KR102166039B1 - Battery raw material input device - Google Patents

Abstract

The present invention relates to an apparatus for inputting raw material of a battery, comprising: a hopper member for inputting raw material, which is installed at the upper part of a main hopper; a height adjustment member for adjusting the height of the hopper member for inputting the raw material; a vibrator member applying vibration to the hopper member for inputting the raw material such that the raw material of the battery to be inputted in the hopper member for inputting the raw material is inputted in a uniform powder state; a mesh member installed at the lower end of the inner side of the hopper member for inputting the raw material; a magnetic member installed at the lower part of the mesh member to remove metal contained in the raw material of the battery; and a duct member for sucking dust, which is installed to remove dust generated when the raw material of the battery is inputted in the hopper member for inputting the raw material, thereby selectively passing only uniform-sized raw material of the battery by the apparatus for inputting the raw material of the battery installed on the main hopper, finely meshing the raw material of the battery, becoming lumpy by moisture or the like, to pass through the mesh member, and sucking the dust, generated when the raw material of the battery is inputted, via the duct member for sucking the dust to make the work environment cleaner and more comfortable.

Description

Battery raw material input device

The present invention relates to a battery raw material input device, and more particularly, a battery raw material input device that removes foreign substances such as metal contained in the battery raw material as well as introducing the battery raw material used in the production of the battery in a uniform powder state. It is about.

In general, a battery used in an electronic product has a cylindrical shape, and has a protruding (+) electrode and a flat (-) electrode at both ends thereof.

In addition, the battery case, which is capable of inserting such a battery, is provided on both sides of the (+) electrode plate and the (-) electrode plate connected to the electronic product. When the battery is inserted into the battery case of the electronic product, the (+) electrode plate of the battery An electrode and a (-) electrode are electrically connected to the electrode plate, and are configured to supply direct current to electronic products.

At this time, when the battery is connected to the battery case upside down, current is supplied in reverse, so that the electronic product does not operate or, in severe cases, a failure occurs.

Accordingly, by drawing a guide or a display picture indicating the direction in which the battery is inserted in the battery case of such an electronic product, the user can insert the battery in the correct direction according to the picture or guide phrase.

Further, in the case of such electronic products, there are many cases in which a high voltage can be output by connecting several batteries in series, rather than using only one battery.

In this case, when a plurality of electrode plates are disposed on both inner sides of the battery case and the batteries are inserted in opposite directions, the batteries are connected in series.

Meanwhile, automobile batteries are used as power sources for gasoline and diesel vehicles. Automotive batteries, which are currently the most used, are called lead acid batteries because the active material is lead.

In 1859, Gaston Plante, a Frenchman, found that it was most advantageous to put various metals in the acid and put lead in dilute sulfuric acid during the experiment, and he put a rubber band between two lead plates and made a eddy shape in dilute sulfuric acid. Charging and discharging occurred when the electric current was applied and this became the typical lead acid battery.

As described above, a battery consists of an electrolyte and a positive electrode made of different metals as electrodes, and when the positive electrode is connected with a conductor, the chemical energy of the active material and the electrolyte of each electrode can be generated as electrical energy.

Conversely, if electrical energy is given, it can return to the original agent with chemical energy. Such a reversible action is called a storage battery (secondary battery), and an irreversible one is called a primary battery.

The difference between a storage battery and a primary battery is that it can generate electrical energy as needed and supplement it.

On the other hand, a battery (battery/storage battery) used in a vehicle is a power source for operating each electric device of a vehicle, and there are two systems, a storage battery and a charging device. When the engine is running, the generator, which is a charging device, supplies power to each electric device, but when the engine is stopped or started, power cannot be obtained from the charging device, so the necessary power depends on the storage battery.

And the storage battery compensates for the lack of output or voltage fluctuations of the generator even when the engine is running to stabilize the power supply.

