JP3176275U - Separate oxygen production and gas transport control device - Google Patents

Abstract

The present invention provides a separation type oxygen production and gas transport control device that first supplies oxygen to an indoor unit after oxygen is produced by an outdoor unit, and supplies the oxygen into the room.
A separate oxygen production and gas transport control device of the present invention includes an outdoor unit, a plurality of indoor units, and a control panel. The control panel includes a control unit. The main purpose is to control the outdoor unit 1 and the indoor unit 3 and to send the oxygen produced by the outdoor unit 1 from the oxygen outlet 33 to the indoor space, thereby achieving the purpose of improving the air quality in the indoor space.
[Selection] Figure 1

Description

The present invention relates to a separate oxygen production and gas transport control device, and more particularly to an apparatus for producing oxygen by an outdoor unit and then sending oxygen to the indoor unit to supply oxygen into the room.

As a known oxygen production apparatus, for example, there is an “aerobic clean separation type air conditioner” according to Patent Document 1. It mainly produces high-concentration oxygen using a high-concentration oxygen production machine installed in the outdoor unit, sends it to the heat exchanger of the indoor unit via a transport pipe, and secondaryly delivers high-temperature, high-water-content oxygen to be ejected. It is to be processed and further sent to the indoor space to increase the oxygen content of the indoor space.

Taiwan Utility Model Notification No. 566521

However, the prior art described above still has the following problems.
(1) The high-concentration oxygen device of the prior art is an accessory device of an air conditioner and is not a dedicated oxygen supply line distribution and control module, and therefore cannot provide a preferable oxygen supply mode.
(2) Prior Art Drawing As can be seen from FIG. 5, the high-concentration oxygenation module of the high-concentration oxygen production machine separates oxygen and nitrogen by an oxygen-concentration membrane (that is, a molecular membrane). Only air with an oxygen content of 30% or less can be produced (the technology for separating oxygen concentrations of 30% or more using molecular membranes is still immature), and even if it is released into the indoor space, the oxygen concentration in the indoor space The improvement is not significant.
(3) Prior art air conditioners do not send clean air to high-concentration oxygen producing machines after first filtering outdoor air, so that oxygen is produced, so the produced oxygen contains impurities, Affects indoor air quality.
(4) The flow rate of oxygen produced by the oxygen-enriched membrane does not exceed 10 liters per minute, and there is a clear shortage in the flow rate supply, so it is difficult to increase the oxygen concentration in the indoor space.
(5) Oxygen produced in the prior art is sent to the indoor unit without going through the drying process first, so there may be blue glaze in the pipeline due to excessive humidity. Affects maintenance.

In view of the above problems, the separated oxygen production and gas transport control device disclosed in the present invention includes an outdoor unit, a plurality of indoor units, and a control panel.
The outdoor unit includes an air purification unit, an oxygen production compression unit, and a multi-molecular sieve unit that are sequentially connected through a pipe line.
The indoor unit is connected to the multi-molecular sieve unit through a pipe line, and each indoor unit includes an oxygen outlet and an oxygen concentration sensor located near the oxygen outlet.
The control panel includes a control unit, and the control unit is electrically connected to the outdoor unit and the indoor unit to control the operation of the outdoor unit and the indoor unit. Thus, any oxygen produced by the outdoor unit is any It is discharged from the oxygen outlet of one indoor unit.

The effects of the present invention are as follows.
(1) In the present invention, one outdoor unit corresponds to a plurality of indoor units, and the indoor units are distributed in each indoor space by the arrangement of pipes, and oxygen is supplied using a control panel. This device specializes in oxygen production and oxygen supply control by controlling the mode (oxygen health concentration or oxygen treatment concentration) and supply position (arbitrary oxygen outlet).
(2) The present invention separates oxygen and nitrogen in the air through a multi-molecular sieve unit to produce high-concentration oxygen with an oxygen content of 40% to 50%, and the flow rate per minute reaches 40 to 50 liters. The oxygen content in the indoor space can be effectively improved by releasing it into the indoor space.
(3) Since the outside air can be effectively filtered, the produced oxygen does not include other impurities.
(4) In the event of an emergency, high oxygen content of 90% can be released and used by sick people who need first aid.
(5) Since it is a separable design, it is possible to keep the quietness in the room, and it is combined with the phytoncide to further improve the quality of the indoor air.
(6) The present invention adjusts the use mode through the control panel. For example, in the artificial control mode, the user manually operates the outdoor unit and supplies oxygen from the oxygen discharge port of any one of the indoor units. By operating, the user can achieve a power saving effect as needed.
(7) The control panel of the present invention further includes a semi-automatic mode and a full-automatic mode, and the user can further select single control or interlock control. The single control automatically increases or decreases the oxygen concentration based on the set value through the oxygen concentration sensor, and the interlock control detects and receives the localization signal emitted from the transmitter through one of the detection receivers. When a person approaches the detection receiver, oxygen production of the outdoor unit is automatically activated to supply oxygen from the oxygen discharge port of the indoor unit where the user is present, and further achieve a power saving effect and an intelligent oxygen production device effect.

