CN204671688U - Respiratory organ structure - Google Patents

Abstract

The utility model discloses a kind of respiratory organ structure, comprise the gas supply device being provided with feedway body, shock-absorbing module and gas generation module.Feedway body is hollow housing structure, has accommodation space, and feedway body one side has the first through hole.Shock-absorbing module installation, at accommodation space, is sequentially stacked by described inwall of feedway body and comprises basal layer; Runner layer, adjacent paracentral inside has passage, and runner layer side has access portal, access portal communicating passage and accommodation space; Bearing bed, the center of one side is recessed to form supporting part towards another side, and runs through another side to form carrying opening.Gas generation module one side has air inlet, and side has outlet, and the part body of the corresponding air inlet of gas generation module is contained in supporting part movably.This utility model, by arranging shock-absorbing module, absorbs gas generation module and operates the vibrations produced, and reaches and solves the problem that described vibrations easily produce noise.

Description

Respiratory organ structure

Technical field

This utility model has to relate to one and comprise respiratory organ technical field, also specifically, is have to relate to a kind of respiratory organ structure arranging multi-layer vibration absorption structure in gas supply device.

Background technology

" snoring " caused because of upper respiratory tract obstruction, the origin cause of formation is such as fat, advanced age tissue deterioration, the narrow person of upper respiratory tract etc., this kind of patient can cause airway collapse because of the of flaccid muscles of bottleneck throat in bed, make air cannot enter pulmonary smoothly, cause blood oxygen concentration too low, now brain can be experienced anoxia and order physical effort and breathes, thus of short duration reviving is caused, the phase of sleeping soundly cannot be entered smoothly, sometimes tens of times can be occurred an evening, even hundred times, namely this suffer from so-called " Sleep Apnea disease ", it can cause patient to be just in awake state of wakeing up the whole night, excellent sleep quality cannot be enjoyed, WA is had a headache indirectly to cause to occur daytime, easily drowsiness or doze, absent minded, hypomnesis, anxiety, personality change, degradation under libido, then have snoring in the evening, the situations such as pollakiuria, and easily cause cardiovascular related diseases.

Usually the therapeutic modality of above-mentioned " Sleep Apnea disease ", if the slight person of situation can pass through motion, sleep in loss of weight, side, sleep before avoid drinking or take sleeping pill, (facing) etc. is improved to wear snore stopper, but when if situation is serious, just must based on the positive pressure respirator of operative treatment or Noninvasive, wherein said positive pressure respirator collocation face shield uses, effect can be treated up to more than ninety percent, it utilizes to put on face shield in bed, the pressure produced by respiratory organ props up soft respiratory tract, unobstructed with Hold up voltage road.

Current respiratory organ contains gas supply device and damping device, and gas supply device, after generation gas, by gas transmission to damping device, then supplies via damping device and draws to user.But, traditional gas supply device because of inner shockproof structure perfect not, causing the inner aerator of gas supply device when operating, easily producing larger noise, make the sleep that user cannot be stable.Further, the vibrational power flow also imperfection of traditional damping device, easily produces damping device internal liquid adverse current in gas supply device.Moreover the combination of stream oriented device and detaching structure are easily too complicated, make user operate not easily.

Utility model content

Because the problem of above-mentioned existing skill, the object of this utility model is providing a kind of respiratory organ structure, exactly to solve the disappearance existing for prior art.

According to one of this utility model object, a kind of respiratory organ structure is proposed, air inclusion feedway.Gas supply device comprises feedway body, shock-absorbing module and gas generation module.Feedway body is hollow housing structure, has accommodation space, and the one side of feedway body has the first through hole, and the side of feedway body has the second through hole.Shock-absorbing module installation is at accommodation space, and shock-absorbing module is sequentially stacked by a described inwall of the first through hole corresponding to feedway body and comprises: basal layer; Runner layer, adjacent paracentral inside has at least one passage, and the side of runner layer has access portal, and access portal is communicated with at least one passage and accommodation space; Bearing bed, the center of one side is recessed to form supporting part towards another side, and runs through another side to form carrying opening.Gas generation module one side has air inlet, the side of gas generation module has outlet, the part body of the corresponding air inlet of gas generation module is contained in supporting part movably, and air inlet correspondence is located in carrying opening, and outlet one end vicinity is at the second through hole.Wherein, gas flow at least one passage via the first through hole, accommodation space and access portal, gas generation module draws the gas at least one passage by air inlet, to produce air-flow, and utilizes outlet to discharge air-flow to feedway body exterior via the second through hole.

Wherein, bearing bed can comprise the first supporting substrate and the second supporting substrate.First supporting substrate vicinity at runner layer, and has carrying opening.Second supporting substrate is arranged on the one side of the first supporting substrate back to runner layer, and the center of the second supporting substrate has supporting part.

Wherein, the outer peripheral edge of described first supporting substrate can be greater than the outer peripheral edge of described second supporting substrate.

