CN214807561U - Respiratory gas delivery pipe, nasal catheter and ventilation treatment equipment - Google Patents

Abstract

The utility model relates to a treatment equipment field of ventilating discloses a breathe gas-supply pipe, nasal catheter and treatment equipment of ventilating. The breathing gas conveying pipe is used for conveying gas to a patient interface and comprises a gas conveying pipe body, and the gas conveying pipe body comprises a gas conveying channel and a heat preservation structure used for preserving heat of the gas in the gas conveying channel. Because the gas transmission pipe body comprises the heat insulation structure for insulating the gas transmission in the gas transmission channel, the temperature drop of the gas transmission channel can be effectively slowed down or avoided through the heat insulation of the gas transmission pipe body by the heat insulation structure, so that the temperature drop of the gas transmitted in the gas transmission channel is further slowed down or avoided, and the generation of condensed water of the gas transmission channel is avoided.

Description

Respiratory gas delivery pipe, nasal catheter and ventilation treatment equipment

Technical Field

The utility model relates to a treatment equipment field of ventilating specifically relates to a breathe gas-supply pipe, a nose is led and a treatment equipment of ventilating.

Background

Currently, ventilation therapy equipment such as a ventilator and a high-flow oxygen therapy apparatus are medical equipment which are vital to maintain breathing, ensure ventilation, save and prolong the life of a patient with respiratory failure, and are effective methods which can replace an artificial self-ventilation function, and are generally used in respiratory failure caused by various reasons, anesthesia and breathing management during major surgery, respiratory support therapy and emergency resuscitation. Nasal catheters for use therein typically include a machine-side interface, a catheter, and a patient interface. The two ends of the conduit are respectively connected with the machine end interface and the patient interface, and the high-temperature and high-humidity gas provided by the machine can be conveyed to the patient interface through the conduit and is transmitted to the respiratory tract of the patient through the patient interface.

In practice, the conduit is usually exposed to room air, and since the gas delivered to the patient is a respiratory gas with high temperature and humidity, the respiratory gas will have a temperature drop in the conduit, with the accompanying formation of condensation, especially in the case of nasal catheters for children, where the gas flow is very low (typically 2-25L/min), and the temperature drop of the gas in the conduit will be very high, and the condensation will be more pronounced.

In addition, the ventilation cross section of the catheter is usually circular, so that the phenomenon of ventilation incapability such as pressing, bending and the like easily occurs when the catheter is squeezed, such as squashed or bent, and if the phenomenon is found out untimely, the treatment of a patient can be influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a breathe gas-supply pipe, this breathe gas-supply pipe self can reduce the gaseous temperature drop of delivery to reduce the production of comdenstion water.

In order to achieve the above object, the utility model provides a breathe gas-supply pipe, breathe the gas-supply pipe and be used for carrying gas to patient's interface, breathe the gas-supply pipe including the gas transmission body, the gas transmission body includes gas transmission passageway and is used for right gas transmission in the gas transmission passageway carries out heat retaining insulation structure.

In this technical scheme, because the gas transmission body carries out heat retaining insulation structure including being used for the gas transmission in the gas transmission passageway, like this, through this heat retaining insulation structure to the gas transmission body, can slow down or avoid the temperature drop of gas transmission passageway effectively to further slow down or avoid the temperature drop of the gas of carrying in the gas transmission passageway, avoided the production of gas transmission passageway comdenstion water.

Further, the insulation structure includes a plurality of layers of insulation structures arranged in a radial direction.

Further, the heat preservation structure can enable the deformation position of the gas transmission channel to have a gas transmission gap for maintaining gas transmission when at least part of the gas transmission pipe body is extruded to deform.

Further, the gas transmission pipe body comprises an inner pipe and an outer pipe, the outer pipe is sleeved outside the inner pipe, pipe supporting ribs for supporting the inner pipe and the outer pipe are arranged between the inner pipe and the outer pipe, so that a heat preservation interval is formed between the inner pipe and the outer pipe, an inner channel of the inner pipe serves as the gas transmission channel, and the heat preservation structure comprises the heat preservation interval.

Further, one end in the radial direction of the tube support rib is integrally formed with the inner tube and the other end in the radial direction of the tube support rib is integrally formed with the outer tube;

alternatively, the first and second electrodes may be,

one end in the radial direction of the tube support rib is integrally formed with one of the inner tube and the outer tube, and the other end in the radial direction of the tube support rib is not integrally formed with the other of the inner tube and the outer tube.

Further, the heat preservation interval is a closed cavity.

Furthermore, a liquid outlet and a side wall door body capable of opening and closing the liquid outlet are arranged on the outer side wall of the heat preservation interval.

Further, the insulation structure includes an electric heating wire disposed within a tube wall of at least one of the inner tube and the outer tube.

Further, the electric heating wire extends axially straight or spirally around the tube.

Further, the heat preservation structure comprises a heat preservation layer, and the heat preservation layer is filled in the heat preservation interval.

Further, at least one of the inner side surface and the outer side surface of the heat preservation interval is provided with an air interval maintaining structure, and the air interval maintaining structure enables the deformation position to maintain the air interval when at least part of the outer pipe is extruded to deform.

