KR102616228B1 - Oxygen supply system for buildings and its construction method - Google Patents

Abstract

The present invention relates to an oxygen supply device for buildings and a construction method thereof. To realize this, the present invention collects nitrogen in the air flowing in from the outside, concentrates the oxygen in a separated state, and stores it in an oxygen storage tank located on one side of the interior. An oxygen generator that stores oxygen, an oxygen pipe whose end is connected to the oxygen storage tank, an LED wire whose end is connected to the power supply of the oxygen generator, and a control wire whose end is connected to the control unit of the oxygen generator are one combined duct. An oxygen supply line accommodated in a cable, installed indoors, and connected to the other end of the oxygen pipe and the other end of the LED wire to provide lighting and an oxygen ejector installed indoors, It is configured to include a controller that is connected to the other end of the controller wire and controls the operation of the oxygen generator through the control unit.

Description

Oxygen supply system for buildings and its construction method}

The present invention relates to a device for supplying oxygen to the interior of a building, and more specifically, to an oxygen supply device for a building and a construction method thereof that can reduce the cost and double the efficiency of installation of the oxygen supply device. It's about.

In general, the effects of oxygen deficiency on the human body have been well known through various papers and news.

For example, lack of oxygen can cause serious disorders in brain function, causing headaches, memory loss, senility, and encephalomalacia, as well as decreased liver function and slowed blood circulation.

In particular, when a person drinks alcohol, the alcohol in the alcohol decomposes into acetaldehyde, which in turn decomposes into carbonic acid and water, which requires three molecules of oxygen in this process. Therefore, the more you drink, the more oxygen you need, and the more oxygen you lack.

In addition, in the case of general drinkers, they smoke excessively along with alcohol. Smoking increases the body's need for oxygen, but also interferes with the smooth supply of oxygen through the lungs, so the combination of drinking and smoking is harmful to the body. This causes excessive oxygen deficiency. Therefore, there is a need to supply a greater amount of oxygen to drinkers, especially those who smoke.

Accordingly, recently, a method of making oxygen using an oxygen generator and supplying it indoors has been used. An oxygen generator is a mechanical device that separates air taken in from the outside into oxygen and gases other than oxygen, and various types have been developed. Methods for generating oxygen from such an oxygen generator include a method using an adsorbent (Pressure Swing adsorption) and a Gas Separation Membrane method that uses differences in diffusion and permeation rates of gas.

And the system for supplying oxygen generated from the oxygen generator to the desired location is an oxygen supply device. This oxygen supply device includes an oxygen generator and an oxygen supply line and controller to accurately and safely supply oxygen generated from the oxygen generator to the desired location. etc. are included.

This type of oxygen supply device can be applied to houses and office spaces in buildings, etc., and has the purpose of providing a comfortable environment by maintaining the oxygen concentration in the area at an optimal level.

However, when installing such an oxygen supply device, conventionally, the oxygen supply line is exposed to the outside, spoiling the aesthetics, the oxygen supply line exposed to the outside can be easily damaged, and it takes up unnecessary space, reducing space efficiency. It caused the decline.

Republic of Korea Patent No. 10-1762269

The present invention was developed to solve the above-mentioned problems, and prevents exposure of the oxygen supply line to the outside by installing the oxygen supply line of the oxygen supply device using the inside of the ceiling or wall of a house or building where a communication line is installed. The purpose is to provide an oxygen supply device for buildings and a construction method that facilitates the installation of oxygen supply lines while improving the interior and exterior aesthetics.

The technical problem to be solved by the present invention does not need to be limited to the technical problem mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below. You will be able to.

The oxygen supply device for buildings according to an embodiment of the present invention for realizing the purpose of the present invention as described above,

An oxygen generator that collects and separates nitrogen from the air flowing in from the outside, concentrates the oxygen, and stores it in an oxygen storage tank located on one side of the interior;

An oxygen pipe with one end connected to the oxygen storage tank, an LED wire with one end connected to the power supply of the oxygen generator, and a controller wire with one end connected to the control unit of the oxygen generator are accommodated in a single combine duct cable. oxygen supply line,

An oxygen ejector installed indoors and connected to the other end of the oxygen pipe and the other end of the LED wire to discharge oxygen into the room while providing lighting, and

It is installed indoors and is configured to include a controller that is connected to the other end of the controller wire and controls the operation of the oxygen generator through the control unit.