Wherein, the thickness of described first supporting substrate can be less than the thickness of described second supporting substrate.

Wherein, gas supply device preferably also can comprise multiple locating module and shock-absorbing covering module.Multiple locating module is rod-like structure, and one end of each locating module is connected to described inwall of feedway body, and is looped around shock-absorbing module.It is shell structure that shock-absorbing hides module, the periphery of shock-absorbing covering module is removably connected to the other end of multiple locating module, shock-absorbing hides the one side of module and to cave inward formation shielding part, shielding part has buffer layer, and shock-absorbing hides the part outer rim of module by the coated gas generation module of buffer layer.

Wherein, gas supply device preferably also can air inclusion transport module, for hollow structure, gas transmission module installation is at the second through hole, one end of gas transmission module is removably connected to the described end of outlet, be exposed at the outside of feedway body outside the other end of gas transmission module, and when gas generation module produces air-flow and utilizes outlet to discharge air-flow, air-flow then flow to feedway body exterior via gas transmission module.

Wherein, respiratory organ structure preferably also can comprise damping device, comprises accommodation device body and water conservancy diversion module.Accommodation device body is hollow housing structure, and has accommodation space, and with accommodating liquid, the side of accommodation device body has the first port, and the one side of accommodation device body has the second port, and the pre-set level height of liquid is lower than the second port.Water conservancy diversion module is tubular structure, and be located in the first port, one end of water conservancy diversion module has input port, input port is positioned at the outside of accommodation device body, and removably connect the other end of gas transmission module, the other end of water conservancy diversion module has delivery outlet, and delivery outlet is arranged in accommodation space, and delivery outlet can towards described of accommodation device body.Wherein, when input port receives air-flow, air-flow then flow in accommodation space via delivery outlet, and with the dampness produced in conjunction with liquid, and the moist air-flow of tool flow to accommodation device body exterior via the second port.

Wherein, one side and the another side of accommodation device body have default angle, and default angle can between 20 ~ 30 degree.

Wherein, default angle can be 25 degree.

Wherein, gas supply device preferably also can comprise conduction device, for tubular structure, outside conduction device, cave in gradually towards center in the contiguous two ends place of body, and one end of conduction device is removably connected to the outlet of gas generation module, the other end of conduction device is removably connected to the described end of gas transmission module.

Wherein, the contiguous two ends place of conduction device inwall forms buckling parts to outer wall respectively, and conduction device is fastened on the described end of outlet and gas transmission module respectively by each buckling parts, to be communicated with the described end of described outlet and described gas transmission module.

Wherein, the outer peripheral edge, side of the described side of accommodation device body stretches out formation extension, the part body of the described one side of the corresponding accommodation device body of extension has impenetrating mouth, and respiratory organ structure preferably also can comprise buckle device, and buckle device comprises press component and conjugative component.The inside of press component one side outwardly forms press section, and press component flexibly can be arranged on extension, and press section is located in impenetrating mouth, and the contiguous side place of described one side of press component stretches out and forms at least one first buckle portion.Conjugative component one end stretches out and forms at least one joint portion, and at least one joint portion is removably combined in the another side of press component, and the both sides of the other end of conjugative component form the second buckle portion respectively to extension.Wherein, corresponding at least one first buckle portion, face, described side of feedway body and multiple second buckle portion have at least one first holding section and multiple second holding section respectively, and buckle device is removably fastened at least one first holding section and multiple second holding section, with bound gas feedway and damping device by least one first buckling parts and multiple second buckle portion.

Wherein, press section by natural compression and drive at least one first buckle portion and multiple second buckle portion to be moved to the second position by primary importance, and gas supply device by external force away from damping device time, gas supply device is then separated with damping device.

From the above, according to respiratory organ structure of the present utility model, one or more following advantage can be had:

(1) this respiratory organ structure is by the setting of shock-absorbing module, the vibrations produced during to absorb the running of gas generation module, easily produces the problem of noise when can solve the running of gas generation module by this.

(2) this respiratory organ structure hides the buffer layer of module by shock-absorbing, the vibrations produced during to absorb the running of gas generation module, easily produces the problem of noise when can solve the running of gas generation module by this.

(3) this respiratory organ structure by by the design of the delivery outlet of water conservancy diversion module towards described of accommodation device body, avoid liquid countercurrent in accommodation device body in gas supply device by this.

(4) this respiratory organ structure is by being cave in conduction device structural design gradually towards center in the contiguous two ends place of outside body, can reduce gas supply device by this by gas transmission to the noise produced during damping device.

(5) this respiratory organ structure is by the setting of buckle device, makes gas supply device to be combined fast with damping device or to dismantle, and can improve the convenience using respiratory organ by this.

Accompanying drawing explanation

Fig. 1 is the schematic diagram of the first embodiment of respiratory organ structure of the present utility model.

Fig. 2 is the shock-absorbing module diagram of respiratory organ structure of the present utility model.

