CN-119916715-B - Oxygenerator control method, oxygenerator control system, UE (user equipment) equipment and oxygenerator

Abstract

The invention provides an oxygenerator control method, an oxygenerator control system, UE equipment and an oxygenerator, and relates to the technical field related to oxygenerator control, wherein when a Bluetooth module is matched with a vehicle Bluetooth, a control module starts a vehicle-mounted mode to control the oxygenerator module to supply oxygen to a vehicle space; the Bluetooth module is matched with the Bluetooth of the UE equipment, and after receiving a hiking start signal sent by the Bluetooth of the UE equipment, the control module starts a hiking mode to control the oxygen generating module to supply oxygen to a person through the oxygen inhalation tube. According to the method, the Bluetooth module of the oxygenerator is connected with the vehicle Bluetooth or UE equipment, so that the switching of the vehicle-mounted oxygenerator and the hiking oxygenerator is realized, the technical problems that the existing oxygenerator is not flexible to control and can not meet different use scene requirements are solved, and the technical effects of flexibly controlling the switching of the oxygenerator and meeting different scene requirements are achieved.

Inventors

• ZHAO XUECHENG
• QIU ZHAOHAO
• WANG KUAN

Assignees

• 徐州市永康电子科技有限公司

Dates

Publication Date

20260508

Application Date

20250120

Priority Date

20241015

Claims (4)

1. 1. The control method of the oxygenerator is characterized by being applied to an oxygenerator control system, wherein the oxygenerator control system comprises UE equipment and the oxygenerator, and the oxygenerator comprises a Bluetooth module, a control module and an oxygenerator module, and the control module is configured into a vehicle-mounted mode and a hiking mode; The control method of the oxygenerator comprises the following steps: when the Bluetooth module is matched with the vehicle Bluetooth, the control module identifies the matched Bluetooth, and after the Bluetooth module is judged to be the vehicle Bluetooth, a vehicle-mounted mode is started to control the oxygen generation module to supply oxygen to the space in the vehicle; When the Bluetooth module is matched with the Bluetooth of the UE equipment, and after receiving a hiking start signal sent by the Bluetooth of the UE equipment, the control module starts a hiking mode to control the oxygen generating module to supply oxygen to a person through an oxygen inhalation tube; The control method of the oxygenerator further comprises the following steps: Determining oxygenerator parameters, wherein the oxygenerator parameters comprise battery capacity, oxygen generation power and oxygen concentration corresponding to each flow per minute; Determining hiking map data based on hiking paths, wherein the hiking map data comprises the steps of determining the altitude change range, hiking mileage and hiking time of a target path based on the hiking paths, dividing the total distance of the hiking paths into n sections of paths according to the altitude change range, determining the average altitude of each section of path, and determining the oxygen content O (H i ) corresponding to each altitude based on the average altitude, wherein the calculation formula is as follows: ; Wherein H i is the average altitude of the i-th segment, i=1. K is the attenuation coefficient of oxygen concentration, O 0 is the sea level oxygen concentration; The actual oxygen consumption rate R i in the ith section is calculated, and the calculation formula is as follows: ; Wherein R b is the basic oxygen consumption rate, and the unit is L/min; for the altitude impact factor of the i-th segment, Alpha is an altitude influence coefficient; based on the hiking map data and the oxygenerator parameters, determining hiking mileage, which comprises determining oxygen flow G i to be supplemented for each journey based on target oxygen concentration, actual oxygen consumption rate and oxygen content corresponding to each altitude, wherein a calculation formula is as follows: wherein O Target object is the target oxygen concentration; based on the oxygen flow to be supplemented, determining the power consumption P i of the oxygenerator in each journey, wherein the calculation formula is as follows: P 0 is the basic power consumption of the oxygenerator, and the total energy consumption for finishing the walking path is determined based on the power consumption of each path and the walking time of each path; based on the battery parameters of the oxygenerator, judging whether the oxygenerator meets the hiking range or not comprises determining the rated range of the battery electric quantity of the oxygenerator, and judging that the oxygenerator meets the hiking range if the hiking range does not exceed the rated range.
2. 2. The method according to claim 1, wherein the oxygen generator outputs oxygen to the in-vehicle space at a constant power after the on-vehicle mode is started.
3. 3. The method according to claim 1, wherein the oxygenerator further comprises a battery management module, the control module is connected to the battery management module, and the oxygenerator control method further comprises: when the Bluetooth module is matched with the vehicle Bluetooth, the control module controls the battery management module to charge; and the Bluetooth module is matched with the Bluetooth of the UE equipment, and after receiving a hiking start signal sent by the Bluetooth of the UE equipment, the control module controls the battery management module to discharge.
4. 4. An oxygenerator control system is characterized in that, The oxygenerator control system comprises UE equipment and an oxygenerator; the oxygen generator comprises a Bluetooth module, a control module and an oxygen generation module; and, the oxygenerator control system being configured and adapted to perform the steps of the oxygenerator control method of any of the preceding claims 1 to 3; the control module is configured into two modes of vehicle-mounted and hiking; when the Bluetooth module is matched with the vehicle Bluetooth, the control module is used for identifying the matched Bluetooth, and after the matched Bluetooth is judged to be the vehicle Bluetooth, the vehicle-mounted mode is started to control the oxygen generation module to supply oxygen to the space in the vehicle; When the Bluetooth module is matched with the Bluetooth of the UE equipment, and after receiving a hiking start signal sent by the Bluetooth of the UE equipment, the control module is used for starting a hiking mode to control the oxygen generating module to supply oxygen to a person through an oxygen inhalation pipe; The UE equipment is also used for determining oxygenerator parameters, wherein the oxygenerator parameters comprise battery capacity, oxygen generation power and oxygen concentration corresponding to each flow per minute; The method for determining the hiking map data based on the hiking path comprises the steps of determining the altitude change range, hiking mileage and hiking time of a target path based on the hiking path, dividing the total distance of the hiking path into n sections of paths according to the altitude change range, determining the average altitude of each section of path, and determining the oxygen content O (H i ) corresponding to each altitude based on the average altitude, wherein the calculation formula is as follows: ; Wherein H i is the average altitude of the i-th segment, i=1. K is the attenuation coefficient of oxygen concentration, O 0 is the sea level oxygen concentration; The actual oxygen consumption rate R i in the ith section is calculated, and the calculation formula is as follows: ; Wherein R b is the basic oxygen consumption rate, and the unit is L/min; for the altitude impact factor of the i-th segment, Alpha is an altitude influence coefficient; the UE device is further configured to determine a hiking range based on the hiking map data and the oxygenerator parameters; determining the cruising mileage based on the hiking map data and the oxygenerator parameters, wherein the method comprises the steps of determining the oxygen flow G i to be supplemented in each section of distance based on the target oxygen concentration, the actual oxygen consumption rate and the oxygen content corresponding to each altitude, and the calculation formula is as follows: wherein O Target object is the target oxygen concentration; based on the oxygen flow to be supplemented, determining the power consumption P i of the oxygenerator in each journey, wherein the calculation formula is as follows: P 0 is the basic power consumption of the oxygenerator, and the total energy consumption for finishing the walking path is determined based on the power consumption of each path and the walking time of each path; The UE equipment is also used for judging whether the oxygenerator meets the hiking range or not based on the battery parameters of the oxygenerator, and comprises the steps of determining the rated range of the battery electric quantity of the oxygenerator, and judging that the oxygenerator meets the hiking range if the hiking range does not exceed the rated range.

