lithium ion battery using the same. More particularly, the present invention relates to an ultrasonic homogenizer for homogenizing and mixing heterogeneous materials and a method for mixing a cathode material of a lithium ion battery.

A homogenizer used to homogenize the quality of a liquid solution or a solution containing colloidal solids has been used for a long time. These homogenizers are roughly divided into mechanical rotators to homogenize the distribution and quality of the solution, and to mechanically homogenize the homogenizer and the particles in the solution by using a stirrer to improve the quality, to separate the solids in solution and distribute them in solution Of the ultrasonic homogenizer.

In the case of the ultrasonic method, the ultrasonic homogenizer horn is disclosed in Korean Patent Laid-Open No. 2001-0106321.

However, conventionally, only a homogenizer of a mechanical system or a homogenizer of an ultrasonic system is used solely, which results in a problem that a mixing time takes a long time when mixing different types of solid and liquid phases.

It is an object of the present invention to provide an ultrasonic homogenizer capable of enhancing mixing efficiency while using an ultrasonic horn and agitation together, and a method for mixing a cathode material of a lithium ion battery using the same .

In order to achieve the above object, an ultrasonic homogenizing apparatus according to the present invention comprises: a mixing vessel having an upper portion thereof opened and a receiving space for receiving a material to be treated therein; At least one ultrasonic horn mounted on an outer surface of the mixing vessel to apply ultrasonic waves to the mixing vessel; And an agitator installed to rotate the stirring vane in the mixing vessel.

The agitator includes a guide shaft extending in the vertical direction of the mixing vessel; A motor for rotationally driving the guide shaft; A stirring blade installed to be able to move up and down along the guide shaft and rotate together with the guide shaft; And a lifting and descending part for lifting and lowering the stirring blade along the guide shaft.

Preferably, the stirrer is installed to be able to move up and down along the guide shaft, and has a first wing formed to form a rising vortex when the guide shaft rotates in the first direction, Wow; And a second stirring vane installed to be able to move up and down along the guide axis and having a second vane formed to form a downward vortex when the guide shaft rotates in the first direction and rotate together with the guide shaft, The ascending / descending portion is provided between the first stirring blade and the second stirring blade so that the first stirring blade and the second stirring blade ascend and descend in a direction in which the first stirring blade and the second stirring blade are moved toward or away from each other.

The mixing vessel is formed in a cylindrical shape, and the ultrasonic horn is horizontally supported on the mixing vessel, and a plurality of the ultrasonic horns are installed at equal intervals along the circumferential direction on the outer surface of the mixing vessel.

In order to achieve the above-mentioned object, the method for mixing a cathode material for a lithium ion battery according to the present invention comprises injecting a solid phase lithium acetate and a liquid polyol into the mixing vessel, and operating the ultrasonic horn and the agitator to mix them.

According to the ultrasonic homogenizer of the present invention and the method of mixing a cathode material of a lithium ion battery using the same, the homogenization process speed for different kinds of materials can be improved.

1 is a sectional view showing an ultrasonic homogenizing apparatus according to the present invention,
FIG. 2 is a partial exploded perspective view showing a state in which a stirring blade is coupled to the guide shaft of FIG. 1,
3 is a partial exploded perspective view illustrating a coupling structure in which an ultrasonic horn is coupled to the mixing vessel of FIG.

Hereinafter, an ultrasonic homogenizing apparatus according to a preferred embodiment of the present invention and a method of mixing a cathode material of a lithium ion battery using the same will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing an ultrasonic homogenizing apparatus according to the present invention.

1, an ultrasonic homogenizer 100 according to the present invention includes a mixing vessel 110, an ultrasonic horn 130, and a stirrer 150.

The mixing vessel 110 has a cylindrical structure in which an upper portion thereof is opened and a receiving space for accommodating a substance to be treated is formed therein.

The ultrasonic horn 130 is mounted on the outer surface 112 extending upward from the bottom surface of the mixing vessel 110 so as to be able to apply ultrasonic waves into the receiving space of the mixing vessel 110.

The ultrasonic horns 130 are horizontally extended to the mixing vessel 110 and are installed on the outer surface 112 of the mixing vessel 110 at regular intervals along the circumferential direction.

The ultrasonic horn 130 vibrates at a frequency of 20,000 to 40,000 Hz in the horn 135 at the end through the booster 135 and the vibration generated from the transducer 131 is generated by a flange (137) is attached to a coupling portion (115) formed in the mixing vessel (110).