Fig. 3 is bearing bed first schematic diagram of respiratory organ structure of the present utility model.

Fig. 4 is bearing bed second schematic diagram of respiratory organ structure of the present utility model.

Fig. 5 is the schematic diagram of the second embodiment of respiratory organ structure of the present utility model.

Fig. 6 is that the shock-absorbing of respiratory organ structure of the present utility model hides module upward view.

Fig. 7 is the schematic diagram of the 3rd embodiment of respiratory organ structure of the present utility model.

Fig. 8 is the schematic diagram of the 4th embodiment of respiratory organ structure of the present utility model.

Fig. 9 is the schematic diagram of the 4th embodiment of respiratory organ structure of the present utility model.

Figure 10 is the buckle device schematic diagram of respiratory organ structure of the present utility model.

Detailed description of the invention

In order to be beneficial to the effect your auditor understands technical characteristic of the present utility model, content and advantage and can reach, hereby this utility model is coordinated accompanying drawing, and be described in detail as follows with the expression-form of embodiment, and wherein used accompanying drawing, purport is only the use of signal and aid illustration book, for the actual proportions after this utility model enforcement and precisely may not configure, therefore the ratio of accompanying drawing that should be just not appended and configuration relation limit to the right of this utility model on reality is implemented, conjunction is first chatted bright.

Hereinafter with reference to relevant drawings, the embodiment according to respiratory organ structure of the present utility model is described, for making to be convenient to understand, the similar elements in following embodiment is labeled the same reference numeral to illustrate.

Please refer to Fig. 1 to Fig. 4, be respectively the schematic diagram of the first embodiment of respiratory organ structure of the present utility model, shock-absorbing module diagram, bearing bed show first intention and bearing bed second schematic diagram.As shown in the figure, respiratory organ structure 1 air inclusion feedway 10.Gas supply device 10 comprises feedway body 100, shock-absorbing module 101 and gas generation module 102.Feedway body 100 is hollow housing structure, has accommodation space 1000, and the one side of feedway body 100 has the first through hole 1001, and the side of feedway body 100 has the second through hole 1002.Shock-absorbing module 101 is arranged on accommodation space 1000, and shock-absorbing module 101 is sequentially stacked by a described inwall of the first through hole 1001 corresponding to feedway body 100 and comprises: basal layer 1010; Runner layer 1011, adjacent paracentral inside has at least one path 10 110, and the side of runner layer 1011 has access portal 10111, and access portal 10111 is communicated with at least one path 10 110 and accommodation space 1000; Bearing bed 1012, the center of one side is recessed to form supporting part 10120 towards another side, and runs through another side to form carrying opening 10121.Gas generation module 102 one side has air inlet 1020, the side of gas generation module 102 has outlet 1021, the part body of the corresponding air inlet 1020 of gas generation module 102 is contained in supporting part 10120 movably, and air inlet 1020 correspondence is located in carrying opening 10121, and outlet 1021 one end vicinity is at the second through hole 1002.Wherein, gas 2 (such as air) flow at least one path 10 110 via the first through hole 1001, accommodation space 1000 and access portal 10111, gas generation module 102 draws the gas 2 at least one path 10 110 by air inlet 1020, to produce air-flow 1022, and outlet 1021 is utilized to discharge air-flow 1022 to feedway body 100 outside via the second through hole 1002.

Specifically, respiratory organ structure 1 of the present utility model is by the setting of shock-absorbing module 101, absorb the vibrations produced when gas generation module 102 operates, to solve the problem easily producing noise when gas generation module 102 operates, and then provide user preferred sleep environment, and improve the sleep quality of user.Gas supply device 10 of the present utility model comprises feedway body 100, shock-absorbing module 101 and gas generation module 102.Feedway body 100 is hollow housing structure, feedway body 100 one side has the first through hole 1001, be communicated with accommodation space 1000 outside with feedway body 100, feedway body 100 side also has the second through hole 1002, is communicated with accommodation space 1000 outside with feedway body 100.Be provided with shock-absorbing module 101 in accommodation space 1000, shock-absorbing module 101 sequentially stacks basal layer 1010, runner layer 1011 and bearing bed 1012 by described inwall of the first through hole 1001 corresponding to feedway body 100.Basal layer 1010 is at the bottom, runner layer 1011 is positioned at intermediate layer, runner layer 1011 center has at least one path 10 110, and runner layer 1011 side has access portal 10111, and access portal 10111 is communicated with at least one path 10 110 and accommodation space 1000.Bearing bed 1012 is in the superiors, the center of bearing bed 1012 one side is recessed to form supporting part 10120 towards another side, supporting part 10120 can carry gas generation module 102, and supporting part 10120 runs through another side to form carrying opening 10121, carrying opening 10121 communicates with at least one path 10 110, shock-absorbing module 101 can be shock-absorbing material, as sponge or silica gel etc., not as limit.Gas generation module 102 one side has air inlet 1020, and gas generation module 102 side has outlet 1021, gas generation module 102 part body is contained in supporting part 10120 movably, air inlet 1020 also correspondence is located in carrying opening 10121, and be exposed at least one path 10 110 outward, and outlet 1021 part body vicinity is at the second through hole 1002, gas generation module 102 can be aerator.