The above-described battery is a secondary battery that can repeat charging and discharging, and most automobiles use lead-acid storage batteries, and they have a long life and good overcharge and discharge, but they are expensive due to restrictions on the supply of raw materials, so they are used for starting diesel engines. There are alkaline storage batteries that are mainly used for turbine startup, broadcast radio waves, and power for alarm devices.

In the battery (lead acid storage battery), two electrodes are made of a lead compound, and dilute sulfuric acid is used as an electrolyte. The rated voltage per unit cell is 2V, and the discharge end voltage is 1.75V, and when it is lowered below that, the sulfation of the electrode plate is promoted, making it impossible to charge any more later. Also, when charging, the cell voltage rises to about 2.75V, and this voltage acts inversely on the charging voltage during charging, so the charger must be adjusted according to the number of cells.

The raw materials used for such a battery are put into a hopper in powder form of lead, carbon, nickel, cobalt, manganese, etc., and these powdered battery raw materials are stored in a bag. Accordingly, some of the battery raw materials are lumped together by moisture, and as the lumped battery raw materials are input, there is a problem that defects occur during battery mass production.

In addition, there is a problem that foreign substances, such as metal, are added together in the raw material of the battery, and thus, the battery is defective.

For example, a "battery manufacturing apparatus" is disclosed in the following patent document 1.

The battery manufacturing apparatus according to the following Patent Document 1 includes a stacking unit for sequentially stacking an electrode plate and a separator, and a transport unit for transporting the electrode plate to the stacking unit, wherein the position at which the electrode plate is stacked in the stacking unit is first In terms of a location, the stacking unit includes a separation membrane supply unit moving in a first direction or a second direction via the first location, and stacking the separation membrane at the first location.

The transport unit includes an arm portion for transporting the electrode plate to the first position by a rotational motion and stacking the electrode plate at the first position, and the arm portion is formed radially around a central axis of the rotational motion. When the first arm and the second arm are included, and the electrode plates are alternately stacked in the first position and the first electrode plate and the second electrode plate are stacked, the first arm is rotated to the first position. And the first pole of the second position and reciprocating the second position

Transport the plate to the first position.

The second arm reciprocates the first position and the third position by the rotational motion, transports the second electrode plate at the third position to the first position, and releases the first electrode plate at the first position. When the loaded first arm is moved away from the first position and the arm unit rotates in a direction in which the second arm picking up the second electrode plate at the third position approaches the first position, the separation membrane is supplied The portion is moved in the first direction between the first arm and the second arm so that collision with the first arm or the second arm is prevented, and the unit is unloaded to the first position by the first arm. The separator is laminated on the first electrode plate.

The first arm picking up the first electrode plate from the second position approaches the first position, and the second arm, which unloads the second electrode plate at the first position, moves away from the first position. When the arm portion rotates, the separation membrane supply portion moves in the second direction between the first arm and the second arm so as to prevent collision with the first arm or the second arm, and Thus, the separation membrane is stacked on the second electrode plate unloaded in the first position.

In Patent Document 2 below, a'mobile phone battery manufacturing apparatus' is disclosed.

The mobile phone battery manufacturing apparatus according to the following Patent Document 2 includes a base frame, a lower plate seated on the upper surface of the base frame, a plurality of support guide members vertically installed on the lower plate, and as long as it is vertically inserted into the support guide member. A pair of pressing means, an upper plate provided on the upper part of the pressing means, a roller gap adjusting member passing through the upper plate and connected to the upper pressing means so as to adjust the gap between the pressing means, and interlocking with the roller gap adjusting member And a drive means built into the base frame and mechanically connected to the lower pressing means.

Korean Patent Publication No. 10-2014-0014556 Republic of Korea Utility Model Registration No. 20-0402008 Korean Patent Registration No. 10-1275937

An object of the present invention is to solve the above-described problems, and to provide a battery raw material input device capable of injecting the battery raw material aggregated by moisture in a uniform powder form when the battery raw material contained in the bag is injected.

