KR101309599B1 - Automatic Detaching Method for Notebook Battery - Google Patents

Abstract

The present invention relates to a method for automatically separating a notebook battery, and more particularly, magnetizing a magnetic mixture which is a mixture of a magnetic material and a high temperature soluble material to form a magnetic mixture; Fusing the magnetization mixture to a laptop battery junction; Protruding an S pole by dissolving the magnetization mixture of the notebook battery junction when a notebook abnormality occurs; Separating the notebook battery by the repulsive force between the protruding S pole and the S pole on the back of the notebook battery junction or the S pole on the back of the notebook battery junction and the S pole of the notebook junction; And the protruding S pole is coupled with the N pole of the notebook battery junction surface.

In the present invention described above, the magnetic poles of the laptop battery and the laptop joint are fused to form magnetic poles of the N and S poles, and the magnetic mixture dissolved at high temperature is bonded to the laptop battery joint. The protruding or unfolding and fusion of the magnetization material on the back side of the notebook battery junction to form a pole of the S pole. If a high temperature occurs when the notebook is short or abnormal, the magnet mixture is fused to bond the protruding S pole to the notebook battery. The notebook battery is automatically separated by the repulsive force with the S pole on the back side or the S pole on the notebook battery junction and the S pole on the notebook junction, and the notebook battery separated by the attraction force of the N and S poles is held. If a laptop malfunctions, the laptop's battery will not be ejected or exploded. Tell the remarkable advantage of the economic damage of the customer is minimized.

Laptop battery, notebook, magnetic mixture, protruding S-pole, magnetic material, repulsive force, welding

Description

Automatic Detaching Method for Notebook Battery

The present invention relates to a method for automatically disconnecting a notebook battery, and more particularly, the method for automatically detaching a notebook battery forms a magnetic pole of the N pole and the S pole by fusing magnetic materials to the notebook battery and the notebook junction, respectively, and notebook battery junction. The magnetic mixture that melts at high temperature is fused to the part so that the magnetic pole of the S pole protrudes or expresses during melting, and the magnetic material is fused to the back of the laptop battery junction to form the magnetic pole of the S pole. And a magnetic battery mixture, wherein the magnetization mixture is melted when the laptop battery is automatically separated by the repulsive force of the S poles and the S poles, and the notebook battery is automatically separated from the N poles and the S poles. .

In general, lithium secondary batteries are used in mobile devices such as mobile phones, PDAs, portable game consoles, MP3s, and notebook computers, and are intended to be used for transportation of vehicles in the future. At present, the demand for lithium secondary batteries is exploding, and thus, there is a need for a technology for producing lithium secondary batteries accordingly in order to produce defects in a fast and practical test.

Since lithium secondary batteries have various combustible materials, there are problems such as overheating and explosion due to overcharging, overcurrent, and physical shocks. How to ensure that is needed.

In particular, since the notebook is an expensive device for operating the battery integrally with the notebook, there is a need for a method of automatically and safely separating the lithium secondary battery using a magnet when the notebook malfunctions.

However, there is no known method of automatically separating a lithium secondary battery with a magnet in a notebook.

In this regard, a technology related to an automatic battery separating apparatus and method and structure (Korean Patent No. 677,417) using a geomagnetic sensor of a portable terminal is known. However, the automatic battery separating device and method and structure using the geomagnetic sensor of the portable terminal, when the geomagnetic unit is integrally provided in the portable terminal detects and outputs a signal due to free fall, driving the motor unit and separating the battery unit under the control of the controller. As it detects the earth's magnetic change and automatically separates the battery, it needs an additional earth magnetic change sensor, and it must be equipped with a control part, a hook separating part, and a motor part. Remains.