Here, the flange 137 is formed in the node region where the longitudinal displacement is fine or zero when the horn 135 resonates, and the coupling structure with the mixing vessel 110 will be described with reference to FIG.

The flange 137 of the ultrasonic horn 130 at the end of the extension portion 116 is formed at the outer surface of the mixing vessel 110. The extension portion 116 extends outwardly and communicates with the accommodation space, Circular bottom connection port 117 is formed so as to be able to insert and support a semicircular portion corresponding to the half of the bottom side of the lower connection port 117. The remaining exposed portion of the flange 137 at the upper portion of the lower connection port 117, And an upper connection port 118 which can be engaged with the lower connection port 117 while being enclosed by the lower connection port 117. [

Here, ribs are formed on the upper surface of the lower connection port 117 and the lower surface of the upper connection port 118 so as to be coupled to each other using a coupling member such as a bolt.

The stirrer 150 is installed to rotate the first and second stirring blades 161 and 162 in the accommodating space of the mixing container 110.

The agitator 150 includes a guide shaft 151, a motor M 153, first and second stirring blades 161 and 163, and an actuator 170.

The guide shaft 151 is vertically extended from the center of the receiving space of the mixing vessel 110 and can be rotated by the motor M 163 so that the first and second stirring blades 161 163 are constrained so as not to rotate with respect to the circumferential direction, and a key groove 162 is formed along the longitudinal direction as shown in FIG. 2 so as to be slidable in the vertical direction, and the first and second stirring blades A key 161 inserted into the key groove 152 to slide the ring portions 161a and 162a upward and downward is formed on the inner side surfaces of the ring portions 161a and 162a inserted to surround the guide shafts 151 164 are formed.

Unlike the illustrated example, the first and second stirring blades 161 and 163 are constrained to the guide shaft 151 without being rotated with respect to the circumferential direction, and the key projections 151 protruded from the surface so as to be slidable in the up- (Not shown) may be formed on the inner surface of the ring portions 161a and 162a, and a key protrusion may be inserted in the inner surface of the ring portions 161a and 162a to provide a groove for guiding the sliding.

The motor 153 is mounted on a support plate 154 installed to be supported across the upper surface of the mixing vessel 110 so that the guide shaft 151 can be rotated.

The first stirring blade 161 is installed to be able to move up and down along the guide shaft 151 and rotates together with the guide shaft 151 and is lifted or lowered along the guide shaft 151 by an actuator 170 .

The second stirring blade 162 is installed above the first stirring blade 161 so as to be able to move up and down along the guide shaft 151 and rotates together with the guide shaft 151 and is guided by an actuator 170 And is lifted or lowered along the shaft 151.

The first wing portion 161b extending from the ring portion 161a of the first stirring vane 161 in the direction in which the outer diameter of the first stirring vane 161 extends extends in a direction in which the guide shaft 151 is rotated The second wing portion 162b extending from the ring portion 162a of the second stirring blade 162 in the direction in which the outer diameter of the second stirring wing 162 extends extends in a direction opposite to the first wing when the guide shaft 151 rotates in the first direction So as to generate a vortex.

That is, the first wing portion 161b and the second wing portion 162b are formed so that their bent shapes are opposite to each other.

The actuator 170 is applied as an ascending / descending portion for moving the first and second stirring vanes 161 and 162 up and down along the guide shaft 151, and a cylinder for advancing and retracting the rod can be applied.

The body 171 of the actuator 170 is provided on the guide shaft 151 between the first stirring blade 161 and the second stirring blade 162 and extends downward from the bottom surface of the body 171 to be advanced and retreated The first rod 173 is engaged with the ring portion 161a of the first stirring vane 161 and the second rod 174 extending upward from the upper surface of the body 171 is advanced and retracted to the second stirring vane 162 And the ring portion 162a of the ring gear 162a.

The actuator 170 advances and retreats the first rod 173 and the second rod 174 so that the first stirring blade 161 and the second stirring blade 162 are moved up and down in a direction in which the first stirring blade 161 and the second stirring blade 162 approach each other or away from each other.

That is, the actuator 170 repeats the process of contracting the first rod and the second rod in a direction in which the length of the first rod and the second rod is reduced from the body 171, and further expanding the first rod and the second rod in a direction in which the length is extended.

