CN217430604U - Ventilation pipeline and breathing equipment - Google Patents

Abstract

The utility model relates to a vent line and breathing equipment, vent line includes the pipeline body, a heater, temperature collector and anion generator, wherein, the heater sets up this internal gas that is used for heating the flow to manage in the pipeline body at the pipeline, temperature collector sets up this internal gas temperature that is used for surveying the flow to manage in the pipeline body at the pipeline, anion generator sets up this internal gas that is used for the ionization flow to manage in the pipeline at the pipeline, thereby realize heating for the gas that flows through vent line through the heater, increase the anion for the gas that flows through vent line through anion generator, and through temperature collector control gas temperature, thereby it is appropriate for the user carries humidity, the temperature is suitable and be rich in the gas of anion, the quality of carrying gas for the user has been improved.

Description

Ventilation pipeline and breathing equipment

Technical Field

The application relates to the technical field of medical equipment, in particular to a ventilation pipeline and breathing equipment.

Background

A ventilator is also a necessary medical device, and is gradually becoming a home device. When the respirator is used, the pressure and the flow rate of the air breathed by a user are far greater than the ordinary breathing state, so that the moisture is accelerated to evaporate, without adding extra humidity, the user feels too dry, resulting in discomfort, therefore, when the breathing machine is used, a humidifier is arranged, after the air flow is heated and humidified by the humidifier, if indoor temperature is less than the air current temperature, the temperature of breathing machine pipe wall also can be less than the air current temperature, the damp and hot air that contains a large amount of steam meets cold pipe wall meeting condensate water, lead to air humidity to descend, the absolute humidity of air current is not enough, cause the unable moisture that supplyes the disappearance of user, lead to the user to appear the lack of water, the nasal cavity, the throat, respiratory tract mucosa is dry, the sputum is viscous, the damaged situation of mucosa can appear even, consequently, in the realization process, the inventor finds that there is the following problem in the conventional art at least: conventional breathing apparatus deliver poor quality gases to the user.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is necessary to provide a ventilation circuit and a breathing apparatus for solving the problem of poor quality of gas delivered to a user by the conventional breathing apparatus.

In order to achieve the above object, in one aspect, an embodiment of the present application provides a ventilation pipeline, including a pipeline body, a heater, a temperature collector, and an anion generator;

the heater is arranged in the pipeline body and used for heating the pipeline body;

the temperature collector is arranged in the pipeline body and used for detecting the temperature of gas flowing through the pipeline body;

the negative ion generator is arranged in the pipeline body and used for ionizing gas flowing through the pipeline body.

In one embodiment, the pipeline body comprises a threaded pipe, an air inlet connector and an air outlet connector;

one end of the screwed pipe is mechanically connected with the air inlet connector, and the other end of the screwed pipe is mechanically connected with the air outlet connector.

In one embodiment, the heater is a heating wire;

the heating wire is embedded into the spiral rib of the threaded pipe; the first contact pin of heater strip imbeds in the wall of air inlet connector.

In one embodiment, the device further comprises a first ground wire;

the first ground wire is embedded into the spiral rib of the threaded pipe and is electrically connected with the heating wire; the second contact pin of the first ground wire is embedded in the wall of the air inlet connector.

In one embodiment, the temperature collector comprises a temperature probe and a first signal wire;

the temperature probe is embedded into the wall of the air outlet connector;

the first signal wire is embedded in a spiral rib of the threaded pipe; one end of the first signal wire is electrically connected with the temperature probe, and the third contact pin at the other end is embedded into the wall of the air inlet connector.

In one embodiment, the ionizer comprises an ionization head and a second signal line;

the ionization head is embedded into the wall of the air outlet connector;

the second signal line is embedded into the spiral rib of the threaded pipe; one end of the second signal wire is electrically connected with the ionization head, and a fourth contact pin at the other end is embedded into the wall of the air inlet connector.

In one embodiment, the device further comprises a second ground wire;

the second ground is embedded into the spiral rib of the threaded pipe and is electrically connected with the second signal wire; and a fifth contact pin of the second ground wire is embedded in the wall of the air inlet connector.

In one embodiment, the gas composition detector is further included;

the gas composition detector is disposed within the pipeline body for detecting a gas cost within the pipeline body.