Still further, the air space maintaining structure includes a protruding portion protruding from at least one of an inner side surface and an outer side surface of the insulation space, the protruding portion being capable of contacting an opposing structure in the insulation space when the outer pipe is pressed to be deformed, to form the air space on at least one circumferential side of the protruding portion.

Furthermore, the raised parts are arranged at intervals along the circumferential direction, and the opposite structures are side surfaces of the heat preservation intervals, which are opposite to the raised parts in the radial direction, or the opposite structures are opposite raised parts extending out of the side surfaces of the heat preservation intervals, which are opposite to the raised parts in the radial direction.

Further, the cross section of the protruding portion is in a peak shape, and the side face of the peak adjacent to the peak in the circumferential direction is an inner concave arc-shaped face.

In addition, optionally, the heat insulation structure comprises a heat insulation layer, the gas transmission pipe body comprises an inner pipe and an outer pipe, the outer pipe is sleeved outside the inner pipe in a supporting mode through the heat insulation layer, and an inner channel of the inner pipe serves as the gas transmission channel.

In addition, optionally, the gas transmission pipe body is a single-layer pipe body, an electric heating wire is arranged in the pipe wall of the single-layer pipe body, and/or a heat insulation layer wraps the outer surface of the single-layer pipe body.

In addition, the gas transmission pipe body comprises a maintaining gas transmission structure, and the maintaining gas transmission structure enables the gas transmission channel to have a gas transmission gap for maintaining gas transmission at the deformation position when at least part of the gas transmission pipe body is extruded to deform.

Further, the gas transmission structure is arranged on the inner surface of the gas transmission channel.

Still further, a width dimension of a cross-section of the gas retention and delivery structure tapers in a radially inward direction.

Further, the gas transmission maintaining structure comprises a protrusion extending inward from the inner surface of the channel, the protrusion extending in the axial direction of the gas transmission channel, and the protrusion being capable of contacting an opposing structure on the inner surface of the channel when the gas transmission pipe is deformed by being pressed, so as to form the gas transmission gap on at least one circumferential side of the protrusion.

Still further, the opposing structure is an inner surface portion of the channel inner surface that is radially opposite the protrusion.

Further, the protrusions are plural and arranged at intervals in the circumferential direction.

Still further, the opposing structure is a protrusion on the inner surface of the channel radially opposite the protrusion.

Further, a width dimension of a cross section of the protrusion is tapered in a radially inward direction.

Further, the cross-sectional shape of the protrusion is a peak.

Still further, at least one peak side surface adjacent to the peak in the circumferential direction is an inner concave arc surface.

Additionally, the utility model provides a nasal catheter, this nasal catheter include air supply connecting terminal, patient interface and above arbitrary breathe the gas-supply pipe, wherein, breathe the one end of gas-supply pipe with air supply connecting terminal connects, breathe the other end of gas-supply pipe with patient interface connects.

Finally, the utility model provides a ventilation treatment device, which comprises the nasal catheter.

Other features and advantages of the present invention will be described in detail in the detailed description which follows.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic cross-sectional view of a first respiratory gas delivery pipe according to an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of a second breathing gas pipe according to an embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view of a third breathing gas pipe according to an embodiment of the present invention;

FIG. 4 is a schematic cross-sectional view of a fourth respiratory gas delivery conduit according to an embodiment of the present invention;

FIG. 5 is a side view of a portion of the structure of the respiratory gas delivery conduit of FIG. 4;

FIG. 6 is a schematic cross-sectional view of a fifth breathing gas pipe according to an embodiment of the present invention;

FIG. 7 is a side view of a portion of the structure of the respiratory gas delivery conduit of FIG. 6;

FIG. 8 is a schematic view of the structure of the respiratory gas delivery conduit of FIG. 3 being compressed;

FIG. 9 is another schematic view of the structure of the respiratory gas delivery conduit of FIG. 3 being compressed;

FIG. 10 is a schematic cross-sectional view of a sixth respiratory gas delivery pipe according to an embodiment of the present invention;

FIG. 11 is a schematic cross-sectional view of a seventh breathing gas pipe according to an embodiment of the present invention;

FIG. 12 is a schematic cross-sectional view of an eighth respiratory gas delivery conduit according to an embodiment of the present invention;

FIG. 13 is a schematic cross-sectional view of a ninth respiratory gas delivery pipe according to an embodiment of the present invention;

FIG. 14 is a schematic structural view of the breathing gas pipe according to the embodiment of the present invention, which has a gas transmission gap at the deformation position for maintaining gas transmission when the breathing gas pipe is deformed by squeezing;

FIG. 15 is another schematic structural view of the breathing gas pipe according to the embodiment of the present invention, which has a gas transmission gap at the deformation position to maintain gas transmission when the breathing gas pipe is deformed by squeezing;

FIG. 16 is a schematic cross-sectional view of a tenth embodiment of a respiratory gas delivery conduit according to the present invention;

FIG. 17 is a schematic view showing a structure of a portion of the respiratory gas conduit of FIG. 16 that maintains an air space at a deformed portion when the insulation space is crushed;

FIG. 18 is a schematic structural view of the connection between the end of the respiratory gas pipe and the connector according to the embodiment of the present invention;

FIG. 19 is a schematic view of another structure of the embodiment of the present invention, in which the end of the breathing gas pipe is connected to the connector;

fig. 20 is a schematic structural view of the connection between the end of the breathing gas pipe and the connector according to the embodiment of the present invention.