Here, the advancing / retreating periods of the first rod 173 and the second rod 174 can be set by an operation unit 181 described later.

In addition, it is needless to say that, unlike the example shown in the drawing, only one stirring blade can be constructed to be raised and lowered.

The operation unit 181 is configured to set a supported function such as a driving on / off selection button of the ultrasonic horn 130 and the stirrer 150, a driving holding time, a forward / backward cycle of the actuator 170,

The control unit 185 controls the driving of the ultrasonic horn 130, the motor 153 and the actuator 170 according to the conditions set by the operation unit 181. [

In the method of mixing a cathode material of a lithium ion battery using the ultrasonic homogenizer 110, a solid phase lithium acetate and a liquid polyol are charged into a mixing vessel 110.

The mixing ratio of the polyol and the lithium acetate may be applied corresponding to the cathode material to be produced.

Here, the polyol may be an ester polyol.

Next, the ultrasonic horn 130 and the stirrer 150 are operated and mixed.

Here, the stirrer 150 operates and stirs the actuator in accordance with the upward and downward repetition cycles set in the directions in which the first agitating blades 161 and the first agitating blades 162 are moved closer to each other.

In this mixing process, the ultrasonic waves emitted from the ultrasonic horn 130 are mixed with the first stirring wing 161 and the first stirring wing 162, which are moved up and down in the vertical direction, It happens quickly.

110: mixing vessel 130: ultrasonic horn
150: stirrer

Claims (6)

A mixing container in which an upper portion is opened and an accommodation space for accommodating a substance to be treated is formed therein;
At least one ultrasonic horn mounted on an outer surface of the mixing vessel to apply ultrasonic waves to the mixing vessel;
And a stirrer installed to rotate the stirring blade in the mixing vessel. The apparatus of claim 1, wherein the agitator
A guide shaft extending in the vertical direction of the mixing vessel;
A motor for rotationally driving the guide shaft;
A stirring blade installed to be able to move up and down along the guide shaft and rotate together with the guide shaft;
And an ascending and descending portion for raising and lowering the stirring vane along the guide shaft. The apparatus of claim 1, wherein the agitator
A guide shaft extending in the vertical direction of the mixing vessel;
A motor for rotationally driving the guide shaft;
A first stirring blade installed to be able to move up and down along the guide axis and having a first vane formed to form a rising vortex when the guide shaft rotates in the first direction and rotate together with the guide shaft;
A second stirring vane installed to be able to move up and down along the guide shaft and having a second vane formed so as to form a descending vortex when the guide shaft rotates in the first direction and rotate together with the guide shaft;
And an ascending and descending portion provided between the first stirring blade and the second stirring blade for raising and lowering the first stirring blade and the second stirring blade in a direction in which the first stirring blade and the second stirring blade are moved toward or away from each other, Homogenizing device. 4. The apparatus according to claim 3, wherein the mixing vessel is formed in a cylindrical shape,
Wherein the ultrasonic horn is horizontally supported on the mixing vessel, and a plurality of the ultrasonic horns are installed on the outer surface of the mixing vessel at regular intervals along the circumferential direction. An ultrasonic horn provided so as to be able to apply ultrasonic waves into the mixing vessel, and a stirrer installed to rotate the stirring vane in the mixing vessel, A method of mixing a cathode material of a lithium ion battery using an ultrasonic homogenizer having a plurality of electrodes,
Wherein the solid phase lithium acetate and the liquid polyol are put into the mixing vessel and the ultrasonic horn and the agitator are operated to mix and mix. 6. The apparatus as claimed in claim 5, wherein the agitator comprises: a guide shaft extending in the vertical direction of the mixing vessel; a motor rotating the guide shaft; and a guide shaft provided to be able to move up and down along the guide shaft, A first stirring vane which is formed with a first vane formed to form a rising vortex during rotation and rotates together with the guide shaft, and a second stirring vane which is installed to be able to move up and down along the guide shaft, A second stirring blade having a second wing formed thereon to rotate together with the guide shaft and a second stirring blade provided between the first stirring blade and the second stirring blade to rotate the first stirring blade and the second stirring blade, And an actuator that moves up and down along the guide shaft,
Wherein the actuator is operated and agitated in accordance with a rising / falling repetition period set in a direction in which the first stirring vane and the first stirring vane are moved closer to each other.

Images