Description

Oxygenerator control method, oxygenerator control system, UE (user equipment) equipment and oxygenerator Technical Field The invention relates to the technical field related to oxygen generation control, in particular to an oxygen generator control method, an oxygen generator control system, UE equipment and an oxygen generator. Background At present, along with popularization of outdoor exercises, people often travel to high-altitude areas, but oxygen in the high-altitude areas becomes thinner, altitude reactions caused by hypoxia often occur in the travel process of people, and particularly, the altitude exercises often endanger lives. The related art provides the scheme of on-vehicle oxygenerator, can put in order to satisfy the oxygen uptake demand of car interior driver and passenger in the car, but when reaching certain scenic spot and need hiking, can't switch into hiking mode voluntarily to and can't evaluate the performance of current oxygenerator in-process hiking can satisfy hiking duration demand. That is, the existing control method of the oxygenerator has the technical problems that the control method is not flexible enough and can not meet the requirements of different use scenes. It should be noted that the above information disclosed in this background section is only for understanding the background of the inventive concept and therefore the above description is not to be construed as constituting prior art information. Disclosure of Invention The invention aims to provide an oxygenerator control method, an oxygenerator control system, UE equipment and an oxygenerator, so as to solve the technical problems that the prior art is not flexible enough and can not meet the requirements of different use scenes. In a first aspect, an embodiment of the invention provides an oxygenerator control method, which is applied to an oxygenerator control system, wherein the oxygenerator control system comprises UE equipment and an oxygenerator, the oxygenerator comprises a Bluetooth module, a control module and an oxygenerator module, the control module starts a vehicle-mounted mode to control the oxygenerator module to supply oxygen to a vehicle space when the Bluetooth module is matched with a vehicle Bluetooth, the Bluetooth module is matched with the UE equipment Bluetooth, and after a hiking start signal sent by the Bluetooth of the UE equipment is received, the control module starts a hiking mode to control the oxygenerator module to supply oxygen to a person through an oxygen inhalation tube. In some alternative implementations, the oxygenerator outputs oxygen to the interior space at a constant power after the on-board mode is activated. In some optional implementations, the method further includes determining oxygenerator parameters including a battery capacity, an oxygen generation power, and an oxygen concentration corresponding to each flow rate per minute, determining hiking map data based on a hiking path, determining hiking mileage based on the hiking map data and the oxygenerator parameters, and determining whether the oxygenerator meets the hiking mileage based on the battery parameters of the oxygenerator. In some alternative implementations, determining the hiking map data based on the hiking path includes determining a range of altitude, a hiking mileage, and a hiking time for the target path based on the hiking path, and determining an oxygen content and an actual oxygen consumption rate corresponding to each altitude based on the range of altitude. In some alternative implementations, determining the oxygen content and the actual oxygen consumption rate corresponding to each altitude according to the altitude variation range includes dividing the total distance of the hiking path into n sections of paths according to the altitude variation range, determining the average altitude of each section of path, determining the oxygen content corresponding to each altitude based on the average altitude, and the calculation formula is: O(Hi)＝O0×e-k*Hi; Wherein H i is the average altitude of the i-th segment, i=1. K is the attenuation coefficient of oxygen concentration, O 0 is the sea level oxygen concentration; The actual oxygen consumption rate R i in the ith section is calculated, and the calculation formula is as follows: Ri＝Rb*AF*AHi; Wherein R b is basic oxygen consumption rate, the unit is L/min, AF is activity intensity coefficient, A Hi is altitude influence coefficient of the ith section, A Hi =1+alpha is Hi, alpha is altitude influence coefficient, and H is altitude. In some optional implementations, determining the cruising mileage based on the hiking map data and the oxygenerator parameters includes determining an oxygen flow to be supplemented for each stretch based on a target oxygen concentration, the actual oxygen consumption rate, and oxygen content corresponding to each altitude, where a calculation formula is: The method comprises the steps of determining the power consumpti