In one embodiment, the mask comprises an oronasal mask;

the mouth-nose mask is mechanically connected with the air outlet connector of the pipeline body.

In another aspect, a breathing apparatus is also provided, which comprises a ventilator and the ventilation pipeline;

the air inlet connector of the ventilation pipeline is connected with a respirator.

One of the above technical solutions has the following advantages and beneficial effects:

the utility model provides a ventilation pipeline, including the pipeline body, a heater, temperature collector and anion generator, wherein, the heater sets up and is used for heating this internal gas of pipeline at this internal in pipeline, this internal gas temperature that is used for surveying the pipeline of flowing through of pipeline is used for to the temperature collector setting in the pipeline, anion generator sets up and is used for the ionization to flow through this internal gas of pipeline at this internal in pipeline, thereby realize through the heater for the gas heating of ventilation pipeline of flowing through, increase the anion for the gas of the ventilation pipeline of flowing through anion generator, and through temperature collector monitoring gas temperature, thereby it is appropriate for the user carries humidity, the temperature is appropriate and be rich in the gas of anion, the quality of carrying gas for the user has been improved.

Drawings

FIG. 1 is a block diagram of a piping body according to an embodiment;

FIG. 2 is a cross-sectional view of a vent line in one embodiment;

FIG. 3 is a view showing the structure of a piping body in another embodiment;

FIG. 4 is a schematic diagram of the internal circuit of the vent line in one embodiment;

FIG. 5 is a cross-sectional view of another embodiment of a vent line;

FIG. 6 is a schematic diagram of the internal circuit of the ventilation circuit according to another embodiment;

FIG. 7 is a cross-sectional view of a vent line in yet another embodiment.

Reference numerals:

10. a pipeline body; 12. a heater; 14. a temperature collector; 16. an anion generator; 102. a threaded pipe; 104. an air inlet connector; 106. an air outlet connector; 120. heating wires; 122. a first pin; 140. a temperature probe; 142. a first signal line; 144. a second pin; 160. an ionization head; 162. a second signal line; 164. a third pin; 18. a first ground line; 180. a fourth pin; 20. a second ground line; 200. and a fifth pin.

Detailed Description

To facilitate an understanding of the present application, the present application will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present application are shown in the drawings. This application may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "connected" to another element, it can be directly connected to the other element and be integral therewith, or intervening elements may also be present. The terms "embedded," "one end," "the other end," and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

In order to solve the technical problem of poor effect of the conventional respiratory apparatus for adjuvant therapy, in one embodiment, as shown in fig. 1 and 2, a ventilation tube is provided, which comprises a tube body 10, a heater 12, a temperature collector 14 and an anion generator 16;

the heater 12 is disposed in the pipe body 10 for heating the pipe body 10;

the temperature collector 14 is arranged in the pipeline body 10 and is used for detecting the temperature of gas flowing through the pipeline body 10;

an anion generator 16 is provided in the pipe body 10 for ionizing the gas flowing through the inside of the pipe body 10.

It should be noted that the pipeline body 10 is a through pipe, and air can flow through the pipeline body 10, in one example, the pipeline body 10 is a plastic hose; in another example, the pipeline body 10 is a metal hose. The specific structure of the pipeline body 10 can be selected according to actual design requirements, and in one example, as shown in fig. 3, the pipeline body 10 includes a threaded pipe 102, an inlet connector 104, and an outlet connector 106; one end of the threaded pipe 102 is mechanically connected with an air inlet connector 104, and the other end is mechanically connected with an air outlet connector 106, wherein the air inlet connector 104 is used for connecting a breathing machine, and comprises mechanical connection with the breathing machine (the air inlet connector 104 is mechanically connected with the breathing machine), and also comprises mechanical connection with the breathing machine (the heater 12, the temperature collector 14 and the ionizer are electrically connected with the breathing machine through the air inlet connector 104); the outlet connector 106 is connected to an oronasal mask for supplying air to the user.