Respiratory organ structure 1 of the present utility model gas supply device 10 operate time, extraneous gas 2 enters in accommodation space 1000 via the first through hole 1001 of feedway body 100, and is flow at least one path 10 110 by access portal 10111.Then, gas generation module 102 draws the gas 2 at least one path 10 110 by air inlet 1020, to produce air-flow 1022, and utilizes outlet 1021 to discharge air-flow 1022 to feedway body 100 outside via the second through hole 1002.Wherein, outlet 1021 can connect at least one conduit and breathing mask, and air-flow 1022 is drawn use via conduit and breathing mask supply user.And while gas generation module 102 operates, the vibrations that bearing bed 1012 Absorbable rod gas generation module 102 produces, runner layer 1011 also Absorbable rod bearing bed 1012 vibrations of conducting.By this, the sound produced when gas generation module 102 operates can be solved, to provide user preferred sleep environment, and improve the sleep quality of user.

Say further, bearing bed 1012 of the present utility model can comprise the first supporting substrate 1012A and the second supporting substrate 1012B.First supporting substrate 1012A is contiguous at runner layer 1011, and has carrying opening 10121.Second supporting substrate 1012B is arranged on the one side of the first supporting substrate 1012A back to runner layer 1011, and the center of the second supporting substrate 1012B has supporting part 10120.

That is, bearing bed 1012 of the present utility model can divide into the first supporting substrate 1012A and the second supporting substrate 1012B further.As shown in Figure 3, first supporting substrate 1012A position in runner layer 1011 one side, center have carrying opening 10111, second supporting substrate 1012B then position in the one side of the first supporting substrate 1012A back to runner layer 1011, second supporting substrate 1012B is hollow structure, forms supporting part 10120.Therefore, when gas generation module 102 operates, the second supporting substrate 1012B first can absorb the vibrations that gas generation module 102 produces, meanwhile, and the first supporting substrate 1012A also Absorbable rod second supporting substrate 1012B vibrations of conducting.By this, the efficiency absorbing the vibrations that gas generation module 102 produces can be improved.

In addition, the outer peripheral edge of the first supporting substrate 1012A of the present utility model can be greater than the outer peripheral edge of the second supporting substrate 1012B.Further, the thickness of the first supporting substrate 1012A can be less than the thickness of the second supporting substrate 1012B.As shown in Figure 4, respiratory organ structure 1 of the present utility model, by increasing the thickness of the second supporting substrate 1012B, with the vibrations produced when significantly mitigation of gases generation module 102 operates, and then makes respiratory organ structure 1 can reach quiet effect when operating.

Please refer to Fig. 5 and Fig. 6, the schematic diagram and the shock-absorbing that are respectively the second embodiment of respiratory organ structure of the present utility model hide module upward view.And please with reference to Fig. 1 to Fig. 4.As shown in the figure, the similar elements described in the respiratory organ structure of the respiratory organ structure in the present embodiment and above-described embodiment to make flowing mode similar, therefore not to be repeated.But it is worth mentioning that, in the present embodiment, gas supply device 10 preferably also can comprise multiple locating module 103 and shock-absorbing hides module 104.Multiple locating module 103 is rod-like structure, and one end of each locating module 103 is connected to described inwall of feedway body 100, and is looped around shock-absorbing module 101.It is shell structure that shock-absorbing hides module 104, the periphery of shock-absorbing covering module 104 is removably connected to the other end of multiple locating module 103, the one side of shock-absorbing covering module 104 caves inward and forms shielding part 1040, shielding part 1040 has buffer layer 1041, and shock-absorbing hides the part outer rim of module 104 by the coated gas generation module 102 of buffer layer 1041.

For example, gas supply device 10 of the present utility model can comprise multiple locating module 103 and shock-absorbing covering module 104 further.Multiple locating module 103 is rod-like structure, and multiple locating module 103 is erected in the accommodation space 1000 of feedway body 100 respectively, and is looped around shock-absorbing module 101.It is the shell structure that one side caves inward that shock-absorbing hides module 104, the periphery of shock-absorbing covering module 104 is removably connected to the other end of multiple locating module 103, the one side of shock-absorbing covering module 104 caves inward and forms shielding part 1040, shielding part 1040 has buffer layer 1041, and shock-absorbing hides the part outer rim of module 104 by the coated gas generation module 102 of buffer layer 1041.

By this, when gas generation module 102 operates, except utilize shock-absorbing module 101 the to absorb vibrations that gas generation module 102 produces of above-mentioned first embodiment, this utility model also absorbs by buffer layer 1041 vibrations that gas generation module 102 produces, to improve the efficiency of absorbing vibration, significantly reduce the sound produced when gas generation module 102 operates.

