CN215900620U - Wearable intelligent open airway and oxygen supply device - Google Patents

Abstract

The utility model relates to a wearable intelligent open airway and oxygen supply device, which comprises a head sleeve, a neck sleeve and a control assembly, wherein the neck sleeve is connected below the head sleeve; an oxygen supply mask is arranged above the head sleeve and positioned on one side of the face, and the oxygen supply mask can be rotatably adjusted on the head sleeve through a driving piece; an oxygen supply connecting port is arranged on the oxygen supply mask in a run-through manner and is connected with the oxygen pipe in a run-through manner; the telescopic rod and the driving piece are electrically connected with the control component, the upper supporting part is pushed by the telescopic rod to simulate the opening of an artificial airway, and oxygen is supplied to a patient through the oxygen supply mask, so that the possible obstruction state of the airway is continuously improved, and the pain of the patient is relieved; this device is dressed conveniently, and the use scene is extensive, and the supplementary open air flue of also can intelligence prevents that the air flue that the improper sleep posture of patient brought from obstructing the risk when sleeping.

Description

Wearable intelligent open airway and oxygen supply device

Technical Field

The utility model relates to the field of medical equipment, in particular to a wearable intelligent open airway and oxygen supply device.

Background

Clinically, patients with dyspnea or apnea syndrome often suffer from respiratory obstruction, tongue root tenesmus, nasal septum deflection and other conditions affecting smooth respiration. For patients with respiratory distress or respiratory failure, oropharyngeal airway assistance is often used to open the airway in conjunction with either a mask to inhale oxygen or a mask to provide positive pressure ventilation for airway management if no tracheal intubation is indicated. However, the oropharyngeal airway is placed at the oropharyngeal portion of a patient when the airway is opened, the oropharyngeal airway has high irritation, the secretion of glands is high, the aspiration is easy to cause, the patient who is generally conscious has intolerance, and the common clinical patient uses the tongue to resist the oropharyngeal airway and cannot be matched for use. Whereas non-invasive positive pressure ventilation performed under mask airway management is generally only used for respiratory support during the induction period of awake patients and general anesthesia patients with spontaneous breathing. For patients with blurred consciousness, delirium agitation, the effectiveness of the mask in providing hypoxic ventilation is greatly affected. In addition, for apnea syndrome, snoring and mild patients who can improve breathing with home oxygen therapy, the use is often reduced or rejected due to the comfort of sleeping affected by wearing an oxygen mask.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the present invention is to provide a wearable intelligent open airway and oxygen supply device, so as to overcome the above-mentioned deficiencies in the prior art.

The technical scheme for solving the technical problems is as follows: a wearable intelligent open airway and oxygen supply device comprises a head sleeve, a neck sleeve and a control assembly, wherein the neck sleeve is connected below the head sleeve; an oxygen supply mask is arranged above the head sleeve and positioned on one side of the face, and the oxygen supply mask can be rotatably adjusted on the head sleeve through a driving piece; an oxygen supply connecting port is arranged on the oxygen supply mask in a run-through manner and is connected with the oxygen pipe in a run-through manner; the telescopic rod and the driving piece are electrically connected with the control assembly.

The utility model has the beneficial effects that: the upper supporting part is pushed by the telescopic rod to simulate the opening of an artificial airway, and oxygen is supplied to a patient through the oxygen supply mask, so that the possible obstruction state of the airway is continuously improved, and the pain of the patient is relieved; this device is dressed conveniently, and the use scene is extensive, and the supplementary open air flue of also can intelligence prevents that the air flue that the improper sleep posture of patient brought from obstructing the risk when sleeping.

On the basis of the technical scheme, the utility model can be further improved as follows.

Further, the control assembly comprises a microcontroller, an air pump, a first electromagnetic valve and a second electromagnetic valve, wherein the air pump, the first electromagnetic valve and the second electromagnetic valve are respectively and electrically connected with the microcontroller; the air pump passes through trachea and first solenoid valve intercommunication, and first solenoid valve passes through the trachea and is connected with the second solenoid valve, and the second solenoid valve passes through pneumatic tube and is connected with the telescopic link.

Adopt above-mentioned further beneficial effect to do: the microcontroller controls the air pump, the first electromagnetic valve and the second electromagnetic valve to be opened and closed, so that automation and intellectualization of the device are realized, and the operation is simpler, more convenient and faster.