It is a figure which shows the correspondence of each component in this invention. FIG. 5 is a diagram illustrating a relationship between each mode switch button on a control panel and a transmitter in a preferred embodiment of the present invention. It is the figure which showed the correspondence at the time of the outdoor unit in the preferable Example of this invention, an indoor unit, and a control panel implementation. It is the figure which showed the correspondence of the transmitter and detection receiver in the preferable Example of this invention. It is the figure which showed the correspondence of the indoor unit containing the electroencephalogram measuring device in the preferable Example of this invention.

First, FIG. 1 shows a preferred embodiment of the separated oxygen production and gas transport control device of the present invention. It includes an outdoor unit 1, one or more indoor units 3, and a control panel 4.

The outdoor unit 1 is disposed in an outdoor space, and the outdoor unit 1 is connected to an air purification unit 11, a dehumidification drying unit 12, a catalyst sterilization unit 13, an oxygen production compression unit 14, and a multimolecular sieve that are sequentially connected via a pipe line 2. Includes unit 15.

The indoor units 3 are all arranged in an indoor space, and the indoor unit 3 is connected to the multimolecular sieve unit 15 via the pipe line 2. The indoor unit 3 is sequentially connected to the flow rate setting unit 31, the humidification and phytoncide unit 32, and the oxygen discharge port 33 via the pipe line 2, and the flow rate sensor 34 is provided, and the oxygen concentration sensor 35 is provided separately, and the indoor unit 3 Connect to

The control panel 4 includes a control unit 41. The control unit 41 is connected to the outdoor unit 1 and the indoor unit 3, and the control unit 41 controls the operation of the outdoor unit 1 and the indoor unit 3.

The point that should be further described is that the outdoor unit 1 receives air entering the air purification unit 11, and the air purification unit 11 is provided with three filtration protection lines. First, heavy metal, large dust, etc. in the air are blocked by the filter paper 111, then deodorized, dehumidified, and dirty air is filtered by the bamboo charcoal filter cotton 112, and finally the nano silver ion filter cotton 113 is used to filter the nano silver. It achieves antibacterial, deodorizing and antiseptic functions, and increases the air clean level through three filter wires.

The air cleaned through the air purification unit 11 is first sent to the dehumidifying and drying unit 12 under the drive of the oxygen production compression unit 14 to remove moisture in the air, and then the catalyst sterilization unit 13 (photocatalyst or cold catalyst). )to go into. The sterilization unit 13 has a sealed sterilization space, both photocatalysts and cold catalysts have a wide range of highly effective sterilization effects, and various bacteria that are effective for commonly seen diseases have preferable suppression and sterilization effects. is there.

The sterilized air is sent to the multi-molecular sieve unit 15. Nitrogen gas having a relatively large particle volume is clogged in the space between the molecular sieves and discharged to the outside. In addition, oxygen having a relatively small particle volume continues to advance through the gaps in the molecular sieve, and continuously produces high-concentration oxygen. In the present embodiment, the molecular sieve unit 15 is provided with twelve molecular sieve pipes, and in order to produce high-concentration oxygen in order, a high flow rate and high-concentration oxygen are continuously supplied.

The indoor unit 3 receives oxygen via the pipe line 2, controls the flow rate by the flow rate setting unit 31, monitors the flow rate by the flow rate sensor 34, and adjusts the relative humidity of the indoor space by the humidification and phytoncide unit 32. . In detail, the humidification and phytoncide unit 32 can be operated in a small amount, a medium amount, and a large amount, and can be adjusted to a relative humidity under a constant temperature. General humidity is controlled between 40% and 60%. Mainly, the water spray for increasing the humidity is sent to the pipe 2, the water spray and oxygen are mixed, and the oxygen discharge port is provided with moisture. Release from 33 to the indoor space.

