CN211068593U - Dual-purpose medical oxygen tube - Google Patents

Abstract

The utility model provides a dual-purpose medical oxygen tube, oxygen tube is including the air supply connector, the oxygen therapy pipe, three way connection and two branch oxygen pipes, three way connection goes up the one end that communicates respectively to the oxygen therapy pipe and two one ends that divide the oxygen pipe, the other end and the air supply connector intercommunication of oxygen therapy pipe, two divide the oxygen pipe to be independent setting, each other intercommunication divide into intranasal branch oxygen pipe and trachea branch oxygen pipe, the intranasal divides the one end that oxygen pipe is not connected with three way connection to be provided with a confined nasal obstruction, the trachea divides the one end that oxygen pipe is not connected with three way connection to be provided with a T type pipe for the oxygen uptake. The oxygen distributing pipe of the utility model is independent, not communicated with each other, and can be connected with different breathing devices or breathing accessories, thereby the oxygen absorbing pipe has the dual clinical use function of oxygen supply through the nose and oxygen supply through the trachea.

Description

Dual-purpose medical oxygen tube

Technical Field

The utility model relates to the technical field of medical equipment, concretely relates to dual-purpose medical oxygen tube.

Background

Operating rooms, post-anesthesia recovery rooms, intensive care units, emergency rooms, and the like are places where a breathing machine is needed to support the breathing of a patient. In these settings, as the patient's vital signs change, the patient often experiences nasal oxygen inhalation, tracheal oxygen inhalation (tracheostomy cannula), anesthesia (ventilator) oxygen delivery, or the reverse. In the process, medical staff need to give oxygen inhalation to a nasal catheter of a patient, oxygen inhalation to a T-tube and respiratory support of an anesthesia machine (respirator) or the opposite flow, establish a corresponding respiratory pipeline, and prepare and replace the nasal oxygen tube and the T-tube for oxygen inhalation for the patient, so that the medical expense of the patient is increased to a certain extent, and the workload of the medical staff is increased.

The oxygen inhalation tube commonly used at present is a disposable transnasal oxygen inhalation tube, which consists of a nasal plug, an oxygen distribution tube fixing ring, a three-way joint, an oxygen therapy tube and an air source joint 6. The nasal oxygen inhalation device is very convenient to use during nasal oxygen inhalation, but is complicated to use in the process of oxygen inhalation by wearing a tracheal catheter (tracheostomy cannula) after the spontaneous respiration of a patient is recovered and is separated from a respirator, the oxygen distribution tube on one side needs to be cut off, the nasal plug is knotted at the near end for sealing, the oxygen distribution tube on the other side extends into the tracheal catheter for oxygen supply, and the risk of too deep oxygen entering the tracheal catheter or falling off exists. In the intensive care unit and other medical places needing the support of a breathing machine, a patient needing oxygen inhalation with a tracheal catheter (tracheostomy cannula) usually inhales oxygen through a T-shaped tube, the T-shaped tube is conveniently and tightly connected with the tracheal catheter (tracheostomy cannula), and an atomization device can be added for carrying out humidification, atomization and other treatments in the trachea. However, after the patient pulls out the tracheal catheter (tracheostomy cannula), the T-shaped oxygen tube cannot be used continuously, and needs to be replaced by a disposable transnasal oxygen tube.

Therefore, in order to reduce medical consumables and the workload of medical staff, the oxygen tube which is clinically used more frequently at present can be structurally optimized, so that the existing use requirements are met.

Disclosure of Invention

In view of this, the utility model aims at providing a dual-purpose medical oxygen tube, this oxygen tube divide the oxygen tube to set up for independent, each other not communicate, can be connected with different respiratory device or breathing accessory to make the oxygen tube have the dual clinical use function of intranasal for oxygen and transtracheal for oxygen.

In order to achieve the above purpose, the utility model adopts the technical scheme that:

the dual-purpose medical oxygen inhalation tube comprises an air source joint, an oxygen delivery tube, a three-way joint and two oxygen distribution tubes, wherein the three-way joint is communicated to one end of the oxygen delivery tube and one ends of the two oxygen distribution tubes respectively, the other end of the oxygen delivery tube is communicated with the air source joint, the two oxygen distribution tubes are arranged independently and are not communicated with each other and are divided into a nasal oxygen distribution tube and a transtracheal oxygen distribution tube, a closed nasal plug is arranged at one end, which is not connected with the three-way joint, of the nasal oxygen distribution tube, and a T-shaped tube for oxygen inhalation is arranged at one end, which is not connected with the three-way joint, of the transtracheal oxygen distribution tube.