Furthermore, the control assembly further comprises a Bluetooth module, the Bluetooth module is connected with the microcontroller circuit, and the Bluetooth module can be in wireless signal transmission with the mobile terminal.

Adopt above-mentioned further beneficial effect to do: real-time monitoring, function control and parameter setting can be carried out through the mobile terminal.

Further, the bluetooth module is connected with the finger pulse oxygen probe clamp through wireless.

Adopt above-mentioned further beneficial effect to do: detect the internal blood oxygen content of patient through pointing pulse oxygen probe clamp to real time monitoring, the data that will indicate pulse oxygen probe clamp to detect simultaneously passes through bluetooth module and conveys microcontroller, opens air flue and oxygen suppliment in order to realize automatic control device.

Furthermore, the two sides of the oxygen supply mask are rotationally connected with the two sides of the head sleeve through rotating shafts.

Adopt above-mentioned further beneficial effect to do: the oxygen supply mask can be conveniently adjusted, and can be folded to the top of the head when oxygen supply is not needed so that the patient can normally breathe air.

Furthermore, the driving part is a motor, the motor is electrically connected with the microcontroller, and the rotating shaft is driven to rotate by the motor.

Adopt above-mentioned further beneficial effect to do: when oxygen supply is needed, the motor can be automatically controlled to rotate by the microcontroller, so that the oxygen supply mask is adjusted to the mouth and the nose.

Further, the microcontroller is an MCU micro control unit.

Adopt above-mentioned further beneficial effect to do: the MCU micro control unit integrates interfaces such as a central processing unit and a memory in a chip, so that the microcontroller is multi-scene and multi-functional in control, the response is quicker, additional parts are reduced, the total weight of the device is reduced, and the wearing effect is more comfortable.

Furthermore, the oxygen supply mask is made of flexible medical plastic.

Adopt above-mentioned further beneficial effect to do: the oxygen supply mask can be better attached to the face in the oxygen supply process, and the use feeling is better.

Further, the head cover is made of soft cloth or net cover material.

Adopt above-mentioned further beneficial effect to do: the patient can wear the clothes more comfortably in the long-time wearing process, and the use experience is better.

Furthermore, the neck sleeve is made of elastic sponge material.

Adopt above-mentioned further beneficial effect to do: the patient can wear the clothes more comfortably in the long-time wearing process, and the use experience is better.

Drawings

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a structural frame diagram of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. headgear, 2, neck cover, 3, control assembly, 4, go up supporting part, 5, lower supporter, 6, telescopic link, 7, oxygen suppliment face guard, 8, driving piece, 71, oxygen suppliment connector, 72, oxygen pipe, 31, microcontroller, 32, air pump, 33, first solenoid valve, 34, second solenoid valve, 311, bluetooth module, 35, finger pulse oxygen probe presss from both sides.

Detailed Description

The principles and features of this invention are described below in conjunction with the following drawings, which are set forth by way of illustration only and are not intended to limit the scope of the utility model.

Embodiment 1, as shown in fig. 1 to 2, a wearable intelligent open airway and oxygen supply device includes a headgear 1, a neck collar 2 connected below the headgear 1, and a control assembly 3, wherein an upper support portion 4 is provided below the headgear 1, a lower support portion 5 is provided below the neck collar 2, and a telescopic rod 6 is connected between the lower support portion 5 and the upper support portion 4; an oxygen supply mask 7 is arranged on one side of the face above the headgear 1, and the oxygen supply mask 7 can be rotatably adjusted on the headgear 1 through a driving piece 8; an oxygen supply connecting port 71 is arranged on the oxygen supply mask 7 in a penetrating way, and the oxygen supply connecting port 71 is connected with an oxygen pipe 72 in a penetrating way; the telescopic rod 6 and the driving piece 8 are both electrically connected with the control component 3.

The device is characterized in that a head cover 1 is worn on the head of a patient, a neck cover 2 is sleeved at the neck of the patient, an upper supporting part 4 is supported at the lower jaw and the chin of the patient, a lower supporting part 5 is supported at the shoulder of the patient, when the airway needs to be opened, a control component 3 controls an expansion rod 6 to extend, the lower end of the expansion rod 6 is supported on the lower supporting part 5, the upper end of the expansion rod 6 supports against the upper supporting part 4 and is jacked upwards, so that the head of the patient is tilted backwards to open the airway; when oxygen supply is needed, the oxygen supply mask 7 is driven by the driving piece 8 to be rotationally covered on the mouth and the nose of the patient so as to realize oxygen supply to the patient.