Another object of the present invention is to provide a battery raw material input device capable of removing foreign substances such as metal contained in a powdered battery raw material.

Another object of the present invention is to provide a battery raw material input device capable of creating a cleaner working environment by removing dust generated when a battery raw material composed of powder is added.

In order to achieve the above object, the battery raw material input device according to the present invention is a battery raw material input device having a main hopper 1 into which the raw material of the battery is injected, which is installed on the main hopper 1. A hopper member 10 for inputting raw materials; A height adjustment member 20 installed outside the raw material input hopper member 10 to adjust the height of the raw material input hopper member 10; A vibrator installed on the outside of the height adjusting member 20 to apply vibration to the raw material input hopper member 10 so that the battery raw material input to the raw material input hopper member 10 is fed in a uniform powder state Member 30; A mesh member 40 installed at an inner lower end of the raw material input hopper member 10; A magnetic member 50 installed under the mesh member 40 to remove metal contained in the uniform battery material that has passed through the mesh member 40; And a dust suction duct member (60) installed outside the raw material input hopper member (10) to remove dust generated when the raw material from the battery is input into the raw material input hopper member (10). do.

The raw material input hopper member 10 includes an upper hopper 11 having a narrow lower portion and a wide upper portion; A lower hopper 12 installed outside the lower part of the upper hopper 11; A fixed frame 13 fixed to the outside of the lower hopper 12; Including; a fixture (14) installed between the upper hopper (11) and the lower hopper (12) to keep the upper hopper (11) fixed by the vibration applied to the lower hopper (12). It features.

The height adjustment member 20 includes a main frame 21 fixed horizontally to the outside of the raw material input hopper member 10; A height adjustment screw 22 fastened to the main frame 21; A pedestal 23 fastened to the lower end of the height adjustment screw 22; It characterized in that it comprises a; a plurality of height adjustment nuts 24 fastened to the height adjustment screw (22).

The vibrator member 30 includes a driving motor 31 driven by an applied power source; A first fixing bracket 32 fixed vertically to one surface of the driving motor 31; A second fixing bracket (33) horizontally fixed to the first fixing bracket (32); A third fixing bracket (34) fixed to an upper surface of the second fixing bracket (33) and fixed to one surface of the raw material input hopper member (10); And a fixing bolt (35) fastened to the first fixing bracket (32) and the third fixing bracket (33).

The magnetic member 50 includes a magnetic case 51 fixed to the lower end of the raw material input hopper member 10; A magnetic mesh 52 installed on the upper surface of the magnetic case 51; A plurality of magnetic holders 53 fixed to the upper surface of the magnetic mesh 52; A magnetic 54 installed inside the magnetic holder 53 to remove metal contained in the battery raw material introduced through the raw material input hopper member 10; It characterized in that it comprises a; mesh handle 55 fixed to the magnetic case 51 so that the magnetic case 51 can be replaced.

As described above, according to the battery raw material input device according to the present invention, only the battery raw material of a uniform size can be selectively passed by the battery raw material input device installed on the main hopper, and the battery is lumped by moisture or the like. The raw material can be crushed finely and passed through the mesh member, and the dust generated when the battery raw material is injected is sucked through the dust suction duct member to create a cleaner and more comfortable working environment.

According to the battery raw material input device according to the present invention, it is possible not only to pass the battery raw material of a uniform size by the mesh member, but also to remove foreign substances such as metal material contained in the battery raw material by the magnetic member. The effect is obtained that the attached magnetic can be easily replaced if necessary.

1 is a cross-sectional view showing a battery raw material input device according to a preferred embodiment of the present invention,
2 is a plan view showing a battery raw material input device according to a preferred embodiment of the present invention;
3 is an enlarged cross-sectional view showing a battery raw material input device according to a preferred embodiment of the present invention;
4 is a partially enlarged cross-sectional view showing a battery raw material input device according to a preferred embodiment of the present invention;
5 is a plan view showing a battery raw material input device according to a preferred embodiment of the present invention;
6 is a plan view showing a mesh member of a battery raw material input device according to a preferred embodiment of the present invention;
7 is a plan view showing a magnetac member of a battery raw material input device according to a preferred embodiment of the present invention;
8 is a view showing a dust suction duct member of the battery raw material input device according to a preferred embodiment of the present invention.