More preferably, the oxygen generator includes one of an air purifying unit for removing foreign substances and bad odors in the air flowing in from the outside, a sterilizing unit for sterilizing concentrated oxygen, and a dehumidifying unit for removing moisture from concentrated oxygen. More may be included.

More preferably, the oxygen ejector may be configured as one of a ceiling type ejector installed on the ceiling, a wall type bubble ejector installed on the wall, a stand type ejector, and a wall type communication outlet ejector.

More preferably, the wall-type communication outlet ejector is one of a wall-type communication outlet consisting of one insertion part into which a communication or cable is inserted, a wall-type communication outlet consisting of two insertions, or a wall-type communication outlet consisting of three insertions. It may be configured using a fitting valve connected to the other end of the oxygen pipe to be exposed to the outside through the insertion portion.

More preferably, a dissolved oxygen meter is installed in the room, the measured value of the dissolved oxygen meter is transmitted to the control unit, and when the dissolved oxygen level in the room deviates from the set value, the amount of oxygen supplied to the room is adjusted through the control unit. It can be configured as follows.

In addition, the construction method of an oxygen supply device for a building according to an embodiment of the present invention to implement the purpose of the present invention is,

An oxygen generator location selection step to install the oxygen generator in a place that is separated from the room and allows ventilation,

An oxygen ejector location selection step for discharging the oxygen produced by the oxygen generator into the room through the oxygen ejector;

A controller location selection step for installing a controller that controls the operation of the oxygen generator, and

Oxygen supply in which an oxygen supply line including oxygen pipes and LED wires for connecting the oxygen generator and the oxygen discharger, and a control wire for connecting the control unit of the oxygen generator and the controller is installed through the inside of the ceiling and the inside of the wall. It consists of a line laying step.

More preferably, the oxygen ejector may be configured as one of a ceiling-type ejector installed on the ceiling, a wall-type bubble ejector installed on the wall, a mobile stand-type ejector, or a wall-type communication outlet ejector installed on the wall.

More preferably, the oxygen ejector may be installed together with at least two of the ceiling-type ejector, the wall-type bubble ejector, the mobile stand-type ejector, or the wall-type communication outlet ejector.

More preferably, the wall-type communication outlet discharger is configured using a wall-type communication outlet having at least one insertion part, and a fitting valve connected to the oxygen pipe of the oxygen supply line may be installed in the insertion part to be exposed to the outside. there is.

More preferably, the insertion part may be further provided with a lighting part connected to the LED wire of the oxygen supply line.

More preferably, in the step of installing the oxygen supply line, a portion of the ceiling is opened in consideration of the positions of the oxygen ejector and the controller that are spaced apart from each other, the open area is selected as a branch point, and one combine duct cable is prepared to connect the ceiling of the branch point. One side of the oxygen pipe is connected to the oxygen generator through the inside or the wall or both, and one side of the oxygen pipe is connected to the oxygen storage tank of the oxygen generator through the single combine duct cable, and one side of the LED wire is connected to the power supply of the oxygen generator, Inserting one controller wire connected to the control unit of the oxygen generator together;

Prepare another combine duct cable and connect it to the oxygen discharger through the inside of the ceiling or the inside of the wall at the branch point, and then connect the other combine duct cable to the oxygen discharger and the other oxygen pipe connected to the oxygen discharger and A step of inserting the other LED wire together,

After preparing another combine duct cable, select a point on the wall where the controller will be installed and drill it, and then connect the other combine duct cable from the branch point to the hole drilled through the inside of the ceiling or the inside of the wall or both. connecting and inserting the other controller wire connected to the controller into the another combine duct cable;

Connecting the end of the one oxygen pipe introduced through the one combine duct cable and the end of the other oxygen pipe introduced through the other combine duct cable at the branch point with an airtight means;

Connecting the end of the one LED wire introduced through the one combine duct cable and the end of the other LED wire introduced through the other combine duct cable at the branch point with an insulating means;

Connecting the end of the one control wire introduced through the one combine duct cable and the end of the other controller wire introduced through the another combine duct cable with an insulating means; and

It may be configured to include the steps of organizing and inserting the interconnected oxygen pipe, the LED wire, and the controller wire into the open branch point, and closing the open branch point.

The oxygen supply device for buildings and its construction method according to the present invention as described above have the following effects.

