阅读说明：本技术 一种多功能智能弥散氧终端 (Multifunctional intelligent oxygen dispersing terminal ) 是由 刘振翰 张金戈 刘绪钦 路金梅 于 2021-01-21 设计创作，主要内容包括：本发明公开了一种多功能智能弥散氧终端,包括机仓,及嵌于机仓前侧,且与主控制板通信连接的触摸屏；及通过螺栓固定于机仓后侧的后盖；所述后盖中部压制有内槽；所述后盖于内槽两侧分别设置有进氧接口和进水接口；所述进氧接口和进水接口分别连接供氧管线和供水管线；所述机仓内前侧固定有雾化器内机箱；所述雾化器内机箱底部设置有超声振荡器和废水排放阀；所述超声振荡器电连接到雾化器控制板,本发明的多功能智能弥散氧终端,能够自动检测氧气浓度和湿度,并进行弥散供氧、不间断供水加湿,且能够检测含氧量、温度、湿度、PM2.5等空气质量参数,并增设了人工吸氧端口和遥控功能。(The invention discloses a multifunctional intelligent oxygen dispersing terminal which comprises a cabin and a touch screen, wherein the touch screen is embedded in the front side of the cabin and is in communication connection with a main control panel; the rear cover is fixed on the rear side of the machine cabin through bolts; an inner groove is pressed in the middle of the rear cover; the rear cover is provided with an oxygen inlet port and a water inlet port on two sides of the inner groove respectively; the oxygen inlet interface and the water inlet interface are respectively connected with an oxygen supply pipeline and a water supply pipeline; an atomizer inner case is fixed on the front side in the case; an ultrasonic oscillator and a wastewater discharge valve are arranged at the bottom of the atomizer inner machine box; the multifunctional intelligent oxygen dispersing terminal can automatically detect oxygen concentration and humidity, perform dispersion oxygen supply and uninterrupted water supply humidification, can detect air quality parameters such as oxygen content, temperature, humidity, PM2.5 and the like, and is additionally provided with a manual oxygen inhalation port and a remote control function.)

1. The utility model provides a multi-functional intelligent dispersed oxygen terminal which characterized in that: the intelligent control system comprises a machine cabin and a touch screen which is embedded in the front side of the machine cabin and is in communication connection with a main control panel; the rear cover is fixed on the rear side of the machine cabin through bolts; an inner groove is pressed in the middle of the rear cover; the rear cover is provided with an oxygen inlet port and a water inlet port on two sides of the inner groove respectively; the oxygen inlet interface and the water inlet interface are respectively connected with an oxygen supply pipeline and a water supply pipeline; an atomizer inner case is fixed on the front side in the case; an ultrasonic oscillator and a wastewater discharge valve are arranged at the bottom of the atomizer inner machine box; the ultrasonic oscillator is electrically connected to the atomizer control panel, and the atomizer control panel is also electrically connected with a high-level liquid level sensor and a low-level liquid level sensor which are arranged on the inner side of the inner box of the atomizer, and a first fan embedded on the upper part of the side wall of the inner box of the atomizer; a partition plate is arranged on the inner side of the atomizer inner box and below the first fan; a water permeable port is arranged on the clapboard; a filter is arranged at the lower part of the inner box of the atomizer; the input end of the filter is connected to the water inlet interface through a first electromagnetic valve; the control end of the first electromagnetic valve is connected to the atomizer control panel through a relay; the top of the machine cabin is provided with a mist outlet communicated with the top of the inner box of the atomizer; the machine cabin is provided with a dispersed oxygen port at the side of the fog outlet; a second fan electrically connected with the main control board is arranged at the dispersed oxygen port; the oxygen inlet interface is connected to a tee joint on the inner side of the machine cabin through a flow valve; one end of the tee joint is connected to an oxygen inhalation interface at the end part of the machine cabin, and the other end of the tee joint is connected to a dispersed oxygen port through a second electromagnetic valve; the control end of the second electromagnetic valve is connected to the main control board through a relay; the main control board is electrically connected with an environment collector arranged on the machine cabin.

2. The multifunctional intelligent oxygen dispersing terminal of claim 1, wherein: the environment collector is an oxygen concentration sensor, a temperature sensor, a humidity sensor and a PM2.5 sensor.

3. The multifunctional intelligent oxygen dispersing terminal of claim 1, wherein: the first fan and the second fan are mute fans.

4. The multifunctional intelligent oxygen dispersing terminal of claim 1, wherein: the oxygen supply pipeline is connected to a pipeline for centralized oxygen supply or an oxygen generator external unit for single-machine oxygen supply.