Say further, gas supply device 10 preferably also can air inclusion transport module 105, for hollow structure, gas transmission module 105 is arranged on the second through hole 1002, one end of gas transmission module 105 is removably connected to the described end of outlet 1021, the outside of feedway body 100 is exposed at outside the other end of gas transmission module 105, and when gas generation module 102 produces air-flow 1022 and utilizes outlet 1021 to discharge air-flow 1022, it is outside that 1022, air-flow flow to feedway body 100 via gas transmission module 105.

That is, gas supply device 10 of the present utility model can arrange gas transmission module 105 at the second through hole 1002 of feedway body 100 further, one end of gas transmission module 105 is connected to outlet 1021, is exposed at the outside of feedway body 100 outside the other end of gas transmission module 105.Therefore, after gas generation module 102 produces air-flow 1022, air-flow 1022 can flow to feedway body 100 outside by outlet 1021 by gas transmission module 105.Wherein, the other end of gas transmission module 105 also can connect at least one conduit and breathing mask, and user can draw through breathing mask thus and conduit the air-flow 1022 that outlet 1021 carries.

Please refer to Fig. 7, is the schematic diagram of the 3rd embodiment of respiratory organ structure of the present utility model.And please with reference to Fig. 1 to Fig. 6.As shown in the figure, the similar elements described in the respiratory organ structure of the respiratory organ structure in the present embodiment and the various embodiments described above to make flowing mode similar, therefore not to be repeated.But it is worth mentioning that, in the present embodiment, respiratory organ structure 1 preferably also can comprise damping device 11, comprises accommodation device body 110 and water conservancy diversion module 111.Accommodation device body 110 is hollow housing structure, and there is accommodation space 1100, with accommodating liquid 3, the side of accommodation device body 110 has the first port 1101, the one side of accommodation device body 110 has the second port 1102, and the pre-set level height of liquid 3 is lower than the second port 1102.Water conservancy diversion module 111 is tubular structure, and be located in the first port 1101, one end of water conservancy diversion module 111 has input port 1110,1110, input port is outside at accommodation device body 110, and removably connect the other end of gas transmission module 105, the other end of water conservancy diversion module 111 has delivery outlet 1111, and delivery outlet 1111 is arranged in accommodation space 1100, and delivery outlet 111 can towards described of accommodation device body 110.Wherein, when input port 1110 receives air-flow 1022,1022, air-flow flow in accommodation space 1100 via delivery outlet 1111, and with the dampness produced in conjunction with liquid 3, and the moist air-flow 1022 of tool flow to accommodation device body 110 outside via the second port 1102.

Specifically, respiratory organ structure 1 of the present utility model also can comprise damping device 11 further, comprises accommodation device body 110 and water conservancy diversion module 111.Accommodation device body 110 is hollow housing structure, there is accommodation space 1100, for accommodating liquid 3 (such as water), and accommodation device body 110 side is provided with the first port 1101, outside with accommodation device body 110 to be communicated with accommodation space 1100, accommodation device body 110 one side also has the second port 1102, same connection accommodation space 1100 is outside with accommodation device body 110, liquid 3 in accommodation space 1100 has pre-set level height, such as 3 or 5 centimeters etc., not as limit.Pre-set level height lower than second port 1102, second port 1102 height lower than the first port 1101.Namely, the distance of pre-set level height and accommodation device body 110 bottom surface, is less than the distance of the second port 1102 and accommodation device body 110 bottom surface, relatively, second port 1102 and the distance of accommodation device body 110 bottom surface, be less than the distance of the first port 1101 and accommodation device body 110 bottom surface.

Water conservancy diversion module 111 is hollow tubular structure, is located in the first port 1101, and extends in accommodation space 1100.Water conservancy diversion module 111 one end has input port 1110, and input port 1110 is positioned at the outside of accommodation device body 110, is removably connected to the other end of gas transmission module 105; Water conservancy diversion module 111 other end has delivery outlet 1111, and delivery outlet 1111 is arranged in accommodation space 1100, and towards described of accommodation device body 110.

When gas supply device 10 utilizes gas generation module 102 to produce air-flow 1022 and discharges via gas transmission module 105, water conservancy diversion module 111 receives air-flow 1022 by input port 1110, and is delivered in accommodation space 1100 by air-flow 1022 via delivery outlet 1111.Afterwards, after the dampness that the air-flow 1022 in accommodation space 1100 and liquid 3 produce is combined, flow to the outside of accommodation device body 110 via the second port 1102.Wherein, the second port 1102 also can connect at least one conduit and breathing mask, and user can draw via breathing mask and conduit the moist air-flow 1022 of tool that the second port 1102 carries.And, when user accidentally causes damping device 11 to rock and makes the liquid 3 in accommodation space 1100 produce fluctuation, because delivery outlet 1111 is towards the end face of accommodation device body 110, therefore, liquid 3 cannot enter delivery outlet 1111, also cannot flow to gas supply device 10.