In other words, as the oxygen supply line connecting the oxygen generator and the oxygen discharger installed indoors is installed between the walls or inside the ceiling of the building where the communication line is installed, the oxygen supply line is exposed to the interior, resulting in appearance defects. It can prevent damage to the oxygen supply line due to external forces, and has the effect of making the installation work of the oxygen supply line simpler and faster.

On the other hand, the effects of the present invention described in this way are naturally exerted by the composition of the described contents regardless of whether the inventor is aware of it, so the above-described effects are only a few effects according to the described contents, and all effects that the inventor has recognized or exist. It should not be accepted as written.

In addition, the effect of the present invention should be further understood by the overall description of the specification, and even if it is not described in explicit sentences, a person skilled in the art in the technical field to which the described content pertains will be able to achieve such effect through this specification. If it is an effect that can be recognized as an effect, it should be viewed as the effect described in this specification.

1 is a diagram schematically showing an oxygen supply system according to an embodiment of the present invention.
Figure 2 (a) is a diagram illustrating a wall-mounted communication outlet discharger using a conventional one-hole wall-mounted communication outlet according to an embodiment of the present invention.
Figure 2 (b) is a diagram illustrating a wall-mounted communication outlet discharger using a conventional two-hole wall-type communication outlet according to an embodiment of the present invention.
Figure 2 (c) is a diagram illustrating a wall-mounted communication outlet ejector using a conventional three-hole wall-type communication outlet according to an embodiment of the present invention.
Figure 3 is a flow chart showing step by step the construction method of an oxygen supply device according to an embodiment of the present invention.

Hereinafter, the configuration and operation according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

This is intended to provide a detailed description so that a person skilled in the art of the present invention can easily practice the contents of the present invention, and does not mean that the technical idea and scope of the present invention are limited. .

In addition, when adding reference numerals to the components in each drawing, it should be noted that they are denoted by the same symbol, and terms specifically defined in consideration of the configuration and operation of the present invention do not depend on the intention or custom of the user or operator. It may vary depending on the situation, and the definitions of these terms should be judged based on the content throughout this specification.

First, the oxygen supply device for buildings according to an embodiment of the present invention includes an oxygen generator that generates oxygen, an oxygen supply line for moving oxygen into the interior of the building and electrically controlling it, and these oxygen supply lines and It can be broadly divided into an oxygen discharger that is connected and supplies oxygen to the room, and a controller that properly discharges oxygen generated from the oxygen generator into the room through the oxygen discharger. Referring to the illustrated drawings below, each configuration will be described in more detail. Looking at it, it is as follows.

First, the oxygen generator 100,

When used in relatively small spaces such as houses, the pressure swing adsorption (PSA) method can be used, for example, an oxygen concentrator equipped with an adsorption tower made of zeolite adsorbent, and the air compressed in this oxygen concentrator. It may be configured to include an air compressor that supplies, and due to the difference in adsorption power from the compressed air supplied into the oxygen concentrator, a relatively superior amount of nitrogen is adsorbed into the adsorption tower, thereby generating concentrated oxygen.

In addition, the concentrated oxygen is supplied to where it is needed via an oxygen storage tank, and the nitrogen adsorbed in the adsorption tower can be separated from the adsorption tower as it returns to atmospheric pressure when the air pressure applied to the adsorption tower is released.

In such an oxygen generator 100, air is usually compressed to a pressure between 2.5 and 3.5 atm and supplied to the oxygen concentrator, and nitrogen adsorbed to the oxygen concentrator is desorbed and discharged at atmospheric pressure.

And when applied to a relatively large space, such as an office in a building, oxygen can be separated from nitrogen in the atmosphere using the vacuum swing adsorption (VSA) method.

As it passes through the oxygen concentrator at atmospheric pressure, a relatively large amount of nitrogen is adsorbed to the adsorption tower and oxygen is concentrated, and the nitrogen adsorbed to the adsorption tower can then be desorbed and separated by maintaining the vacuum inside the oxygen concentrator.

Meanwhile, such an oxygen generator 100 may include an air purifying unit to remove foreign substances and bad odors from the air sucked into the interior as needed. For example, an intake unit that introduces air into the oxygen generator 100. A HEPA filter, a fine dust removal filter, or both may be installed, or the concentrated oxygen may be configured to be exported indoors through a separate ultra-fine dust removal filter before being exported indoors.

In addition, the oxygen generator 100 may further include a dehumidifying unit to remove moisture generated during the oxygen concentration process, if necessary, and at the same time, ultraviolet rays in the wavelength range of 250 to 280 nm are irradiated to the oxygen moved into the room to increase the oxygen concentration. A sterilizing unit may be further included to ensure that it is moved indoors in a sterilized state.

