CN219462208U - High flow respirator based on oxygen concentration and blood oxygen saturation - Google Patents

Abstract

The utility model discloses a high-flow respirator based on oxygen concentration and blood oxygen saturation, which relates to the technical field of respirators and comprises the following components: the liquid crystal display, the bottom of liquid crystal display is provided with the whole frame of environment-friendly, the centre department at the whole frame back of environment-friendly is provided with the annex frame, one side of liquid crystal display is provided with the hack lever, one side of hack lever is provided with the second and breathes the intubate, this high flow respirator based on oxygen concentration and blood oxygen saturation removes the sleeve pipe to the position that is close to first breathing intubate or second breathing intubate to with first breathing intubate or second breathing intubate card go into the inboard of fixture block, remove the clamp on the protruding pole this moment, make the clamp to be close to first breathing intubate or second breathing intubate, first breathing intubate or second breathing intubate will be by the inboard of chucking at the fixture block like this, make medical personnel convenient operation.

Description

High flow respirator based on oxygen concentration and blood oxygen saturation

Technical Field

The utility model relates to the technical field of respirators, in particular to a high-flow respirator based on oxygen concentration and blood oxygen saturation.

Background

The breathing machine is a device which can replace, control or change normal physiological breathing of people, increase the ventilation quantity of lungs, improve the respiratory function, lighten the consumption of breathing work and save the reserve capacity of the heart. When the infant is complicated with acute respiratory failure, the active conservative treatment is ineffective, the respiration is weakened, the sputum is excessive and thick, the sputum is difficult to discharge, the airway is blocked or the lung is not stretched, and the trachea cannula and the respirator should be considered.

The application number is CN202021582403.9, the respiratory medicine nursing is a respirator with a respiratory monitoring function, the respirator is connected with an oxygen pipe, the oxygen pipe is connected with an oxygen inhalation mask, and oxygen is inhaled through the oxygen inhalation mask; the breathing machine is connected with a breathing monitor through a data line, and blood oxygen saturation and pulse are monitored through the breathing monitor. The respiration monitor is wrist-type and worn on the wrist, and is provided with a blood oxygen saturation probe, and the blood oxygen saturation probe is sleeved on the finger to measure the blood oxygen saturation. Be provided with the fixed band on the oxygen inhalation mask, through fixed oxygen inhalation mask of fixed band, but this equipment can involve a lot of breathing intubates when using, and the complex work can make medical personnel distinguish unclear to the breathing intubate of difference to the intubate is very easy to be in a chaotic state of putting, has caused a lot of puzzlements for medical personnel.

In view of the above, research and improvement have been made to solve the drawbacks of the conventional protection structure, and a high-flow ventilator based on oxygen concentration and blood oxygen saturation has been proposed.

Disclosure of Invention

The utility model aims to provide a high-flow respirator based on oxygen concentration and blood oxygen saturation so as to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a high flow ventilator based on oxygen concentration and blood oxygen saturation, comprising: the liquid crystal display is provided with an environment-friendly integral rack at the bottom end, an accessory frame is arranged in the middle of the back surface of the environment-friendly integral rack, one side of the liquid crystal display is provided with a hack lever, one side of the hack lever is provided with a second breathing insertion pipe, one end of the second breathing insertion pipe is provided with a breathing cover, and the upper end of the outer side of the hack lever is provided with a containing structure;

the liquid crystal display is characterized in that an induction box is arranged at the lower end of the front face of the liquid crystal display, a first breathing insertion pipe is arranged at the front face of the induction box, a base is arranged at the bottom end of the environment-friendly integral frame, pulleys are arranged at the bottom end of the base, vertical grooves are formed in two sides of the base, and limiting structures are arranged on the inner sides of the vertical grooves.

Further, accomodate the structure and include sleeve pipe, fixture block, clamp, protruding pole and movable block, the outside of hack lever is provided with the sleeve pipe, the sheathed tube inboard is provided with the movable block, the one end of movable block is provided with the fixture block, the centre department in the fixture block outside is provided with protruding pole, the outside of protruding pole is provided with the clamp, constitute sliding construction between sleeve pipe and the hack lever, the sleeve pipe of being convenient for removes in the outside of hack lever.

Further, the movable block is fixedly connected with the clamping block, so that the clamping block is prevented from being separated.

Further, a movable structure is formed between the clamp and the convex rod, so that the clamp can slide on the outer side of the convex rod conveniently.

Further, the length of the inner side of the clamping block is equal to the diameter of the first respiration cannula or the second respiration cannula, so that the first respiration cannula or the second respiration cannula is clamped into the inner side of the clamping block.

Further, limit structure includes sucking disc, bull stick, inner chamber, horizontal rail pole and inside groove, the inboard in perpendicular groove transversely is provided with horizontal rail pole, the inboard of horizontal rail pole is provided with the inside groove, the inboard in inside groove is provided with the bull stick, the one end of bull stick is provided with the sucking disc, and the inboard of sucking disc is provided with the inner chamber, constitute revolution mechanic between bull stick and the inside groove, the bull stick of being convenient for rotates.