Accordingly, an object of the present invention is to solve the problem that the automatic separation of the battery is not possible without employing the conventional geomagnetic sensor, geomagnetic unit, control unit, motor unit, and hook separation unit by fusing magnetic materials to the notebook battery, the junction portion of the notebook and the N pole and Form a magnetic pole of the S pole, fusion of the magnetization mixture dissolved at high temperature to the laptop battery junction to protrude or express the magnetic pole of the S pole during melting, and to fuse the magnetic material on the back of the laptop battery junction to stimulate the magnetic pole of the S pole When the high temperature occurs when the short or spec of the notebook is formed, the magnetic mixture is melted and the repulsive force between the protruding S-pole and the S-pole behind the notebook battery junction or the S-pole and the notebook junction behind the notebook battery junction The laptop battery is automatically separated by repulsion with the S pole of The purpose of the present invention is to provide a method of automatically removing a notebook battery.

In order to solve the above object, the present invention provides a notebook battery automatic separation method,

Magnetizing the magnetic mixture, which is a mixture of the magnetic material and the hot melt material, to form a magnetic mixture;

Fusing the magnetization mixture to a laptop battery junction;

Protruding an S pole by dissolving the magnetization mixture of the notebook battery junction when a notebook abnormality occurs;

Separating the notebook battery by the repulsive force between the protruding S pole and the S pole on the back of the notebook battery junction or the S pole on the back of the notebook battery junction and the S pole of the notebook junction; And

The protruding S-pole is coupled to the N-pole of the surface of the notebook battery junction portion; provides a method for automatically separating the notebook battery.

The present invention also provides a notebook battery separated by the notebook battery automatic separation method.

Automatic laptop battery separation method of the present invention by fusion of the magnetic material to the notebook battery, the notebook junction to form the magnetic pole of the N pole and S pole, fusion of the magnetic mixture dissolved at high temperature to the notebook battery junction fusion S The magnetic poles are protruded or exposed and the magnetic material is fused to the back side of the laptop battery junction to form the magnetic poles of the S pole. The notebook battery is automatically separated by the repulsion between the S pole on the back of the laptop battery junction or the S pole on the back of the laptop battery junction and the S pole on the laptop junction, and the notebook is separated by the attraction of the N and S poles. Hold the battery so that if the laptop malfunctions, the notebook battery will not be ejected or exploded from the notebook. Only the battery connection is cut off, and the advantages of being safe and minimizing the customer's economic damage are remarkable.

The present invention provides a method for automatically separating a notebook battery, the method comprising: magnetizing a magnetic mixture which is a mixture of a magnetic material and a high temperature soluble material to form a magnetic mixture; Fusing the magnetization mixture to a laptop battery junction; Protruding an S pole by dissolving the magnetization mixture of the notebook battery junction when a notebook abnormality occurs; Separating the notebook battery by the repulsive force between the protruding S pole and the S pole on the back of the notebook battery junction or the S pole on the back of the notebook battery junction and the S pole of the notebook junction; And the protruding S pole is coupled to the N pole of the notebook battery junction surface.

Specifically, the notebook battery automatic separation method is to fuse the magnetic material to the notebook battery, the notebook junction to form a magnetic pole of the N pole and the S pole, respectively, when melting the magnetic mixture melted at a high temperature on the notebook battery junction The magnetic poles of the S poles are protruded or exposed and the magnetic material is fused to the back side of the laptop battery junction to form the magnetic poles of the S poles. The laptop battery is automatically separated by the repulsion of the poles, and the notebook battery separated by the attraction force of the N and S poles is held.

At this time, the notebook battery is not to be thrown away but only the notebook and the notebook battery connection is cut off so that the notebook battery is still attached to the notebook.

Here, the N pole and the S pole of the present invention may be entirely changed.

In addition, the notebook battery automatic separation method, magnetizing the magnetic material to form a magnetic material; Fusing the magnetic material to expose an N pole on a surface of the notebook battery; And fusion bonding the magnetic material to the N pole of the notebook battery so that the S pole is exposed at the notebook junction.

Here, the north pole of the notebook battery and the south pole of the notebook junction portion are welded to form a north pole and a south pole on the surface of the notebook battery and the notebook junction portion, respectively, the magnetized material magnetized magnetic material.

At this time, the notebook battery separated by the repulsive force between the S poles by the attraction force between the S pole of the notebook junction portion and the N pole of the notebook battery is held so as not to bounce anymore.