Here, the air purifying unit, dehumidifying unit, or sterilizing unit described above may be provided not inside the oxygen generator 100 but in the oxygen ejector 300, which will be described later.

Additionally, a magnetization generator can be installed in the oxygen storage tank where the oxygen concentrated in the oxygen generator 100 is temporarily stored to change the stored oxygen into highly reactive oxygen and move it indoors.

Here, the magnetization generator installs, for example, a N-pole permanent magnet on the upper surface of the oxygen storage tank and an S-pole permanent magnet on the bottom of the oxygen storage tank, so that the oxygen stored in the oxygen storage tank is within the magnetic force range of the permanent magnet. Oxygen can be magnetized by placing it inside, and the magnetized oxygen can act as an ion compared to general oxygen, and a deodorizing effect can be expected to supply fresher oxygen to the room.

And the oxygen supply line 200,

Oxygen pipes 210a and 210b are used to connect the above-mentioned oxygen generator 100 and the oxygen ejector 300, which will be described later, to each other and to move oxygen generated in the oxygen generator 100 to the oxygen ejector 300. And, the LED wires 220a and 220b that electrically connect the power unit of the oxygen generator 100 and the oxygen ejector 300, and the control unit of the oxygen generator 100 and the controller 400, which will be described later, are electrically connected. It is configured to include controller wires (230a) (230b), and these oxygen pipes (210a) (210b), LED wires (220a) (220b), and controller wires (230a) (230b) use a binding means such as a tie. It can be configured by being tied through or accommodated by combine duct cables 240a, 240b, 240c, etc., and can also be configured using existing communication lines, electric lines, or air conditioning lines installed in the building.

Such an oxygen supply line 200 is preferably installed through the inside of a ceiling or inside a wall, and in environments where it is difficult to install through the inside of a ceiling or inside a wall, it is treated with molding to minimize exposure to the outside. This is desirable.

And the oxygen ejector 300,

It allows the oxygen generated in the oxygen generator 100 to be moved through the oxygen pipes 210a and 210b of the oxygen supply line 200 and discharged into the room.

The oxygen ejector 300 may further include a lighting means, and these lighting means are connected to the power supply unit of the oxygen generator 100 through the LED wires 220a and 220b of the oxygen supply line 200, thereby discharging oxygen. As the lighting means operates according to the operation of the device 300, the operating state of the oxygen ejector 300 can be visually confirmed.

In addition, when the oxygen ejector 300 also functions as a humidifier, a drive motor for driving the vibrator may be connected to the power supply of the oxygen generator 100 through the LED wires 220a and 220b.

The oxygen ejector 300 does not need to be set in any one form, and may be a ceiling-type ejector 310 installed on the ceiling, a wall-type bubble ejector 320 installed on the wall, or placed at a desired location and moved nearby. It may be composed of a stand-type discharger 330 capable of this or a wall-type communication outlet discharger 340 that uses an existing wall-type communication outlet installed on the wall.

Here, as shown in (a), (b), and (c) of Figure 2, the existing wall-type communication outlet 10 is a one-hole or insertion section ( 11), or a two-hole type consisting of two insertion parts 11, a three-hole type consisting of three insertion parts 11, or, although not illustrated in the drawing, a multi-hole type consisting of a plurality of insertion parts, etc. can be modified and configured.

That is, as shown in (a) of FIG. 2, the one-hole wall-type communication outlet 10 consisting of one insertion part 11 is composed of a wall-type communication outlet ejector 340 consisting of one insertion part 341. It can be done, and the two-hole wall-type communication outlet 10 consisting of two insertion parts 11 as shown in (b) of FIG. 2 is a wall-type communication outlet ejector 340 consisting of two insertion parts 11. It can be configured as a three-hole wall-mounted communication outlet (10) consisting of three insertion parts (11), as shown in (c) of Figure 2, a wall-type communication outlet ejector (10) consisting of three insertion parts (11). 340), and the fitting valve portion 341 connected to the oxygen pipes 210a and 210b may be installed to be exposed to the outside through the insertion portion 11.