Further, a moving structure is formed between the vertical groove and the transverse rail rod, so that the transverse rail rod can move up and down conveniently.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the sleeve is moved to a position close to the first respiration cannula or the second respiration cannula at the moment, the first respiration cannula or the second respiration cannula is clamped into the inner side of the clamping block, the clamp is moved on the convex rod at the moment, so that the clamp is abutted to the first respiration cannula or the second respiration cannula, and the first respiration cannula or the second respiration cannula is clamped into the inner side of the clamping block, so that medical staff can operate conveniently;

2. according to the utility model, the transverse rail rod at the inner side of the vertical groove is moved, at the moment, the transverse rail rod moves downwards, then the rotating rod at the inner side of the inner groove is rotated, meanwhile, the rotating rod drives the sucking disc to be close to the ground, and then the inner cavity is tightly sucked to the ground, so that the pulley at the bottom end of the base cannot move, and the environment-friendly integral frame is kept stable.

Drawings

FIG. 1 is a schematic view of the appearance structure of the present utility model;

FIG. 2 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

FIG. 3 is a schematic cross-sectional view of a sleeve structure according to the present utility model;

FIG. 4 is a schematic view of the structure of the suction cup of the present utility model;

fig. 5 is a schematic view of the internal structure of the transverse rail of the present utility model.

In the figure: 1. an accessory frame; 2. a first respiratory cannula; 3. a respiratory mask; 4. a second respiratory cannula; 5. a storage structure; 501. a sleeve; 502. a clamping block; 503. a clamp; 504. a protruding rod; 505. a movable block; 6. a hack lever; 7. a liquid crystal display; 8. an induction box; 9. an environment-friendly integral frame; 10. a base; 11. a pulley; 12. a limiting structure; 1201. a suction cup; 1202. a rotating rod; 1203. an inner cavity; 1204. a transverse rail; 1205. an inner tank; 13. vertical grooves.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-2, the high flow respirator based on oxygen concentration and blood oxygen saturation comprises a liquid crystal display 7, wherein an environment-friendly integral rack 9 is arranged at the bottom end of the liquid crystal display 7, an accessory frame 1 is arranged in the middle of the back surface of the environment-friendly integral rack 9, a hack lever 6 is arranged on one side of the liquid crystal display 7, a second breathing cannula 4 is arranged on one side of the hack lever 6, one end of the second breathing cannula 4 is provided with a breathing cover 3, and a containing structure 5 is arranged at the upper end of the outer side of the hack lever 6;

the positive lower extreme of LCD 7 is provided with induction box 8, and induction box 8's front is provided with first breathing intubate 2, and the bottom of the whole frame of environmental protection 9 is provided with base 10, and the bottom of base 10 is provided with pulley 11, and the both sides of base 10 are provided with perpendicular groove 13, and the inboard of perpendicular groove 13 is provided with limit structure 12.

As shown in fig. 1-5, a high flow respirator based on oxygen concentration and blood oxygen saturation comprises a containing structure 5, wherein the containing structure comprises a sleeve 501, a clamping block 502, a clamp 503, a protruding rod 504 and a movable block 505, the sleeve 501 is arranged on the outer side of a hack lever 6, the movable block 505 is arranged on the inner side of the sleeve 501, the clamping block 502 is arranged at one end of the movable block 505, the protruding rod 504 is arranged in the middle of the outer side of the clamping block 502, the clamp 503 is arranged on the outer side of the protruding rod 504, a sliding structure is formed between the sleeve 501 and the hack lever 6, the first breathing cannula 2 or the second breathing cannula 4 is clamped into the clamping block 502 on the sleeve 501, the sleeve 501 is moved, the clamp 503 is moved at the moment, and the clamp 503 is moved at the outer side of the protruding rod 504, and the clamp 503 is clamped on the outer side of the first breathing cannula 2 or the second breathing cannula 4.

As shown in fig. 1-5, a high flow respirator based on oxygen concentration and blood oxygen saturation comprises a limiting structure 12, wherein the limiting structure comprises a sucker 1201, a rotating rod 1202, an inner cavity 1203, a transverse rail 1204 and an inner groove 1205, the transverse rail 1204 is transversely arranged on the inner side of the vertical groove 13, the inner groove 1205 is arranged on the inner side of the transverse rail 1204, the rotating rod 1202 is arranged on the inner side of the inner groove 1205, one end of the rotating rod 1202 is provided with the sucker 1201, the inner side of the sucker 1201 is provided with the inner cavity 1203, a rotating structure is formed between the rotating rod 1202 and the inner groove 1205, the transverse rail 1204 on the inner side of the vertical groove 13 is moved, then the rotating rod 1202 on the inner side of the inner groove 1205 is rotated, the rotating rod 1202 drives the sucker 1201, the sucker 1201 is close to the ground, and the inner cavity 1203 on the inner side of the sucker 1201 sucks the ground.