5. The multifunctional intelligent oxygen dispersing terminal of claim 1, wherein: the main control board is electrically connected with a remote control transceiver; the remote control transceiver is communicatively connected to a remote control terminal.

6. The multifunctional intelligent oxygen dispersing terminal of claim 1, wherein: the terminal comprises environment monitoring, humidification and oxygen supply;

the environment monitoring is as follows:

collecting the oxygen concentration, temperature, humidity and PM2.5 in a room through an environment collector; the data are sent to the main control panel, so that the main control panel processes the data and sends the processed data to the touch screen for display; when the data is lower than or higher than a preset threshold value, independently humidifying and/or supplying oxygen by the main control board;

the humidification work is as follows:

a. water supply of the atomizer internal box: the water supply pipeline supplies water to the water inlet interface, and then the water inlet interface supplies water to the inner case of the atomizer through the first electromagnetic valve and the filter; when water is supplied, water level detection is carried out through the high-level liquid level sensor and the low-level liquid level sensor, so that high liquid level signals and low liquid level signals are transmitted to the atomizer control panel, when the high liquid level signals are received, the atomizer control panel sends signals to the relay, the relay closes the first electromagnetic valve, when the low liquid level signals are received, the atomizer control panel sends signals to the relay, the relay reopens the first electromagnetic valve, and water replenishing work is carried out again;

b. humidifying the inner box of the atomizer:

the atomizer control panel sends signals to the ultrasonic oscillator and the first fan, the ultrasonic oscillator oscillates and atomizes at the bottom of the inner box of the atomizer, the first fan generates suction force, atomized liquid is sucked into the first fan inlet from the water permeable port, and the atomized liquid is sent to the mist outlet through the first fan to humidify a room; the wastewater discharge valve is used for discharging wastewater periodically;

the oxygen supply work is as follows:

oxygen is generated by utilizing centralized oxygen supply equipment or single-machine oxygen supply equipment and is sent to the oxygen inlet interface through a pipeline, the oxygen inlet interface supplies oxygen to the tee joint through a flow valve, and oxygen is supplied to the oxygen absorption interface and the dispersed oxygen port through the tee joint respectively; thereby satisfying the oxygen inhalation of individuals and the oxygen supply in rooms.

Technical Field

The invention relates to a dispersed oxygen terminal, in particular to a multifunctional intelligent dispersed oxygen terminal, and belongs to the technical field of dispersed oxygen terminals.

Background

The severe plateau environment mainly shows the aspects of anoxic drying and the like, and with the increasingly mature molecular sieve oxygen generation technology, the dispersion oxygen supply has gradually started to be popularized in plateau areas, and the plateau dispersion oxygen supply mainly has two modes, namely single machine oxygen supply, centralized oxygen supply, wherein the single machine oxygen supply is suitable for scattered rooms, and the centralized oxygen supply is suitable for centralized residential building communities, hotel institutions and the like; the severe oxygen-deficient environment of the plateau is solved by oxygen supply; for the dry environment on the plateau, the improvement is generally realized by humidifying the rooms, the adopted scheme is that a single-machine mode of adding a humidifier for each room is adopted, and the water source of the humidifier mostly adopts an injection type water storage tank for supplying water; the prior art product has the defects of single function and only can complete oxygen supply or humidification; the water storage tank of the humidifier is used for supplying water, water needs to be added frequently, and water shortage is easy to occur; the diffusion oxygen supply lacks intelligent control.

Disclosure of Invention

In order to solve the problems, the invention provides a multifunctional intelligent oxygen dispersion terminal which can automatically detect oxygen concentration and humidity, perform dispersion oxygen supply and uninterrupted water supply humidification, can detect air quality parameters such as oxygen content, temperature, humidity, PM2.5 and the like, and is additionally provided with a manual oxygen inhalation port and a remote control function.