Hereinafter, a battery raw material input device according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

A battery raw material input device according to a preferred embodiment of the present invention is a battery raw material input device having a main hopper 1 into which the raw material of the battery is input, and a raw material input hopper member installed above the main hopper 1 ( 10), a height adjustment member 20 installed outside the raw material input hopper member 10 so as to adjust the height of the raw material input hopper member 10, and the raw material input hopper member 10 A vibrator member 30 installed outside the height adjustment member 20 so as to apply vibration to the raw material input hopper member 10 so that the battery raw material injected into the battery is injected in a uniform powder state, and the raw material input The mesh member 40 installed at the inner bottom of the hopper member 10 for use, and the mesh member 40 installed under the mesh member 40 to remove the metal contained in the uniform battery raw material that has passed through the mesh member 40 A magnetic member 50 and a dust suction duct member 60 installed outside the raw material input hopper member 10 to remove dust generated when a battery raw material is injected into the raw material input hopper member 10 Includes.

1 is a cross-sectional view showing a battery raw material input device according to a preferred embodiment of the present invention, Figure 2 is a plan view showing a battery raw material input device according to a preferred embodiment of the present invention, and Figure 3 is a preferred embodiment of the present invention An enlarged cross-sectional view showing a battery raw material input device according to an example.

1 is a cross-sectional view showing a state in which the battery material input device of the present invention is installed on the main hopper 1, and FIG. 2 is a plan view showing the state where the battery material input device is installed on the main hopper 1, 3 is a cross-sectional view showing the battery raw material input device of the present invention.

1 to 3, the battery raw material input device according to the embodiment of the present invention is installed on the main hopper 1 so that the battery raw material input to the main hopper 1 is injected in a uniform powder form. do.

A height adjustment member 20 for adjusting the height of the raw material input hopper member 10 is installed on the main hopper 1 and on the outside of the raw material input hopper member 10 Is installed, and a vibrator member 30 for applying vibration to the raw material input hopper member 10 is installed.

In addition, a mesh member 40 is installed in the raw material input hopper member 10 to allow uniform powder to pass therethrough, and a lower portion of the raw material input hopper member 10 removes foreign substances such as metal contained in the battery raw material. A magnetic member 50 is installed, and a dust suction duct member 60 is installed outside the raw material input hopper member 10 to remove dust generated when the battery raw material is input.

4 is a partially enlarged cross-sectional view showing a battery raw material input device according to a preferred embodiment of the present invention, and FIG. 5 is a plan view showing a battery raw material input device according to a preferred embodiment of the present invention.

The raw material input hopper member 10 includes an upper hopper 11 having a narrow lower portion and a wide upper portion, a lower hopper 12 installed outside the lower portion of the upper hopper 11, and the lower hopper 12. Between the upper hopper 11 and the lower hopper 12 to maintain the fixed frame 13 fixed to the outside and the upper hopper 11 fixed by the vibration applied to the lower hopper 12 It includes a fixture (14) installed on.

4 and 5, the raw material input hopper member 10 is composed of an upper hopper 11 and a lower hopper 12, and the upper hopper 11 is a funnel having a narrow lower portion and a wide upper portion. It is formed in a shape, and the lower hopper 12 is installed on the lower outside of the upper hopper 11.

Further, a fixing frame 13 is installed outside the lower hopper 12, and a fixture 14 for fixing the upper hopper 11 is installed between the upper hopper 11 and the lower hopper 12.

In addition, a vertical support (15) is installed outside the upper hopper (11), a fixing frame (16) is installed on the upper surface of the vertical support (15), and the fixing frame (16) is fixed to the vertical support (15). The bolt 17 is fastened.

