KR102649527B1 - Assembly block-type auxiliary battery with variable capacity structure - Google Patents

Abstract

An assembled block-type auxiliary battery including a variable capacity structure is disclosed. The assembly block-type auxiliary battery according to an embodiment of the present invention has a structure on the outer surface that is detachable from another assembly block-type auxiliary battery, has a power output unit mounted inside, and has a plurality of detachable power storage units on one side. An assembly block housing with a capable structure; A power output unit mounted inside the assembly block housing and equipped with a power output terminal on one side of the assembly block housing for drawing power from the power storage unit and providing it to the outside; and a power storage unit having a structure that is detachable from one side of the assembly block housing and a secondary battery capable of storing power is mounted therein.
According to the present invention, it is possible to solve the problem of having to carry an auxiliary battery of a burdensome size even when going out lightly, and the storage capacity, size, and weight that can be carried can be changed depending on the amount of power required for the electronic device being carried, making it portable. An assembly block-type auxiliary battery that can reduce the burden can be provided.

Description

Assembly block-type auxiliary battery with variable capacity structure}

The present invention relates to an assembly block-type auxiliary battery, and more specifically, to an assembly block-type auxiliary battery including a structure capable of changing power storage capacity.

Recently, various mobile devices have been developed, and among them, smartphones have become widely popular and established. Smartphones are used by many people around the world regardless of age and gender, and as their performance improves, numerous applications are continuously being developed and provided. For example, it has become possible to utilize a wide variety of functions, including navigation, music and video streaming services, and vehicle linkage services.

However, there is a problem in that using a service that requires sending, receiving, or processing a lot of information using a smartphone causes extreme battery consumption and a sharp decrease in the available time. In other words, the capacity of the battery installed in the smartphone is limited, so when using such high-specification services, the inconvenience of having to frequently charge using a charger arises.

To solve this problem, external auxiliary batteries that are connected to smartphones with a cable have recently been developed and sold. In particular, recently, smartphones have adopted their own external cases made of metal, and all-in-one products with batteries that cannot be replaced due to design reasons are being released, and the smartphone external auxiliary battery market is growing further.

However, conventional auxiliary batteries are manufactured so that consumers can select and use them within the battery capacity range set by the manufacturer, and the capacity range of most auxiliary batteries is mainly distributed in a specific band. Therefore, the capacity of the auxiliary battery that the user can select is limited, and in particular, the user may need auxiliary batteries of different capacities depending on the situation. In any case, an auxiliary battery with a fixed capacity must be used. To solve this problem, various There was an inefficiency in having to purchase and use batteries of sufficient capacity.

For example, a large-capacity auxiliary battery is suitable for traveling or long-term business trips, and a small-capacity auxiliary battery is suitable for simply going out. However, users have no choice but to always use an auxiliary battery with a certain capacity, and in various situations. There were limitations that made it impossible to select flexible capacity.

Meanwhile, recent smartphones are manufactured to enable fast charging at 9V or 12V, but most auxiliary batteries used in these smartphones only support regular charging at 5V.

In addition, when performing office work or applying makeup in a small space, portable equipment that can easily purify the air in a small indoor space is needed, and technology that can be operated with an auxiliary battery is needed.

Therefore, there is a need for a technology that can solve the problems caused by the prior art mentioned above.

Korean Patent Publication No. 10-1848726 (Registration date: April 9, 2018)

The purpose of the present invention is to solve the problem of having to carry an auxiliary battery of a burdensome size even when going out lightly, and to change the storage capacity, size, and weight that can be carried depending on the amount of power required for the electronic device being carried. The purpose is to provide an assembly block-type auxiliary battery that can reduce the burden of.

In order to achieve this purpose, an assembly block-type auxiliary battery including a capacity variable structure according to an aspect of the present invention has a structure that is detachable from another assembly block-type auxiliary battery on the outer surface, and a power output unit is mounted inside. An assembly block housing having a structure on one side of which a plurality of power storage units can be attached and detached; A power output unit mounted inside the assembly block housing and equipped with a power output terminal on one side of the assembly block housing for drawing power from the power storage unit and providing it to the outside; and a power storage unit having a structure that is detachable from one side of the assembly block housing and a secondary battery capable of storing power is mounted therein.