Description of the reference numerals

1-gas transmission pipe body, 2-gas transmission channel, 3-gas transmission gap, 4-inner pipe, 5-outer pipe, 6-pipe support rib, 7-heat preservation interval, 8-electric heating wire, 9-heat preservation layer, 10-inner side surface, 11-outer side surface, 12-air interval, 13-bulge, 14-peak, 15-peak side surface, 16-channel inner surface, 17-bulge, 18-inner surface part, 19-connector, 20-plug and 21-plug.

Detailed Description

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings. It is to be understood that the description of the embodiments herein is for purposes of illustration and explanation only and is not intended to limit the invention.

Referring to the respiratory gas pipe of the different embodiments shown in fig. 1-4, fig. 6, fig. 10, fig. 11, fig. 12, fig. 13 and fig. 16, the utility model provides a respiratory gas pipe is used for carrying gas to patient interface, and respiratory gas pipe includes gas transmission pipe body 1, and gas transmission pipe body 1 includes gas transmission channel 2 and is used for carrying out heat retaining insulation structure to the gas transmission in gas transmission channel 2.

In this breathing gas-supply pipe, because gas transmission body 1 carries out heat retaining insulation structure including being used for the gas transmission in gas transmission passageway 2, like this, through this heat retaining insulation structure to gas transmission body 1, can slow down or avoid gas transmission passageway's temperature drop effectively to further slow down or avoid gas transmission passageway in the temperature drop of carrying, avoided gas transmission passageway comdenstion water's production.

In addition, in the respiratory gas pipe, the heat preservation structure may be a layer, refer to a layer of heat preservation space 7 shown in fig. 1-3, or in order to further improve the heat preservation effect, the heat preservation structure includes a plurality of layers of heat preservation structures arranged in the radial direction, refer to an electric heating wire 8 (one layer of heat preservation structure) and a heat preservation space 7 (another layer of heat preservation structure) shown in fig. 4. Of course, the multi-layer insulation structure is not limited to two layers, and may be three or four layers arranged in sequence in the radial direction.

In addition, the heat preservation structure of the breathing gas conveying pipe has the heat preservation function and also has the following function of keeping the gas conveying gap 3, namely, the heat preservation structure can enable the deformation part of the gas conveying channel 2 to be provided with the gas conveying gap 3 for keeping gas conveying when at least part of the gas conveying pipe body 1 is extruded and deformed. The gas transmission gap 3 can be referred to fig. 8, 9, 14 and 15. Like this, because the insulation construction that gas transmission body 1 includes can further strengthen gas transmission body 1's anti extrusion deformation intensity, make at least part of gas transmission body 1 extruded and when taking place to warp, can slow down gas transmission channel 2's deformation degree in order to avoid with gas transmission channel 2 complete extrusion seal in the department of extrusion and unable the ventilation, thereby form gas transmission clearance 3 in the department of deformation, like this, the gas that gas transmission channel 2 carried can be carried through gas transmission clearance 3, avoid producing adverse effect to patient's treatment.

Of course, in the respiratory gas pipe of the present invention, the heat-insulating structure may have various types, and the various types of the heat-insulating structure will be described in detail below.

In a first type of the heat insulating structure, referring to fig. 1 to 4, 6 and 16, the gas transmission pipe body 1 includes an inner pipe 4 and an outer pipe 5, the outer pipe 5 is fitted around the outer portion of the inner pipe 4, a pipe support rib 6 for supporting the inner pipe and the outer pipe is provided between the inner pipe 4 and the outer pipe 5, so that a heat insulating space 7 is formed between the inner pipe 4 and the outer pipe 5, the inner passage of the inner pipe 4 serves as the gas transmission passage 2, and the heat insulating structure includes the heat insulating space 7. Therefore, in practical use, the heat preservation interval 7 is in sealed filling, and as the heat conductivity coefficient of air is far smaller than that of the pipe wall, the air layer in the heat preservation interval 7 is basically not communicated, so that the heat insulation and heat preservation effects are achieved. The high-temperature and high-humidity breathing gas in the inner tube 4 can be conducted to the air layer through the tube wall of the inner tube 4, and then the air layer is conducted to the tube wall of the outer tube 5, and then heat is released to the atmosphere. Because the heat conductivity of the air is very low, and the air layer in the heat preservation interval 7 basically does not circulate, after the breathing gas pipe works for a short time, the air layer can be heated to the temperature close to the breathing gas in the inner pipe 4, so that the temperature difference of two sides of the pipe wall of the inner pipe 4 is reduced, the breathing gas cannot have great temperature drop at the pipe wall of the inner pipe 4, and the phenomenon that the temperature of the breathing gas is reduced to generate excessive condensate water is reduced. For example, at room temperature of 25 ℃, the breathing gas transmitted by the breathing gas pipe is 37 ℃, the temperature difference between the inner side and the outer side of the existing common single-layer conduit is 12 ℃, so that the inner wall of the conduit has a larger temperature difference than the breathing gas, the breathing gas contacting with the inner wall can generate temperature drop, and further condensed water is generated. In the use process of the air layer in the heat-preservation interval 7 of the embodiment of the application, the temperature of the air layer in the heat-preservation interval 7 is between 25 and 37 ℃ (taking the intermediate value of 31 ℃ as an example), if the inner pipe is regarded as an existing common single-layer conduit, the air layer in the heat-preservation interval 7 equivalently raises the ambient temperature to 31 ℃, so that the temperature difference of two sides of the pipe wall of the inner pipe is reduced, the temperature of the inner side of the pipe wall of the inner pipe is raised, the temperature drop of respiratory gas contacting with the inner side of the pipe wall of the inner pipe is reduced, and the generation of condensed water on the pipe wall of the inner pipe is reduced.