In addition, the notebook battery automatic separation method, magnetizing the magnetic material to form a magnetic material; The N pole on the surface of the notebook battery joint portion in which the magnetic material is fused so as to expose the N pole on the surface of the notebook battery junction portion, which is disposed between the notebook battery and the notebook junction portion and has a side diagonal line formed of an elastic material. Binding with the S pole; Binding the protruding S pole with an N pole of a surface of the notebook battery junction; And binding the S pole of the back surface of the notebook battery junction where the magnetization material is fused to expose the S pole on the back side of the notebook battery junction with the N pole of the surface of the notebook battery junction.

Here, the north pole of the surface of the notebook battery junction and the south pole of the back of the notebook battery junction are fused to form a magnetization material of the magnetized magnetic material so that the north pole and the south pole respectively.

At this time, the attraction force between the N pole of the notebook battery junction portion and the S pole of the notebook junction portion, the attraction force of the N pole and the protruding S pole of the notebook battery junction portion, the side slant of the elastic material is formed, the notebook The notebook battery separated by the repulsive force between the S poles is held by the attraction force between the N pole of the battery joint and the S pole of the back of the laptop joint so that it is no longer thrown out.

Here, the magnetic material is a natural magnet, neodymium iron boron compound (Nd ₂ Fe ₁₄ B), magnetic iron alloy, iron dioxide (FeO), ferric trioxide (Fe ₂ O ₃ ), triiron tetraoxide (Fe ₃ O ₄ ) Or niobium titanium compound (Nb ₃ Sn).

Natural magnets refer to naturally occurring magnetized minerals and usually refer to large magnetite. When the magnetite's ore is placed in a strong magnetic field, it becomes a natural magnet. The cause of the magnetic field is lightning.

Nd-Fe-B-based permanent magnets based on neodymium iron boron compounds (Nd ₂ Fe ₁₄ B) were developed by Sagawa in 1984, and have been developed because they have the best magnetic properties among the existing permanent magnets. Commercialization began in 1988, two years later. The use of Nd-Fe-B magnets is mostly used in small motor parts such as VTRs, video cameras, cassettes, and the like, and nuclear magnetic resonance imaging devices for medical use. In addition, their applicability has been discussed in automobiles requiring 30-50 magnets.

Magnetic iron alloy refers to an alloy of iron and nonferrous metals such as iron-chromium alloy, iron-copper alloy, iron-nickel alloy, iron-zinc alloy, or iron-tin alloy.

Iron (II) is FeO, also called iron monoxide or iron dioxide. It is produced by reducing iron (III) oxide with hydrogen or by blocking the air and heating iron oxalate, but pure ones are difficult to obtain. Heating in air results in iron (III) oxide. Made at low temperatures is rich in reactivity and strong magnetism. Reduced by hydrogen to produce iron.

Iron (III) oxide is Fe ₂ O ₃ , also referred to as ferric trioxide or iron trioxide. Naturally, it is widely produced as hematite, and is a factor of the color of red soil. It is a reddish brown powder, specific gravity 4.5-5.2, melting | fusing point 1,550 degreeC, oil absorption 22-75%. It is fairly stable against sunlight, air, moisture, heat, etc., and once heated, it does not melt well and shows magnetism. It is produced by heating iron in the air. In the past, it was made by baking iron sulfate, but recently, it is made from iron sulfate produced from the waste liquid of the steel industry or plating industry. According to the manufacturing method, the color may be yellow, brown, purple, or black, but the color may be different from the particle size, the type of admixture, and the integrity of the crystal lattice. Industrially, Bengala is used as a red pigment and as an abrasive for glass, precious metals, and diamonds. High purity is used as a semiconductor and also as a raw material for magnets and magnetic tapes.

Ferric tetraoxide is a heavy black powder as Fe ₃ O _4, which is naturally produced as magnetite. It is produced by burning iron wire in air or by contacting steam with hot iron.

Niobium tin compound (Nb ₃ Sn) is also a superconducting composite wire.

Here, as an example, a method for preparing a Nd-Fe-B permanent magnet based on the neodymium iron boron compound (Nd ₂ Fe ₁₄ B) may include preparing a powder metal; Pressing step; Heating step; Annealing step; Finishing step; And a magnetization step.