Preferably, the oxygen tube further comprises an oxygen tube fixing ring, the oxygen tube fixing ring is arranged at any position of the nasal oxygen tube and the tracheal oxygen tube to the pipeline part of the three-way joint, and the oxygen tube fixing ring is fixedly connected with the nasal oxygen tube and the tracheal oxygen tube.

Preferably, the nasal oxygen separation tube is provided with a first flow stopping clip on the pipeline part between the nasal plug and the oxygen separation tube fixing ring.

Preferably, the transtracheal oxygen distribution tube is provided with a second flow stopping clip at a pipe portion between the oxygen inhalation T-shaped tube and the oxygen distribution tube fixing ring.

Preferably, the middle part of the T-shaped tube for oxygen inhalation is connected with the transtracheal oxygen distribution tube, and the two ends are respectively a pipeline end connected with the tracheal cannula or the tracheostomy cannula and a device end connected with the breathing device.

Preferably, the pipeline end of the T-shaped pipe has an inner diameter of 15mm and an outer diameter of 22 mm.

Preferably, the device end of the T-shaped oxygen absorption tube has an inner diameter of 11mm and an outer diameter of 15 mm.

Compared with the prior art, the utility model provides a pair of dual-purpose medical oxygen tube, two branch oxygen tubes that should inhale oxygen tube and contain are different from the present state that oxygen tube is the intercommunication, and two branch oxygen tubes are independent settings, each other do not communicate. And a first flow stopping clip is added on the transnasal oxygen distribution tube, a closed nose plug is arranged at the end part of the first flow stopping clip and is used for the patient to inhale oxygen through the transnasal catheter, a second flow stopping clip is added on the transtracheal oxygen distribution tube, and a T-shaped tube for inhaling oxygen is connected at the end part of the second flow stopping clip and is used for the patient to inhale oxygen through the transtracheal catheter or the tracheostomy cannula. The oxygen tube is simple to manufacture, has two functions, reduces the medical expense of a patient on one hand, reduces the work of medical staff on the other hand, and improves the treatment service quality.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of a dual-purpose medical oxygen tube provided by the utility model.

Reference numerals and component parts description referred to in the drawings:

1. a gas source connector; 2. an oxygen delivery tube; 3. a three-way joint; 4. a nasal oxygen separation tube; 5. a transtracheal oxygen-distributing tube; 6. a nasal obstruction; 7. a T-shaped tube for oxygen inhalation; 8. an oxygen separation tube fixing ring; 9. a first flow stop clip; 10. a second flow stop clip;

701. a pipeline end; 702. and a device end.

Detailed Description

The disposable nasal oxygen inhalation tube commonly used at present is very convenient to use during nasal oxygen inhalation, but the use is more tedious in the process of wearing a tracheal catheter to inhale oxygen after the spontaneous respiration of a patient is recovered to be separated from a breathing machine, the oxygen distribution tube at one side needs to be cut off, the nasal obstruction is knotted and sealed at the near end, the oxygen distribution tube at the other side extends into the tracheal catheter to supply oxygen, and the risk of too deep entering the tracheal catheter or falling off exists. In intensive care units and other medical places needing support of a breathing machine, a patient needing oxygen inhalation with a tracheal catheter usually receives T-shaped tube oxygen inhalation, the T-shaped tube oxygen inhalation is conveniently and tightly connected with the tracheal catheter, and an atomization device can be added for humidification, atomization and other treatments in the tracheal catheter. However, after the patient pulls out the tracheal catheter, the T-shaped oxygen tube cannot be used continuously, and the T-shaped oxygen tube needs to be replaced by a disposable transnasal oxygen tube. Consequently, in order to reduce medical consumptive material, reduce medical personnel's work load, the utility model discloses carry out configuration optimization to the oxygen uptake pipe that uses more commonly clinically at present to satisfy current user demand.