In addition, a cover lever 18 for detaching a cover (not shown) for opening and closing the upper hopper 11 is rotatably installed at the upper end of the upper hopper 11.

The height adjustment member 20 includes a main frame 21 fixed horizontally to the outside of the raw material input hopper member 10, a height adjustment screw 22 fastened to the main frame 21, and the height It includes a pedestal 23 fastened to the lower end of the adjusting screw 22, and a plurality of height adjusting nuts 24 fastened to the height adjusting screw 22.

Outside of the fixed frame 13, a height adjusting member 20 is installed to adjust the height of the hopper member 10, and the main frame 21 of the height adjusting member 20 is It is installed on the top surface.

A height adjustment screw 22 having a certain height is fastened to the main frame 21, and a pedestal 23 is installed at the lower end of the height adjustment screw 22. The pedestal 23 includes a pedestal body 23a made of a metal material and a rubber pedestal 23b made of a soft rubber material.

This is to prevent the vibration of the vibrator member 30 from being transmitted to the main hopper 1 as well as allowing the height of the raw material input hopper member 10 to be adjusted according to the working position.

Of course, a plurality of height adjustment nuts 24 are fastened to the height adjustment screw 22.

The vibrator member 30 includes a driving motor 31 driven by an applied power source, a first fixing bracket 32 fixed perpendicularly to one surface of the driving motor 31, and the first fixing bracket 32 ) A second fixing bracket (33) fixed horizontally, and a third fixing bracket (34) fixed to the upper surface of the second fixing bracket (33) and fixed to one surface of the raw material input hopper member (10) And, a fixing bolt 35 fastened to the first fixing bracket 32 and the third fixing bracket 33.

The vibrator member 30 applies vibration to the hopper member 10 for raw material input, so that the battery raw material lumped out of the battery raw material input to the raw material input hopper member 10 is supplied in a powder form. .

The driving motor 31 is installed outside the height adjustment member 20, a first fixing bracket 32 is installed on one surface of the driving motor 31, and a bottom surface of the first fixing bracket 32 is The second fixing bracket 33 is installed horizontally.

In addition, a third fixing bracket 34 is installed at the front end of the second fixing bracket 33, and the third fixing bracket 34 is seated on the upper surface of the second fixing bracket 33, and the third fixing bracket One side of 34 is fixed to the lower hopper 12 by welding or the like.

Meanwhile, a fixing bolt 35 is fastened to the first fixing bracket 32 and the second fixing bracket 33, and the fixing bolt 35 is fastened to the second fixing bracket 33 and the third fixing bracket 34. do.

In addition, a buffer spring 36 is installed between the main frame 21 and the second fixing bracket 33 so that the vibration generated from the vibrator member 30 is not applied to the height adjustment member 20.

6 is a plan view showing a mesh member of a battery raw material input device according to a preferred embodiment of the present invention.

As shown in FIG. 6, the mesh member 40 allows the battery raw material in the form of powder to be fed in a uniform particle state, and the mesh member 40 has a predetermined size on a plate 41 having a predetermined diameter. The hole 42 is formed.

Accordingly, the battery raw material in powder form injected into the upper hopper 11 falls through the hole 42 to the lower portion of the hopper member 10 for raw material input, and at this time, the battery raw material in the form of a lump larger than the hole 42 is vibrated. It is crushed by the generated hopper member 10 and then passes through the hole 42.

The magnetic member 50 includes a magnetic case 51 fixed to the lower end of the raw material input hopper member 10, a magnetic mesh 52 installed on the upper surface of the magnetic case 51, and the magnetic mesh ( A plurality of magnetic holders 53 fixed to the upper surface of 52), and a magnetic installed inside the magnetic holder 53 to remove metal contained in the battery raw material introduced through the raw material input hopper member 10 And a mesh handle 55 fixed to the magnetic case 51 so that the magnetic case 51 can be replaced.