In the step of preparing the powdered metal, neodymium, iron, and boron are first dissolved in vacuo by heating. Working in a vacuum prevents chemical reactions with dissolved substances that can contaminate air and the final metal alloy. When the metal is cooled and solidified, it is broken into small pieces and ground in a ball mill with fine metal powder.

In the pressing step, the fine metal powder is placed on a die having the same size as the final magnet, and then magnetic force is applied to arrange the fine metal powder in the direction of the magnetic force. While applying the magnetic force, the fine metal powder is manufactured to have a thickness of 0.2 ~ 0.5cm by pressing up and down by hydraulic or hydraulic pressure and mechanical ramp press. At this time, the pressure applied is about 7 to 12 atmospheres. Magnets of various types are obtained by placing the fine metal powder in a flexible hermetic discharge container and pressing it by hydraulic or air pressure to form a desired shape.

In the heating step, the compressed slag of the fine metal powder is removed from the die, placed in an oven, and heated. At this time, in the step of heating the compressed slag, the pressed slag is changed into a molten solid metal piece by sintering, which is a phenomenon of tightly contacting and solidifying each other when heating the press-molded powder into an appropriate shape. In the heating step, the compressed slag is first heated at a low temperature to slowly evaporate moisture and other impurities. Then, the heating temperature is 70 to 90% of the melting point of the metal alloy to be heated for several hours to several days to allow the small particles to melt together. Finally, the sintered solid metal pieces are slowly cooled by the controlled temperature drop.

In the annealing step, the sintered solid metal pieces are again heated, cooled and annealed. The annealing step serves to remove the remaining stress of the sintered solid metal pieces and to strengthen the material. The annealed solid metal pieces have the desired final shape and size.

In the finishing step, as a mechanical process, the unnecessary portions of the annealed solid metal pieces are removed and the surface where necessary is smoothed. A protective coating is then applied to the solid metal pieces produced by the finishing process.

In the magnetizing step, the protective coated solid metal piece is placed on the anode of the strong electromagnet and energy is applied to the electromagnet for a predetermined time to arrange the protective coated solid metal piece in the direction of the magnetic field line. At this time, the magnetic force arranges atoms, atomic groups, or magnetic domains in the protective coated solid metal piece so that the protective coated solid metal piece becomes a strong permanent magnet.

The magnetization of the magnetic material is arranged in the direction of the magnetic field in the magnetic field is magnetized.

The magnetization of the magnetic material is magnetized by placing the magnetic material between the anodes of a strong electromagnet and applying energy to the electromagnet to arrange the magnetic material in the direction of the magnetic field by the magnetic force.

The magnetized material is fused in the form of a band, a film, a film, a plate, a circle, a polygon, an oval, or a three-dimensional shape thereof.

Since the magnetic material magnetized magnetized material is fused to the back surface of the notebook battery, the notebook junction, and the notebook battery junction respectively to form a magnetic pole of the N pole and the S pole, the shape of the magnetized material is the notebook battery, notebook According to the shape of the bonding portion, it has a band shape, a film shape, a film shape, a plate shape, circular, polygonal, oval, or a three-dimensional shape thereof, but is not limited thereto.

In addition, the magnetic mixture may be at least one of a high temperature melting material of polyester, nylon, epoxy, urethane, polyolefin, aluminum, or zinc; Natural magnet, neodymium iron boron compound (Nd ₂ Fe ₁₄ B), magnetic iron alloy, iron dioxide (FeO), ferric trioxide (Fe ₂ O ₃ ), triiron tetraoxide (Fe ₃ O ₄ ), or niobium tin compound It is a mixture with any one or more of (Nb ₃ Sn) magnetic material.

Here, the hot melt material may include a process of preheating to be mixed with the magnetic material as a material that is melted by the high temperature generated when the notebook abnormality.

The magnetic mixture is a material before being magnetized as a mixture of the hot melt material and the magnetic material. The magnetic mixture is magnetized to form the magnetic mixture and then fused to the notebook battery junction.

The description of the magnetic material uses the above description.