The oxygen ejector 300 is a ceiling-type ejector 310 installed on the ceiling described above, a wall-type bubble ejector 320 installed on the wall, or a stand-type ejector 330 that can be placed at a desired location or moved nearby. Alternatively, any one or at least two of the wall-mounted communication outlet ejectors 340 installed on the wall may be configured together and installed indoors. If multiple oxygen ejectors 300 are installed, each oxygen ejector 300 may be installed indoors. It is preferable that a needle valve is installed in the oxygen pipe 210b connected to the machine 300 to ensure uniform discharge of oxygen.

The controller 400,

It is a device that is installed on one side of the room and controls the operation of the oxygen generator (100).

The controller 400 is connected to the control unit of the oxygen generator 100 through the controller wires 230a and 230b included in the oxygen supply line 200, and the installation location of the controller 400 and the oxygen ejector 300 is As they are spaced apart from each other, the controller wires 230a and 230b may be connected to the controller 400 while branching from a certain point of the oxygen supply line 200.

The controller 400 has a receiving module in the control part of the oxygen generator 100, rather than a wired connection between the control part of the oxygen generator 100 and the controller wires 230a and 230b, and communicates with this receiving module in the controller 400. The operation of the oxygen generator 100 can also be controlled wirelessly through the controller 400 while having a transmitting module capable of this.

Meanwhile, for example, a dissolved oxygen meter may be installed indoors as needed, and by displaying measured values on the dissolved oxygen meter as numerical values, the user can control the oxygen level through the control of the controller 400 by referring to such numerical values. It can be used while manually adjusting the oxygen supply amount of the generator 100. As another example, if the measured value of the dissolved oxygen meter is outside the set value while the dissolved oxygen meter is electrically connected to the control unit of the oxygen generator 100, the oxygen generator The control unit of 100 may be configured to automatically adjust the supply amount of oxygen.

Meanwhile, the construction method of the oxygen supply device configured as described above will be examined in detail with reference to FIG. 3 as follows.

First, an oxygen generator location selection step (S1) may be performed.

The oxygen generator 100 is a device that separates nitrogen in the air brought in from the outdoors and creates oxygen. This oxygen generator 100 is separated from the indoor space, has no slope, and is not exposed to shock from the outside, such as a veranda or utility room or It can be installed on rooftops, etc., taking into account the location of the oxygen ejector 300 installed indoors and the installation location of the oxygen supply line 200 connecting the oxygen ejector 300 and the oxygen generator 100. You need to choose a location.

Since the oxygen generator 100 may generate vibration during operation after installation, the oxygen generator 100 may further include vibration reduction means to reduce such vibration.

Here, the vibration reducing means is, for example, installed on the bottom legs of the oxygen generator 100 when installing the oxygen generator 100, or installed on the anti-vibration plate in advance with an anti-vibration plate on the installation surface. By positioning the oxygen generator 100, vibration and related noise that may occur during operation of the oxygen generator 100 may be reduced.

When selecting the location of the oxygen generator 100, the power supply of the oxygen generator 100 needs to be considered, and a power outlet is provided so that the power line 110 connected to the power supply unit of the oxygen generator 100 can be safely and easily connected. It is desirable to install the oxygen generator 100 nearby.

Next, the oxygen ejector position selection step (S2) can be performed.

The oxygen ejector 300 is a device for discharging the oxygen produced in the oxygen generator 100 at an appropriate place indoors. The oxygen ejector 300 does not need to be set in any one form, and the environment of the indoor space It can be installed in various forms, for example, as a ceiling-type ejector 310 that is hung and attached to the ceiling, or as a wall-type bubble ejector 320 that is installed on the wall and acts as a humidifier. It may be installed as a stand-type discharger 330 that can be placed around a bed or on a desk and freely moved over a short distance, or it may be installed in the form of a wall-mounted communication outlet discharger 340 installed on a wall.

Here, the wall-type communication outlet discharger 340 utilizes an existing wall-type communication outlet 10 installed on an indoor wall, and its form is a communication 8p or CATV insertion part 11 into which a communication or cable is inserted. ) A wall-mounted communication outlet (10) consisting of one communication 8p or a wall-mounted communication outlet (10) consisting of two insertion parts (11) for communication 8p or CATV, or a wall consisting of three insertion parts (11) for communication 8p or CATV Using the shaped communication outlet 10, a wall-type communication outlet ejector 340 consisting of one insertion part 11 or a wall-type communication outlet ejector 340 consisting of two insertion parts 11 or an insertion part ( 11) is composed of three wall-mounted communication outlet dischargers 340, and a fitting valve 341 connected to the oxygen pipes 210a and 210b of the oxygen supply line 200 is installed at the insertion portion 11. It can be configured to be exposed to the outside.