The technical solution of the present invention will be described clearly and completely through the following detailed description. It is to be understood that the embodiments described are only some embodiments of the invention, and not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1, the dual-purpose medical oxygen tube is the same as the existing disposable oxygen tube and comprises an air source joint 1, an oxygen tube 2, a three-way joint 3 and two oxygen distribution tubes, wherein the three-way joint 3 is also communicated to one end of the oxygen tube 2 and one ends of the two oxygen distribution tubes respectively, and the other end of the oxygen tube 2 is communicated with the air source joint 1. But with the difference of current disposable oxygen tube, the utility model provides an intraductal two branch oxygen tubes of oxygen uptake are independent setting, each other not communicate, divide into intranasal branch oxygen tube 4 and trachea branch oxygen tube 5. Wherein, the end of the nasal oxygen tube 4 which is not connected with the three-way joint 3 is provided with a closed nasal plug 6 for the patient to inhale oxygen through the nasal cavity, and the end of the nasal oxygen tube 5 which is not connected with the three-way joint 3 is provided with a T-shaped tube 7 for inhaling oxygen through the tracheal tube for the patient to inhale oxygen through the tracheal tube.

Because two branch oxygen tubes are independent settings, the utility model provides an oxygen tube is still including a branch oxygen tube solid fixed ring 8, divides oxygen tube solid fixed ring 8 to set up at intranasal branch oxygen tube 4 and 5 to three way connection 3's pipeline part optional position departments of trachea branch oxygen tube, and all with intranasal branch oxygen tube 4 and 5 fixed connection of trachea branch oxygen tube. When this oxygen tube is taking in under the unused state, divide oxygen tube fixed ring 8 can slide to two tip that divide oxygen tube not with three way connection 3 junction, be close to two branch oxygen tubes and set up, conveniently accomodate. When the oxygen tube is in a state of needing to be used, the oxygen tube fixing ring 8 can slide towards the end part of the joint of the two oxygen tubes and the three-way joint 3, so that the two oxygen tubes are separated, and the oxygen tube is convenient for a patient to use.

In order to prevent the oxygen inhalation tube from being interfered during nasal inhalation or tracheal inhalation, the nasal oxygen distribution tube 4 is provided with a first flow stopping clip 9 on the pipeline part between the nasal plug 6 and the oxygen distribution tube fixing ring 8, and the tracheal oxygen distribution tube 5 is provided with a second flow stopping clip 10 on the pipeline part between the T-shaped tube 7 for oxygen inhalation and the oxygen distribution tube fixing ring 8. The middle part of the T-shaped tube 7 for oxygen inhalation is connected with the transtracheal oxygen distribution tube 5, and the two ends are respectively a pipeline end 701 connected with the tracheal intubation or the tracheostomy cannula and a device end 702 connected with the breathing device. The tube end 701 of the T-shaped oxygen inhalation tube 7 is connected with the endotracheal tube, the inner diameter of the T-shaped oxygen inhalation tube 7 corresponds to the outer diameter of the port of the endotracheal tube, the inner diameter of the T-shaped oxygen inhalation tube is 15mm, the outer diameter of the T-shaped oxygen inhalation tube is 22mm, the device end 702 of the T-shaped oxygen inhalation tube 7 is not connected with a breathing device when the patient breathes autonomously, the T-shaped oxygen inhalation tube is used for discharging the inhaled gas of the patient, and the T-shaped oxygen inhalation tube can be connected with a breathing device (a respirator or a breathing air bag) under the condition.

When a patient needs to inhale oxygen through a trachea, the first flow stop clamp 9 is closed, the pipeline end 701 of the T-shaped oxygen inhalation pipe 7 is connected with a tracheal catheter or an tracheostomy sleeve, the second flow stop clamp 10 is opened, and oxygen flows through the trachea oxygen distribution pipe 5 and is inhaled into the body of the patient to finish oxygen inhalation.

When the patient pulls out the tracheal catheter and needs to inhale oxygen through nose, the first flow stop clip 9 is opened, the second flow stop clip 10 is closed, the nasal plug 6 at the end part of the nasal oxygen separation tube 4 is placed in the nostril or mouth of the patient, oxygen flows through the nasal oxygen separation tube 4 and is inhaled into the body of the patient, and oxygen inhalation is completed.

The first embodiment is as follows: the patient is xu a certain time, female, age 61, and selected period trachea cannula general anesthesia descending spinal cord tumor excision, lumbar vertebra posterior internal fixation. The postoperative anesthesia is not waken, the patient enters a post-anesthesia recovery room (PACU) with a tracheal catheter, the room-entering vital sign blood pressure of the patient is 156/80mmHg, the heart rate is 60 times/min, and the pulse oxygen is 98%. The patient enters the room and then is controlled to breathe by a breathing machine, the parameters of the breathing machine are 450ml, the breathing frequency is 12 times/minute, and the inspired oxygen concentration is 45 percent. After 10 minutes, the muscle relaxation part of the patient recovers, the patient breathes for 10 times/minute or so, the consciousness does not recover, the vital sign blood pressure is 174/91mmHg, the heart rate is 76 times/minute, and the pulse oxygen is 100 percent.