The heater 12 may be disposed in a cavity of the pipe body 10, or may be embedded in a wall of the pipe body 10, for heating the pipe body 10 to prevent moisture contained in the gas flowing through the pipe body 10 from being liquefied. In one example, the heater 12 may be an electromagnetic heater or an infrared heater. In another example, as shown in fig. 4 and 5, the heater 12 is a heating wire 120. The heater can be controlled by, but is not limited to, the following two ways: in one mode, a control circuit and a power supply are arranged on a pipeline body, and the control circuit controls the power supply to supply power to a heater; in another mode, the pipeline body 10 includes a threaded pipe 102, an inlet connector 104 and an outlet connector 106; in the example where one end of the threaded pipe 102 is mechanically connected to the inlet connector 104 and the other end is mechanically connected to the outlet connector 106, the heating wire 120 is embedded in the spiral rib of the threaded pipe 102; a first prong 122 of the heating wire 120 (for electrical connection with a power supply, such as a ventilator supply) is embedded in the wall of the inlet connector 104, so that the heating wire 120 is properly disposed in the conduit body 10, ensuring that the heating wire 120 can be bent and contracted along with the threaded pipe 102. To ensure heating safety of the heating wire 120, in one example, as shown in fig. 4 and 5, a first ground wire 18 is further included; the first ground wire 18 is embedded in the spiral rib of the threaded pipe 102 and is electrically connected with the heating wire 120; a second prong 144 of the first ground wire 18 (for electrical connection to a grounding device, such as a ventilator ground) is embedded within the wall of the inlet connector 104.

The temperature collector 14 is used for detecting the temperature of the gas flowing through the pipeline body 10, and the temperature collector 14 may be disposed in a cavity of the pipeline body 10, may also be disposed at an air inlet of the pipeline body 10, and may also be disposed at an air outlet of the pipeline body 10. In one example, the temperature harvester 14 is a wireless temperature harvester. In another example, the temperature collector 14 is a wired temperature collector, and specifically, as shown in fig. 4 and 5, the temperature collector 14 includes a temperature probe 140 and a first signal line 142, and further, the pipeline body 10 includes a threaded pipe 102, an inlet connector 104 and an outlet connector 106; in the example where one end of the threaded pipe 102 is mechanically connected to the inlet connector 104 and the other end is mechanically connected to the outlet connector 106, the temperature probe 140 is embedded in the wall of the outlet connector 106; the first signal wire 142 is embedded in the spiral rib of the threaded pipe 102; one end of the first signal wire 142 is electrically connected to the temperature probe 140, and a third pin 164 (for electrically connecting to a power supply and signal receiving device, such as a ventilator, and feeding back the collected temperature to the ventilator, which controls a heater based on the received temperature to control the temperature within a set range) at the other end is embedded in the wall of the air inlet connector 104, so that the first signal wire 142 is reasonably arranged in the pipeline body 10, and the first signal wire 142 can be ensured to be contracted along with the bending of the threaded pipe 102. In another example, a control circuit and a power supply are arranged on the pipeline body, the control circuit controls the power supply to supply power to the temperature collector, the temperature collector feeds the detected temperature back to the control circuit, and the control circuit controls the power supply based on the received temperature so as to control the temperature within a set range.

The anion generator 16 is used for ionizing the gas flowing through the pipeline body 10 to increase the content of anions in the gas, the anion generator 16 may be disposed in the cavity of the pipeline body 10, or disposed at the air inlet of the pipeline body 10, or disposed at the air outlet of the pipeline body 10, in one example, as shown in fig. 4 and 5, the anion generator 16 includes an ionization head 160 and a second signal line 162; further, the pipeline body 10 includes a threaded pipe 102, an inlet connector 104 and an outlet connector 106; in the example where one end of the threaded tube 102 is mechanically connected to the inlet connector 104 and the other end is mechanically connected to the outlet connector 106, the ionization head 160 is embedded in the wall of the outlet connector 106; the second signal line 162 is embedded in the spiral rib of the threaded pipe 102; a second signal wire 162 has one end electrically connected to the ionization head 160 and a fourth pin 180 (for electrical connection to a power and signal receiving device, such as a ventilator) at the other end embedded in the wall of the inlet connector 104. In order to ensure safe operation of the ionizer 16, in one example, as shown in fig. 6 and 7, a second ground 20 is further included; the second ground 20 is embedded in the spiral rib of the threaded pipe 102 and is electrically connected with the second signal line 162; a fifth prong 200 of the second ground 20 (for electrical connection to a power receiving device, such as with a ventilator power supply) is embedded within the wall of the inlet connector 104. In another example, a control circuit and a power supply are arranged on the pipeline body, and the control circuit controls the power supply to supply power to the anion generator.