In one embodiment of the present invention, the assembly block housing has a rectangular parallelepiped structure or a cubic structure, is formed on the left or right side of the assembly block housing, and has a structure that is detachable from another assembly block housing, and includes a power output unit and A first connection structure that is electrically connected; a second coupling structure formed on the lower surface of the assembly block housing, having a structure that is detachable from the power storage unit, and electrically connected to the power output unit; And a charging structure that is mounted inside the assembly block housing, has a charging terminal for receiving power from the outside on the upper surface of the assembly block housing, and charges the power storage unit with the power provided from the charging terminal through a second connection structure. It may be a configuration that includes a module.

In one embodiment of the present invention, the power storage unit has a square pillar structure having an upper surface of the same structure as the lower surface of the assembly block housing, and a structure in which a space for storing a plurality of plate-shaped secondary batteries is formed. storage housing; It is formed on the left or right side of the storage housing, and has a structure that allows slidingly inserting or ejecting a plate-shaped secondary battery into the storage housing, and has a structure that electrically connects the inserted plate-shaped secondary battery to the power output unit and charging module. rail; and a plate-shaped secondary battery that has a plate-shaped structure that can be slidably inserted into or discharged from the binding rail and that can be electrically connected to the binding rail.

In one embodiment of the present invention, the assembly block-type auxiliary battery is mounted in a detachable structure to the first connection structure of the assembly block housing, operates by receiving power through the first connection structure, and operates by receiving power from the surrounding air. An air purification unit configured to suck in and purify air and then exhaust the purified air through an exhaust nozzle; A plurality of nozzle mounting units are mounted on the outer side of the air purifying unit at regular intervals and are configured to deliver air purified from the air purifying unit to the exhaust nozzle; and a detachable structure mounted on the nozzle mounting part, a structure extending by a predetermined length, a structure that can be bent according to the user's intention, and an exhaust structure that exhausts the purified air delivered through the nozzle mounting part from one end. It may be configured to include a nozzle.

In one embodiment of the present invention, the air purifying unit is formed inside the air purifying unit, and draws external air from the upper surface of the air purifying unit on which the filter is mounted and flows in the direction of the nozzle mounting unit on which the exhaust nozzle is mounted. an air flow channel forming a furnace; It is mounted symmetrically on both sides inside the air inlet side of the air flow channel, has a hollow airfoil structure, and is arranged so that the front end of the airfoil structure faces toward the air inlet side, and compressed air flows toward the rear end of the airfoil structure. A flow rate generator having a structure formed with a compressed air injection port for spraying; An intake pump mounted inside the air purification unit and sucking in external air from the upper surface of the air purifying unit on which a filter is mounted and supplying compressed air into the flow generating unit; It is mounted inside the air flow channel and includes a first electrode mounted on a front portion where external air is sucked and a second electrode mounted at a predetermined distance from the first electrode, and a high voltage applied to the first electrode and the second electrode. an ion generator that applies; and an exhaust pump mounted at the rear end of the air flow channel and configured to flow air passing through the ion generator to a nozzle mounting portion where an exhaust nozzle is mounted.

As described above, according to the assembly block-type auxiliary battery of the present invention, by providing an assembly block housing of a specific structure, a power output unit, and a power storage unit, the problem of having to carry an auxiliary battery of a burdensome size even when going out lightly is solved. It is possible to provide an assembly block-type auxiliary battery that can reduce the burden of carrying by changing the portable storage capacity, size, and weight depending on the amount of power required for the electronic device being carried.

In addition, according to the assembled block-type auxiliary battery of the present invention, by providing a power storage unit including a storage housing of a specific structure, a binding rail, and a plate-type secondary battery, not only the number of power storage units installed, but also the power storage unit can be inserted into one power storage unit. Even the quantity of plate-type secondary batteries mounted can be changed, making it possible to provide an assembled block-type auxiliary battery that can be changed to a lighter portable storage capacity and weight.

In addition, according to the assembled block-type auxiliary battery of the present invention, by providing a power storage unit including a storage housing of a specific structure, a binding rail, and a plate-shaped secondary battery, a plurality of plate-shaped secondary batteries inserted and mounted inside the power storage unit can be connected in series. The range of the output voltage value can be easily changed depending on the number of plate-type secondary batteries that are connected and mounted, and by assembling different quantities of power storage units to match the voltage value of each power storage unit, various voltages and power amounts can be realized. An assembly block-type auxiliary battery can be provided.

In addition, according to the assembly block-type auxiliary battery of the present invention, by providing an air purifying unit, a nozzle mounting unit, and an exhaust nozzle of a specific structure, the air in a specific space is purified into the space intended by the user during indoor daily life. It can be configured to provide clean air, providing an assembly block-type auxiliary battery that can purify the surrounding air while utilizing various electronic devices.