In addition, the number of the tube support ribs 6 may be selected as required, for example, 2, 3, or 4, as long as the inner tube 4 and the outer tube 5 can be spread apart.

In addition, referring to fig. 1, the one end in the radial direction of the tube support rib 6 is integrally formed with the inner tube 4 and the other end in the radial direction of the tube support rib 6 is integrally formed with the outer tube 5, which facilitates the molding and also facilitates the stable and reliable connection between the inner tube 4 and the outer tube 5. Alternatively, referring to fig. 2, the tube support ribs 6 may be separate from the inner tube 4 or the outer tube 5, i.e., one radial end of the tube support ribs 6 is integrally formed with one of the inner tube 4 and the outer tube 5, while the other radial end of the tube support ribs 6 is non-integrally formed with the other of the inner tube 4 and the outer tube 5 to form an assembled relationship. Alternatively, the radial both ends of the tube support rib 6 are non-integrally formed with the inner tube 4 and the outer tube 5, respectively, and are in a shape-assembled relationship, for example, the tube support rib 6 may be pasted on the inner tube 4, and then the outer tube 5 is fitted and the inner surface of the outer tube 5 is brought into contact with the tube support rib 6.

In addition, the tube support ribs 6 may be annular tube support ribs, and the plurality of annular tube support ribs 6 are arranged at intervals along the length direction (axial direction) of the breathing gas pipe. Or, the tube support rib 6 may be an axially extending rib section having a predetermined length, and the plurality of axially extending ribs may be arranged at intervals along the length direction (axial direction) of the breathing gas pipe, or the axially extending rib section may extend continuously from one end of the breathing gas pipe to the other end.

In addition, in an embodiment of the breathing gas pipe, before the breathing gas pipe is not used, the heat-preserving space 7 may be an open space, and when the breathing gas pipe is used, the heat-preserving space 7 is connected and matched with the connecting head 19 or the plug 20 (refer to fig. 18-20), for example, the heat-preserving space may be plugged by the end face of the connecting head 19 or plugged by the plug 21 on the end face of the connecting head 19, so as to encapsulate the heat-preserving space 7 to form a sealing space. After the use, the breathing gas pipe can be separated from the connector 19 or the plug 20, and at the moment, if condensed water exists in the heat preservation interval 7, the condensed water can be thrown out.

Or, in another embodiment of the respiratory gas pipe, the heat-insulating space 7 is a closed cavity, for example, the end faces of the two axial ends of the outer pipe 5 are connected with the inner pipe 4 through the annular end wall to encapsulate the heat-insulating space 7 into a closed cavity, and in actual use, the two ends of the inner pipe 4 are respectively connected with the gas source connecting terminal and the patient interface. Or, the two ends of the breathing gas pipe are respectively connected with a connector 19 or a plug 20 (refer to fig. 18-20) to encapsulate the heat-insulating space 7 into a closed cavity, and in practical use, the connector 19 is respectively connected with the gas source connecting terminal and/or the patient interface, or the two ends of the breathing gas pipe are respectively connected with the gas source connecting terminal and the patient interface.

In addition, in actual use, condensed water may be generated in the closed heat-retaining spacer 7, and for this reason, a liquid discharge port and a side wall door body capable of opening and closing the liquid discharge port are provided on an outer side wall of the heat-retaining spacer 7. Therefore, after the heat preservation partition 7 is used, the side wall door body is opened, and condensed water in the heat preservation partition 7 is thrown out. The side door can be a connector 19 or a plug 20 or other door structure. For example, when the tube support ribs 6 are a plurality of annular tube support ribs and are arranged at intervals along the length direction (axial direction) of the breathing gas delivery pipe, the annular heat preservation interval 7 between adjacent annular tube support ribs is an annular closed cavity, at this time, the annular tube support ribs at the two axial ends of the annular closed cavity are located in the outer tube 5 and are not easy to open, at this time, the tube wall section of the outer tube 5 forming the annular closed cavity can be provided with a liquid discharge port and a side wall door body capable of opening and closing the liquid discharge port, after use, if condensed water exists in the annular closed cavity, the side wall door body can be opened to discharge the condensed water, and if the condensed water does not exist, the side wall door body is not opened.

In addition, in an embodiment, referring to fig. 16 and 17, at least one of the inner side surface 10 and the outer side surface 11 of the heat-retaining space 7 is provided with a holding air space structure which allows the deformed portion to hold the air space 12 when the outer tube 5 is deformed by being pressed at least partially. Like this, in the use of reality, if outer tube 5 is when being extrudeed and take place to warp, keep the air space structure and can keep air space 12 in the department of warping, for example, outer tube 5 is when external force is shriveled, bend, can also guarantee that heat preservation interval 7 between inner tube and the outer tube is not totally extruded and pastes the death, make the heat preservation interval 7 between inner tube and the outer tube partly still form air space 12, the air bed in the air space 12 still can play thermal-insulated, the heat preservation effect to the breathing gas in the inner tube, thereby heat preservation performance when preventing outer tube 5 even breathing gas pipe from being extruded is invalid.