Working principle: when the high-flow respirator based on oxygen concentration and blood oxygen saturation is used, firstly, the respirator 3 is covered on the face of a patient, then a power supply is connected, at this time, the liquid crystal display 7 starts to work, the liquid crystal display 7 can conduct screen separation and change the visual angle, the liquid crystal display 7 can also display various waveforms such as pressure, time, flow rate and volume, then a respiration control valve is opened, meanwhile, the environment-friendly integral frame 9 starts to work, and the environment-friendly integral frame 9 is good in air tightness, small in air resistance and easy to clean and disinfect, meanwhile, an accessory frame 1 can be used for placing medical spare parts, when the environment-friendly integral frame 9 needs to be stable, a transverse rail 1204 on the inner side of a vertical groove 13 is moved, then a rotating rod 1202 on the inner side of the rotating rod 1205 is rotated, at this time, the sucking disc 1201 is driven by the sucking disc 1201, at this time, the sucking disc 1201 is close to the ground, and an inner cavity 1203 on the inner side of the sucking disc 1201 is sucked to the ground, at this time, a pulley 11 on the bottom end of the base 10 cannot move, when a first respiration cannula 2 or a second respiration cannula 4 is generated, a medical staff clamps the first respiration cannula 2 or the second respiration cannula 4 into a clamping block 502 on a sleeve, and the sleeve is moved, and the oxygen concentration of the first respiration cannula 501 is enabled to move on the proper position of the inner groove 501, and the second respiration cannula 503 is saturated with the oxygen concentration, at the outer side of the breathing cannula 503, and the high-flow clip is moved on the basis of the breathing cannula 503, and the proper position of the breathing cannula is moved, and the breathing cannula is positioned on the inner groove 503, and the breathing cannula is moved.

The embodiments of the utility model have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (7)

1. A high flow ventilator based on oxygen concentration and blood oxygen saturation, comprising: the liquid crystal display (7), characterized in that, the bottom of liquid crystal display (7) is provided with environment-friendly whole frame (9), the centre department at the back of environment-friendly whole frame (9) is provided with annex frame (1), one side of liquid crystal display (7) is provided with hack lever (6), one side of hack lever (6) is provided with second breathing intubate (4), and the one end of second breathing intubate (4) is provided with respiratory mask (3), the upper end in hack lever (6) outside is provided with storage structure (5);

the liquid crystal display (7) positive lower extreme is provided with induction box (8), the front of induction box (8) is provided with first breathing intubate (2), the bottom of environment-friendly whole frame (9) is provided with base (10), the bottom of base (10) is provided with pulley (11), the both sides of base (10) are provided with perpendicular groove (13), the inboard of perpendicular groove (13) is provided with limit structure (12).

2. The high flow respirator based on oxygen concentration and blood oxygen saturation according to claim 1, wherein the accommodating structure (5) comprises a sleeve (501), a clamping block (502), a clamp (503), a protruding rod (504) and a movable block (505), the sleeve (501) is arranged on the outer side of the hack lever (6), the movable block (505) is arranged on the inner side of the sleeve (501), the clamping block (502) is arranged at one end of the movable block (505), the protruding rod (504) is arranged in the middle of the outer side of the clamping block (502), the clamp (503) is arranged on the outer side of the protruding rod (504), and a sliding structure is formed between the sleeve (501) and the hack lever (6).

3. The high flow ventilator of claim 2, wherein the movable block (505) is fixedly connected to the clamping block (502).

4. A high flow ventilator based on oxygen concentration and blood oxygen saturation according to claim 2, wherein the collar (503) and the boss (504) form a movable structure therebetween.

5. A high flow ventilator based on oxygen concentration and blood oxygen saturation according to claim 2, characterized in that the length of the inside of the cartridge (502) is equal to the diameter of the first breathing cannula (2) or the second breathing cannula (4).

6. The high flow ventilator according to claim 1, wherein the limiting structure (12) comprises a suction cup (1201), a rotating rod (1202), an inner cavity (1203), a transverse rail (1204) and an inner groove (1205), the inner side of the vertical groove (13) is transversely provided with the transverse rail (1204), the inner side of the transverse rail (1204) is provided with the inner groove (1205), the inner side of the inner groove (1205) is provided with the rotating rod (1202), one end of the rotating rod (1202) is provided with the suction cup (1201), the inner side of the suction cup (1201) is provided with the inner cavity (1203), and a rotating structure is formed between the rotating rod (1202) and the inner groove (1205).

7. The high flow ventilator of claim 6, wherein the vertical slot (13) and the transverse rail (1204) form a moving structure therebetween.