Here, an LED light connected to the LED wires 220a and 220b of the oxygen supply line 200 is installed in the insertion part 11 where the fitting valve 341 is installed, so that oxygen is supplied through the fitting valve 341. It may be configured to visually confirm the supply of oxygen through the fitting valve 341 by allowing the LED lighting to operate together.

In addition, a detachable stopper can be installed at the end of the fitting valve 341, so that when the supply of oxygen through the fitting valve 341 is not needed, the fitting valve 341 is closed with a stopper, so that the fitting valve (341) can be installed at the end of the fitting valve 341. 341), unnecessary contamination or blockage due to foreign substances can be prevented.

Therefore, this wall-type communication outlet ejector 340 utilizes the existing wall-type communication outlet 10, so that it can be used as a ceiling-type ejector 310, a wall-type bubble ejector 320, or a stand-type ejector 330. Unlike this, the configuration is not complicated, so it is easy to manufacture, the cost of manufacturing is low, and the oxygen supply line (200) can be installed by referring to the wiring of the existing wall-type communication outlet (10), so the oxygen supply line (200) 200) can be installed simply and quickly.

Next, the controller position selection step (S3) can be performed.

The controller 400 is connected to the oxygen generator 100 and is a device that allows the user to control the operation of the oxygen generator 100 indoors.

In order to install the controller 400, the location where the controller 400 will be installed needs to be determined, can be easily accessed by users, and can be installed on a wall at an appropriate height.

For example, it can be installed near an indoor lighting button or an air conditioning system control button. For this purpose, a hole is formed by drilling a hole in the wall, and the control wire 230b branching from the oxygen supply line 200 is drawn through this hole. Then, with the controller wire 230b connected to the controller 400, the controller 400 can be installed on the wall using a bracket or the like to cover the perforated hole.

The controller 400 may be connected by wire through the controller lines 230a and 230b, but as mentioned above, it may also be connected wirelessly. For this, the receiver connected to the control unit inside the oxygen generator 100 By installing the module and installing a transmitting module that communicates with the receiving module in the controller 400, the operation of the oxygen generator 100 can be controlled more conveniently while carrying the controller 400 in a wireless manner.

Next, the oxygen supply line installation step (S4) can be performed.

This is a step of installing the oxygen supply line 200, which connects the oxygen generator 100, the oxygen ejector 300, and the controller 400, inside the ceiling or wall so as not to be exposed to the outside as much as possible. It is desirable to lay it using , and if it is unavoidably exposed to the outside, it is desirable to finish it attractively by treating it with molding.

If the oxygen generator 100 is located outdoors, the oxygen supply line 200 is drilled into the wall that separates the indoor and outdoor spaces so that the oxygen supply line 200 can enter the indoor space from the outdoors. ) can be constructed by inserting the air conditioner, using a perforated hole to install an air conditioner such as an air conditioner, or, if the air conditioner is not installed, by inserting it into the room together with the air conditioner's system piping.

Additionally, this oxygen supply line 200 may be constructed by branching one oxygen supply line 200 into multiple numbers depending on the installed number of oxygen ejectors 300.

Meanwhile, the installation step (S4) of such an oxygen supply line may include the following steps.

In most cases, the oxygen ejector 300 is positioned high, and the controller 400 is positioned relatively low for the user's convenience, and each installation location is also spaced apart from each other.

Therefore, considering the positions of the oxygen ejector 300 and the controller 400, which are spaced apart from each other, part of the ceiling is opened, the open area is selected as the branch point 500, and one combine duct cable 240a is prepared to One side of the oxygen pipe is connected to the oxygen generator 100 through the inside of the ceiling or the inside of the wall at the branch point 500, and is connected to the oxygen storage tank of the oxygen generator 100 through this one combine duct cable 240a. A step of inserting (210a), one LED wire (220a) connected to the power supply unit of the oxygen generator 100, and one controller wire (230a) connected to the control unit of the oxygen generator 100 can be performed.

Then, prepare another combine duct cable (240b) and connect it to the oxygen ejector (300) through the inside of the ceiling or the inside of the wall at the branch point (500) or both, and then into this other combine duct cable (240b). A step of inserting the other oxygen pipe 210b and the other LED wire 220b connected to the oxygen ejector 300 may be performed.