Further, the humidification and phytoncide unit 32 is provided with a wind outlet of the phytoncide oil tank, and when oxygen flows in the outlet direction, the fragrance of the phytoncide in the tank is diffused into the indoor space. Further, any one of the indoor units 3 is provided with an emergency oxygen supply pipeline 36 so that 90% or more of oxygen can be supplied to a sick person who needs first aid in an emergency.

As shown in FIG. 2, the control panel 4 includes a control unit 41, and the control panel 4 further includes three types of modes that can be selected by the user. That is, the artificial control mode 411, the semi-automatic mode 412, and the fully automatic mode 413. Among them, the artificial control mode 411 includes an outdoor unit switch button 4111 and five oxygen outlet switch buttons 4112. The semi-automatic mode 412 includes an outdoor unit switch button 4121, five oxygen outlet switch buttons 4122, a single control switch button 4123, and an interlock control switch button 4124. The fully automatic mode 413 includes an outdoor unit switch button 4131, five oxygen outlet switch buttons 4132, a single control switch button 4133, and an interlocking control switch button 4134. The control panel 4 further includes a wireless transmission / reception processor 414, which is electrically connected to each switch button of the artificial control mode 411, the semi-automatic mode 412, and the fully automatic mode 413. Further, the transmitter 5 corresponding to the wireless transmission / reception processor 414 is a remote controller in the present embodiment, and the artificial control mode is mainly based on a selection signal issued from the transmitter 5 to the wireless transmission / reception processor 414. Whether to activate 411, semi-automatic mode 412 or full-automatic mode 413 is selected. This design lets the user choose between manual mode and remote control for the required mode selection.

As shown in FIGS. 1 to 3, the control panel 4 including the control unit 41 is installed in the warehouse A, and the five indoor units 3 having the oxygen discharge ports 33 are installed in the living room B of the house, the main bedroom C, and the sub bedroom. Installed in 1D, 2E in sub-bedroom, and dining room F respectively. When the user operates the control panel 4 manually or remotely and neither mode is selected, oxygen produced by the outdoor unit 1 is released from the oxygen outlet 33 of the indoor unit 3 in the living room B. When the user selects the single control switch buttons 4123 and 4133 in the semi-automatic mode 412 or the full-automatic mode 413, the oxygen concentration sensor 35 connected to the indoor unit 3 is activated. In a general natural environment, the oxygen content in the air is about 20.6% to 20.9%, and the oxygen concentration provided in the room is most preferably 21% to 30%. Then, the upper and lower limits for the required oxygen amount are set, and a signal is fed back to the control unit 41 through automatic sensing of the oxygen concentration sensor 35, and oxygen is discharged from the corresponding oxygen discharge port 33. Thereby, the required oxygen in the room can be maintained. Among them, the control panel 4 can set two modes. The first mode is oxygen health concentration. It is equal to the standard of the oxygen concentration of the forest bath in nature, and the lower limit of the oxygen concentration is kept at 21% and the upper limit is kept at 24% through the oxygen concentration sensor 35. For general people. The second mode is oxygen therapy concentration. It keeps the lower limit of oxygen concentration at 24% and the upper limit at 30%, making it suitable for hypoxia. When the oxygen concentration falls below the lower limit based on the required setting, when the oxygen concentration sensor 35 sends a signal to the control unit 41, the control flow rate setting unit 31 starts supplying oxygen and the oxygen concentration exceeds the upper limit. Is measured, the oxygen supply is stopped and the automatic control state is entered.

As shown in FIG. 4, when the user selects the interlock control switch button 4124 in the semi-automatic mode 412 or the interlock control switch button 4134 in the fully automatic mode 413, the oxygen concentration sensor 35 and the detection receiver 37 are simultaneously activated. Among them, through detection and reception of the localization signal transmitted from the transmitter 5 by the detection receiver 37, the oxygen outlet 33 in each space is automatically opened and closed. The oxygen outlet 33 opens and closes automatically, saving power.