1 is a photograph showing an auxiliary battery according to the prior art.
Figure 2 is a perspective view showing an assembly block-type auxiliary battery according to an embodiment of the present invention.
FIG. 3 is a perspective view showing expanding power storage capacity by assembling two assembly block-type auxiliary batteries shown in FIG. 2.
FIG. 4 is an exploded view showing the assembly block housing, power storage unit, and plate-type secondary battery of the assembly block-type auxiliary battery shown in FIG. 2 in a separated state.
Figure 5 is a perspective view showing an assembly block-type auxiliary battery according to another embodiment of the present invention.
Figure 6 is a cross-sectional schematic diagram specifically showing the air purification unit shown in Figure 6.
Figure 7 is a partial enlarged view showing the flow rate generator of Figure 6 in more detail.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. Prior to this, terms and words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, but should be construed with meanings and concepts consistent with the technical idea of the present invention.

Throughout this specification, when a member is said to be located “on” another member, this includes not only cases where a member is in contact with another member, but also cases where another member exists between the two members. Throughout this specification, when a part "includes" a certain component, this means that it may further include other components rather than excluding other components, unless specifically stated to the contrary.

Figure 2 shows a perspective view showing an assembly block-type auxiliary battery according to an embodiment of the present invention.

Referring to FIG. 2, the assembly block-type auxiliary battery 100 according to this embodiment is provided with an assembly block housing 110, a power output unit 120, and a power storage unit 130 of a specific structure, so that it can be used even when going out lightly. An assembly block that can solve the problem of having to carry an auxiliary battery of a burdensome size, and can change the storage capacity, size, and weight that can be carried depending on the amount of power required for the electronic device being carried, thereby reducing the burden of carrying it. A type auxiliary battery can be provided.

Hereinafter, each component of the assembly block-type auxiliary battery 100 according to this embodiment will be described in detail with reference to the drawings.

FIG. 3 shows a perspective view showing expanding the power storage capacity by assembling two assembly block-type auxiliary batteries shown in FIG. 2, and FIG. 4 shows an assembly block housing of the assembly block-type auxiliary battery shown in FIG. 2. , an exploded assembly diagram showing the power storage unit and the plate-type secondary battery in a separated state is shown.

Referring to FIGS. 2 to 4, the assembly block housing 110 of the assembly block-type auxiliary battery 100 according to this embodiment has a structure on the outer surface that is detachable from another assembly block-type auxiliary battery, and has a structure on the inside. The power output unit 120 is mounted, and a structure in which a plurality of power storage units 130 can be attached and detached is formed on one side.

The power output unit 120 according to this embodiment is mounted inside the assembly block housing 110, and draws power from the power storage unit 130 on one side of the assembly block housing 110 and provides it to the outside. It is a structure equipped with a power output terminal 121.

The power storage unit 130 according to this embodiment has a structure that is detachable from one side of the assembly block housing 110, and has a structure in which a secondary battery capable of storing power is mounted.

Specifically, the assembly block housing 110 may have a rectangular parallelepiped structure or a cubic structure, and may include a first coupling structure 111, a second coupling structure 112, and a charging module 113 of a specific structure. The first coupling structure 111 of the assembly block housing 110 is formed on the left or right side of the assembly block housing 110, has a structure that is detachable from another assembly block housing 110, and has a power output unit 120. It is a structure that is electrically connected to. The second coupling structure 112 is formed on the lower surface of the assembly block housing 110, is detachable from the power storage unit 130, and is electrically connected to the power output unit 120. In addition, the charging module 113 is a component mounted inside the assembly block housing 110, and a charging terminal 114 for receiving power from the outside is mounted on the upper surface of the assembly block housing 110, and the charging terminal ( It is a structure that charges the power storage unit 130 with the power provided from 114) through the second connection structure 112.

As shown in FIGS. 2 and 4, the power storage unit 130 may be configured to include a storage housing 131 of a specific structure, a binding rail 132, and a plate-shaped secondary battery 133.

Specifically, the storage housing 131 of the power storage unit 130 has a rectangular pillar structure or square pillar structure with an upper surface of the same structure as the lower surface of the assembly block housing 110, and a plurality of plate-shaped secondary batteries ( 133) is a structure that has a space for storing things. The binding rail 132 is formed in a shape that is recessed to a predetermined depth on the left or right side of the storage housing 131, and is capable of slidingly inserting or discharging the plate-shaped secondary battery 133 into the storage housing 131. It is a structure that electrically connects the inserted plate-shaped secondary battery 133, the power output unit 120, and the charging module 113. In addition, the plate-shaped secondary battery 133 has a plate-shaped structure that can be slidably inserted into or discharged from the binding rail 132, and has a structure that can be electrically connected to the binding rail 132.