Further, an electrical socket is formed on the air inlet connector 104, and the first pin 122, the second pin 144, the third pin 164, the fourth pin 180 and the fifth pin 200 are disposed in the electrical socket.

In one example, a gas composition detector is further included; the gas composition detector is provided in the pipe body 10 for detecting the gas cost in the pipe body 10. It should be noted that the gas component detector is used for detecting gas components flowing through the pipeline body 10, so as to ensure the quality of gas delivered to a user, and the gas component detector may be disposed in a cavity of the pipeline body 10, may also be disposed at a gas inlet of the pipeline body 10, and may also be disposed at a gas outlet of the pipeline body 10.

In one example, an oronasal mask is included; the oronasal mask is mechanically coupled to the outlet connector 106 of the manifold body 10 so as to be conveniently worn by a user.

In one embodiment, there is provided a vent line comprising:

the pipeline comprises a pipeline body 10, wherein the pipeline body 10 comprises a threaded pipe 102, an air inlet connector 104 and an air outlet connector 106, one end of the threaded pipe 102 is mechanically connected with the air inlet connector 104, and the other end of the threaded pipe is mechanically connected with the air outlet connector 106;

the heating wire 120 is embedded into the spiral rib of the threaded pipe 102, the first contact pin 122 of the heating wire 120 is embedded into the wall of the air inlet connector 104, and the heating wire 120 is used for heating the pipeline body 10;

the temperature collector 14, the temperature collector 14 includes a temperature probe 140 and a first signal line 142, the temperature probe 140 is embedded in the wall of the outlet connector 106, the first signal line 142 is embedded in the spiral rib of the threaded pipe 102, one end of the first signal line 142 is electrically connected to the temperature probe 140, a third pin 164 at the other end is embedded in the wall of the inlet connector 104, and the temperature collector 14 is used for detecting the temperature of the gas flowing through the pipeline body 10;

the negative ion generator 16, the negative ion generator 16 includes an ionization head 160 and a second signal line 162, the ionization head 160 is embedded into the wall of the air outlet connector 106, the second signal line 162 is embedded into the spiral rib of the threaded pipe 102, one end of the second signal line 162 is electrically connected to the ionization head 160, the fourth contact pin 180 at the other end is embedded into the wall of the air inlet connector 104, and the negative ion generator 16 is used for ionizing the gas flowing through the pipeline body 10;

a first ground wire 18, the first ground wire 18 being embedded in the spiral rib of the threaded pipe 102 and electrically connected to the heating wire 120; the second prong 144 of the first ground wire 18 is embedded within the wall of the inlet connector 104.

In one embodiment, there is provided a vent line comprising:

the pipeline comprises a pipeline body 10, wherein the pipeline body 10 comprises a threaded pipe 102, an air inlet connector 104 and an air outlet connector 106, one end of the threaded pipe 102 is mechanically connected with the air inlet connector 104, and the other end of the threaded pipe is mechanically connected with the air outlet connector 106;

the heating wire 120 is embedded into the spiral rib of the threaded pipe 102, the first contact pin 122 of the heating wire 120 is embedded into the wall of the air inlet connector 104, and the heating wire 120 is used for heating the pipeline body 10;

the temperature collector 14, the temperature collector 14 includes a temperature probe 140 and a first signal line 142, the temperature probe 140 is embedded in the wall of the outlet connector 106, the first signal line 142 is embedded in the spiral rib of the threaded pipe 102, one end of the first signal line 142 is electrically connected to the temperature probe 140, a third pin 164 at the other end is embedded in the wall of the inlet connector 104, and the temperature collector 14 is used for detecting the temperature of the gas flowing through the pipeline body 10;

the negative ion generator 16, the negative ion generator 16 includes an ionization head 160 and a second signal line 162, the ionization head 160 is embedded into the wall of the air outlet connector 106, the second signal line 162 is embedded into the spiral rib of the threaded pipe 102, one end of the second signal line 162 is electrically connected to the ionization head 160, the fourth contact pin 180 at the other end is embedded into the wall of the air inlet connector 104, and the negative ion generator 16 is used for ionizing the gas flowing through the pipeline body 10;

a first ground wire 18, the first ground wire 18 being embedded in the spiral rib of the threaded pipe 102 and electrically connected to the heating wire 120; the second pin 144 of the first ground wire 18 is embedded in the wall of the inlet connector 104;

a second ground 20, the second ground 20 being embedded in the spiral rib of the threaded pipe 102 and electrically connected to the second signal line 162; the fifth pin 200 of the second ground 20 is embedded in the wall of the inlet connector 104.