By this, delivery outlet 1111, by the structural design by water conservancy diversion module 111, is designed to towards the end face of accommodation device body 110 by respiratory organ structure 1 of the present utility model, to avoid liquid 3 adverse current in accommodation device body 110 in gas supply device 10.

In addition, damping device 11 also can comprise heating component (not illustrating in the drawings), such as heating cushion, be arranged on bottom accommodation device body 110, heating component by signal control and to when heating bottom accommodation device body 110, liquid in accommodation device body 110 3 absorbs the heat energy that heating component produces, and produces dampness in accommodation space 1100.

In above-described embodiment, water conservancy diversion module 111 can be L-type hollow tubular structure.Further, accommodation device body 110 one side has default angle a with another side, and presetting angle a can between 20 ~ 30 degree.Preferably, preset angle a and can be 25 degree.Therefore, when the dampness that liquid 3 produces condenses into aqueous body again at the end face of accommodation device body 110 inside, described aqueous body then can be moved to described end face one end away from delivery outlet 1111 along accommodation device body 110 end face, and avoids aqueous body to drop in delivery outlet 1111.

Please refer to Fig. 8, is the schematic diagram of the 4th embodiment of respiratory organ structure of the present utility model.And please with reference to Fig. 1 to Fig. 7.As shown in the figure, the similar elements described in the respiratory organ structure of the respiratory organ structure in the present embodiment and the various embodiments described above to make flowing mode similar, therefore not to be repeated.But, it is worth mentioning that, in the present embodiment, gas supply device 10 preferably also can comprise conduction device 12, for tubular structure, outside conduction device 12, cave in gradually towards center in the contiguous two ends place of body, and one end of conduction device 12 is removably connected to the outlet 1021 of gas generation module 102, and the other end of conduction device 12 is removably connected to the described end of gas transmission module 105.

For example, gas supply device 10 of the present utility model also can arrange conduction device 12 further, to reduce the noise produced when air-flow 1022 is transported to damping device 11 by gas supply device 10.As shown in (b) part in Fig. 8, conduction device 12 can be tubular structure, outside conduction device 12, cave in gradually towards center in the contiguous two ends place of body, slightly become I-shaped, thickness between conduction device 12 two ends external diameter and internal diameter is greater than the thickness between the external diameter of mid portion and internal diameter, and one end of conduction device 12 is connected to outlet 1021, conduction device 12 other end is then connected to the described end of gas transmission module 105.

Therefore, as shown in (a) part in Fig. 8, at gas generation module 102, air-flow 1022 is transferred to via gas transmission module 105 in the process of damping device 11, the place that air-flow 1022 flows through all can produce vibrations, and pass through the thinner structural design of conduction device 12 mid portion, the vibrations that Absorbable rod conducts airflow 1022 produces, and then the noise that reduction transmission airflow 1022 produces.

Furthermore, the contiguous two ends place of conduction device 12 inwall of the present utility model forms buckling parts 120 to outer wall respectively, conduction device 12 is fastened on the described end of outlet 1021 and gas transmission module 105 respectively by each buckling parts 120, to be communicated with the described end of described outlet 1021 and described gas transmission module 105.That is, conduction device 12 two ends inwall can arrange buckling parts 120 respectively, with the described end of the outlet 1021 and gas transmission module 105 that are fastened on gas supply device 10 respectively, and then improve the bonding strength of gas supply device 10 and gas transmission module 105.Wherein, outlet 1021 also may correspond to the projecting integrated structure of buckling parts 120 with the described end of gas transmission module 105.

Please refer to Fig. 9 and Figure 10, be respectively schematic diagram and the buckle device schematic diagram of the 4th embodiment of respiratory organ structure of the present utility model.And see also Fig. 1 to Fig. 8.As shown in the figure, the similar elements described in the respiratory organ structure of the respiratory organ structure in the present embodiment and the various embodiments described above to make flowing mode similar, therefore not to be repeated.But, it is worth mentioning that, in the present embodiment, the outer peripheral edge, side of the described side of accommodation device body 110 stretches out and forms extension 1103, the part body of the described one side of extension 1103 corresponding accommodation device body 110 has impenetrating mouth 1104, respiratory organ structure 1 preferably also can comprise buckle device 13, and buckle device 13 comprises press component 130 and conjugative component 131.The inside of press component 130 one side outwardly forms press section 1300, press component 130 can flexibly be arranged on extension 1103, and press section 1300 can flexibly be arranged on impenetrating mouth 1104, the contiguous side place of described one side of press component 130 stretches out and forms at least one first buckle portion 1301.Conjugative component 131 one end stretches out and forms at least one joint portion 1310, and at least one joint portion 1310 is removably combined in the another side of press component 130, and the both sides of the other end of conjugative component 131 form the second buckle portion 1311 respectively to extension.Wherein, corresponding at least one first buckle portion 1301, described side of feedway body 100 and multiple second buckle portion 1311 have at least one first holding section 1004 and multiple second holding section 1005 respectively, and buckle device 13 is removably fastened at least one first holding section 1004 and multiple second holding section 1005 with multiple 1311, second buckle portion, with bound gas feedway 10 and damping device 11 by least one first buckling parts 1301.