In addition, the magnetization of the magnetic mixture is arranged in the direction of the magnetic field in the magnetic field is magnetized.

The magnetization of the magnetic mixture is magnetized by placing the magnetic mixture between the anodes of a strong electromagnet and applying energy to the electromagnet to arrange the magnetic mixture in the direction of the magnetic field by the magnetic force.

At this time, the shape of the magnetized mixture is fused, strip-shaped, film, film, plate-like, circular, polygonal, oval, or three-dimensional shape thereof.

Since the magnetic mixture is fused with the magnetized magnetized mixture to the laptop battery junction to form a magnetic pole of the S pole, the shape of the magnetized mixture fused according to the shape of the laptop battery bonded portion in the form of a strip, film, film , Plate-shaped, circular, polygonal, elliptical, or three-dimensional form thereof, but is not limited thereto.

The fusion includes thermal fusion, laser fusion, ultrasonic fusion or high pressure heat fusion.

Here, the magnetic material and the magnetization mixture are fused by thermal fusion of 50 to 700 ° C.

In addition, the magnetic material and the magnetic mixture are fused with a laser including an excimer laser such as a carbon dioxide laser, an argon laser, a helium-silver laser, a Yttrium Aluminum Garnet (Nd: YAG) laser, and a xenon chloride laser.

At this time, the magnetic material and the magnetic mixture are fused with ultrasonic waves of 20 KHz to 200 MHz, respectively.

In addition, the magnetic material and the magnetized mixture are fused by high pressure heat fusion of 1.5 to 10 atm and 50 to 1000 ° C.

In addition, the present invention includes a notebook battery separated by the notebook battery automatic separation method.

1 is a cross-sectional view showing a method for automatically removing a notebook battery according to the present invention, Figure 2 is another cross-sectional view showing a method for automatically disconnecting a notebook battery according to the present invention.

As shown in FIG. 1, the magnetization material is fused to the notebook junction portion 100 so that the S pole is formed on the surface thereof, and the magnetization mixture is fused to the notebook battery junction portion 110. Here, the magnetic material is fused to the surface of the notebook battery junction portion 120 so that the N pole is formed on the surface, and the magnetic material is fused to the surface of the notebook junction portion 150 so that the S pole is formed on the surface.

In this case, the elastic material 125 is further formed on the side surface of the laptop battery junction portion 120 so that the elastic material 125 prevents the laptop battery from being separated and bounced off. That is, the notebook battery does not bounce off the notebook when detached, but the notebook battery is continuously attached to the notebook by the elastic material 125 and only the connection is blocked. The elastic material 125 is not exposed out when it is connected to the notebook, but when the notebook battery is fully connected to the notebook, the elastic material 125 pops out to ensure the safety of the customer that may occur when detaching. .

Here, the magnetic material is fused to the laptop battery 200 so that the N pole is formed on the surface thereof.

As shown in FIG. 2, the magnetization mixture is fused to the notebook battery junction 110, the magnetization material is fused to the notebook battery junction surface 120 so that the N pole is formed on the surface thereof, and the magnetization of the notebook junction back surface 150 is magnetized. The material is fused so that the S pole is formed on the surface.

Magnified A shows the magnetized mixture 180 fused to the notebook battery junction 110. Magnified B shows the magnetized mixture 180 fused to the notebook battery junction 110. It can be seen that the pole 170 and the hot melt material (175).

Here, the protruding S-pole 170 is separated from the high-temperature melting material 175 when the magnetization mixture 180 is melted due to high heat when a laptop abnormality occurs.

When the surface of the magnetization mixture 180 melts due to the high temperature generated when the magnetization mixture 180 is abnormal in the notebook, the magnetic material having the S pole is exposed to the outside.

The protruding S-pole 170 formed by melting the magnetized mixture by heat and exposing the magnetic material of the S-pole to the outside is bound to the N-pole 120 on the surface of the laptop battery junction by attraction and is formed on the back of the laptop battery junction. S pole 150 is pushed away.

When the protruding S-pole 170 is separated, only the S-pole 150 on the back side of the notebook battery junction remains, and the notebook junction S-pole 100 acts as a repulsive force with each other, and the notebook battery is automatically separated from the notebook.