The multifunctional intelligent oxygen dispersing terminal comprises a cabin and a touch screen, wherein the touch screen is embedded in the front side of the cabin and is in communication connection with a main control board; the rear cover is fixed on the rear side of the machine cabin through bolts; an inner groove is pressed in the middle of the rear cover; the rear cover is provided with an oxygen inlet port and a water inlet port on two sides of the inner groove respectively; the oxygen inlet interface and the water inlet interface are respectively connected with an oxygen supply pipeline and a water supply pipeline; an atomizer inner case is fixed on the front side in the case; an ultrasonic oscillator and a wastewater discharge valve are arranged at the bottom of the atomizer inner machine box; the ultrasonic oscillator is electrically connected to the atomizer control panel, and the atomizer control panel is also electrically connected with a high-level liquid level sensor and a low-level liquid level sensor which are arranged on the inner side of the inner box of the atomizer, and a first fan embedded on the upper part of the side wall of the inner box of the atomizer; a partition plate is arranged on the inner side of the atomizer inner box and below the first fan; a water permeable port is arranged on the clapboard; a filter is arranged at the lower part of the inner box of the atomizer; the input end of the filter is connected to the water inlet interface through a first electromagnetic valve; the control end of the first electromagnetic valve is connected to the atomizer control panel through a relay; the top of the machine cabin is provided with a mist outlet communicated with the top of the inner box of the atomizer; the machine cabin is provided with a dispersed oxygen port at the side of the fog outlet; a second fan electrically connected with the main control board is arranged at the dispersed oxygen port; the oxygen inlet interface is connected to a tee joint on the inner side of the machine cabin through a flow valve; one end of the tee joint is connected to an oxygen inhalation interface at the end part of the machine cabin, and the other end of the tee joint is connected to a dispersed oxygen port through a second electromagnetic valve; the control end of the second electromagnetic valve is connected to the main control board through a relay; the main control board is electrically connected with an environment collector arranged on the machine cabin.

Further, the environment collector is an oxygen concentration sensor, a temperature sensor, a humidity sensor and a PM2.5 sensor.

Further, the first fan and the second fan are mute fans.

Furthermore, the oxygen supply pipeline is connected to a pipeline for centralized oxygen supply or an oxygen generator external unit for single-machine oxygen supply.

Further, the main control board is electrically connected with a remote control transceiver; the remote control transceiver is in communication connection with the remote control terminal, the remote control terminal sends a control signal to the remote control transceiver, and the main control board controls the remote control transceiver according to the control signal.

Further, the terminal comprises environment monitoring, humidification and oxygen supply;

the environment monitoring is as follows:

collecting the oxygen concentration, temperature, humidity and PM2.5 in a room through an environment collector; the data are sent to the main control panel, so that the main control panel processes the data and sends the processed data to the touch screen for display; when the data is lower than or higher than a preset threshold value, independently humidifying and/or supplying oxygen by the main control board;

the humidification work is as follows:

a. water supply of the atomizer internal box: the water supply pipeline supplies water to the water inlet interface, and then the water inlet interface supplies water to the inner case of the atomizer through the first electromagnetic valve and the filter; when water is supplied, water level detection is carried out through the high-level liquid level sensor and the low-level liquid level sensor, so that high liquid level signals and low liquid level signals are transmitted to the atomizer control panel, when the high liquid level signals are received, the atomizer control panel sends signals to the relay, the relay closes the first electromagnetic valve, when the low liquid level signals are received, the atomizer control panel sends signals to the relay, the relay reopens the first electromagnetic valve, and water replenishing work is carried out again;

b. humidifying the inner box of the atomizer:

the atomizer control panel sends signals to the ultrasonic oscillator and the first fan, the ultrasonic oscillator oscillates and atomizes at the bottom of the inner box of the atomizer, the first fan generates suction force, atomized liquid is sucked into the first fan inlet from the water permeable port, and the atomized liquid is sent to the mist outlet through the first fan to humidify a room; the wastewater discharge valve is used for discharging wastewater periodically;

the oxygen supply work is as follows:

oxygen is generated by utilizing centralized oxygen supply equipment or single-machine oxygen supply equipment and is sent to the oxygen inlet interface through a pipeline, the oxygen inlet interface supplies oxygen to the tee joint through a flow valve, and oxygen is supplied to the oxygen absorption interface and the dispersed oxygen port through the tee joint respectively; thereby satisfying the oxygen inhalation of individuals and the oxygen supply in rooms.

Compared with the prior art, the multifunctional intelligent oxygen dispersion terminal can automatically detect oxygen concentration and humidity, perform dispersion oxygen supply and uninterrupted water supply humidification, can detect air quality parameters such as oxygen content, temperature, humidity, PM2.5 and the like, and is additionally provided with a manual oxygen uptake port and a remote control function.

Drawings

Fig. 1 is a schematic view of the overall structure of the terminal of the present invention.

Fig. 2 is a schematic view of the structure of the cover of the present invention.

Fig. 3 is a schematic diagram of the internal structure of the terminal of the present invention.

Fig. 4 is a schematic view of the mounting structure of the cabinet in the atomizer and the cabinet of the present invention.

Fig. 5 is a schematic view of the internal structure of the housing in the atomizer according to the present invention.

Fig. 6 is a schematic diagram of the control structure of the atomizer of the present invention.