Of course, the air space maintaining structure may have various structural forms, for example, in one structural form of the air space maintaining structure, the air space maintaining structure is a support column whose radial connections are respectively connected to the outer surface of the inner tube and the inner surface of the outer tube, so that when the outer tube is pressed, air spaces 12 are formed at both sides of the support column.

Alternatively, in another form of the structure for maintaining the air space, referring to fig. 16 and 17, the structure for maintaining the air space includes a protruding portion 13 protruding from at least one of the inner side surface 10 and the outer side surface 11 of the heat-retaining space 7, the protruding portion 13 may extend in the axial direction of the air delivery passage 2 or in the circumferential direction to form a circumferentially extending segment or ring-shaped protruding portion, and when the outer pipe 5 is pressed to be deformed, the protruding portion 13 can contact with the opposing structure in the heat-retaining space 7 to form the air space 12 on at least one circumferential side of the protruding portion 13. For example, in fig. 16, the convex portions 13 are projected on both the inner side surface 10 and the outer side surface 11, and in fig. 17, when the outer tube 5 is pressed to be deformed, the convex portions 13 on the inner side surface 10 and the convex portions 13 on the outer side surface 11 are abutted, thereby forming the air spaces 12 at the circumferential side portions. Alternatively, for example, the inner surface 10 has the protruding portion 13 protruding therefrom, the outer surface 11 has no protruding portion 13 formed thereon, and when the outer tube 5 is pressed and deformed, the protruding portion 13 on the inner surface 10 and the outer surface 11 abut against each other, thereby forming the air space 12 at the circumferential side portion.

Of course, the projection 13 may be one or plural. For example, in one embodiment, the protrusions 13 are arranged at intervals in the circumferential direction, the opposite structure is the side surface of the heat-insulating space 7 which is opposite to the protrusions 13 in the radial direction, for example, the protrusions 13 do not protrude from the inner side surface 10, the protrusions 13 protrude from the outer side surface 11, and when the outer pipe 5 is pressed to deform, the opposite structure is the inner side surface 10, and at this time, the protrusions 13 on the outer side surface 11 and the inner side surface 10 abut, so that the air spaces 12 are formed at the circumferential side. Alternatively, referring to fig. 17, the opposite structure is the opposite protruding portion 13 protruding from the side surface of the heat-insulating space 7 radially opposite to the protruding portion 13, the two protruding portions 13 contacting each other can increase the size of the air space 12, and improve the heat-insulating capability, and the protruding portions 13 protrude from both the inner side surface 10 and the outer side surface 11, and in fig. 17, when the outer pipe 5 is pressed to be deformed, the opposite structure is the protruding portion 13, and the protruding portion 13 on the inner side surface 10 and the protruding portion 13 on the outer side surface 11 abut against each other, so that the air space 12 is formed at the circumferential side portion.

Of course, the opposite structure may be other bumps or protrusions formed on the inner side surface 10 or the outer side surface 11, which are different from the protrusions 13.

In addition, the cross section of the boss 13 may have various shapes, such as a rectangle, that is, the boss 13 has the same size in the radial direction, for example, the boss 13 may be a cylinder.

In one embodiment, in order to minimize the occupation of the heat-retaining space 7 by the protrusion 13 and improve the heat-retaining performance, the width dimension of the cross section of the protrusion 13 is reduced in the radially inward direction, for example, the cross section of the protrusion 13 may be trapezoidal, triangular, semicircular, or the like.

In addition, referring to fig. 16, the cross-sectional shape of the convex portion 13 is a peak 14, and a peak side surface 15 circumferentially adjoining the peak 14 is an inward concave arc surface. In this way, the peak 14 itself can reduce the occupation of the insulation space 7, while the concave arc-shaped surface can further reduce the occupation of the insulation space 7 by the peak 14.

Furthermore, referring to fig. 4 and 6, in an embodiment, in practical use, the heat-insulating space 7 is only used for heat insulation, and in case of a relatively large heat dissipation, such as a particularly low room temperature or a relatively large air flow in the room, the heat-insulating space 7 may still have a relatively large heat loss, so that the temperature drop of the respiratory gas in the inner tube is still relatively large. For this purpose, the insulation structure comprises an electric heating wire 8, the electric heating wire 8 being arranged in the wall of at least one of the inner tube 4 and the outer tube 5; for example, in fig. 4 and 6, the electric heating wire 8 is arranged in the wall of the inner pipe 4, so that the electric heating wire 8 and the insulating space 7 form a two-layer insulating structure. Therefore, the combined action of the inner pipe of the electric heating wire and the heat preservation interval 7 is added, so that the heat preservation and heat insulation effects are achieved, the breathing gas in the inner pipe can be heated, the proper temperature of a patient is reached, and the generation of condensed water is prevented. Of course, the electric heating wire 8 may be arranged in the wall of the outer tube, or both the inner and outer tubes.