7 is a plan view showing a magnetac member of a battery raw material input device according to a preferred embodiment of the present invention.

3 and 7, the magnetic case 51 is installed at the lower end of the lower hopper 12, and the magnetic mesh 52 is installed at the lower surface of the magnetic case 51. Is installed.

A magnetic holder 53 surrounding the magnetic 54 is installed on the upper surface of the magnetic mesh 52, and a magnetic 54 is provided inside the magnetic holder 53 so that foreign substances of a metal material included in the battery material are attached Installed.

In addition, a mesh handle 55 is installed in the magnetic case 51 so that the magnetic 54 can be replaced.

8 is a view showing a dust suction duct member of the battery raw material input device according to a preferred embodiment of the present invention.

Fig. 8(a) is a plan view showing the dust suction duct member 60, and Fig. 8(b) is a front view showing the dust suction duct member 60.

As shown in FIGS. 1 to 4 and 8, a dust suction duct member 60 is installed outside the upper hopper 11 to remove dust generated when the battery raw material is poured and supplied in a powder form.

The dust suction duct member 60 has a suction duct 61 formed in an arc shape having a predetermined diameter, and the suction duct 61 is installed on the outer upper side of the upper hopper 11.

A plurality of suction holes 62 having a predetermined length are formed in the suction duct 61 at regular intervals, and a transfer duct 63 for discharging the sucked dust is installed in the suction duct 61.

In addition, an intake opening/closing valve 64 for controlling the suction of dust is installed in the transfer duct 63, and a height adjusting screw 65 is installed in the suction duct 61 to adjust the height.

A pedestal 66 is installed on the bottom of the height adjustment screw 65, and a plurality of height adjustment nuts 67 for adjusting the height of the suction duct 61 are fastened to the height adjustment screw 65.

Next, a method of operating a battery raw material input device according to an embodiment of the present invention will be described with reference to FIGS. 1 to 8.

1 to 8, the battery raw material input device according to the preferred embodiment of the present invention is installed on the main hopper 1, and the raw material input hopper using the height adjusting member 20 according to the working position The height of the member 10 is adjusted.

In addition, as the driving motor 31 of the vibrator member 30 is driven by applying power, the raw material input hopper member 10 vibrates.

In this way, while the raw material input hopper member 10 is vibrated, the battery raw material in the form of powder contained in the bag is injected. The powdery battery raw material is introduced into the raw material input hopper member 10 to generate dust, and the dust is sucked into the dust suction duct member 60 installed above the raw material input hopper member 10.

These dusts are introduced through the suction hole 62 of the suction duct 61 and discharged to the outside along the transfer duct 63, and the suction duct 61 adjusts the height fastened to the height adjustment screw 65 The installation position can be adjusted according to the working environment by the nut 67.

As for the battery raw material, powder having a uniform size is selectively passed by the mesh member 40 installed under the raw material input hopper member 10, and the battery raw material agglomerated by moisture is the vibration of the hopper member 10. As the lump is crushed by this, the battery material in the form of particles smaller than the hole 42 of the mesh member 40 passes.

The battery raw material passing through the mesh member 40 passes through the magnetic member 50, and foreign substances such as a metal material included in the battery raw material are adhered by the magnetic force of the magnetic member 54.

In this way, by introducing the battery raw material in a uniform powder form, it is possible not only to reduce defects generated during battery manufacturing, but also to reduce defects caused by battery manufacturing by removing metals other than the battery raw material by the magnetic member 50. There will be.

Although the invention made by the present inventor has been described in detail according to the above embodiment, the invention is not limited to the above embodiment, and can be changed in various ways without departing from the gist of the invention.