In this case, according to the present embodiment, the power storage unit 130 is installed by providing a storage housing 131 of a specific structure, a binding rail 132, and a plate-shaped secondary battery 133. Not only the quantity but also the quantity of plate-type secondary batteries inserted and mounted inside one power storage unit can be changed, making it possible to provide an assembled block-type auxiliary battery that can change the portable storage capacity and weight to become lighter. In addition, by connecting a number of plate-shaped secondary batteries inserted and mounted inside the power storage unit in series, the range of the output voltage value can be easily changed depending on the number of plate-shaped secondary batteries mounted, and the voltage value of each power storage unit can be changed. By assembling the power storage units in different quantities, it is possible to provide an assembled block-type auxiliary battery that can implement various voltages and amounts of power.

Figure 5 shows a perspective view showing an assembly block-type auxiliary battery according to another embodiment of the present invention, Figure 6 shows a cross-sectional schematic diagram specifically showing the air purification unit shown in Figure 6, and Figure 7 shows A partial enlarged view showing the flow rate generator in 6 in more detail is shown.

Referring to these drawings, the assembly block-type auxiliary battery 100 according to this embodiment may be configured to further include an air purifying unit 140, a nozzle mounting unit 146, and an exhaust nozzle 150 of a specific structure.

Specifically, the air purification unit 140 is a detachable structure mounted on the first coupling structure 111 of the assembly block housing 110, and operates by receiving power through the first coupling structure 111, It is a structure that sucks in the surrounding air, purifies it, and then exhausts the purified air through the exhaust nozzle (150). A plurality of nozzle mounting units 146 are mounted on the outer side of the air purifying unit 140 at regular intervals and are structured to deliver air purified from the air purifying unit 140 to the exhaust nozzle 150. In addition, the exhaust nozzle 150 is a structure that is mounted on the nozzle mounting part 146 in a detachable structure, has a structure that extends a predetermined length, and has a structure that can be bent according to the user's intention, and is connected to the nozzle mounting part 146 through the nozzle mounting part 146. It is a structure that exhausts the delivered purified air from one end.

The air purification unit 140 according to this embodiment includes an air flow channel 141 of a specific structure, a flow rate generator 143, an intake pump 142, an ion generator 144, and an exhaust pump 145. It may be a configuration.

Specifically, the air flow channel 141 of the air purifying unit 140 is formed inside the air purifying unit 140 and sucks external air from the upper surface of the air purifying unit 140 on which the filter (F) is mounted. This forms a flow path that causes the air to flow in the direction of the nozzle mounting portion 146 on which the exhaust nozzle 150 is mounted. The flow generator 143 is mounted symmetrically on both sides inside the air inlet side of the air flow channel 141, has a hollow airfoil structure, and is arranged so that the front end of the airfoil structure faces in the direction of the air inlet. It is a structure in which a compressed air injection port is formed to spray compressed air toward the rear end of the foil structure. The intake pump 142 is a component mounted inside the air purification unit 140, and sucks external air from the upper surface of the air purification unit 140 on which the filter (F) is mounted and flows it into the flow generator 143. Compressed air can be supplied.

The ion generator 144 according to this embodiment is mounted inside the air flow channel 141, and includes a first electrode 144a mounted on the front portion where external air is sucked, a first electrode 144a, and a predetermined amount. It includes a second electrode (144b) that is mounted at a distance apart from each other, and has a structure that applies a high voltage to the first electrode (144a) and the second electrode (144b).

The exhaust pump 145 according to this embodiment is mounted at the rear end of the air flow channel 141 and flows the air passing through the ion generator 144 to the nozzle mounting portion 146 on which the exhaust nozzle 150 is mounted. It is a structure.

Specifically, the air sucked into the air flow channel 141 by the intake pump 142 and the flow generator 143 passes through the first electrode 144a and the second electrode 144b and is sterilized and disinfected. . The first electrode 144a and the second electrode 144b are spaced apart by a predetermined distance and a high voltage is applied to generate ions.

The first electrode 144a may include vanadium-based metal oxide. Preferably, the vanadium-based metal oxide may be vanadium pentoxide (V ₂ O ₅ ). In addition, the first electrode 144a includes divanadium pentoxide (V ₂ O ₅ ) as a vanadium-based metal oxide, and is selected from the group consisting of barium oxide (BaO), ferric oxide (Fe ₂ O ₃ ), and zinc oxide (ZnO). It can include at least one of them.