Detailed Description

Example 1:

the multifunctional intelligent oxygen dispersing terminal shown in fig. 1 to 6 comprises a cabin 1 and a touch screen 2 embedded in the front side of the cabin and in communication connection with a main control board; and a rear cover 3 fixed to the rear side of the machine room by bolts; an inner groove 4 is pressed in the middle of the rear cover 3; the rear cover 3 is respectively provided with an oxygen inlet port 5 and a water inlet port 6 at two sides of the inner groove; the oxygen inlet connector 5 and the water inlet connector 6 are respectively connected with an oxygen supply pipeline and a water supply pipeline; an atomizer inner box 7 is fixed on the front side in the machine bin 1; the bottom of the atomizer inner machine box 7 is provided with an ultrasonic oscillator 8 and a wastewater discharge valve 9; the ultrasonic oscillator 8 is electrically connected to an atomizer control panel 10, and the atomizer control panel 10 is also electrically connected with a high-level liquid level sensor 11 and a low-level liquid level sensor 12 which are arranged on the inner side of an atomizer inner box, and a first fan 13 embedded in the upper part of the side wall of the atomizer inner box; a partition plate 14 is arranged at the lower part of the first fan at the inner side of the atomizer inner cabinet 7; a water permeable opening is formed in the partition plate 14; a filter 15 is arranged at the lower part of the atomizer inner machine box 7; the input end of the filter 15 is connected to the water inlet interface 6 through a first electromagnetic valve 16; the control end of the first electromagnetic valve 16 is connected to the atomizer control board 10 through a relay; the top of the machine bin 1 is provided with a mist outlet 17 communicated with the top of an inner box of the atomizer; a dispersed oxygen port 18 is formed in the side of the mist outlet of the machine bin 1; a second fan 20 electrically connected with the main control board 19 is arranged at the dispersed oxygen port 18; the oxygen inlet interface 5 is connected to a tee 23 at the inner side of the machine cabin 1 through a flow valve 22; one end of the tee 23 is connected to an oxygen inhalation interface 24 at the end part of the machine cabin, and the other end of the tee is connected to a dispersed oxygen port 25 through a second electromagnetic valve; the control end of the second electromagnetic valve 21 is connected to the main control board 19 through a relay; the main control board 19 is electrically connected with an environment collector arranged on the machine cabin.

Wherein, the environment collector is an oxygen concentration sensor, a temperature sensor, a humidity sensor and a PM2.5 sensor. The first fan 13 and the second fan 20 are silent fans. The oxygen supply pipeline is connected to a pipeline for centralized oxygen supply or an oxygen generator external unit for single-machine oxygen supply. The main control board 19 is electrically connected with a remote control transceiver; the remote control transceiver is in communication connection with the remote control terminal, the remote control terminal sends a control signal to the remote control transceiver, and the main control board controls the remote control transceiver according to the control signal.

The terminal comprises environment monitoring, humidification and oxygen supply;

the environment monitoring is as follows:

collecting the oxygen concentration, temperature, humidity and PM2.5 in a room through an environment collector; the data are sent to the main control panel, so that the main control panel processes the data and sends the processed data to the touch screen for display; when the data is lower than or higher than a preset threshold value, independently humidifying and/or supplying oxygen by the main control board;

the humidification work is as follows:

a. water supply of the atomizer internal box: the water supply pipeline supplies water to the water inlet interface, and then the water inlet interface supplies water to the inner case of the atomizer through the first electromagnetic valve and the filter; when water is supplied, water level detection is carried out through the high-level liquid level sensor and the low-level liquid level sensor, so that high liquid level signals and low liquid level signals are transmitted to the atomizer control panel, when the high liquid level signals are received, the atomizer control panel sends signals to the relay, the relay closes the first electromagnetic valve, when the low liquid level signals are received, the atomizer control panel sends signals to the relay, the relay reopens the first electromagnetic valve, and water replenishing work is carried out again;

b. humidifying the inner box of the atomizer:

the atomizer control panel sends signals to the ultrasonic oscillator and the first fan, the ultrasonic oscillator oscillates and atomizes at the bottom of the inner box of the atomizer, the first fan generates suction force, atomized liquid is sucked into the first fan inlet from the water permeable port, and the atomized liquid is sent to the mist outlet through the first fan to humidify a room; the wastewater discharge valve is used for discharging wastewater periodically;

the oxygen supply work is as follows:

oxygen is generated by utilizing centralized oxygen supply equipment or single-machine oxygen supply equipment and is sent to the oxygen inlet interface through a pipeline, the oxygen inlet interface supplies oxygen to the tee joint through a flow valve, and oxygen is supplied to the oxygen absorption interface and the dispersed oxygen port through the tee joint respectively; thereby satisfying the oxygen inhalation of individuals and the oxygen supply in rooms.

The above-described embodiments are merely preferred embodiments of the present invention, and all equivalent changes or modifications of the structures, features and principles described in the claims of the present invention are included in the scope of the present invention.