10: raw material input hopper member 11: upper hopper
12: lower hopper 13: fixed frame
14: fixture 15: vertical support
16: fixing frame 17: fixing bolt
18: cover lever
20: height adjustment member 21: main frame
22: height adjustment screw 23: base
23a: base body 23b: rubber base
24: height adjustment nut
30: vibrator member 31: drive motor
32: first fixing bracket 33: second fixing bracket
34: third fixing bracket 35: fixing bolt
36: buffer spring
40: mesh member 41: plate
42: hole
50: magnetic member 51: magnetic case
52: magnetic mesh 53: magnetic holder
54: magnetic 55: mesh handle
60: dust suction duct member 61: suction duct
62: suction hole 63: transfer duct
64: intake open/close valve 65: height adjustment screw
66: base 67: height adjustment nut

Claims (5)

As a battery raw material input device having a main hopper (1) into which raw materials of the battery are injected,
A hopper member 10 for inputting raw materials installed on the upper part of the main hopper 1;
A height adjustment member 20 installed outside the raw material input hopper member 10 to adjust the height of the raw material input hopper member 10;
A vibrator installed on the outside of the height adjusting member 20 to apply vibration to the raw material input hopper member 10 so that the battery raw material input to the raw material input hopper member 10 is fed in a uniform powder state Member 30;
A mesh member 40 installed at an inner lower end of the raw material input hopper member 10;
A magnetic member 50 installed under the mesh member 40 to remove metal contained in the uniform battery material that has passed through the mesh member 40; And
Including; a dust suction duct member (60) installed outside the raw material input hopper member (10) to remove dust generated when a battery raw material is introduced into the raw material input hopper member (10),
The magnetic member 50 is
A magnetic case 51 fixed to the lower end of the raw material input hopper member 10;
A magnetic mesh 52 installed on the upper surface of the magnetic case 51;
A plurality of magnetic holders 53 fixed to the upper surface of the magnetic mesh 52;
A magnetic 54 installed inside the magnetic holder 53 to remove metal contained in the battery raw material introduced through the raw material input hopper member 10; And
And a mesh handle (55) fixed to the magnetic case (51) so that the magnetic case (51) can be replaced.
The method of claim 1,
The raw material input hopper member 10 includes an upper hopper 11 having a narrow lower portion and a wide upper portion;
A lower hopper 12 installed outside the lower part of the upper hopper 11;
A fixed frame 13 fixed to the outside of the lower hopper 12;
Including; a fixture (14) installed between the upper hopper (11) and the lower hopper (12) to keep the upper hopper (11) fixed by the vibration applied to the lower hopper (12). Battery raw material input device, characterized in that.
The method of claim 1,
The height adjustment member 20 includes a main frame 21 fixed horizontally to the outside of the raw material input hopper member 10;
A height adjustment screw 22 fastened to the main frame 21;
A pedestal 23 fastened to the lower end of the height adjustment screw 22;
A battery raw material input device comprising: a plurality of height adjustment nuts (24) fastened to the height adjustment screw (22).
The method of claim 1,
The vibrator member 30 includes a driving motor 31 driven by an applied power source;
A first fixing bracket 32 fixed vertically to one surface of the driving motor 31;
A second fixing bracket (33) horizontally fixed to the first fixing bracket (32);
A third fixing bracket (34) fixed to an upper surface of the second fixing bracket (33) and fixed to one surface of the raw material input hopper member (10);
And a fixing bolt (35) fastened to the first fixing bracket (32) and the third fixing bracket (34).
The method of claim 1,
The dust suction duct member 60 includes a suction duct 61 formed in an arc shape having a predetermined diameter;
A plurality of suction holes 62 having a predetermined length in the suction duct 61 and formed at regular intervals;
A transfer duct 63 installed in the suction duct 61 to discharge the sucked dust;
An intake opening/closing valve 64 installed in the transfer duct 63 to control suction of dust;
A height adjustment screw 65 installed to adjust the height of the suction duct 61;
A pedestal 66 installed on the bottom of the height adjustment screw 65;
And a plurality of height adjustment nuts (67) fastened to the height adjustment screw (65) to adjust the height of the suction duct (61).

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