In each embodiment of this application vent line, including the pipeline body, a heater, temperature collector and anion generator, wherein, the heater setting is used for heating the internal gas that flows through the pipeline body at this internal being used for of pipeline, temperature collector sets up and is used for surveying the internal gas temperature that flows through the pipeline body at this internal being used for of pipeline at the pipeline, anion generator sets up and is used for the internal gas that the ionization flows through the pipeline body at this internal being used for of pipeline, thereby realize through the heater for the gas heating of the vent line that flows through, increase the anion for the gas that flows through the vent line through anion generator, and monitor gas temperature through temperature collector, thereby it is appropriate for the user to carry humidity, the temperature is suitable and be rich in the gas of anion, the quality of carrying gas for the user has been improved.

In one embodiment, there is also provided a breathing apparatus comprising a ventilator and the ventilation circuit described above;

the air inlet connector of the ventilation pipeline is connected with a respirator.

It should be noted that the vent pipeline in this embodiment is the vent pipeline described in the vent pipeline embodiment of the present application, and for the specific case, reference is made to the foregoing embodiment, which is not described herein again.

In various embodiments of the breathing apparatus of the present application, the calling device is capable of providing the user with oxygen at an appropriate temperature, an appropriate humidity, and enriched with negative ions.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the claims. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A ventilation pipeline is characterized by comprising a pipeline body, a heater, a temperature collector and a negative ion generator;

the heater is arranged in the pipeline body and used for heating the pipeline body;

the temperature collector is arranged in the pipeline body and used for detecting the temperature of gas flowing through the pipeline body;

the negative ion generator is arranged in the pipeline body and used for ionizing gas flowing through the pipeline body.

2. The vent line of claim 1, wherein the line body comprises a threaded tube, an inlet connector, and an outlet connector;

one end of the threaded pipe is mechanically connected with the air inlet connector, and the other end of the threaded pipe is mechanically connected with the air outlet connector.

3. The ventilation circuit of claim 2, wherein said heater is a heating wire;

the heating wire is embedded into the spiral rib of the threaded pipe; the first contact pin embedding of heater strip in the wall of connector admits air.

4. The vent line of claim 3, further comprising a first ground;

the first ground wire is embedded into the spiral rib of the threaded pipe and is electrically connected with the heating wire; and the second contact pin of the first ground wire is embedded into the wall of the air inlet connector.

5. The vent line of claim 2, wherein the temperature collector comprises a temperature probe and a first signal line;

the temperature probe is embedded into the wall of the air outlet connector;

the first signal wire is embedded into a spiral rib of the threaded pipe; one end of the first signal wire is electrically connected with the temperature probe, and a third contact pin at the other end of the first signal wire is embedded into the wall of the air inlet connector.

6. The ventilation circuit of claim 2, wherein said anion generator comprises an ionization head and a second signal line;

the ionization head is embedded into the wall of the air outlet connector;

the second signal wire is embedded into a spiral rib of the threaded pipe; one end of the second signal wire is electrically connected with the ionization head, and a fourth contact pin at the other end of the second signal wire is embedded into the wall of the air inlet connector.

7. The vent line of claim 6, further comprising a second ground line;

the second ground is embedded into the spiral rib of the threaded pipe and is electrically connected with the second signal wire; and a fifth contact pin of the second ground wire is embedded in the wall of the air inlet connector.

8. The vent line of claim 1, further comprising a gas composition detector;

the gas composition detector is disposed within the pipeline body for detecting a gas cost within the pipeline body.

9. The vent line of any one of claims 1 to 8, further comprising an oronasal mask;

the oronasal mask is mechanically connected with the air outlet connector of the pipeline body.

10. A breathing apparatus comprising a ventilator and a ventilation circuit as claimed in any one of claims 1 to 9;

and the air inlet connector of the ventilation pipeline is connected with the breathing machine.

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