As shown in FIG. 5, each of the indoor units 3 includes an electroencephalogram measuring device 38, detects the electroencephalogram of the human body in the indoor space, and converts the α and β values of the electroencephalogram into electrical signals (the human body has different oxygen concentrations). When it is received, it produces a different EEG, based on the EEG value to know if it is suitable for the oxygen content of the human body). The control panel 4 adjusts the oxygen concentration to be output based on the converted electrical signal. The purpose is to adjust the oxygen concentration in the indoor space to a concentration most suitable for the human body.

1: outdoor unit, 11: air purification unit, 111: filter paper, 112: bamboo charcoal filter cotton, 113: nano silver ion filter cotton, 12: dehumidification drying unit, 13: catalyst sterilization unit, 14: oxygen production compression unit, 15 : Multi-molecular sieve unit, 2: Pipe line, 3: Indoor unit, 31: Flow rate setting unit, 32: Humidification and phytoncide unit, 33: Oxygen outlet, 34: Flow rate sensor, 35: Oxygen concentration sensor, 36: Emergency oxygen Supply pipeline, 37: detection receiver, 38: electroencephalograph, 4: control panel, 41: control unit, 411: artificial control mode, 4111: outdoor unit switch button, 4112: oxygen outlet switch button, 412: semi-automatic mode , 4121: Outdoor unit switch button, 4122: Oxygen outlet switch button, 4123: Single control switch button, 4124: Interlocking control switch button, 413: Fully automatic mode, 4131: Outdoor unit switch button, 4132: Oxygen outlet switch Bota 4133: Single control switch button, 4134: Interlocking control switch button, 414: Wireless transmission / reception processor, 5: Transmitter.

Claims (10)

In an outdoor unit, a plurality of indoor units, and a separate oxygen production and gas transport control device including a control panel,
The outdoor unit includes an air purification unit, an oxygen production compression unit, and a multi-molecular sieve unit that are sequentially connected via a pipe line,
The indoor unit is connected to the multi-molecular sieve unit via a pipe line, and each indoor unit includes an oxygen outlet and an oxygen concentration sensor located near the oxygen outlet,
The control panel includes a control unit, and the control unit is electrically connected to the outdoor unit and the indoor unit to control the operation of the outdoor unit and the indoor unit, whereby oxygen produced by the outdoor unit is A separate oxygen production and gas transport control device, characterized in that it is discharged from the oxygen outlet of any one indoor unit. The separation type oxygen production and gas transport control device according to claim 1, wherein the air purification unit includes filter paper, bamboo charcoal filter cotton, and nano silver ion filter cotton. The dehumidifying and drying unit included in the outdoor unit is connected between the air purification unit and the oxygen production compression unit via the pipe, and the catalyst sterilization unit included in the outdoor unit is connected to the air through the pipe. The separation type oxygen production and gas transport control device according to claim 1, wherein the separation type oxygen production and gas transport control device is connected between a dehumidification drying unit and the oxygen production compression unit. The separation type oxygen production and gas transport control device according to claim 1, wherein the control panel includes an artificial control mode, a semi-automatic mode, and a fully automatic mode. The apparatus of claim 4, wherein the artificial control mode includes an outdoor unit switch button and a plurality of oxygen outlet switch buttons. 5. The separation according to claim 4, wherein the semi-automatic mode includes an outdoor unit switch button, a plurality of oxygen outlet switch buttons, a single control switch button, and an interlock control switch button. Oxygen production and gas transport control device. The full automatic mode includes one outdoor unit switch button, a plurality of oxygen outlet switch buttons, one single control switch button, and one interlock control switch button. Separate oxygen production and gas transport control device. The control panel further includes a wireless transmission / reception processor, and the transmitter sends a selection signal to the wireless transmission / reception processor to select whether to activate the artificial control mode, semi-automatic mode, or full-automatic mode. The separation type oxygen production and gas transport control device according to claim 4 characterized by things. The separation type oxygen production and gas transport control device according to claim 8, wherein the indoor unit is provided with a detection receiver, and the detection receiver detects and receives a localization signal transmitted by a transmitter. . The indoor unit is provided with an electroencephalograph, the electroencephalograph detects a brain wave of a human body and converts it into an electric signal, and the control panel adjusts an oxygen concentration to be output based on the electric signal. The separation type oxygen production and gas transport control device according to claim 1.