Specifically, respiratory organ structure 1 of the present utility model also can arrange buckle device 13 further, to provide gas supply device to be combined fast with damping device or to dismantle, and then improves the convenience of respiratory organ operation.As shown in (a), (b) part in Figure 10, the outer peripheral edge, side of the described side of accommodation device body 110 can stretch out and form extension 1103, and extension 1103 has impenetrating mouth 1104.The inside of press component 130 one side of buckle device 13 outwardly forms press section 1300, press component 130 can flexibly be arranged on extension 1103, and press section 1300 is located in impenetrating mouth 1104, namely press section 1300 is arranged on extension 1103 by elastic component (not illustrating in figure), to make press section 1300 can carry out shift reciprocately in impenetrating mouth 1104, described contiguous side place of press component 130 also can stretch out formation first buckle portion 1301 (in the present embodiment with exemplarily multiple).Conjugative component 131 one end of buckle device 13 stretches out and forms at least one joint portion 1310, at least one joint portion 1310 is removably combined in the another side of press component 130, and the both sides of the other end of conjugative component 131 form the second buckle portion 1311 respectively to extension.Wherein, conjugative component 131 can be slightly " ㄇ " font.

And corresponding multiple first buckle portion 1301, described side of feedway body 100 and multiple second buckle portion 1311 are also respectively equipped with multiple first holding section 1004 and multiple second holding section 1005.By this, after buckle device 13 utilizes multiple first buckling parts 1301 to be fastened on multiple first holding section 1004 and multiple second holding section 1005 respectively with multiple 1311, second buckle portion, namely gas supply device 10 is combined in damping device 11.

Furthermore, press section 1300 drives at least one first buckle portion 1301 and multiple second buckle portion 1311 to be moved to the second position by primary importance by natural compression, and when gas supply device 10 is by external force away from damping device 11, gas supply device 10 is separated with damping device 11.

That is, dismounting gas supply device 10 or damping device 11 is wanted at user, when gas supply device 10 is separated with damping device 11, user can bestow pressure to press section 1300, press section 1300 is made in impenetrating mouth 1104, to carry out displacement by natural compression, and drive multiple first buckle portions 1301 (in the present embodiment with exemplarily multiple) and multiple second buckle portion 1311 to be moved to the second position by primary importance, namely the first buckle portion 1301 and the second buckle portion 1311 are by being fastened on the position displacement of the first holding section 1004 and the second holding section 1005 to the position departing from the first holding section 1004 and the second holding section 1005.Afterwards, gas supply device 10 can be got from damping device 11 by user, and gas supply device 10 be subject to user take external force time, gas supply device 10 is separated with damping device 11.

Relatively, when user wants bound gas feedway 10 and damping device 11, thrust can be bestowed to gas supply device 10, multiple first buckling parts 1301 and multiple second buckle portion 1311 is pushed against respectively to make multiple first holding section 1004 and multiple second holding section 1005, displacement is produced with multiple second buckle portion 1311 to order about multiple first buckling parts 1301, and then be fastened on multiple first holding section 1004 and multiple second holding section 1005, make gas supply device 10 be combined in damping device 11.

In above-mentioned, the first holding section 1004 is not limited in and arranges one, also can arrange multiple.

The foregoing is only illustrative, but not be restricted person.Anyly do not depart from spirit of the present utility model and category, and to its equivalent modifications of carrying out or also become, all should be included in appended according in claims.

Claims (13)

1. a respiratory organ structure, is characterized in that, comprises:

Gas supply device, comprises:

Feedway body, is hollow housing structure, has accommodation space, and the one side of described feedway body has the first through hole, and the side of described feedway body has the second through hole;

Shock-absorbing module, is arranged on described accommodation space, and shock-absorbing module is sequentially stacked by a described inwall of described first through hole corresponding to described feedway body and comprises:

Basal layer;

Runner layer, adjacent paracentral inside has at least one passage, and the side of described runner layer has access portal, and described access portal is communicated with described at least one passage and described accommodation space; And

Bearing bed, the center of one side is recessed to form supporting part towards another side, and runs through described another side to form carrying opening; And

Gas generation module, one side has air inlet, the side of described gas generation module has outlet, the part body of the corresponding described air inlet of described gas generation module is contained in described supporting part movably, and described air inlet correspondence is located in described carrying opening, one end vicinity of described outlet is at described second through hole;

Wherein, gas flow in described at least one passage via described first through hole, described accommodation space and described access portal, described gas generation module draws the gas in described at least one passage by described air inlet, to produce air-flow, and described outlet is utilized to discharge described air-flow to described feedway body exterior via described second through hole.