Example 2, as shown in fig. 1 to 2, this example is a further improvement on example 1, and specifically includes the following:

the control assembly 3 comprises a microcontroller 31, an air pump 32, a first electromagnetic valve 33 and a second electromagnetic valve 34, wherein the air pump 32, the first electromagnetic valve 33 and the second electromagnetic valve 34 are respectively electrically connected with the microcontroller 31; the air pump 32 is communicated with the first electromagnetic valve 33 through an air pipe, the first electromagnetic valve 33 is connected with the second electromagnetic valve 34 through an air pipe, and the second electromagnetic valve 34 is connected with the telescopic rod 6 through a pneumatic pipe.

When the air pump 32 is inflated, the first electromagnetic valve 33 controls the extension of the telescopic rod 6 to open the air passage; when the air pump 32 retracts, the first electromagnetic valve 33 controls the telescopic rod 6 to retract; when the air pump 32 does not work, the second electromagnetic valve 34 is communicated with the outside air, and the telescopic rod 6 can freely move without resistance, so that the head and the neck of the patient can freely move.

Example 3, as shown in fig. 1 to 2, this example is a further improvement on example 2, and specifically includes the following:

the control component 3 further comprises a bluetooth module 311, the bluetooth module 311 is in circuit connection with the microcontroller 31, the bluetooth module 311 can perform wireless signal transmission with the mobile terminal, and the mobile terminal can be provided with a relevant APP to realize data monitoring or function control of the blood oxygen saturation.

Example 4, as shown in fig. 1 to 2, this example is a further improvement on example 3, and specifically includes the following steps:

the Bluetooth module 311 is wirelessly connected with a finger pulse oxygen probe clip 35.

The finger pulse oxygen probe clip 35 can be connected with the Bluetooth module 311 of the device, the blood oxygen saturation degree can be detected through the finger pulse oxygen probe clip 35, and the detected data can be transmitted to the microcontroller 31 through the Bluetooth module 311.

Example 5, as shown in fig. 1 to 2, this example is a further improvement on example 1, and specifically includes the following:

the two sides of the oxygen supply mask 7 are rotationally connected with the two sides of the head sleeve 1 through rotating shafts.

Example 6, as shown in fig. 1 to 2, this example is a further improvement on example 5, and specifically includes the following:

the driving part 8 is a motor, the driving part 8 is electrically connected with the microcontroller 31, and the rotating shaft is driven to rotate by the driving part 8 so as to control the opening or closing of the oxygen supply mask 7.

Example 7, as shown in fig. 1 to 2, this example is a further improvement on example 2, and specifically includes the following:

the microcontroller 31 is an MCU microcontrol unit.

Embodiment 8, as shown in fig. 1 to 2, this embodiment is a further improvement on any embodiment of embodiments 1 to 7, and is specifically as follows:

the oxygen supply mask 7 is made of flexible medical plastic.

Example 9, as shown in fig. 1 to 2, this example is a further improvement on any one of examples 1 to 7, and specifically includes the following steps:

the head cover 1 is made of soft cloth or net cover material and is designed with the neck cover as a whole so as to fix the head of the whole device.

Example 10, as shown in fig. 1 to 2, this example is a further improvement on any one of examples 1 to 7, and specifically includes the following steps:

the neck sleeve 2 is made of elastic sponge material.

The specific working mode of the utility model is as follows:

the installation mode is as follows: the device is worn on the head of a human body, the upper supporting part 10 is attached to the mandible and the angle of the chin of a patient, the lower supporting part is supported on the shoulder of the patient, the finger pulse oxygen probe clamp 35 is clamped on a finger, the Bluetooth module 311 is opened to be connected with the finger pulse oxygen probe clamp 35 and the mobile terminal, and the oxygen tube 72 is connected with oxygen supply equipment.

The treatment process comprises the following steps: the microcontroller 31 can be controlled through the mobile terminal to set upper and lower limit parameters of the degree of blood oxygen saturation, when the finger pulse oxygen probe clamp 35 detects that the degree of blood oxygen saturation of a patient is lower than the lower limit value, data information is sent to the microcontroller 31 through the Bluetooth module 311, the microcontroller 31 receives the data information, the air pump 32 is started to inflate, the first electromagnetic valve 33 controls the extension of the telescopic rod 6, the upper supporting part 10 is pushed upwards, the airway of the patient is opened, meanwhile, the microcontroller 31 controls the driving piece 8, the oxygen supply mask 7 is rotated to the mouth and nose, and the oxygen supply function is started; when continuously monitoring the improvement of the blood oxygen saturation condition of the patient, the microcontroller 31 controls the air pump 32 and the first and second electromagnetic valves 33 and 34 to reduce the inflation or the air pump 32 is pumped back, so that the telescopic rod 6 is automatically contracted.