The protruding S-pole is coupled to the N-pole 120 on the surface of the laptop battery joint to prevent the battery from being thrown off and being held by the laptop battery.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

1 is a cross-sectional view showing a method of automatically removing a notebook battery according to the present invention.

2 is another cross-sectional view showing a method of automatically removing a notebook battery according to the present invention.

Description of the Related Art [0002]

100: notebook junction 110: notebook battery junction

120: laptop battery junction surface 125: elastic material

150: behind the laptop battery junction 170: protruding S pole

175: hot melt material 200: notebook battery

Claims (11)

Magnetizing the magnetic mixture, which is a mixture of the magnetic material and the hot melt material, to form a magnetic mixture; Fusing the magnetization mixture to a laptop battery junction; Protruding an S pole by dissolving the magnetization mixture of the notebook battery junction when a notebook abnormality occurs; Separating the notebook battery by the repulsive force between the protruding S pole and the S pole on the back of the notebook battery junction or the S pole on the back of the notebook battery junction and the S pole of the notebook junction; And The protruding S-pole is coupled to the N-pole of the surface of the laptop battery joint; laptop battery automatic separation method comprising a. The method of claim 1, wherein the notebook battery automatic separation method, Magnetizing the magnetic material to form a magnetic material; Fusing the magnetic material to expose an N pole on a surface of the notebook battery; And Fusing the magnetic material to bind the N pole of the notebook battery so that the S pole is exposed at the notebook junction; and automatically discharging the notebook battery. The method of claim 1, wherein the notebook battery automatic separation method, Magnetizing the magnetic material to form a magnetic material; The N pole on the surface of the notebook battery joint portion in which the magnetic material is fused so as to expose the N pole on the surface of the notebook battery junction portion, which is disposed between the notebook battery and the notebook junction portion and has a side diagonal line formed of an elastic material. Binding with the S pole; Binding the protruding S pole with an N pole of a surface of the notebook battery junction; And Binding the S pole on the back side of the notebook battery junction where the magnetization material is fused so that the S pole is exposed on the back side of the notebook battery junction; and the N pole on the surface of the notebook battery junction. How to automatically remove your notebook battery. The magnetic material of claim 1, wherein the magnetic material is natural magnet, neodymium iron boron compound (Nd ₂ Fe ₁₄ B), magnetic iron alloy, iron dioxide (FeO), ferric trioxide (Fe _2). O ₃ ), triiron tetroxide (Fe ₃ O ₄ ), or niobium tin compound (Nb ₃ Sn) any one or more of the automatic battery battery separation method. 4. The method of claim 2, wherein the magnetization of the magnetic material is arranged in the direction of the magnetic field in the magnetic field and magnetized. The method of claim 2 or 3, wherein the magnetic material is fused in the shape of a strip, film, film, plate, circular, polygonal, oval, or three-dimensional laptop battery automatic separation method characterized in that. The method of claim 1, wherein the magnetic mixture is polyester, nylon, epoxy, urethane, polyolefin, aluminum, or any one or more of the hot melt material of zinc; Natural magnet, neodymium iron boron compound (Nd ₂ Fe ₁₄ B), magnetic iron alloy, iron dioxide (FeO), ferric trioxide (Fe ₂ O ₃ ), triiron tetraoxide (Fe ₃ O ₄ ), or niobium tin compound (Nb ₃ Sn) of any one or more of the magnetic materials; laptop battery automatic separation method characterized in that the mixture with. The method of claim 1, wherein the magnetization of the magnetic mixture is arranged in the direction of the magnetic field in the magnetic field and is magnetized automatically. The method of claim 1, wherein the magnetized mixture is fused in the form of a strip, film, film, plate, circular, polygonal, oval, or three-dimensional laptop battery automatic separation method characterized in that. The method of any one of claims 1 to 3, wherein the fusion comprises a thermal fusion, laser fusion, ultrasonic fusion, or high pressure thermal fusion method of the notebook battery automatic separation. A notebook battery separated by the notebook battery automatic separation method according to any one of claims 1 to 3.

Images