In addition, after preparing another combine duct cable (240c), select a point on the wall where the controller 400 will be installed and drill it, and then drill it through the inside of the ceiling or the inside of the wall or all of them at the branch point (500). A step may be performed of connecting another combine duct cable 240c through the hole and inserting the other controller wire 230b connected to the controller 400 into this other combine duct cable 240c.

Thereafter, at the branch point 500, the end of one oxygen pipe (210a) introduced through one combine duct cable (240a) and the end of the other oxygen pipe (210b) entered through the other combine duct cable (240b) A step of connecting them to each other may be performed, and at this time, it is preferable to connect the end of one oxygen pipe (210a) and the other end of the oxygen pipe (201b) to each other through an airtight means for maintaining airtightness, for example, one end of the oxygen pipe (210a). A fitting part consisting of a fitting valve can be formed at the end of the oxygen pipe 210a, and the other end of the oxygen pipe 210b can be connected to this fitting part.

And the end of one LED wire (220a) introduced through one combine duct cable (240a) and the end of the other LED wire (220b) introduced through another combine duct cable (240b) are connected to each other, A step of closing the connection portion through an insulating means such as an insulating tape may be performed.

And the end of one control wire (230a) introduced through one combine duct cable (240a) and the end of the other controller wire (230b) introduced through another combine duct cable (240c) are connected to each other, A step of closing the connection portion through an insulating means such as an insulating tape may be performed.

Afterwards, the connected oxygen pipes (210a) (210b), LED wires (220a) (220b), and controller wires (230a) (230b) are organized and inserted into the open branch point (500), and the open branch point ( A finishing step may be performed by closing 500).

As described above, in the detailed description of the present invention, specific embodiments have been described, but of course, various modifications are possible without departing from the scope of the described content. Therefore, the scope of the described content need not be limited to the described embodiments, and should be determined by the claims described below as well as equivalents to these claims.

100: oxygen generator 110: power line
200: Oxygen supply line 210a, 210b: Oxygen piping
220a, 220b: LED wire 230a, 230b: Controller wire
240a, 240b, 240c: Combine duct cable 300: Oxygen discharger
310: Ceiling-type ejector 320: Wall-mounted bubble ejector
330: Stand-type discharger 340: Wall-mounted communication outlet discharger
341: fitting valve 400: controller
500: Branch point

Claims (11)