In addition, the electric heating wire 8 extends axially straight to facilitate arrangement of the electric heating wire 8, refer to fig. 5; alternatively, the electric heating wire 8 is spirally extended around the pipe (inner pipe or outer pipe), referring to fig. 7, thereby increasing the heating area of the electric heating wire. Of course, the electrical heating wire 8 may extend obliquely from one end of the respiratory gas conduit to the other end without being wound helically.

In an alternative embodiment, referring to fig. 11, the insulation structure comprises insulation 9, and insulation 9 is filled in insulation space 7. Therefore, the heat preservation layer 9 can enhance the heat preservation capability, and the heat preservation material of the heat preservation layer 9 can be soft material, so that the softness of the breathing gas pipe is not obviously affected.

In addition, in the second type of the heat insulating structure, referring to fig. 12, the heat insulating structure includes a heat insulating layer 9, the gas delivery pipe body 1 includes an inner pipe 4 and an outer pipe 5, the outer pipe 5 is supported and sleeved outside the inner pipe 4 through the heat insulating layer 9, and an inner passage of the inner pipe 4 serves as the gas delivery passage 2. The heat preservation layer 9 can strengthen the heat preservation capability, and the heat preservation material of the heat preservation layer 9 can be soft material, and has no obvious influence on the softness of the breathing gas pipe.

In addition, in the third type of the heat insulating structure, referring to fig. 10, the gas transmission pipe body 1 is a single-layer pipe body, and the electric heating wire 8 is provided in the pipe wall of the single-layer pipe body, and the electric heating wire 8 may be axially and straightly extended so as to be arranged, or the electric heating wire 8 may be spirally extended around the single-layer pipe body so as to increase the heating area of the electric heating wire.

In addition, in the fourth type of the heat insulating structure, referring to fig. 13, the outer surface of the single-layered pipe body is wrapped with the heat insulating layer 9. The heat preservation layer 9 can strengthen the heat preservation capability, and the heat preservation material of the heat preservation layer 9 can be soft material, and has no obvious influence on the softness of the breathing gas pipe. Or an electric heating wire 8 is arranged in the pipe wall of the single-layer pipe body, and a heat preservation layer 9 is wrapped on the outer surface of the single-layer pipe body.

In addition, referring to the various embodiments shown in fig. 3, 4, 6, 8-9, 10, 11-16, the gas delivery tube body 1 comprises a gas delivery retention structure that, when the gas delivery tube body 1 is deformed by being compressed at least in part, causes the gas delivery channel 2 to have a gas delivery gap 3 at the deformation that retains gas delivery. The air delivery gap 3 can prevent the deformation part from being completely extruded and sealed and cannot be ventilated, so that the air delivered by the air delivery channel 2 can be delivered through the air delivery gap 3, and the adverse effect on the treatment of a patient is avoided.

In one embodiment, the gas transmission maintaining structure may include any of the above-mentioned heat insulating structures, for example, an electric heating wire, a heat insulating layer, and the like, which may further enhance the anti-extrusion strength of the gas transmission pipe body 1, for example, the heat insulating space 7 between the inner pipe and the outer pipe, or the heat insulating layer disposed in the heat insulating space 7, and the like, which may also further enhance the anti-extrusion strength of the gas transmission pipe body 1.

In one embodiment, the gas transmission structure is a reinforcing structure formed on the outer surface of the gas transmission pipe body 1, such as a spiral rib, and the reinforcing structure can further reinforce the anti-extrusion deformation strength of the gas transmission pipe body 1, so that when at least part of the gas transmission pipe body 1 is extruded and deformed, the deformation degree of the gas transmission channel 2 can be reduced to avoid complete extrusion and sealing of the gas transmission channel 2 at the extrusion part and incapability of ventilation, and a gas transmission gap 3 is formed at the deformation part, so that gas transmitted by the gas transmission channel 2 can be transmitted through the gas transmission gap 3, and adverse effects on treatment of a patient are avoided.

In one embodiment, the gas retention structure is provided on the channel inner surface 16 of the gas delivery channel 2, so that the gas retention structure on the channel inner surface 16 makes it easier to form the gas delivery gap 3 directly in the gas delivery channel.

The gas retaining structure may have the same dimensions in the radial direction. Or, in addition, in order to further reduce the occupation of the gas delivery channel 2 to minimize the influence on the delivered gas, the width dimension of the cross section of the gas delivery structure is kept tapered in the radially inward direction. In this way, the occupation of the gas delivery channel 2 can be reduced as much as possible, while ensuring a stable and reliable connection between the gas delivery structure and the channel inner surface 16 through a large contact area, due to the reduced width dimension.

In addition, in one embodiment, the gas retaining structure includes a support bar having opposite ends attached to respective opposite surface portions of the channel inner surface 16. Alternatively, the gas transmission structure includes a projection 17 projecting inward from the inner surface 16 of the passage, the projection 17 extending in the axial direction of the gas transmission passage 2, and when the gas transmission pipe body 1 is deformed by being pressed, the projection 17 can be brought into contact with an opposing structure on the inner surface 16 of the passage to form the gas transmission gap 3 on at least one circumferential side of the projection 17, referring to fig. 8, 9, 14 and 15. The projection 17 effectively reduces the occupation of the gas transmission channel 2 with respect to the support bar.