Mode adjustment: the mode can be adjusted according to the requirements of patients, namely a mild mode: if in order to reach the unobstructed purpose of breathing when generally improving sleep night, when need not to carry out the oxygen suppliment, adjustable mild mode, when patient's position or the appearance of sleeping influence breathe unobstructed, this device can give the patient automatically and assist the open air flue. Moderate mode: if improve moderate oxygen deficiency, can set to moderate mode, oxygen source and oxygen suppliment face guard 7 are continuously opened, realize continuously supplying oxygen, and in the oxygen suppliment process, if oxyhemoglobin saturation drops to the lower limit value that sets up, microcontroller 31 then starts air pump 32 immediately, makes telescopic link 6 extension to open patient's air flue, with better auxiliary patient respiratory function. ③ Severe mode: if the emergency rescue is in a critical rescue situation, the emergency rescue system is adjusted to be in a severe mode, so that the telescopic rod 6 is in a continuous extension state, the air passage of the patient is continuously opened, oxygen is continuously supplied to the oxygen supply mask 7, and the functions of automatically opening the air passage and effectively supplying oxygen are realized to support advanced life support when the trachea is intubated.

Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims (10)

1. A wearable intelligent open airway and oxygen supply device is characterized by comprising a head cover (1), a neck sleeve (2) connected below the head cover (1) and a control component (3), wherein an upper supporting part (4) is arranged below the head cover (1), a lower supporting part (5) is arranged below the neck sleeve (2), and a telescopic rod (6) is connected between the lower supporting part (5) and the upper supporting part (4); an oxygen supply mask (7) is arranged on one side of the face above the headgear (1), and the oxygen supply mask (7) can be rotatably adjusted on the headgear (1) through a driving piece (8); an oxygen supply connecting port (71) is arranged on the oxygen supply mask (7) in a penetrating way, and the oxygen supply connecting port (71) is connected with an oxygen pipe (72) in a penetrating way; the telescopic rod (6) and the driving piece (8) are electrically connected with the control component (3).

2. The wearable intelligent open airway and oxygen supply device according to claim 1, wherein the control component (3) comprises a microcontroller (31), an air pump (32), a first solenoid valve (33) and a second solenoid valve (34), and the air pump (32), the first solenoid valve (33) and the second solenoid valve (34) are respectively electrically connected with the microcontroller (31); the air pump (32) is communicated with the first electromagnetic valve (33) through an air pipe, the first electromagnetic valve (33) is connected with the second electromagnetic valve (34) through an air pipe, and the second electromagnetic valve (34) is connected with the telescopic rod (6) through a pneumatic pipe.

3. The wearable intelligent open airway and oxygen supply device according to claim 2, wherein the control component (3) further comprises a bluetooth module (311), the bluetooth module (311) is electrically connected with the microcontroller (31), and the bluetooth module (311) can perform wireless signal transmission with a mobile terminal.

4. The wearable intelligent open airway and oxygen supply device according to claim 3, wherein the Bluetooth module (311) is wirelessly connected with a finger pulse oxygen probe clip (35).

5. The wearable intelligent open airway and oxygen supply device according to claim 1, wherein two sides of the oxygen supply mask (7) are rotatably connected with two sides of the headgear (1) through rotating shafts.

6. A wearable intelligent open airway and oxygen supply apparatus according to claim 5, wherein the driving member (8) is a motor, the motor is electrically connected to the microcontroller (31), and the rotating shaft is driven to rotate by the motor.

7. A wearable intelligent open airway and oxygen supply device according to claim 2, characterized in that the microcontroller (31) is an MCU micro control unit.

8. A wearable intelligent open airway and oxygen supply apparatus according to any of claims 1-7, wherein the oxygen supply mask (7) is made of flexible medical plastic.

9. The wearable intelligent open airway and oxygen supply device according to any one of claims 1-7, wherein the headgear (1) is made of soft cloth or mesh.

10. A wearable intelligent open airway and oxygen supply apparatus according to any of claims 1-7, wherein the neck collar (2) is made of elastic sponge material.

Images