General metal oxides may have metallic properties or insulating properties depending on the vacancy of oxygen atoms in the oxide. When a large number of oxygen atom vacancies are distributed within the metal oxide, the metal oxide has conductive characteristics close to that of a metal, and when there are a small number of oxygen atom vacancies distributed within the metal oxide, the metal oxide has characteristics close to an insulator. The vacancies of these oxygen atoms vary depending on the type of metal that makes up the material and the temperature.

The vanadium-based metal oxide contained in the first electrode 144a, particularly divanadium pentoxide (V ₂ O ₅ ), has conductivity characteristics close to those of metal. Additionally, the first electrode 144a containing vanadium-based metal oxide is resistant to corrosion by strong acids and has excellent corrosion resistance.

The first electrode 144a according to this embodiment includes divanadium pentoxide, a vanadium-based metal oxide, and is formed by using a material in which at least one metal oxide selected from the group consisting of barium oxide, ferric oxide, and zinc oxide is melted, using a cooling roll. Pass through to obtain rapidly frozen powder. Preferably, the quick-frozen powder may contain 50 to 70 wt% divanadium pentoxide.

The powder is crushed to produce 3μm-sized powder and 80nm-sized powder, mixed, and injection molded to create a sharp shape like a pencil lead. The first electrode 144a, compressed by injection molding into a sharp shape like a pencil lead, is heated to 550°C, a temperature below the melting point, and undergoes an atmospheric pressure sintering process in which the powders are brought into close contact with each other and sintered. The first electrode 144a, for which atmospheric pressure sintering has been completed, is sealed with metal foil or glass and subjected to a hot isostatic press process of pressure sintering while isotropically pressurized with an inert gas to form a homogeneous, high-density first electrode ( 144a) Remove the pores within.

A strong electric field is formed around the first electrode 144a, which has a sharp shape like a pencil lead. That a strong electric field will be generated around the first electrode 144a can be predicted based on the characteristics of charge distribution on the surface of a conductor and Gauss's law.

As described above, the second electrode 144b to which high voltage is applied is an electrode toward which molecules converted from neutral molecules to anion molecules by colliding with negative ions by corona discharge are directed, and includes an ion generator according to an embodiment of the present invention. The dust collector functions as a dust collection unit where dust particles combined with anion molecules are collected.

The first electrode 144a and the second electrode 144b are not particularly limited as long as the distance allows corona discharge to be generated under the best conditions, but may be preferably spaced apart from 5 to 7 mm.

The second electrode 144b may have a plate shape or a cylindrical shape with a cavity, but is not necessarily limited thereto, and is preferably mounted in a detachable structure so that dust collected in the second electrode 144b can be easily removed. .

The second electrode 144b of a thin plate structure may be a combination of a metal alloy unit and a metal oxide unit containing vanadium-based metal oxide, and the metal oxide unit is coated on the surface of a predetermined area of the metal alloy unit to form a second electrode ( 144b) may be formed.

The purified, sterilized, and disinfected air that passes through the first electrode 144a and the second electrode 144b inside the air flow channel 141 is sprayed to the exhaust nozzle 150 through the exhaust pump 145. The exhaust nozzle 150 is a pipe structure that extends a predetermined length and whose bending direction and bending angle can be changed according to the operator's intention.

In this case, according to the present embodiment, by providing an air purifying unit 140, a nozzle mounting unit 146, and an exhaust nozzle 150 of a specific structure, the air in a specific space is purified during indoor daily life, allowing the user to It can be configured to provide purified air to the intended space, providing an assembly block-type auxiliary battery that can purify the surrounding air while utilizing various electronic devices.

In the above detailed description of the present invention, only special embodiments thereof have been described. However, it should be understood that the present invention is not limited to the particular form mentioned in the detailed description, but rather is understood to include all modifications, equivalents and substitutes within the spirit and scope of the present invention as defined by the appended claims. It has to be.

That is, the present invention is not limited to the specific embodiments and descriptions described above, and various modifications may be made by anyone skilled in the art without departing from the gist of the present invention as claimed in the claims. is possible, and such modifications fall within the scope of protection of the present invention.