In addition, the opposing structure may be of various types, for example, one type of opposing structure, the opposing structure being an inner surface portion 18 of the channel inner surface 16 that is diametrically opposed to the projection 17. Referring to fig. 9 and 15, at this time, regardless of whether the number of the projections 17 is 1 or a plurality, such as two, three, four, or five, when the air delivery pipe is compressed, such as crushed or folded, the projections 17 will come into contact with the inner surface portion 18 to form the air delivery gap 3 on at least one circumferential side of the projections 17.

Of course, the protrusions 17 may be one or more and circumferentially spaced, and the circumferentially spaced arrangement of the plurality of protrusions 17 may effectively improve the gas transmission maintaining capability of the gas transmission pipe body 1, for example, the gas transmission gap 3 can be formed by the protrusions 17 at the corresponding positions no matter where the positions are pressed.

Correspondingly, in another type of opposing arrangement, referring to fig. 8 and 14, the protrusions 17 are multiple and circumferentially spaced, the opposing arrangement being the protrusions 17 on the channel inner surface 16 radially opposite the protrusions 17. Thus, when the gas delivery pipe is squeezed, for example, collapsed or folded, the two protrusions 17 will come into contact to form the gas delivery gap 3 on at least one circumferential side of the protrusions 17, and the two protrusions 17 in contact can increase the size of the gas delivery gap 3, improving the ability to maintain gas delivery.

Of course, the opposing structure may also be other bumps or protrusions formed on the channel inner surface 16 than the protrusions 17.

In addition, the cross-section of the protrusion 17 may have various shapes, such as a rectangular shape, that is, the protrusions 17 have the same size in the radial direction. In one embodiment, in order to minimize the occupation of the gas delivery channel 2 by the projection 17 and to improve the gas delivery retention capacity, the width dimension of the cross section of the projection 17 is tapered in a radially inward direction. For example, the cross-sectional shape of the projection 17 may be trapezoidal, triangular, or semicircular, etc.

In addition, referring to fig. 16, in one embodiment, the cross-sectional shape of the protrusion 17 is a peak 14. In this way, the spike 14 itself can reduce the occupation of the gas transmission channel 2.

In addition, at least one peak side surface 15 adjacent to the peak 14 in the circumferential direction is an inner concave arc surface. In this way, the peak 14 itself can reduce the occupation of the gas transmission channel 2, while the concave arc-shaped surface can further reduce the occupation of the peak 14 on the gas transmission channel 2, which can further improve the gas transmission holding capacity at the extrusion deformation.

Furthermore, the utility model provides a nasal catheter, this nasal catheter include air supply connecting terminal, patient interface and above arbitrary breathe the gas-supply pipe, wherein, breathe the one end and the air supply connecting terminal connection of gas-supply pipe, breathe the other end and the patient interface connection of gas-supply pipe. In this way, the overall performance of the nasal catheter is improved.

Finally, the utility model provides a ventilation treatment device, which comprises the nasal catheter. The ventilation treatment equipment can be a breathing machine or a high-flow oxygen therapy instrument.

The preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, however, the present invention is not limited to the details of the above embodiments, and the technical concept of the present invention can be within the scope of the present invention to perform various simple modifications to the technical solution of the present invention, and these simple modifications all belong to the protection scope of the present invention.

It should be noted that the various features described in the above embodiments may be combined in any suitable manner without departing from the scope of the invention. In order to avoid unnecessary repetition, the present invention does not separately describe various possible combinations.

In addition, various embodiments of the present invention can be combined arbitrarily, and the disclosed content should be regarded as the present invention as long as it does not violate the idea of the present invention.

Claims (28)

1. The utility model provides a breathe gas-supply pipe, breathe the gas-supply pipe and be used for carrying gas to patient's interface, its characterized in that, breathe the gas-supply pipe including gas transmission body (1), gas transmission body (1) is including gas transmission passageway (2) and be used for right gas transmission in gas transmission passageway (2) carries out heat retaining insulation structure.

2. The respiratory gas delivery conduit according to claim 1, wherein the insulation structure comprises a multi-layer insulation structure arranged in a radial direction.

3. The respiratory gas delivery pipe according to claim 1, wherein the heat preservation structure enables the deformation part of the gas delivery channel (2) to have a gas delivery gap (3) for maintaining gas delivery when at least part of the gas delivery pipe body (1) is extruded and deformed.

4. The respiratory gas delivery pipe according to claim 1, wherein the gas delivery pipe body (1) comprises an inner pipe (4) and an outer pipe (5), the outer pipe (5) is sleeved outside the inner pipe (4), a pipe support rib (6) for supporting the inner pipe and the outer pipe is arranged between the inner pipe (4) and the outer pipe (5), so that a heat preservation interval (7) is formed between the inner pipe (4) and the outer pipe (5), an internal channel of the inner pipe (4) serves as the gas delivery channel (2), and the heat preservation structure comprises the heat preservation interval (7).

5. The respiratory gas delivery pipe according to claim 4, wherein one radial end of the pipe support rib (6) is integrally formed with the inner pipe (4) and the other radial end of the pipe support rib (6) is integrally formed with the outer pipe (5);

alternatively, the first and second electrodes may be,

one end of the tube support rib (6) in the radial direction is integrally formed with one of the inner tube (4) and the outer tube (5), and the other end of the tube support rib (6) in the radial direction is not integrally formed with the other of the inner tube (4) and the outer tube (5).