2. respiratory organ structure according to claim 1, is characterized in that, described bearing bed comprises:

First supporting substrate, is adjacent to described runner layer, and has described carrying opening; And

Second supporting substrate, be arranged on the one side of described first supporting substrate back to described runner layer, the center of described second supporting substrate has described supporting part.

3. respiratory organ structure according to claim 2, is characterized in that, the outer peripheral edge of described first supporting substrate is greater than the outer peripheral edge of described second supporting substrate.

4. respiratory organ structure according to claim 2, is characterized in that, the thickness of described first supporting substrate is less than the thickness of described second supporting substrate.

5. respiratory organ structure according to claim 1, is characterized in that, described gas supply device also comprises:

Multiple locating module is rod-like structure, and one end of each described locating module is connected to described inwall of described feedway body, and is looped around described shock-absorbing module; And

Shock-absorbing hides module, for shell structure, the periphery of described shock-absorbing covering module is removably connected to the other end of described multiple locating module, the one side that described shock-absorbing hides module caves inward formation shielding part, described shielding part has buffer layer, and described shock-absorbing hides the part outer rim of module by the coated described gas generation module of described buffer layer.

6. respiratory organ structure according to claim 1, is characterized in that, described gas supply device also comprises:

Gas transmission module, for hollow structure, described gas transmission module installation is at described second through hole, one end of described gas transmission module is removably connected to the described end of described outlet, the outside of described feedway body is exposed at outside the other end of described gas transmission module, and when described gas generation module produces described air-flow and utilizes described outlet to discharge described air-flow, described air-flow then flow to described feedway body exterior via described gas transmission module.

7. respiratory organ structure according to claim 6, is characterized in that, also comprises damping device, comprises:

Accommodation device body, is hollow housing structure, and has accommodation space, with accommodating liquid, the side of described accommodation device body has the first port, and the one side of described accommodation device body has the second port, and the pre-set level height of liquid is lower than described second port; And

Water conservancy diversion module, for tubular structure, and be located in described first port, one end of described water conservancy diversion module has input port, input port is positioned at the outside of described accommodation device body, and removably connects the other end of described gas transmission module, and the other end of described water conservancy diversion module has delivery outlet, delivery outlet is arranged in described accommodation space, and described delivery outlet is towards described of described accommodation device body;

Wherein, when described input port receives described air-flow, described air-flow then flow in described accommodation space via described delivery outlet, and with the dampness produced in conjunction with liquid, and the moist described air-flow of tool flow to the outside of described accommodation device body via described second port.

8. respiratory organ structure according to claim 7, is characterized in that, the one side of described accommodation device body has default angle with another side, and described default angle is between 20 ~ 30 degree.

9. respiratory organ structure according to claim 8, is characterized in that, described default angle is 25 degree.

10. respiratory organ structure according to claim 6, it is characterized in that, described gas supply device also comprises conduction device, for tubular structure, outside described conduction device, cave in gradually towards center in the contiguous two ends place of body, and one end of described conduction device is removably connected to the described outlet of described gas generation module, the other end of described conduction device is removably connected to the described end of described gas transmission module.

11. respiratory organ structures according to claim 10, it is characterized in that, the contiguous two ends place of described conduction device inwall forms buckling parts to outer wall respectively, described conduction device is fastened on the described end of described outlet and described gas transmission module respectively by each described buckling parts, to be communicated with the described end of described outlet and described gas transmission module.

12. respiratory organ structures according to claim 7, it is characterized in that, the outer peripheral edge, side of the described side of described accommodation device body stretches out formation extension, the part body of the described one side of the corresponding described accommodation device body of described extension has impenetrating mouth, described respiratory organ structure also comprises buckle device, and buckle device comprises:

Press component, the inside of one side outwardly forms press section, described press component can flexibly be arranged on described extension, and described press section is located in described impenetrating mouth, and the contiguous side place of described one side of described press component stretches out and forms at least one first buckle portion; And

Conjugative component, one end stretches out and forms at least one joint portion, and described at least one joint portion is removably combined in the another side of described press component, and the both sides of the other end of described conjugative component form the second buckle portion respectively to extension;

Wherein, corresponding described at least one first buckle portion, face, described side of described feedway body and described multiple second buckle portion have at least one first holding section and multiple second holding section respectively, and described buckle device is removably fastened on described at least one first holding section and described multiple second holding section by described at least one first buckling parts and described multiple second buckle portion, with in conjunction with described gas supply device and described damping device.

13. respiratory organ structures according to claim 12, it is characterized in that, described press section drives described at least one first buckle portion and described multiple second buckle portion to be moved to the second position by primary importance by natural compression, and when described gas supply device is by external force away from described damping device, described gas supply device is then separated with described damping device.