The oxygen inhalation mode is that oxygen is inhaled through a trachea, an air source connector of the dual-purpose medical oxygen inhalation tube is connected with a central oxygen supply source, a first flow stopping clip is closed, a second flow stopping clip is opened, an oxygen inhalation T tube at the end part of a trachea oxygen distribution tube is connected with a tracheal catheter, the oxygen flow is regulated to be 5L/min, a monitor shows that the patient has vital signs of blood pressure of 170/86mmHg, heart rate of 77 times/min and pulse oxygen of 100 percent, after 4 minutes, the consciousness of the patient is recovered, muscle relaxation is basically recovered, eyes can be blinked and the like, and the monitor shows that the patient has vital signs of blood pressure of 162/92mmHg, heart rate of 77 times/min and pulse oxygen of 100 percent.

After the sputum is fully sucked, the tracheal cannula is pulled out, the dual-purpose medical oxygen suction tube is still used for oxygen suction and oxygen inhalation after the trachea is pulled out, the oxygen inhalation mode is changed into the mode that the nasal oxygen suction and oxygen inhalation is performed, the second flow stopping clip is closed, the first flow stopping clip is opened, the nasal plug at the end part of the nasal oxygen distribution tube is plugged into the nostril of the patient, the oxygen flow is still 5L/min, the monitor shows the vital signs of the patient, namely blood pressure is 163/90mmHg, heart rate is 78 times/min, and pulse oxygen is 100%, after 30 minutes, the vital signs of the patient are stable, the PACU standard is reached, and.

So from the in-process of transnasal oxygen uptake mode conversion to trachea oxygen uptake mode at the patient, only need use a fundamental utility model provide a dual-purpose medical oxygen tube can, reduced patient's medical consumptive material expense, medical personnel no longer need change the oxygen tube operation in the nursing process simultaneously, also reduced medical personnel's work load to a certain extent.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (7)

1. The utility model provides a dual-purpose medical oxygen tube, oxygen tube is including air supply joint, oxygen therapy pipe, three way connection and two branch oxygen pipes, last intercommunication respectively of three way connection to the one end of oxygen therapy pipe and two divide the one end of oxygen pipe, the other end of oxygen therapy pipe with the air supply connects the intercommunication, its characterized in that: the two oxygen distribution pipes are arranged independently and are not communicated with each other, and are divided into a nasal oxygen distribution pipe and a transtracheal oxygen distribution pipe, a closed nasal plug is arranged at one end of the nasal oxygen distribution pipe, which is not connected with the three-way joint, and a T-shaped pipe for oxygen absorption is arranged at one end of the transtracheal oxygen distribution pipe, which is not connected with the three-way joint.

2. The dual-purpose medical oxygen tube of claim 1, wherein: the oxygen tube is still including a solid fixed ring of oxygen tube, divide the solid fixed ring setting of oxygen tube to be in nasal oxygen tube with divide the oxygen tube extremely through the trachea the pipeline part optional position department of three way connection, and all with nasal oxygen tube with divide oxygen tube fixed connection through the trachea.

3. The dual-purpose medical oxygen tube of claim 2, wherein: the nasal oxygen separation tube is provided with a first flow stopping clip on the part of the pipeline between the nasal plug and the oxygen separation tube fixing ring.

4. The dual-purpose medical oxygen tube of claim 2, wherein: and a second flow stopping clamp is arranged on the pipeline part of the transtracheal oxygen distribution pipe between the T-shaped pipe for oxygen inhalation and the oxygen distribution pipe fixing ring.

5. The dual-purpose medical oxygen tube of claim 1, wherein: the middle part of the T-shaped tube for oxygen inhalation is connected with the transtracheal oxygen distribution tube, and the two ends are respectively a pipeline end connected with the tracheal intubation or the tracheostomy cannula and a device end connected with the breathing device.

6. The dual-purpose medical oxygen tube of claim 5, wherein: the pipeline end of the T-shaped pipe for oxygen inhalation has an inner diameter of 15mm and an outer diameter of 22 mm.

7. The dual-purpose medical oxygen tube of claim 5, wherein: the inner diameter of the device end of the T-shaped tube for oxygen inhalation is 11mm, and the outer diameter is 15 mm.

Images