6. The breathing gas delivery pipe according to claim 4, characterized in that the heat-insulating spacer (7) is a closed cavity.

7. The breathing gas pipe according to claim 6, wherein a liquid outlet and a side wall door body capable of opening and closing the liquid outlet are arranged on the outer side wall of the heat preservation space (7).

8. The respiratory gas delivery conduit according to claim 4, wherein the thermal insulation structure comprises an electric heating wire (8), the electric heating wire (8) being arranged in a conduit wall of at least one of the inner conduit (4) and the outer conduit (5).

9. The respiratory gas delivery conduit according to claim 8, characterized in that the electrical heating wire (8) extends axially straight or spirally around the conduit.

10. The breathing gas pipe according to claim 4, wherein the heat insulation structure comprises a heat insulation layer (9), and the heat insulation layer (9) is filled in the heat insulation space (7).

11. The respiratory gas delivery pipe according to claim 4, characterized in that at least one of the inner side surface (10) and the outer side surface (11) of the heat-insulating space (7) is provided with a maintaining air space structure which maintains the air space (12) at the deformation when the outer pipe (5) is deformed by being pressed at least partially.

12. The respiratory gas delivery conduit according to claim 11, wherein the air space maintaining structure comprises a protruding portion (13) protruding from at least one of the inner side surface (10) and the outer side surface (11) of the insulation space (7), the protruding portion (13) being capable of contacting an opposing structure within the insulation space (7) when the outer tube (5) is compressed and deformed to form the air space (12) on at least one circumferential side of the protruding portion (13).

13. The respiratory gas delivery conduit according to claim 12, characterized in that the raised portions (13) are provided in plurality and are arranged at intervals in the circumferential direction, and the opposite structure is a side surface of the heat-retaining space (7) which is diametrically opposite to the raised portions (13), or the opposite structure is an opposite raised portion (13) which protrudes from the side surface of the heat-retaining space (7) which is diametrically opposite to the raised portions (13).

14. The respiratory gas delivery pipe according to claim 12, wherein the cross-sectional shape of the convex part (13) is a peak (14), and the peak side surface (15) which is circumferentially adjacent to the peak (14) is an inner concave arc surface.

15. The respiratory gas delivery pipe according to claim 1, wherein the heat insulation structure comprises a heat insulation layer (9), the gas delivery pipe body (1) comprises an inner pipe (4) and an outer pipe (5), the outer pipe (5) is supported and sleeved outside the inner pipe (4) through the heat insulation layer (9), and an inner channel of the inner pipe (4) serves as the gas delivery channel (2).

16. The respiratory gas delivery pipe according to claim 1, wherein the gas delivery pipe body (1) is a single-layer pipe body, an electric heating wire (8) is arranged in the pipe wall of the single-layer pipe body, and/or an insulating layer (9) is wrapped on the outer surface of the single-layer pipe body.

17. The respiratory gas delivery conduit according to any one of claims 1 to 16, wherein the gas delivery pipe body (1) comprises a gas retention structure which, when the gas delivery pipe body (1) is deformed by being compressed at least locally, causes the gas delivery channel (2) to have a gas delivery gap (3) at the deformation for gas delivery.

18. The respiratory gas delivery conduit according to claim 17, wherein the gas retention delivery structure is provided on the inner channel surface (16) of the gas delivery channel (2).

19. The respiratory gas delivery conduit according to claim 18, wherein the transverse cross-sectional width dimension of the retention gas delivery structure tapers in a radially inward direction.

20. The respiratory gas delivery conduit according to claim 18, wherein the gas delivery retention structure comprises a protrusion (17) projecting inwardly from the inner surface (16) of the passage, the protrusion (17) extending in the axial direction of the gas delivery passage (2), the protrusion (17) being adapted to contact an opposing structure on the inner surface (16) of the passage when the gas delivery conduit body (1) is deformed by being squeezed so as to form the gas delivery gap (3) on at least one circumferential side of the protrusion (17).

21. The respiratory gas delivery conduit according to claim 20, wherein the opposing structure is an inner surface portion (18) of the channel inner surface (16) that is diametrically opposite the protuberance (17).

22. The respiratory gas delivery conduit according to claim 20, wherein the protrusions (17) are plural and arranged at intervals in the circumferential direction.

23. The respiratory gas delivery conduit according to claim 20, wherein the opposing structure is a projection (17) on the inner surface (16) of the channel that is diametrically opposite the projection.

24. The respiratory gas delivery conduit according to claim 20, wherein the cross-sectional width dimension of the projection (17) tapers in a radially inward direction.

25. The respiratory gas delivery conduit according to claim 24, wherein the cross-sectional shape of the projection (17) is a peak (14).

26. The respiratory gas delivery conduit according to claim 25, wherein at least one peak side surface (15) circumferentially adjacent to the peak (14) is an inner concave arc surface.

27. A nasal catheter comprising an air supply connection terminal, a patient interface and a respiratory air delivery conduit according to any of claims 1 to 26, wherein one end of the respiratory air delivery conduit is connected to the air supply connection terminal and the other end of the respiratory air delivery conduit is connected to the patient interface.

28. A ventilation therapy device comprising a nasal cannula according to claim 27.

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