An oxygen generator (100) that collects and separates nitrogen in the air flowing in from the outside, concentrates the oxygen, and stores it in an oxygen storage tank located on one side of the interior;
One end of the oxygen pipe (210a) is connected to the oxygen storage tank, one end of the LED wire (220a) is connected to the power supply of the oxygen generator (100), and one end is connected to the control unit of the oxygen generator (100). An oxygen supply line (200) in which one controller wire (230a) is accommodated within the combine duct cables (240a, 240b, and 240c);
It is installed indoors and is connected to the other end of the other oxygen pipe (210b) connected to the one oxygen pipe (210a) and the other end of the other LED wire (220b) connected to the one LED wire (220a) to provide lighting. An oxygen ejector (300) that discharges oxygen into the room while doing so; and
It is installed indoors and is connected to the other end of the other control wire (230b) connected to the one control wire (230a), and includes a controller (400) that controls the operation of the oxygen generator (100) through the control unit.
The oxygen ejector 300 includes a ceiling-type ejector 310 installed on the ceiling, a wall-type bubble ejector 320 installed on the wall, a stand-type ejector 330, and a wall-type communication outlet ejector. Any one of (340),
The wall-mounted communication outlet ejector 340 is a wall-mounted communication outlet 10 consisting of one insertion part 11 into which a communication or cable is inserted, or a wall-mounted communication outlet 10 consisting of two insertions 11. Alternatively, the insertion portion 11 is configured using any one of three wall-type communication outlets 10, and the fitting valve 341 connected to the other end of the other oxygen pipe 210b is connected to the insertion portion 11. ) An oxygen supply device for buildings, characterized in that it is configured to be exposed to the outside through ). In claim 1,
The oxygen generator 100,
Characterized in that it further includes one of an air purifying unit for removing foreign substances and bad odors in the air flowing in from the outside, a sterilizing unit for sterilizing concentrated oxygen, and a dehumidifying unit for removing moisture from the concentrated oxygen. Oxygen supply equipment for buildings. delete delete In claim 1
A dissolved oxygen meter is provided indoors, and the measured value of the dissolved oxygen meter is transmitted to the control unit. If the dissolved oxygen level in the room deviates from the set value, the oxygen supplied to the room is reduced through the control unit of the oxygen generator 100. An oxygen supply device for buildings, characterized in that it is configured to control the supply amount. A method of constructing an oxygen supply device to supply oxygen to the interior of a building,
An oxygen generator location selection step (S1) for installing the oxygen generator 100 in a place separated from the room and capable of ventilation;
An oxygen ejector positioning step (S2) for discharging the oxygen produced in the oxygen generator (100) into the room through the oxygen ejector (300);
A controller position selection step (S3) for installing a controller 400 that controls the operation of the oxygen generator 100; and
Oxygen pipes (210a) (210b) and LED wires (220a) (220b) for connecting the oxygen generator (100) and the oxygen ejector (300), the control unit of the oxygen generator (100), and the controller (400) ) includes an oxygen supply line installation step (S4) in which the oxygen supply line 200, which includes control lines 230a and 230b for connecting, is installed through the inside of the ceiling and the inside of the wall,
In the oxygen supply line installation step (S4),
Considering the positions of the oxygen ejector 300 and the controller 400, which are spaced apart from each other, part of the ceiling is opened, the open area is selected as the branch point 500, and one combine duct cable 240a is prepared to It is connected to the oxygen generator 100 through the inside of the ceiling or the inside of the wall of the branch point 500, and one side is connected to the oxygen storage tank of the oxygen generator 100 through the single combine duct cable 240a. Inserting the oxygen pipe (210a), one LED wire (220a) connected to the power supply unit of the oxygen generator 100, and one controller wire (230a) connected to the control unit of the oxygen generator 100;
Prepare another combine duct cable (240b) and connect it to the oxygen ejector 300 through the inside of the ceiling or the inside of the wall of the branch point 500 or both, and then connect the other combine duct cable (240b) Inserting the other oxygen pipe (210b) and the other LED wire (220b) connected to the oxygen ejector (300) into the oxygen ejector (300);
After preparing another combine duct cable (240c), select a point on the wall where the controller 400 will be installed and drill it, and then drill it through the inside of the ceiling or the inside of the wall or all of them at the branch point (500). Connecting the another combine duct cable (240c) to the hole and inserting the other controller wire (230b) connected to the controller 400 into the another combine duct cable (240c);
The end of the one oxygen pipe (210a) introduced through the one combine duct cable (240a) at the branch point (500) and the other oxygen pipe (210b) introduced into the other combine duct cable (240b) ) Connecting the ends of ) with an airtight means;
The end of the one LED wire 220a introduced through the one combine duct cable 240a at the branch point 500 and the other LED wire introduced through the other combine duct cable 240b ( Connecting the end of 220b) with an insulating means;
The end of the one controller wire (230a) introduced through the one combine duct cable (240a) and the end of the other controller wire (230b) introduced through the another combine duct cable (240c) are insulated. Step of connecting to; and
The interconnected oxygen pipes (210a) (210b), the LED wires (220a) (220b), and the controller wires (230a) (230b) are arranged and inserted into the open branch point (500), and the opened A construction method of an oxygen supply device for a building , characterized in that it includes the step of closing the branch point (500) . In claim 6,
The oxygen ejector 300,
A ceiling-type ejector (310) installed on the ceiling, a wall-type bubble ejector (320) installed on the wall, a stand-type ejector (330) that can be moved nearby, or a wall-type communication outlet ejector (340) installed on the wall. A method of constructing an oxygen supply device for a building, characterized in that one of the following. In claim 6,
The oxygen ejector 300,
A ceiling-type ejector (310) installed on the ceiling, a wall-type bubble ejector (320) installed on the wall, a stand-type ejector (330) that can be moved nearby, or a wall-type communication outlet ejector (340) installed on the wall. A construction method of an oxygen supply device for a building, characterized in that at least two of the following are installed together. The method of claim 7 or 8,
The wall-type communication outlet discharger 340 is configured using a wall-type communication outlet 10 provided with at least one insertion part 11, wherein the insertion part 11 is configured to supply oxygen to the oxygen supply line 200. A construction method of an oxygen supply device for a building, characterized in that the fitting valve 341 connected to the pipe 210b is installed to be exposed to the outside. In claim 9,
A method of constructing an oxygen supply device for a building, characterized in that the insertion part (11) is further provided with a lighting part connected to the LED wire (220b) of the oxygen supply line (200).





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