100: Assembly block type auxiliary battery
110: Assembly block housing
111: First binding structure
112: Second binding structure
113: Charging module
114: Charging terminal
120: Power output unit
121: Power output terminal
130: Power storage unit
131: storage housing
132: Binding rail
133: Plate-type secondary battery
140: Air purification unit
141: Air flow channel
F: filter
142: intake pump
143: Flow generator
H: Compressed air nozzle
FE: Front end of airfoil structure
RE: Rear end of airfoil structure
144: Ion generation unit
144a: first electrode
144b: second electrode
145: exhaust pump
146: Nozzle mounting part
150: Exhaust nozzle

Claims (5)

An assembly block in which another assembly block-type auxiliary battery and a detachable structure are formed on the outer surface, a power output unit 120 is mounted on the inside, and a structure in which a plurality of power storage units 130 are detachable is formed on one side. housing (110);
A power structure that is mounted inside the assembly block housing 110 and has a power output terminal 121 on one side of the assembly block housing 110 that draws power from the power storage unit 130 and provides it to the outside. Output unit 120; and
A power storage unit 130 that is detachable from one side of the assembly block housing 110 and has a secondary battery capable of storing power therein;
Including,
The assembly block housing 110 is,
It is a cuboidal structure or a cubic structure,
A first binding structure 111 formed on the left or right side of the assembly block housing 110, has a structure that is detachable from another assembly block housing 110, and is electrically connected to the power output unit 120. ;
A second coupling structure 112 formed on the lower surface of the assembly block housing 110, has a structure that is detachable from the power storage unit 130, and is electrically connected to the power output unit 120; and
It is mounted inside the assembly block housing 110, and a charging terminal 114 for receiving power from the outside is mounted on the upper surface of the assembly block housing 110, and the power provided from the charging terminal 114 is connected to the second binder. A charging module 113 configured to charge the power storage unit 130 through the structure 112;
Including,
The power storage unit 130,
A storage housing 131 having a square pillar structure having an upper surface of the same structure as the lower surface of the assembly block housing 110 and having a space therein for storing a plurality of plate-shaped secondary batteries 133;
It is formed on the left or right side of the storage housing 131, and has a structure capable of slidingly inserting or discharging the plate-shaped secondary battery 133 into the storage housing 131, and outputs power with the inserted plate-shaped secondary battery 133. A binding rail 132 having a structure that electrically connects the unit 120 and the charging module 113; and
A plate-shaped secondary battery 133 that has a plate-shaped structure that can be slidably inserted into or discharged from the binding rail 132 and is electrically connected to the binding rail 132;
Including,
It is mounted in a detachable structure on the first coupling structure 111 of the assembly block housing 110, operates by receiving power through the first coupling structure 111, and purifies the surrounding air by sucking it in. An air purifying unit 140 configured to exhaust air through an exhaust nozzle 150;
A plurality of nozzle mounting units 146 are mounted on the outer side of the air purifying unit 140 at regular intervals and are configured to transmit the air purified from the air purifying unit 140 to the exhaust nozzle 150; and
It is mounted in a detachable structure on the nozzle mounting part 146, has a structure extending by a predetermined length, and can be bent according to the user's intention, and purified air delivered through the nozzle mounting part 146 is supplied from one end. An exhaust nozzle 150 having an exhaust structure;
An assembled block-type auxiliary battery comprising:
delete delete delete According to paragraph 1,
The air purification unit 140,
It is formed inside the air purifying unit 140, and external air is sucked in from the upper surface of the air purifying unit 140 on which the filter (F) is mounted, in the direction of the nozzle mounting unit 146 on which the exhaust nozzle 150 is mounted. an air flow channel 141 forming a flow path;
It is mounted symmetrically on both sides inside the air inlet side of the air flow channel 141, has a hollow airfoil structure, and is arranged so that the front end of the airfoil structure faces in the direction of the air inlet, and the rear end of the airfoil structure is directed. A flow rate generator 143 having a structure formed with a compressed air injection port that sprays compressed air into the;
An intake unit installed inside the air purifying unit 140 and sucking in external air from the upper surface of the air purifying unit 140 on which the filter (F) is mounted and supplying compressed air into the flow generating unit 143. pump 142;
A first electrode (144a) installed inside the air flow channel 141 and mounted on the front portion where external air is sucked, and a second electrode (144b) installed at a predetermined distance from the first electrode (144a). An ion generator 144 that includes and applies a high voltage to the first electrode 144a and the second electrode 144b; and
An exhaust pump 145 installed at the rear end of the air flow channel 141 and configured to flow the air passing through the ion generating unit 144 to the nozzle mounting unit 146 on which the exhaust nozzle 150 is mounted;
An assembled block-type auxiliary battery comprising: